TW564548B - Semiconductor device and the manufacturing method thereof - Google Patents

Semiconductor device and the manufacturing method thereof Download PDF

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Publication number
TW564548B
TW564548B TW91111191A TW91111191A TW564548B TW 564548 B TW564548 B TW 564548B TW 91111191 A TW91111191 A TW 91111191A TW 91111191 A TW91111191 A TW 91111191A TW 564548 B TW564548 B TW 564548B
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Taiwan
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gate
region
insulating film
semiconductor device
aforementioned
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TW91111191A
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Chinese (zh)
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Masayuki Ichige
Yuji Takeuchi
Michiharu Matsui
Atsuhiro Sato
Kikuko Sugimae
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Toshiba Corp
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Abstract

The semiconductor device of the present invention includes: a semiconductor substrate; source and drain regions; a channel region; a gate insulating film; a charge storage layer; and a control gate electrode. The source and drain regions are formed on the semiconductor substrate, which include the first impurities of the first conductivity type. The channel region are formed on the semiconductor substrate between the source and drain regions, which includes the second impurities of a second conductivity type. The gate insulating film are formed on the semiconductor substrate, which includes the second impurities in a region thereof located immediately above at least a portion of the channel region. The charge storage layer is formed on the gate insulating film above the channel region. The control gate electrode is provided on the charge storage layer. The control gate electrode is formed on the charge storage layer, and is electrically connected to the charge storage layer by a connection portion provided on a part of the charge storage layer, which is located immediately above at least a part of the region of the gate insulating film including the second impurities.

Description

564548 A7 __B7 五、發明説明(!) 相關申請之交叉春老 此申請係依據2001年5月28日日本專利申請No. 2001· 15 8066、及2001年7月2日日本專利申請2001-201866號並要 求其優先權。其整體内容如下所示。 發明背景 1.發明領域 本發明係關於半導體裝置及其製造方法。尤其是和具有 在通道區域佈植雜質之電晶體的微細半導體裝置相關。 又,和NAND型快閃記憶體之列系核心部的構造相關。 近年來,可以實施資料之電性寫入及消除的非揮發性半 導體記憶體,以 EEPROM (Electrically Erasable and Programmable Read Only Memory、電可擦及可程式唯讀記 憶體)較有名。EEPROM中有可整體刪除之快閃記憶體。尤 其是容易被高積體化之NAND型快閃記憶體被廣泛使用。 習知之NAND型快閃記憶體的製造方法,例如,有S. Aritome 等人提出之 IEDM (1994) pp61-64,,A 0.67/zm2 SELF-ALIGNED SHALLOW TRENCH ISOLATION CELL (SA-STI CELL) FOR 3V-only 256 Mbit NAND EEPROMs”、及 Y· Takeuchi等人提出之 1998 Symposium on VLSI Technology Digest of Technical Papers,pp 102-103 ·’A Self-Aligned STI Process Integration for Low Cost and Highly Reliable 1 Gbit Flash Memories"等。依該提案,記憶胞間之元件隔離區域 係以STI(Shallow Trench Isolation、淺溝隔隔層)技術形成。 因此,為了使其對此元件隔離區域具有自我整合之構造 -5- 本紙張尺度適用中國國家標準(CNS) A4規格(210X 297公釐) 564548 A7 ----*----------- 五、發明説明(2 ) (SA-STI),而形成浮動閘極。利用此方式,可以實現高密 度配置微細記憶胞之記憶胞列。此種製造方法時,元件隔 離區域會在形成部份或全部問極氧化膜及浮動開極材料後 才形成…將雜質導入記憶胞及周邊控制系統使用之電 晶體的通道區域上’可在形成閘極氧化膜前佈植離子,然 後再形成閘極氧化膜。而導人之雜質的熱擴散係由其後之 兀件隔離區域形成步驟中的熱處理來執行,雜質會因此埶 擴散而活性化。 ” ~ 然而,NAND型快閃記憶體在記憶胞寫入「丨」資料(未 對浮動閘極佈植電子,保持刪除時之臨界值)時,位元線 會充電至起始電位。又,對選取之字元線施加窝入電壓, 對非選取之字元線施加傳送電壓。其次,利用電容耦合使 記憶胞電晶體之通道區域電位昇壓,使電子不會佈植於浮 動閘極。降低通道區域之雜質濃度會使通道電容降低,故 通道區域之電位容易昇壓。結果,提高對記憶胞之「i」 資料的窝入特性。 」 有鑑於前述窝入動作,有數種著眼於記憶胞電晶體之通 道區域雜質濃度控制的快閃記憶體製造方法被提出。例 如’日本特開2002-009173號公報之手法,係在依序形成 閘極氧化膜及元件隔離區域後,越過閘極氧化膜及浮動閘 極佈植離子。利用本手法,通道區域内之雜質濃度分布不 會受到元件隔離區域製造過程之熱步騾的影響。因此,可 以實現急速變化之雜質濃度分布。故,在推動通道長度之 微細化時’亦可確保通道區域内之雜質濃度的控制性。 -6- 564548564548 A7 __B7 V. Description of the Invention (!) Cross-Relaxation of Related Applications This application is based on Japanese Patent Application No. 2001 · 15 8066 on May 28, 2001, and Japanese Patent Application No. 2001-201866 on July 2, 2001. And claim its priority. The overall contents are shown below. BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a semiconductor device and a method for manufacturing the same. This is particularly relevant to a fine semiconductor device having a transistor in which an impurity is implanted in a channel region. It is also related to the structure of the core part of the NAND flash memory. In recent years, EEPROM (Electrically Erasable and Programmable Read Only Memory), which is a non-volatile semiconductor memory that can perform the electrical writing and erasing of data, is more famous. EEPROM contains flash memory that can be deleted in its entirety. In particular, NAND-type flash memory, which is easily accumulative, is widely used. Conventional NAND flash memory manufacturing methods, for example, IEDM (1994) pp61-64, A 0.67 / zm2 SELF-ALIGNED SHALLOW TRENCH ISOLATION CELL (SA-STI CELL) FOR 3V proposed by S. Aritome et al. -only 256 Mbit NAND EEPROMs ", and 1998 Symposium on VLSI Technology Digest of Technical Papers proposed by Y. Takeuchi et al., pp 102-103 · 'A Self-Aligned STI Process Integration for Low Cost and Highly Reliable 1 Gbit Flash Memories " According to the proposal, the element isolation area between the memory cells is formed by STI (Shallow Trench Isolation, Shallow Trench Isolation) technology. Therefore, in order to have a self-integrating structure for this element isolation area-5- This paper Standards are in accordance with China National Standard (CNS) A4 specifications (210X 297 mm) 564548 A7 ---- * ----------- V. Description of the invention (2) (SA-STI), forming a floating Gate. With this method, a high-density memory cell array with fine memory cells can be realized. In this manufacturing method, the element isolation area will be formed after forming part or all of the interlayer oxide film and floating open-electrode material ... Impurities The channel area of the transistor introduced into the memory cell and the peripheral control system can be implanted with ions before the gate oxide film is formed, and then the gate oxide film is formed. The thermal diffusion of the inductive impurities is followed by The heat treatment is performed in the step of forming the isolation region of the element, and the impurities will be activated due to the diffusion. "~ However, the NAND type flash memory writes" 丨 "data in the memory cell (the floating gate is not implanted with electrons, and it is maintained. When the threshold is deleted), the bit line will be charged to the starting potential. Further, a nesting voltage is applied to the selected word line, and a transmission voltage is applied to the non-selected word line. Secondly, the potential of the channel region of the memory cell transistor is boosted by capacitive coupling, so that the electrons will not be implanted on the floating gate. Reducing the impurity concentration in the channel region will reduce the channel capacitance, so the potential in the channel region is likely to be boosted. As a result, the incorporation characteristics of the "i" data of the memory cells are improved. In view of the aforementioned nesting actions, several flash memory manufacturing methods focusing on the control of the impurity concentration in the channel region of the memory cell crystal have been proposed. For example, in the method of JP-A-2002-009173, after a gate oxide film and a device isolation region are sequentially formed, ions are implanted across the gate oxide film and the floating gate. With this method, the impurity concentration distribution in the channel region is not affected by the thermal steps in the manufacturing process of the device isolation region. Therefore, a rapidly changing impurity concentration distribution can be achieved. Therefore, when the miniaturization of the channel length is promoted, the controllability of the impurity concentration in the channel region can be ensured. -6- 564548

又,美國專利申請10/058,343(對應日本專利申請編號: 曰本特願2001-23973號)中,則主要是針對NAND型快閃記 憶體的提案。亦即,係在記憶胞電晶體上形成遮罩後,從 斜向對相鄰之選擇電晶體間的雜質擴散層實施雜質之離子 佈植。利用此方法,記憶胞電晶體及選擇電晶體之通道區 域的雜質;辰度會維持相同,亦容易實施選擇電晶體之特性 控制。 其次,美國專利申請09/956,986(對應日本專利申請編 號:曰本特願2000-291910號)亦是針對NAND型快閃記憶體 的提案。亦即,在周邊控制系統電晶體及選擇電晶體之閘 極上,去除隔離浮動閘極及控制閘極之閘極絕緣膜的方 法。利用此方式,可以使浮動閘極及控制閘極獲得電性連 矣士 〇 、、、口 又,日本特開昭59-74677號公報中,如其圖4至圖11等 所示,周邊電晶體之浮動閘極及控制閘極間的絕緣膜上設 有開口部。結果,提高了配線設計之自由度。 如前面所述,以往就曾針對快閃記憶體之製造方法提出 各種提案。然而,在形成通道區域後,再形成元件隔離區 方法上,因通道區域内之雜質容易擴散,有時會阻礙 電晶體<通道長度微細化。因為,在通道區域之後尚有許 多熱步驟。此種現象在記憶胞電晶體之閘極長度小於〇. 2 μ m時特別明顯。 又’以不同步騾實施記憶胞電晶體通道部之離子佈植、 及實施選擇電晶體通道部之離子佈植的方法,隨著微細化Also, in US Patent Application No. 10 / 058,343 (corresponding to Japanese Patent Application No .: Japanese Patent Application No. 2001-23973), the proposal is mainly directed to a NAND flash memory. That is, after forming a mask on the memory cell transistor, the impurity diffusion layer between adjacent selected transistors is implanted with ions from an oblique direction. With this method, the impurities in the channel region of the cell transistor and the selected transistor are retained; the degree will remain the same, and it is easy to implement the characteristic control of the selected transistor. Secondly, U.S. Patent Application No. 09 / 956,986 (corresponding to Japanese Patent Application No .: 2000-291910) is also a proposal for NAND-type flash memory. That is, a method of removing the gate insulating film that isolates the floating gate and the control gate from the peripheral control system transistor and the gate of the selection transistor. In this way, the floating gate and the control gate can be electrically connected. In Japanese Patent Application Laid-Open No. 59-74677, as shown in FIG. 4 to FIG. 11 and the like, peripheral transistors are provided. An opening is provided on the insulating film between the floating gate and the control gate. As a result, the degree of freedom in wiring design is improved. As mentioned above, various proposals have been made in the past regarding the method of manufacturing flash memory. However, in the method of forming an element isolation region after forming the channel region, impurities in the channel region are likely to diffuse, which may hinder the miniaturization of the transistor < channel length. Because there are many thermal steps after the channel area. This phenomenon is particularly noticeable when the gate length of the memory cell crystal is less than 0.2 μm. In addition, the method of performing ion implantation of the channel portion of the memory cell in a non-synchronized manner and the method of ion implantation of the selected channel portion of the transistor are implemented.

564548 A7 B7 五、發明説明(4 ) 之推動而有其實施上的困難。此外,因石版印刷步騾增 加,而增加了製造步騾。例如,以選擇電晶體之通道長度 為0.3//m以下、記憶胞電晶體之通道長度為0.15# m以下之 微細化來形成高密度之記憶胞構件時,很難以前述方法來 實施。 然而5若同時形成記憶胞電晶體及選擇電晶體之通道區 域的雜質區域,則很難提高選擇電晶體之通道區域的雜質 濃度。結果,有時會使選擇電晶體之截止特性惡化。亦 即,選擇電晶體之通道區域的雜質濃度設定上,必須為可 滿足記憶胞電晶體必要之記憶胞特性的濃度。此雜質濃度 通常低於選擇電晶體之必要濃度。換言之,選擇電晶體之 通道區域的雜質濃度,不得不低於理想濃度。所以,選擇 電晶體之臨界值電壓會降低,待機漏電流會增加,而無法 正常動作。又,前述記憶胞特性係指,如資料儲存特性、 寫入刪除特性、以及寫入刪除特性之劣化程度。 然而,NAND型快閃記憶體EEPROM亦和DRAM(Dynamic Random Access Memory)或 SRAM (Static RAM)等之其他半 導體記憶體相同,以列解碼器選取1條字元線,執行選取 之記憶胞(頁)的寫入或讀取。列解碼器具有列主解碼器電 路及列系核心部(列輔助解碼器電路)。列主解碼器電路依 據列位址信號,產生必須施加於記憶胞列内之控制閘極線 及選擇閘極線的特定電壓。列系核心部具有列主解碼器電 路及記憶胞列間之開關的機能。 以圖1A及圖1B說明前述列系核心部之構成。圖1A係列 -8- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐) 564548 A7 ___ B7 五、發明説明(5 ) 系核心部之平面圖,圖1B為圖1A中之1Β·1Β線的剖面圖。 如圖所示,矽基板200上設有格狀之複數個活性區域ΑΑ (Active Area)。相鄰之活性區域ΑΑ間,設有元件隔離區域 STI。電性隔離之各活性區域AA内,分別形成傳輸閘極電 晶體TGTD、TGTS、TGT、TGT,…。這些傳輸閘極電晶 體TGTD、TGTS、TGT、TGT,…分別具有閘極TG及雜質 擴散層(圖上未標示)。閘極TG設置於活性區域AA上之閘 極絕緣膜210。同時,具有多晶矽膜220、以及藉由閘極間 絕緣膜230設於多晶矽膜220上之多晶矽膜240。又,多晶 矽膜220、240在活性區域AA上進行電性連結。其次,以 覆蓋述傳輸閘極電晶體TGTD、TGTS、TGT、TGT,…之 方式,設置層間絕緣膜260、280。 前述核心部中,設於同一列之活性區域AA上的傳輸閘 極電晶體TGTD、TGTS、TGT、TGT,…之閘極TG係共同 連結。而傳輸閘極電晶體TGTD、TGTS、TGT、TGT,… 之一側的雜質擴散層(汲極區域)則分別連結著汲極侧之選 擇閘極線SGD、源極侧之選擇閘極線SGS、及控制閘極線 CG、CG、…。亦即,選擇閘極線SGD、SGS、及控制閘極 線CG、CG、…係利用設置於層間絕緣膜260内之分流配線 290連結至核心部内。且,經由連結孔C20連結於對應之傳 輸閘極電晶體TGTD、TGTS、TGT、TGT,…的雜質擴散 層上。此外,經由金屬配線層300,對傳輸閘極電晶體 TGTD、TGTS、TGT、TGT,…之另一侧雜質擴散層(源極 區域),施加列主解碼器產生之特定電壓。 -9- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐) 564548 A7 B7 五、發明説明(6 ) 圖1C係圖1B之放大圖。如圖所示,沿著控制閘極線方 向、相鄰之活性區域AA間的區域,存在寄生MOS電晶 體。此寄生MOS電晶體係以多晶矽膜240做為閘極,而以 閘極絕緣膜230及元件隔離區域STI做為閘極絕緣膜。傳輸 閘極電晶體TGTD、TGTS、TGT、TGT,…為導通狀態 時,會對閘極TG施加高電壓Vpgm。此時,前述寄生MOS 電晶體有時會處於導通狀態。因此,元件隔離區域STI之 周邊會形成反轉區域CH。所以,夾著元件隔離區域STI相 鄰之活性區域AA間,有時會處於導通狀態。 又,傳輸閘極電晶體TGT之設計上,會避免使同一列内 之導通狀態的傳輸閘極電晶體TGT、及斷開狀態的傳輸閘 極電晶體TGT相鄰。換言之,連結於同一列内之傳輸閘極 電晶體TGT之控制閘極線的設計上,不會產生控制閘極線 之選取及非選取狀態相鄰的情形。其理由在於,尤其是寫 入時,會對選取之傳輸閘極電晶體TGT的活性區域AA(雜 質擴散層)施加高電壓Vpgm。相對於此,對非選取之傳輸 閘極電晶體TGT活性區域AA則施加0 V。如上面所述,當 相鄰接之活性區域AA間的電位差變大時,就無法維持該 活性區域AA間之絕緣。 然而,若選擇閘門線SGD或SGS連結之傳輸閘極電晶體 TGTD、TGTS、以及控制閘極線CG連結之傳輸閘極電晶體 TGT設於同一列内時,兩者之間實在很難避免發生選取· 非選取之關係。 參閱圖1C針對此狀態進行說明。如圖所示,連結於選 -10- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐)564548 A7 B7 V. The invention (4) has its implementation difficulties. In addition, the increase in lithographic printing steps has increased the manufacturing steps. For example, it is difficult to implement a high-density memory cell structure by selecting a miniaturization with a channel length of 0.3 // m or less and a channel length of 0.15 # m or less for a memory cell transistor. However, if the impurity region of the memory cell transistor and the channel region of the selected transistor is formed at the same time, it is difficult to increase the impurity concentration of the channel region of the selected transistor. As a result, the cut-off characteristics of the selected transistor may be deteriorated. That is, the impurity concentration of the channel region of the selected transistor must be set to a concentration that can satisfy the characteristics of the memory cell necessary for the memory cell transistor. This impurity concentration is usually lower than the concentration necessary to select a transistor. In other words, the impurity concentration of the channel region of the transistor must be lower than the ideal concentration. Therefore, the threshold voltage of the selected transistor will decrease, and the standby leakage current will increase, which will prevent normal operation. In addition, the aforementioned memory cell characteristics refer to, for example, the degree of deterioration of data storage characteristics, write-delete characteristics, and write-delete characteristics. However, NAND-type flash memory EEPROM is also the same as other semiconductor memories such as DRAM (Dynamic Random Access Memory) or SRAM (Static RAM). A row decoder selects a word line and executes the selected memory cell (page ) Write or read. The column decoder includes a column main decoder circuit and a column system core (column auxiliary decoder circuit). The column main decoder circuit generates a specific voltage for controlling the gate line and selecting the gate line in the memory cell according to the column address signal. The core of the line system has the function of a switch between the line main decoder circuit and the memory cell line. The structure of the above-mentioned core system will be described with reference to Figs. 1A and 1B. Figure 1A series-8- This paper size applies Chinese National Standard (CNS) A4 specification (210 X 297 mm) 564548 A7 ___ B7 V. Description of the invention (5) is a plan view of the core part, Figure 1B is 1B in Figure 1A · Sectional view of line 1B. As shown in the figure, the silicon substrate 200 is provided with a plurality of grid-shaped active areas AA (Active Area). Between adjacent active regions AA, a device isolation region STI is provided. In each of the active regions AA which are electrically isolated, transmission gate transistors TGTD, TGTS, TGT, TGT, ... are formed, respectively. These transmission gate electric crystals TGTD, TGTS, TGT, TGT, ... each have a gate TG and an impurity diffusion layer (not shown in the figure). The gate electrode TG is provided on the gate insulating film 210 on the active area AA. At the same time, it has a polycrystalline silicon film 220 and a polycrystalline silicon film 240 provided on the polycrystalline silicon film 220 via an inter-gate insulating film 230. The polycrystalline silicon films 220 and 240 are electrically connected to the active region AA. Next, interlayer insulating films 260, 280 are provided so as to cover the transmission gate transistors TGTD, TGTS, TGT, TGT, .... In the aforementioned core part, the gate TGs of the transmission gate transistors TGTD, TGTS, TGT, TGT, ... on the active area AA in the same row are connected together. The impurity diffusion layer (drain region) on one side of the transmission gate transistor TGTD, TGTS, TGT, TGT, ... is connected to the selection gate line SGD on the drain side and the selection gate line SGS on the source side, respectively. , And control gate lines CG, CG, .... That is, the selected gate lines SGD, SGS, and the control gate lines CG, CG, ... are connected to the core portion by a shunt wiring 290 provided in the interlayer insulating film 260. And, it is connected to the impurity diffusion layers of the corresponding transmission gate transistors TGTD, TGTS, TGT, TGT, ... via the connection hole C20. In addition, a specific voltage generated by the column main decoder is applied to the other impurity diffusion layer (source region) on the other side of the transmission gate transistors TGTD, TGTS, TGT, TGT, ... via the metal wiring layer 300. -9- This paper size is in accordance with Chinese National Standard (CNS) A4 (210 X 297 mm) 564548 A7 B7 V. Description of the invention (6) Figure 1C is an enlarged view of Figure 1B. As shown in the figure, a parasitic MOS transistor exists in the area between the adjacent active areas AA along the direction of the control gate line. In this parasitic MOS transistor system, a polycrystalline silicon film 240 is used as a gate, and a gate insulating film 230 and an element isolation region STI are used as gate insulating films. Transmission When the gate transistors TGTD, TGTS, TGT, TGT, ... are on, a high voltage Vpgm is applied to the gate TG. At this time, the aforementioned parasitic MOS transistor may be in an on state. Therefore, an inversion region CH is formed around the element isolation region STI. Therefore, the active region AA adjacent to the device isolation region STI may be turned on in some cases. In addition, the design of the transmission gate transistor TGT avoids that the on-state transmission gate transistor TGT and the off-state transmission gate transistor TGT in the same column are prevented from being adjacent to each other. In other words, the design of the control gate lines of the transmission gate transistors TGT connected in the same row will not cause the selection and non-selection of the control gate lines to be adjacent. The reason is that, especially when writing, a high voltage Vpgm is applied to the active region AA (heterodiffusion layer) of the selected transmission gate transistor TGT. In contrast, 0 V is applied to the non-selected transmission gate transistor TGT active region AA. As described above, when the potential difference between adjacent active regions AA becomes large, the insulation between the active regions AA cannot be maintained. However, if the transmission gate transistors TGTD and TGTS connected to the gate line SGD or SGS and the transmission gate transistor TGT connected to the control gate line CG are set in the same row, it is difficult to avoid the occurrence of the two. Selection and non-selection relationship. This state is described with reference to FIG. 1C. As shown in the figure, linked to the selection -10- This paper size applies the Chinese National Standard (CNS) A4 specification (210 X 297 mm)

裝 訂 t 564548 A7 B7 五、發明説明(7 ) 取之控制閘極線CG的傳輸閘極電晶體TGT、及連結於非選 取之選擇閘門線SGD的傳輸閘極電晶體TGTD會在同一列 内相鄰接。此時,夹著元件隔離區域STI,兩活性區域 AA、AA之電位分別為高電位Vpgm、接地電位GND。又, 元件隔離區域STI上,存在為閘極TG之一部份的多晶矽膜 240。會對多晶矽膜240,施加使傳輸閘極電晶體TGTD、 TGT成為導通狀態之高電壓Vpgm。如此,活性區域AA、 AA間之電位差將會超過元件隔離區域STI之元件隔離耐 壓。結果,元件隔離區域STI有時就無法維持活性區域 AA、AA間之電性絕緣。 為了解決前述元件隔離之相關問題,可以採取的方法, 為擴大沿著控制閘極線CG方向之元件隔離區域STI的寬度 dlO (參照圖1A)。然而,在控制閘極線方向,傳輸閘極電 晶體TGT及傳輸閘極電晶體TGTD、TGTS會以隨機方式出 現相鄰的情形。因此,為了解決前述問題,必須擴大整個 核心部區域之元件隔離區域STI的寬度dlO。如此一來,核 心部的面積會變大,而無法獲得NAND型快閃記憶體 EEPROM之小型化。 發明之摘要 依據本發明之半導體裝置,係含有: 半導體基板; 形成於前述半導體基板中,含有第1導電電型之第1雜質 的源極•沒極區域; 形成於前述源極•汲極區域間之前述半導體基板中,含 -11- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐) 564548 A7 B7 8 五、發明説明( 有第2導電型之第2雜質的通道區域; 形成於前述半導體基板上,至少在前述通道區域之部份 區域的正上方區域含有第2雜質之閘極絕緣膜; 形成於前述通道區域上方之閘極絕緣膜上的電荷蓄積 層;以及 設於前述電荷蓄積層上之控制閘極,此控制閘極係利用 设於則述電荷蓄積層上之連結部和前述電荷蓄積層實施電 性連結’而前述電荷蓄積層係至少位於含有第2雜質之閘 極絕緣膜區域中部份區域的正上方。 依據本發明之另一半導體裝置,係含有: 以元件隔離區域互相電性隔離,且含有沿著第1方向設 置之複數活性區域的第1活性區域群; 以元件隔離區域互相電性隔離,且含有沿著第丨方向之 垂直方向設置之複數前述活性區域的第2活性區域群;以及 分別設置於前述活性區域之MOS電晶體; 遠MOS電晶體具有··複數之前述第j活性區域群間共同 連結之閘極;連結於記憶胞之控制閘極及選擇M〇s電晶體 <選擇閘極中其一的第丨雜質擴散層;以及由承受列解碼 器提供之電壓的第2雜質擴散層;此選擇閘極上連結之前 述MOS電晶體,只設置於前述第2活性區域群内之端部的 前述活性區域内,含有此選擇閘極上連結之M〇s電晶體的 前述第1活性區域群、以及相鄰之前述第丨活性區域AA群 間的7C件隔離區域寬度,大於只含有連結於控制閘極之 MOS電晶體的前述第i活性區域群間的元件隔離區域寬 -12- 本紙張尺度適用巾@ a家標準(CNS) A4規格(⑽X 29?公爱) 564548Binding t 564548 A7 B7 V. Description of the invention (7) The transmission gate transistor TGT, which controls the gate line CG, and the transmission gate transistor TGTD, which is connected to the non-selected selection gate line SGD, will be phased in the same row. Adjacency. At this time, sandwiching the element isolation region STI, the potentials of the two active regions AA and AA are the high potential Vpgm and the ground potential GND, respectively. Also, a polycrystalline silicon film 240 is formed on the element isolation region STI as a part of the gate TG. A high voltage Vpgm is applied to the polycrystalline silicon film 240 to make the transfer gate transistors TGTD and TGT into an on state. In this way, the potential difference between the active regions AA and AA will exceed the element isolation withstand voltage of the element isolation region STI. As a result, the element isolation region STI sometimes cannot maintain electrical insulation between the active regions AA and AA. In order to solve the aforementioned problems related to the isolation of the components, a method that can be adopted is to increase the width d10 of the element isolation region STI along the direction of the control gate line CG (see FIG. 1A). However, in controlling the direction of the gate line, the transmission gate transistor TGT and the transmission gate transistors TGTD and TGTS may appear adjacent to each other in a random manner. Therefore, in order to solve the foregoing problem, it is necessary to increase the width d10 of the element isolation region STI in the entire core region. As a result, the area of the core portion becomes larger, and the miniaturization of the NAND-type flash memory EEPROM cannot be obtained. SUMMARY OF THE INVENTION A semiconductor device according to the present invention includes: a semiconductor substrate; a source / non-electrode region formed in the aforementioned semiconductor substrate and containing a first impurity of a first conductivity type; and formed in the aforementioned source / drain region Among the aforementioned semiconductor substrates, there are -11- This paper size applies to the Chinese National Standard (CNS) A4 specification (210 X 297 mm) 564548 A7 B7 8 V. Description of the invention (the channel with the second impurity of the second conductivity type) A region; a gate insulating film containing a second impurity at least in a region directly above a portion of the channel region; a charge storage layer formed on the gate insulating film above the channel region; and The control gate provided on the charge storage layer is electrically connected by the connection portion provided on the charge storage layer and the charge storage layer, and the charge storage layer is located at least in the second place. The gate insulating film region of the impurity is directly above a part of the region. Another semiconductor device according to the present invention includes: an element isolation region is electrically isolated from each other; And a first active region group including a plurality of active regions disposed along the first direction; a second active region electrically isolated from each other by an element isolation region and including a plurality of the foregoing active regions disposed in a vertical direction along the first direction Groups; and MOS transistors provided in the aforementioned active regions, respectively; far MOS transistors having a plurality of gates connected in common to the aforementioned j-th active region groups; control gates connected to the memory cells and selection of MOS transistors The crystal < selects the first impurity diffusion layer of the gate; and the second impurity diffusion layer which bears the voltage provided by the column decoder; the aforementioned MOS transistor connected to the selected gate is provided only in the aforementioned second activity The width of the 7C element isolation region between the first active region group including the Mos transistor connected to the selection gate and the adjacent first active region AA group in the active region at the end of the region group. It is larger than the element isolation region between the i-th active region group containing only the MOS transistor connected to the control gate. -12- This paper size is suitable for towel @ a 家 标准 (CNS) A4 specification (⑽X 29? Public love) 564548

度。 依據本發明之另一半導體裝置的製造方法,係含有: 對半導體基板表面佈植第1濃度之第1導電型雜質; 在如述半導體基板表面形成閘極絕緣膜; 在前述閘極絕緣膜形成電荷蓄積層; 在前述半導體基板中及前述閘極絕緣膜中形成元件隔離 區域; 在前述元件隔離區域及前述電荷蓄積層上形成閘極間絕 緣膜; 在前述閘極間絕緣膜上形成具有至少露出部份前述閘極 間絕緣膜表面之開口部的遮罩材; 經由前述遮罩材之開口部,對前述半導體基板中佈植第 1導電型雜質,其濃度為高於前述第1濃度之第2濃度\ 在前述閘極間絕緣膜上形成控制閘極,此控制閘極經由 訂 已除去前述閘極間絕緣膜之區域和前述電荷蓄積層相連 結; 以前述電荷蓄積層、前述閘極間絕緣膜、及前述控制閘 極之圖案化來形成層積閘極;以及 對前述閘極周圍之前述半導體基板中佈植第2導電型雜 質’形成源極•沒極區域。 周面之簡單說昍 圖1A係習知之NAND型快閃記憶體的平面圖,· 圖1B係圖1A之1B-1B線的剖面圖; 圖1C係圖1B之放大圖; ___«13· 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公一 564548 A7 B7 五、發明説明(1〇 ) 圖2 A係本發明之第1實施形態快閃記憶體的剖面圖; 圖2B係具有本發明第1實施形態之快閃記憶體的選擇電 晶體之通道區域雜質濃度分布圖; 圖3 A係本發明第1實施形態之NAND型快閃記憶體的電 路圖; 圖3B係本發明第1實施形態之NAND型快閃記憶體的平 面圖; 圖3C係圖3B之3C_3C線的剖面圖; 圖3D係含有本發明第1實施形態NAND型快閃記憶體之 選擇電晶體及記憶胞電晶體,相對於通道長度之臨界值電 壓的變化圖; 圖4A、圖4B至圖15A、圖UB係本發明第1實施形態之 NAND型快閃記憶體的製造步騾剖面圖; 圖16A及圖16B係本發明第1實施形態第1變形例之NAND 型快閃記憶體的製造步騾剖面圖; 圖16C及圖16D係本發明第1實施形態第2變形例之NAND 型快閃記憶體的製造步驟剖面圖; 圖17係本發明第1實施形態第3變形例之NAND型快閃記 憶體的製造步騾剖面圖; 圖18係本發明第2實施形態之NAND型快閃記憶體的電路 Γ5Ϊ · 圔, 圖19A係本發明第3實施形態之NAND型快閃記憶體部份 内部構成的方塊圖, 圖19B係具有本發明第3實施形態之NAND型快閃記憶體 -14- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐) 564548 A7 B7 五、發明説明(Ή ) 的記憶胞列及列系核心部電路圖; 圖19C係具有本發明第3實施形態之NAND型快閃記憶體 的記憶胞列及列系核心部平面圖; 圖19D係圖19C之19D_19D線的剖面圖; 圖19E係圖19C之19E-19E線的剖面圖; 圖19F係圖19C之19F-19F線的剖面圖; 圖19G係圖19C之19G-19G線的剖面圖; 圖20係本發明第3實施形態NAND型快閃記憶體之寫入、 讀取、及刪除動作時的各電晶體閘極電壓關係圖; 圖21A係具有本發明第3實施形態之NAND型快閃記憶體 的記憶胞列及列系核心部平面圖; 圖21B係圖21A之21B-21B線的剖面圖; 圖22A係具有本發明第4實施形態之NAND型快閃記憶體 的列系核心部平面圖; 圖22B係圖22A之22B-22B線的剖面圖; 圖22C係圖22A之22C-22C線的剖面圖; 圖23A係具有本發明第5實施形態之NAND型快閃記憶體 的列系核心部平面圖; 圖23B係圖23A之23B_23B線的剖面圖; 圖24係具有本發明第6實施形態之NAND型快閃記憶體的 列系核心部平面圖;及 圖25係具有本發明第7實施形態之NAND型快閃記憶體的 列系核心部平面圖。 發明之詳細說明 -15- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐) 564548 A7degree. According to another method of manufacturing a semiconductor device according to the present invention, the method includes: implanting a first-conductivity impurity having a first concentration on a surface of a semiconductor substrate; forming a gate insulating film on the surface of the semiconductor substrate as described above; and forming the gate insulating film on the surface of the semiconductor substrate A charge storage layer; forming an element isolation region in the semiconductor substrate and the gate insulation film; forming an inter-gate insulation film on the element isolation region and the charge storage layer; forming at least one inter-gate insulation film A part of the masking material on the opening of the surface of the insulating film between the gates is exposed; the first conductive type impurity is implanted in the semiconductor substrate through the opening of the masking material, and its concentration is higher than that of the first concentration. 2nd concentration \ A control gate is formed on the inter-gate insulation film, and the control gate is connected to the charge storage layer through a region in which the inter-gate insulation film has been removed; the charge storage layer and the gate are connected to each other; An interlayer insulating film and the control gate are patterned to form a laminated gate; and a second semiconductor substrate is planted in the semiconductor substrate around the gate. The conductive impurity ′ forms a source / impulse region. Brief description of the surface: Figure 1A is a plan view of a conventional NAND flash memory, Figure 1B is a cross-sectional view of line 1B-1B of Figure 1A, and Figure 1C is an enlarged view of Figure 1B; ___ «13 · This paper The dimensions are applicable to the Chinese National Standard (CNS) A4 specification (210 X 297 public 564548 A7 B7 V. Description of the invention (10) Figure 2 A is a cross-sectional view of a flash memory according to the first embodiment of the present invention; Figure 2B is provided with The impurity concentration distribution in the channel region of the selection transistor of the flash memory according to the first embodiment of the present invention; FIG. 3 A is a circuit diagram of the NAND flash memory according to the first embodiment of the present invention; FIG. 3B is the first embodiment of the present invention. A plan view of a NAND-type flash memory according to an embodiment; FIG. 3C is a cross-sectional view taken along line 3C_3C of FIG. 3B; FIG. 3D is a selection transistor and a memory cell including a NAND-type flash memory according to the first embodiment of the present invention. FIG. 4A, FIG. 4B to FIG. 15A, and FIG. UB are cross-sectional views of manufacturing steps of a NAND flash memory according to the first embodiment of the present invention; FIG. 16A and FIG. 16B are NAND-type flash memory according to the first modification of the first embodiment of the present invention 16C and 16D are cross-sectional views showing the steps of manufacturing a NAND flash memory according to the second modification of the first embodiment of the present invention; and FIG. 17 is a NAND view of the third modification of the first embodiment of the present invention. Fig. 18 is a circuit diagram of a NAND-type flash memory according to the second embodiment of the present invention, and Fig. 19A is a NAND-type flash memory according to the third embodiment of the present invention. A block diagram of part of the internal structure, FIG. 19B is a NAND-type flash memory with the third embodiment of the present invention. 14- This paper size is applicable to China National Standard (CNS) A4 specification (210 X 297 mm) 564548 A7 B7 5. Circuit diagram of the core of the memory cell and column system of the description of the invention (;); FIG. 19C is a plan view of the core of the memory cell and column system of the NAND flash memory according to the third embodiment of the present invention; 19C is a sectional view taken on line 19D_19D; FIG. 19E is a sectional view taken on line 19E-19E of FIG. 19C; FIG. 19F is a sectional view taken on line 19F-19F of FIG. 19C; FIG. 19G is a sectional view taken on line 19G-19G of FIG. 19C; FIG. 20 shows the writing and writing of a NAND flash memory according to the third embodiment of the present invention. FIG. 21A is a plan view of a memory cell array and a core system of a NAND flash memory according to a third embodiment of the present invention, and FIG. 21B is a plan view of a core portion of the transistor gate voltage during the operation of fetching and deleting. A cross-sectional view taken along line 21B-21B; FIG. 22A is a plan view of a core portion of a row system having a NAND flash memory according to a fourth embodiment of the present invention; FIG. 22B is a cross-sectional view taken along line 22B-22B of FIG. 22A; A sectional view taken along line 22C-22C of FIG. 22A; FIG. 23A is a plan view of a core portion of a column system having a NAND flash memory according to a fifth embodiment of the present invention; FIG. 23B is a sectional view taken along line 23B_23B of FIG. 23A; FIG. 25 is a plan view of a core system of a column system of a NAND type flash memory according to a sixth embodiment of the present invention; and FIG. 25 is a plan view of a core system of a column system of a NAND type flash memory according to the seventh embodiment of the present invention. Detailed description of the invention -15- This paper size applies to China National Standard (CNS) A4 (210 X 297 mm) 564548 A7

564548564548

且至少涵蓋開口部16之正下方區域的方式,形成通道擴散 層19。通道擴散層18具有和記憶胞電晶體2之通道擴散層 U相同的雜質濃度。且通道擴散層18在半導體基板丨之垂 直方向上,和通道擴散層丨丨具有相同之擴散分布。通道擴 散層19之形成上,具有比通道擴散層18更高的雜質濃度, 且比通運擴散層18更深。選擇電晶體3之閘極13的高度, 大致和、記憶胞電晶體2之閘極7相同。閘極間絕緣膜9係由 如矽氧化膜、矽氮化膜、以及矽氧化膜之層積膜〇N〇 (Oxide-Nitride-Oxide)膜所構成。此構成上,選擇電晶體3 可從外部對電荷蓄積層14提供電位。亦即,選擇電晶體3 具有一般MOSFET之機能。又,此層積閘極構造上,除了 具有開口部16以外,其餘和記憶胞電晶體2相同。 又,本實施形態應用於快閃記憶體時,通常,記憶胞電 晶體2之閘極7的長度、及源極•汲極區域4、5所夾之通道 區域的長度,會小於選擇電晶體3之閘極13的長度、及源 極•汲極區域5、12所夾之通道區域的長度。當然,因為 製品規格的緣故,選擇電晶體3之通道長度有時會小於記 憶胞電晶體2之通道長度。亦即,記憶胞電晶體2之閘極7 的長度亦可能大於選擇電晶體3之閘極13。又,因為製品 規格的緣故,選擇電晶體3之通道長度亦可能等於記憶胞 電晶體2之通道長度。 此外,開口部16之大小約為選擇電晶體3之閘極13長度 的一半。例如,若閘極13之長度約為0.3 ,則開口部16 之長度約為0.15//m左右。又,若記憶胞電晶體2之閘極7 -17- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐) 564548 A7 B7 五、發明説明(14 ) 長度例如為約0.15 // m時,則其通道長度約為0 · 15 // m,則 選擇電晶體3之通道區域整體的長度約為0.3 //m。如上面 所述,記憶胞電晶體2之通道區域11長度會小於選擇電晶 體3之通道擴散層18及通道擴散層19之長度和。 又’選擇電晶體3之通道擴散層19的長度,可以控制開 口部16之長度方式來改變。而且,經由開口部16佈植於間 極13下方之離子量,可以和記憶胞電晶體2分開控制,故 可自由設定選擇電晶體3之通道擴散層的濃度。選擇電晶 體3通道部的雜質濃度為,例如程度。 圖2B係圖2 A所選擇電晶體3之通道區域的p型雜質濃 度分佈。如圖所示,雜質濃度之分佈上,係以開口部16正 下方之區域’亦即,含有通道區域中央部之區域為最大 值。 如上面所述,利用本實施形態之半導體裝置,可實現間 極長度為0 · 15 # m以下之記憶胞電晶體。更可實現閘極長 度為0.3 以下之選擇電晶體。結果,可提供比以往更微 細化之半導體記憶裝置。又,追求前述微細化之同時,亦 可提升選擇電晶體之截止特性。因此,實現臨界值電壓之 通道長度依存性不同的選擇電晶體及記憶胞電晶體。又, 圖2中各電晶體2、3之各雜質區域4、5、11、12、18、19 亦可形成於設在半導體基板1表面附近之凹部區域中。 圖3 A係使用圖2所示半導體裝置之NAND型快閃記憶體 記憶胞列的電路圖。圖3A中之非揮發性記憶胞MC,和圖2 之記憶胞電晶體2具有相同之構造。又,圖3A之選擇電晶 -18- 564548 A7 B7 五、發明説明(15 ) 體ST1、ST2,和圖2之選擇電晶體3具有相同之構造。 如圖所示,記憶胞列具有複數之記憶塊MB (NAND胞)。 記憶塊MB含有η個(η為自然數)之記憶胞MC、MC.....汲 極側選擇電晶體ST1、及源極侧選擇電晶體ST2。記憶胞 MC、MC、…之相鄰者會共用源極、汲極,其電流路徑則 為串聯。選擇電晶體ST1連結於串聯之記憶胞MC電流路徑 的一端,(汲極侧),選擇電晶體ST2則連結於另一端(源極 侧)。 各記憶胞MC之閘極則分別連結著控制閘極線 CG1〜CGn(字元線WL1〜WLn)。汲極侧選擇電晶體ST1之閘 極上,連結著選擇閘極線SGD,源極選擇電晶體ST2之閘 極則連結著選擇閘極線SGS。 各記憶塊MB内之選擇電晶體ST1的源極,分別連結著資 料線之位元線BL1〜BLm (m為自然數)。源極選擇電晶體 ST2之源極則連接著共用源極線SL。 圖上未標示,複數個記憶塊MB係沿著位元線BL1〜BLm 之方向配置,各位元線BL1〜BLm上連結著複數個記憶塊 MB。另外,沿著控制閘極線CG1〜CGn之方向,各位元線 BL1〜BLm亦設有相同之記憶塊MB。 此外,不一定需要選擇電晶體ST1、ST2之雙方。只要 可選取記憶塊MB,則亦可只設置其中一方。 其次,以圖3B說明前述記憶胞列之平面構造。圖3B係 圖3A所示記憶胞列之平面圖。 如圖所示,複數之活性區域21、21、…係為線條狀平行 -19- 本紙張尺度適用中國國家標準(CNS) A4規格(210X 297公釐) 564548 A7 B7The channel diffusion layer 19 is formed so as to cover at least the area directly below the opening 16. The channel diffusion layer 18 has the same impurity concentration as the channel diffusion layer U of the memory cell crystal 2. And the channel diffusion layer 18 has the same diffusion distribution in the vertical direction of the semiconductor substrate as the channel diffusion layer. The channel diffusion layer 19 is formed to have a higher impurity concentration than the channel diffusion layer 18 and is deeper than the transport diffusion layer 18. The height of the gate 13 of the transistor 3 is selected to be substantially the same as that of the gate 7 of the memory cell 2. The gate-to-gate insulating film 9 is composed of a laminated film such as a silicon oxide film, a silicon nitride film, and a silicon oxide film (Oxide-Nitride-Oxide) film. In this configuration, the selection transistor 3 can supply a potential to the charge storage layer 14 from the outside. That is, the selection transistor 3 has the function of a general MOSFET. The laminated gate structure is the same as the memory cell 2 except that it has an opening portion 16. In addition, when this embodiment is applied to a flash memory, generally, the length of the gate 7 of the memory cell 2 and the length of the channel region sandwiched by the source and drain regions 4 and 5 are smaller than those of the selected transistor. The length of the gate 13 of 3 and the length of the channel region sandwiched by the source and drain regions 5 and 12. Of course, because of product specifications, the channel length of transistor 3 is sometimes smaller than the channel length of memory cell 2. That is, the length of the gate 7 of the memory cell 2 may be larger than that of the gate 13 of the selection transistor 3. In addition, because of product specifications, the channel length of transistor 3 may also be equal to the channel length of memory cell 2. The size of the opening 16 is about half the length of the gate electrode 13 of the selection transistor 3. For example, if the length of the gate electrode 13 is about 0.3, the length of the opening 16 is about 0.15 // m. In addition, if the gate electrode 7 of the memory cell 2 is -17- This paper size applies the Chinese National Standard (CNS) A4 specification (210 X 297 mm) 564548 A7 B7 V. Description of the invention (14) The length is, for example, about 0.15 / / m, the channel length is approximately 0 · 15 // m, and the overall channel area of transistor 3 is approximately 0.3 // m. As described above, the length of the channel region 11 of the memory cell 2 will be smaller than the sum of the lengths of the channel diffusion layer 18 and the channel diffusion layer 19 of the selection transistor 3. Also, the length of the channel diffusion layer 19 of the transistor 3 can be selected, and the length of the opening portion 16 can be controlled to change. In addition, the amount of ions implanted under the electrode 13 through the opening 16 can be controlled separately from the memory cell 2, so the concentration of the channel diffusion layer of the transistor 3 can be freely set. The impurity concentration of the channel portion of the electric crystal is selected to be, for example, a degree. Fig. 2B shows the p-type impurity concentration distribution in the channel region of the transistor 3 selected in Fig. 2A. As shown in the figure, the distribution of the impurity concentration is based on a region 'directly below the opening portion 16, that is, a region including the central portion of the channel region as the maximum value. As described above, the semiconductor device of this embodiment can realize a memory cell crystal having an electrode length of 0. 15 # m or less. Selective transistors with a gate length of 0.3 or less can be realized. As a result, a more compact semiconductor memory device can be provided than before. In addition to pursuing the aforementioned miniaturization, the cut-off characteristics of selected transistors can also be improved. Therefore, the selection transistor and the memory cell transistor with different channel length dependence of the threshold voltage are realized. In addition, the impurity regions 4, 5, 11, 12, 18, and 19 of the transistors 2 and 3 in FIG. 2 may be formed in a recessed region provided near the surface of the semiconductor substrate 1. FIG. 3A is a circuit diagram of a NAND-type flash memory memory cell using the semiconductor device shown in FIG. 2. FIG. The non-volatile memory cell MC in FIG. 3A has the same structure as the memory cell transistor 2 in FIG. 2. In addition, the selection transistor of FIG. 3A -18- 564548 A7 B7 V. Description of the invention (15) The bodies ST1 and ST2 have the same structure as the selection transistor 3 of FIG. 2. As shown in the figure, the memory cell array has a plurality of memory blocks MB (NAND cells). The memory block MB contains n (n is a natural number) memory cells MC, MC ..... the drain-side selection transistor ST1 and the source-side selection transistor ST2. The neighbors of the memory cells MC, MC, ... will share the source and sink, and their current paths are connected in series. The selection transistor ST1 is connected to one end (the drain side) of the series-connected memory cell MC current path, and the selection transistor ST2 is connected to the other end (the source side). The gates of each memory cell MC are connected to control gate lines CG1 to CGn (character lines WL1 to WLn). The gate of the drain-side selection transistor ST1 is connected to the selection gate line SGD, and the gate of the source selection transistor ST2 is connected to the selection gate line SGS. The source of the selection transistor ST1 in each memory block MB is connected to the bit lines BL1 to BLm of the data line (m is a natural number). The source of the source selection transistor ST2 is connected to the common source line SL. Not shown in the figure, the plurality of memory blocks MB are arranged along the bit lines BL1 to BLm, and each of the element lines BL1 to BLm is connected to the plurality of memory blocks MB. In addition, along the direction of the control gate lines CG1 to CGn, each element line BL1 to BLm is also provided with the same memory block MB. It is not necessary to select both of the transistors ST1 and ST2. As long as the memory block MB can be selected, only one of them can be set. Next, the planar structure of the aforementioned memory cell array will be described with reference to FIG. 3B. Fig. 3B is a plan view of the memory cell array shown in Fig. 3A. As shown in the figure, the plural active areas 21, 21, ... are parallel in a line shape. -19- This paper size applies the Chinese National Standard (CNS) A4 specification (210X 297 mm) 564548 A7 B7

五、發明説明(16 ) 汲極區域。又,各活性區5. Description of the invention (16) Drain region. Also, each active area

配置。活性區域21内形成源極· 域21間設有 7、7係為線 相交。又, ST1、ST2的閘極13、13,且和記憶胞!^之閘極7平行。 選擇電晶體STI、ST2之閘極13、 近,設有圖2說明之開口部16。名 圖3B中,對半導體基板中之區域2〇佈植雜質。此區域川 之一部,份,具有記憶胞電晶體2之通道區域機能。此外, 、及活性區域21的交點附 從此開口部16將雜質佈植 至矽基板中。此佈植雜質之區域,具有選擇電晶體STi、 ST2之通道區域機能。其雜質濃度不同於記憶胞電晶體之 通道區域。 各記憶胞MC、MC、…之源極及汲極,相鄰者採共同連 結。如上面所述,複數之記憶胞MC、MC、···採串聯之電 流路徑,故形成一個記憶塊(nand胞)。 其次’針對前述記憶胞列之剖面構造進行說明。圖2A 相S於圖3B之2·2線的剖面圖。所以,省略2_2線方向之剖 面構造的說明。圖3C係圖3Β之3C-3C線的剖面圖,也是選 擇電晶體S Τ1之剖面構造。 如圖所示,複數之元件隔離區域22設於半導體基板1 中’其上部突出半導體基板1表面。元件隔離區域22間之 半導體基板1的表面會形成通道擴散層19。通道擴散層19 上形成閘極絕緣膜6。閘極絕緣膜6之材料為氧化矽膜或氮 氧化合物膜中之其一。閘極絕緣膜6上設有電荷蓄積層 本紙張尺度適财國S家標準(CNS) Α4規格(210 X 297公釐) 564548 A7 B7 五、發明説明(17 ) 14,其上面會高於元件隔離區域22之上面。電荷蓄積層14 及元件隔離區域22之上面,會形成閘極間絕緣膜15。閘極 間絕緣膜15上形成控制閘極17。選擇電晶體ST1、ST2之控 制閘極17及電荷蓄積層14採電性連結,具有選擇閘極線 SGD、SGS之機能。 圖3D係本實施形態之選擇電晶體ST1 (ST2)及記憶胞電 晶體M.C之臨界值電壓的通道長度依存性圖表。如前面所 述,選擇電晶體ST1、ST2、及記憶胞電晶體MC之通道區 域的雜質濃度並不相同。結果,如圖3D所示,同一通道 長度時,記憶胞電晶體MC之臨界值電壓會低於選擇電晶 體ST1、ST2。 又,通道長度小至某種程度時,各電晶體之臨界值電壓 都會急速下降。圖3D中,選擇電晶體ST1、ST2在A1點 時、以及記憶胞電晶體在A2點(A2>A1)時,臨界值電壓會 急速下降。通道長度在小於此A1點、A2點之區域時,電 晶體之特性會不安定。所以,想要當做製品推出時,設計 上,必須使選擇電晶體ST1、ST2、及記憶胞電晶體MC之 各通道長度分別大於A1點、A2點。又,通道長度A1及A2 間,具有AKA2之關係。. 然而,記憶胞列内,記憶胞電晶體之數量遠大於其他電 晶體。因此,減少記憶胞電晶體之通道長度,是半導體記 憶裝置之微細化上不可或缺的。設計上,選擇電晶體之通 道長度會大於記憶胞電晶體之通道長度。其目的在於,將 選擇電晶體之臨界值電壓設定為大於記憶胞電晶體之臨界 -21- 本紙張尺度適用中國國家標準(CNS) A4規格(210X 297公釐) 564548 A7 B7 五、發明説明(18 ) 值電壓的電壓,使選擇電晶體可以獲得必要之截止特性。 如上面所述,利用本實施形態可以實現選擇電晶體之微 細化。更具體而言,即可獲得更微細之選擇電晶體。因 為,選擇電晶體之電荷蓄積層14及控制閘極17間設有開口 部16。利用此開口部16,可以自動整合對選擇電晶體之通 道部的離子佈植。以往,以個別步騾對記憶胞電晶體及選 擇電晶.體之通道部實施離子佈植時,在石版印刷時之尺寸 控制及校準精度等微細加工精度上會受到限制。然而,利 用本實施形態,可自動整合離子佈植,而排除這些限制。 因此,可實現選擇電晶體之微細化。 又,選擇電晶體之通道長度和記憶胞電晶體之通道長度 不同。利用此方式之設計,使選擇電晶體及記憶胞電晶體 有不同之臨界值電壓。同時,利用前述開口部16之離子佈 植,可以在和記憶胞電晶體無關之情形下,單獨控制選擇 電晶體之通道區域的雜質濃度。因此,可提升選擇電晶體 之截止特性。又,可以彌補因通道長度微細化而導致之選 擇電晶體開關特性的劣化。因此,可抑制選擇電晶體之短 路通道效應。結果,可更進一步獲得記憶胞列之微細化及 高密度。 其次,選擇電晶體之通道長度可以大於記憶胞電晶體之 通道長度,且選擇電晶體之通道區域的雜質濃度可以高於 記憶胞電晶體之通道區域的雜質濃度。因此,選擇電晶體 之臨界值電壓可以大於記憶胞電晶體之臨界值電壓。結 果,實現具有必要截止特性(電流截止特性)之選擇電晶體 -22- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐)Configuration. A source electrode is formed in the active region 21, and 7, 7 lines are arranged between the domains 21 for line intersection. The gates 13 and 13 of ST1 and ST2 are parallel to the gate 7 of the memory cell! The gates 13, near the selection transistors STI and ST2, are provided with openings 16 as described in FIG. In FIG. 3B, a region 20 in a semiconductor substrate is implanted with impurities. One part of this area has the function of channel area of memory cell 2. In addition, the intersections of the active region 21 and the active region 21 are implanted with impurities from the opening 16 into a silicon substrate. The region where the impurities are implanted has the function of selecting the channel region of the transistors STi and ST2. Its impurity concentration is different from the channel region of the memory cell crystal. The source and drain of each memory cell MC, MC, ... are connected together by neighbors. As described above, the plural memory cells MC, MC, ... take a series current path, so a memory block (nand cell) is formed. Next, the cross-sectional structure of the aforementioned memory cell array will be described. FIG. 2A is a cross-sectional view taken along line 2-2 of FIG. 3B. Therefore, the description of the sectional structure in the 2_2 line direction is omitted. Fig. 3C is a cross-sectional view taken along the line 3C-3C in Fig. 3B, and is also a cross-sectional structure of the selective transistor ST1. As shown in the figure, a plurality of element isolation regions 22 are provided in the semiconductor substrate 1 'and an upper portion thereof protrudes from the surface of the semiconductor substrate 1. A channel diffusion layer 19 is formed on the surface of the semiconductor substrate 1 between the element isolation regions 22. A gate insulating film 6 is formed on the channel diffusion layer 19. The material of the gate insulating film 6 is one of a silicon oxide film and a nitrogen oxide film. The gate insulating film 6 is provided with a charge accumulating layer. The size of the paper is suitable for the country ’s standard (CNS) A4 specification (210 X 297 mm) 564548 A7 B7 V. Description of the invention (17) 14, which will be higher than the element Above the isolation area 22. Above the charge accumulation layer 14 and the element isolation region 22, an inter-gate insulating film 15 is formed. A control gate electrode 17 is formed on the inter-gate insulating film 15. The control gate 17 and the charge accumulation layer 14 of the selection transistors ST1 and ST2 are electrically connected, and have the function of selecting the gate lines SGD and SGS. FIG. 3D is a graph of the channel length dependence of the threshold voltage of the selection transistor ST1 (ST2) and the memory cell transistor M.C in this embodiment. As described above, the impurity concentrations of the channel regions of the selection transistors ST1, ST2, and the memory cell transistor MC are not the same. As a result, as shown in FIG. 3D, for the same channel length, the threshold voltage of the memory cell MC will be lower than that of the selection transistors ST1 and ST2. In addition, when the channel length is as small as possible, the threshold voltage of each transistor will decrease rapidly. In Fig. 3D, when the transistors ST1 and ST2 are selected at point A1 and the memory cell transistor is at point A2 (A2> A1), the threshold voltage will drop rapidly. When the channel length is smaller than the points A1 and A2, the characteristics of the transistor will be unstable. Therefore, when launching as a product, the design must make the length of each channel of the selection transistors ST1, ST2, and memory cell transistor MC greater than points A1 and A2, respectively. The channel lengths A1 and A2 are related to AKA2. However, in the memory cell array, the number of memory cell transistors is much larger than other transistors. Therefore, reducing the channel length of the memory cell crystal is indispensable for miniaturizing semiconductor memory devices. By design, the channel length of the selected transistor will be greater than the channel length of the memory cell transistor. The purpose is to set the threshold voltage of the selected transistor to be greater than the threshold of the memory cell transistor. -21- This paper applies the Chinese National Standard (CNS) A4 specification (210X 297 mm) 564548 A7 B7 V. Description of the invention ( 18) the voltage of the voltage, so that the selection of the transistor can obtain the necessary cut-off characteristics. As described above, according to this embodiment, miniaturization of the selective transistor can be achieved. More specifically, finer selection transistors can be obtained. This is because an opening 16 is provided between the charge storage layer 14 and the control gate 17 of the selection transistor. With this opening portion 16, the ion implantation to the channel portion of the selection transistor can be automatically integrated. In the past, when ion implantation was performed on a memory cell transistor and a selective transistor channel in individual steps, the micro-processing accuracy such as dimensional control and calibration accuracy during lithography was limited. However, with this embodiment, ion implantation can be automatically integrated, and these limitations are eliminated. Therefore, miniaturization of the selected transistor can be achieved. In addition, the channel length of the selected transistor is different from the channel length of the memory cell transistor. The design of this method makes the selection transistor and the memory cell transistor have different threshold voltages. At the same time, by using the ion implantation of the opening portion 16, the impurity concentration in the channel region of the selected transistor can be controlled independently of the memory cell transistor. Therefore, the cut-off characteristics of the selected transistor can be improved. In addition, it is possible to compensate for the deterioration of the switching characteristics of the selected transistor due to the miniaturization of the channel length. Therefore, the short path effect of selecting a transistor can be suppressed. As a result, miniaturization and high density of the memory cell array can be further obtained. Secondly, the channel length of the selected transistor can be greater than the channel length of the memory cell, and the impurity concentration of the channel region of the selected transistor can be higher than that of the channel region of the memory cell. Therefore, the threshold voltage of the selected transistor can be greater than the threshold voltage of the memory cell transistor. As a result, a selection transistor with the necessary cut-off characteristics (current cut-off characteristics) was realized. -22- This paper size applies to China National Standard (CNS) A4 (210 X 297 mm)

裝 f 564548 A7 ___ _ B7 五、發明説明(19 ) 的半導體記憶裝置。 又’利用設置於浮動閘極14及控制閘極17間之開口部 16 ’可以改變選擇電晶體及記憶胞電晶體之通道區域的雜 質濃度。因此,實現具有含必要高雜質濃度之通道區域的 選擇電晶體、以及含適合微細化、低雜質濃度通道區域之 兄憶胞電晶體的微細半導體記憶裝置。所以,可以提高如 資料寫人特性、資料儲存特性、以及對讀取應力之耐性等 $己憶胞電晶體之特性。 其次,以圖4A、圖4B至圖15A、圖15B來說明前述構成 之半導體裝置的製造方法。圖4A、圖4B至圖15A、圖15B 係NAND型快閃記憶體之製造步騾的剖面圖,圖4A至圖 15A係圖3B之2_2線、圖4B至圖15B則係3C-3C線之剖面構 造。 如圖4A及圖4B所示,半導體基板型矽基板上, 形成犧牲矽氧膜30。犧牲矽氧膜30可保護半導體基板1表 面避免受到離子佈植導致的破壞。其次,有時會以離子饰 植來將雜質導入半導體基板1内。然後,實施導入之雜質 的活性化,形成含有P型凹部、或η型凹部及p型凹部之二 重凹部等。 其次,在半導體基板1表面、或形成凹部時以對該凹部 表面實施通道離子佈植,形成離子佈植層31。佈植之雜質 需視記憶胞電晶體及選擇電晶體之導電型而定。例如,電 晶體之導電性為η型時,導入硼等ρ型雜質。此離子佈植: 目的在執行電晶體之通路控制,故同時對記憶胞電晶體及 -23-F 564548 A7 ___ _ B7 5. Semiconductor memory device of invention description (19). Furthermore, by using the opening 16 provided between the floating gate 14 and the control gate 17, the impurity concentration of the channel region of the selection transistor and the memory cell transistor can be changed. Therefore, a selective transistor having a channel region containing a necessary high impurity concentration, and a fine semiconductor memory device including a cell transistor suitable for miniaturization and a low impurity concentration channel region are realized. Therefore, the characteristics of the self-transistor can be improved, such as the characteristics of data writers, data storage, and resistance to read stress. Next, a method for manufacturing a semiconductor device having the above-mentioned configuration will be described with reference to Figs. 4A and 4B to Figs. 15A and 15B. 4A, FIG. 4B to FIG. 15A, and FIG. 15B are cross-sectional views of the manufacturing steps of the NAND-type flash memory, and FIGS. 4A to 15A are the lines 2_2 of FIG. Section structure. As shown in FIGS. 4A and 4B, a sacrificial silicon oxide film 30 is formed on a semiconductor substrate type silicon substrate. The sacrificial silicon oxide film 30 protects the surface of the semiconductor substrate 1 from damage caused by ion implantation. Second, impurities may be introduced into the semiconductor substrate 1 by ion implantation. Then, the introduced impurities are activated to form a double recessed portion including a P-type recessed portion, or an n-type recessed portion and a p-type recessed portion. Next, when the surface of the semiconductor substrate 1 or a recess is formed, channel ion implantation is performed on the surface of the recess to form an ion implantation layer 31. The implanted impurities depend on the memory cell transistor and the conductivity type of the transistor. For example, when the conductivity of the transistor is n-type, a p-type impurity such as boron is introduced. This ion implantation: The purpose is to implement the pathway control of the transistor, so it simultaneously controls the memory cell and -23-

564548 A7 _______B7 五、發明説明(2〇 ) 選擇電晶體之預定形成區域整體實施。 如圖5A及圖5B所示,剝離犧牲矽氧膜3〇後,半導體基 板1上會形成閘極氧化膜6。接著,在閘極氧化膜6上層積 浮動閘極之電極材料如多晶[形成浮動閘極層32。又, 因浮動閘極層32必須具導電性,故採用如預先摻雜磷 (Phosphorus)之多晶矽。當然’亦可層積未摻雜之多晶矽 後,再實施磷之離子俜植。其次,浮動閘極層32上,形成 如矽氮化膜(ShN4)等之遮罩材料33。此遮罩材料33係用於 形成元件隔離區域。 其次,在遮罩材料33上敷塗抗蝕劑(圖上未標示),以光 石版印刷技術使抗蝕劑形成元件隔離區域之圖案。再將圖 案化之抗蝕劑當做遮罩,實施遮罩材料33之圖案化。再將 圖案化之遮罩材料33當做遮罩,實施浮動閘極層32、閘極 絕緣膜6、及半導體基板丨之蝕刻。蚀刻通常會採用 (Reactive Ion Etching、活性離子蝕刻)。利用此方式,遮罩 材料33表面至半導體基板j會形成元件隔離區域用溝(圖上 未標示)。溝之深度為,例如〇 25 # m程度。其次,以高溫 使溝之侧面及底面產生氧化,形成矽熱氧化膜。形成此熱 氧化膜之目的,在於恢復蝕刻時所受到的破壞、保護各層 界面、或針對其他目的。然後,以例如CVD (Chemical Vapor Deposition、化學汽相澱積)法實施元件隔離用矽氧 化膜 34之層積。此時,使用 HDP_CVD (High Density Plasma CVD、高密度電漿CVD)法等。然後,使層積之矽氧化膜 34平坦化,讓遮罩材料33上之表面和矽氧化膜34上之表面 -24- 本紙張尺度適用中@ ϋ家料(CNS) A4規格(⑽X 297公爱) 564548 A7 B7 五、發明説明(21 ) 一致。此平坦化步驟,通常採用CMP (Chemical Mechanical Polishing、化學機械研磨)法,亦可採用回蝕法。又,以 CMP法實施平坦化時,遮罩材料33之矽氮化膜被當做CMP 之制動(stopper)膜。再對矽氧化膜34實施退火使其高密度 化。利用此方式,使矽氧化膜34之結晶性接近矽熱氧化 膜,而成為良質之矽氧化膜。結果,可得到圖6A及圖6B 所示構造。 其次,如圖7A及圖7B所示,去除遮罩材料33。再以RIE 法或濕式蝕刻使矽氧化膜34之上面向後退。如此,即完成 元件隔離區域22。 其次,如圖8A及圖8B所示,在外露之元件隔離區域22 及浮動閘極層32之表面上層積閘極間絕緣膜35。閘極間絕 緣膜35為,例如0N0膜。 其次,如圖9Α及圖9Β所示,在閘極間絕緣膜35上層積 遮罩材料36。遮罩材料3 6為,例如多晶矽或矽氧化膜。 又如圖10Α及圖10Β所示,在遮罩材料36上敷塗抗蝕劑 37。再以光石版印刷技術實施抗蝕劑37之圖案化,去除抗 蝕劑37,其區域則至少為對應必須成為選擇電晶體之通道 區域的部份區域。結果,形成圖示之開口部38。 如圖11Α及圖11Β所示,利用以抗蝕劑37做為遮罩之蝕 刻,去除位於開口部38正下方之遮罩材料36。實施此遮罩 材料36之蚀刻步驟時,採用例如Deep UV (Ultraviolet)石版 印刷法。利用本方法,因可以使用短波長之光源,可以實 施極高精度之圖案化。因此,可以將遮罩材料36及開口部 -25- 本紙張尺度適用中國國家標準(CNS) A4規格(210X 297公釐) 22 五、發明説明( 可使閘極間絕 3 8之位置偏離抑制於最小。本步驟之結果 緣膜35從開口部38之底部露出。 m圖以及圖i2B所示’在必須成為選擇電晶體 I通道區域的半導體基板1中,實施雜質之離子佈植,來 =通道擴散層19。本離子侔植之雜質,會經由問極間絕緣 浮動閘極層32、及閘極絕緣膜6被導入半導體基板1 中。雜質之種類需視選擇電晶體之導電型而定,η通道時 可:用硼、ρ通道時則可使用磷。又,在殘留抗蝕劑37之 狀態下實施離子佈植,係可以利用抗蝕劑37做為離子伟植 之緩衝材料。 在本步騾中,必須形成記憶胞電晶體之區域存在遮罩材 料36。其膜厚則設定為離子佈植之離子種類會在遮罩材料 36中衰減的程度。同時,必須形成選擇電晶體之區域,進 行離子佈植之加速能量的調整,使離子能貫穿浮動閘極層 32並到達半導體基板1之程度。 如圖13Α及圖13Β所示,以蚀刻去除開口部π正下方之 閘極間絕緣膜35。又,以形成圖12Α及圖12Β說明之通道 擴散層19為目的的離子佈植,在本步驟中,亦可在閘極間 絕緣膜35之蚀刻後再實施。若在殘留閘極間絕緣膜35之狀 態下實施離子佈植,可以防止浮動閘極層32之表面受到污 染。因為閘極間絕緣膜35具有浮動閘極層32之保護膜的機 其次,如圖14Α及圖14Β所示,去除遮罩材料36。在閘 極間絕緣膜35上形成控制閘極材料39。控制閘極材料39含 -26- 本紙張尺度適用中國國家標準(CNS) Α4規格(210X 297公釐) 564548 A7 - —_____B7 五、發明説明(23 ) 有如多晶石夕膜及WSi (Tungsten Silicide、鶴碎)等金屬石夕化 物膜。當然,不使用金屬矽化物膜而只使用多晶矽膜亦 可。此外,記憶胞電晶體預定形成區域可以為含有多晶矽 膜及金屬矽化合物膜之多層構造,而選擇電晶體預定形成 區域則可以為只含有多晶矽膜之構造。 利用光石版印刷技術及RIE法等各向異性蝕刻,實施控 制閘極、材料39、閘極間絕緣膜35、及浮動閘極層32之圖案 化。結果,如圖15A及圖15B所示,形成含有電荷蓄積層 8、閘極間絕緣膜9、及控制閘極10之記憶胞電晶體mc的 閘極7。又,完成含有電荷蓄積層14、閘極間絕緣膜15、 及控制閘極17之選擇電晶體ST1、ST2的閘極13。又,圖 14A及圖14B所示之步騾中,以多晶矽膜形成控制閘極材 料39時,亦可在執行本步騾之圖案化後,以Salidde (Self_ Aligned Silicide)形成矽化合物膜。 其後’將具有層積閘極構造之閘極7、13當做遮罩使 用’實施離子佈植將雜質導入半導體基板1中。結果,半 導體基板1中形成源極•汲極區域4、5、12,完成圖2及圖 3C所示構造。 如上面所述,採用本實施形態之半導體裝置製造方法, 可去除使電荷蓄積層14及控制閘極π形成電性隔離之閘極 間絕緣膜15的一部份。此種處理亦適用於周邊控制系統之 電晶體的閘極、以及記憶胞列内之選擇電晶體的閘極。其 目的則是,使電荷蓄積層14及控制閘極17形成電性連結。 然而’只有在滿足下列條件時,才可以在前述處理過程 ____ -27- 本紙張尺度適财S ®家標準(CNS) Μ規格(21GX 297公董) 五 發明説明(24 中’越過浮動閘極將雜質以離子佈植方式導入至半導體基 板内。 a π即,該雜質會在記憶胞電晶體之遮罩材科中衰減而不 會到達電荷蓄積f,且可貫穿選擇電晶體之電荷蓄積層及 閘極絕緣膜並到達半導體基板。 f如此,記憶胞電晶體及選擇電晶體間,會形成不同雜質 濃度之通道區域,且該通道區域可分別滿足各電晶體之必 要特性。又,可以不必追加新的石版印刷步騾等即提升各 電晶體之特性。且可自動整合該處理。 如上面所述,可以自動整合處理形成具有通道區域之選 擇電晶體’而前述通道區域含有濃度區域,其濃度不同於 记憶胞電晶體之通道區域雜質濃度。如發明背景中之說明 所示,習知之方法時,要分別對記憶胞電晶體及選擇電晶 體之各通道區域實施離子佈植,有實際上的困難。此時, 兩者之通道區域的雜質濃度分佈,在橫向及縱向會大致相 同。然而,利用本實施形態之方法,經由開口部16之離子 伟植步驟係針對選擇閘門電晶體實施。因此,兩者之通道 區域在橫向及縱向會有不同之雜質濃度分佈。 又’選擇電晶體中,實施通道離子佈植時之部份離子會 殘留於閘極絕緣膜6内。而該區域為含有開口部16正下方 區域之區域。 本實施形態可以為η通道電晶體’亦可以為p通道電晶 體。以控制記憶胞電晶體及選擇電晶體為目的而實施離子 佈植之雜質,可以為硼,亦可以為磷。又,閘極間絕緣膜 -28- 本紙張尺度適用中國國家標準(CNS) Α4規格(210X 297公釐) 564548 五 發明説明( 25 15中形成開π部16後實施離子佈植,可以防止石版印刷步 驟之增加。 如上面所述,利用本實施形態之半導體裝置及其製造方 法、,可以利用對應選擇電晶體之通道區域的開口部,實施 通道區域疋離子佈植。所以,可以有效抑制通道佈植時之 偏離。 又’以遮罩材料覆蓋記憶胞電晶體之狀態下,實施對選 擇電晶體之通道區域的離子佈植。因此,記憶胞電晶體之 通道區域的濃度,可以和選擇電晶體之通道濃度分開設 定。 又,本實施形態會在半導體基板丨中形成通道區域等。 然而,預先將低濃度雜質佈植半導體基板丨之元件區域來 形成凹部亦可。而且,亦可以在凹部中形成通道區域等。 又,NAND胞可以如2個選擇閘極夾著8個電晶體之方式來 形成。然而,NAND胞之電晶體個數不限為8個,此數量無 特別限制。例如,可以8至32之任意數量來形成。又,相 鄰之圮憶胞電晶體的閘極間距離為〇 2 # m以下時,本實施 形怨之效果會更為顯著。前述實施形態中,係針對半導體 基板1為p型、源極•沒極區域為n型時進行說明,但,半 導體基板1亦可為η型、源極•汲極區域4亦可為?型。本實 施形怨之選擇電晶體的構成,亦可適用於周邊電路含有之 MOS電晶體。 ° 如前面所述,不會經由記憶胞電晶體之閘極絕緣膜實施 通道佈植。因此,尤其是不會導致具有浮動閘極構造之非 •29· 本紙張尺度適财a gi家標準(CNS) Α4規格(21GX 297公爱)564548 A7 _______B7 V. Description of the Invention (20) The predetermined formation area of the transistor is selected and implemented as a whole. As shown in FIGS. 5A and 5B, after the sacrificial silicon oxide film 30 is peeled off, a gate oxide film 6 is formed on the semiconductor substrate 1. Next, the gate oxide film 6 is laminated with an electrode material of a floating gate, such as polycrystalline silicon [to form a floating gate layer 32. In addition, since the floating gate layer 32 must be conductive, polycrystalline silicon such as Phosphorus is pre-doped. Of course, it is also possible to stack un-doped polycrystalline silicon and then perform ion implantation of phosphorus. Next, a masking material 33 such as a silicon nitride film (ShN4) is formed on the floating gate layer 32. This masking material 33 is used to form an element isolation region. Next, a resist (not shown in the figure) is applied on the masking material 33, and the resist is formed into a pattern of an element isolation region by a photolithography technique. The patterned resist is used as a mask, and the mask material 33 is patterned. The patterned masking material 33 is used as a mask, and the floating gate layer 32, the gate insulating film 6, and the semiconductor substrate are etched. Etching is usually used (Reactive Ion Etching). In this way, a trench (not shown in the figure) is formed from the surface of the mask material 33 to the semiconductor substrate j. The depth of the groove is, for example, about 0.25 # m. Next, the side and bottom surfaces of the trench are oxidized at a high temperature to form a silicon thermal oxide film. The purpose of forming this thermal oxide film is to restore the damage suffered during etching, protect the interfaces of the layers, or for other purposes. Then, for example, a CVD (Chemical Vapor Deposition) method is used to laminate the silicon oxide film 34 for element isolation. At this time, HDP_CVD (High Density Plasma CVD, high-density plasma CVD) method or the like is used. Then, the laminated silicon oxide film 34 is flattened, so that the surface on the masking material 33 and the surface on the silicon oxide film 34 -24- This paper size is applicable @ ϋ 家 料 (CNS) A4 size (⑽X 297) Love) 564548 A7 B7 5. The invention description (21) is the same. In this planarization step, a CMP (Chemical Mechanical Polishing) method is generally used, and an etch-back method can also be used. When the planarization is performed by the CMP method, the silicon nitride film of the mask material 33 is used as a CMP stopper film. The silicon oxide film 34 is further annealed to increase its density. In this way, the crystallinity of the silicon oxide film 34 is made close to that of the silicon thermal oxide film, and it becomes a good silicon oxide film. As a result, a structure shown in FIGS. 6A and 6B can be obtained. Next, as shown in FIGS. 7A and 7B, the mask material 33 is removed. Then, the upper surface of the silicon oxide film 34 is retracted by RIE or wet etching. In this way, the element isolation region 22 is completed. Next, as shown in FIGS. 8A and 8B, an inter-gate insulation film 35 is laminated on the surface of the exposed element isolation region 22 and the floating gate layer 32. The inter-gate insulating film 35 is, for example, an ONO film. Next, as shown in FIGS. 9A and 9B, a masking material 36 is laminated on the inter-gate insulating film 35. The masking material 36 is, for example, polycrystalline silicon or a silicon oxide film. 10A and 10B, a resist 37 is applied to the masking material 36. The photolithography technique is then used to pattern the resist 37 to remove the resist 37, and its area is at least a part of the area corresponding to the channel area that must be selected as a transistor. As a result, the illustrated opening portion 38 is formed. As shown in Figs. 11A and 11B, the mask material 36 located immediately below the opening portion 38 is removed by etching using the resist 37 as a mask. In the etching step of the mask material 36, for example, a deep UV (Ultraviolet) lithography method is used. With this method, a short-wavelength light source can be used, and extremely high-precision patterning can be implemented. Therefore, the mask material 36 and the opening -25 can be applied to this paper size according to the Chinese National Standard (CNS) A4 specification (210X 297 mm). 22 5. Description of the invention As a result of this step, the edge film 35 is exposed from the bottom of the opening 38. As shown in FIG. 2B and FIG. 2B, in the semiconductor substrate 1 that must be a channel region of the selective transistor I, an ion implantation of impurities is performed to Channel diffusion layer 19. The impurities implanted by the ions will be introduced into the semiconductor substrate 1 through the inter-insulating floating gate layer 32 and the gate insulating film 6. The type of impurities depends on the conductivity type of the selected transistor In the case of η channel, it is possible to use boron and in the case of ρ channel. Phosphorus can be used. In addition, the ion implantation is performed under the state of the remaining resist 37, which can use the resist 37 as a buffer material for ion implantation. In this step, a masking material 36 is present in the area where the memory cell transistor must be formed. The film thickness is set to the extent that the ion species implanted in the masking material 36 will be attenuated in the masking material 36. At the same time, a selective transistor Area, carry off The acceleration of the implanted energy is adjusted so that the ions can penetrate the floating gate layer 32 and reach the semiconductor substrate 1. As shown in FIGS. 13A and 13B, the inter-gate insulating film 35 directly below the opening π is removed by etching. In addition, the ion implantation for the purpose of forming the channel diffusion layer 19 described in FIGS. 12A and 12B may be performed after the inter-gate insulating film 35 is etched in this step. If the inter-gate insulating film remains Implementing ion implantation under the condition of 35 can prevent the surface of the floating gate layer 32 from being contaminated. The inter-gate insulating film 35 has a protective film of the floating gate layer 32, as shown in Figs. 14A and 14B. Remove the masking material 36. The control gate material 39 is formed on the inter-gate insulation film 35. The control gate material 39 contains -26- This paper size applies to China National Standard (CNS) A4 specification (210X 297 mm) 564548 A7 -— _____B7 V. Description of the invention (23) There are metal silicate films such as polycrystalline silicon films and WSi (Tungsten Silicide, crane broken). Of course, instead of using metal silicide films, only polycrystalline silicon films can be used. In addition, Memory cell transistor scheduled The formation area can be a multilayer structure containing a polycrystalline silicon film and a metal silicon compound film, and the selected formation area of the transistor can be a structure containing only a polycrystalline silicon film. Using anisotropic etching such as photolithography and RIE, a control gate Patterning of the electrode, the material 39, the inter-gate insulating film 35, and the floating gate layer 32. As a result, as shown in FIGS. 15A and 15B, a charge storage layer 8, an inter-gate insulating film 9, and a control gate are formed. The gate 7 of the memory cell transistor mc of the pole 10. The gate 13 including the charge accumulation layer 14, the inter-gate insulating film 15, and the selection transistor ST1, ST2 of the control gate 17 is completed. 14A and 14B, when the control gate material 39 is formed of a polycrystalline silicon film, the silicon compound film may be formed by Salidde (Self Aligned Silicide) after performing the patterning of this step. Thereafter, the gate electrodes 7, 13 having a laminated gate structure are used as a mask, and ion implantation is performed to introduce impurities into the semiconductor substrate 1. As a result, source / drain regions 4, 5, and 12 are formed in the semiconductor substrate 1, and the structures shown in FIGS. 2 and 3C are completed. As described above, by using the semiconductor device manufacturing method of this embodiment, a part of the gate-to-gate insulating film 15 that electrically isolates the charge accumulation layer 14 and the control gate π can be removed. This process is also applicable to the gates of the transistors of the peripheral control system and the gates of the selected transistors in the memory cell array. The purpose is to electrically connect the charge accumulation layer 14 and the control gate 17. However, 'Only when the following conditions are met, the aforementioned processing can be performed ____ -27- This paper size is suitable for S ® Home Standards (CNS) M specifications (21GX 297 public directors) Five invention notes (24 in' crossing the floating gate ' The electrode introduces impurities into the semiconductor substrate by ion implantation. A π That is, the impurities will decay in the mask material family of the memory cell without reaching the charge accumulation f, and the charge accumulation can be penetrated through the selected transistor. Layer and gate insulating film and reach the semiconductor substrate. F In this way, between the memory cell and the selection transistor, channel regions with different impurity concentrations will be formed, and the channel regions can meet the necessary characteristics of each transistor. It is not necessary to add new lithographic printing steps to improve the characteristics of each transistor. And the process can be integrated automatically. As mentioned above, the process can be automatically integrated to form a selection transistor with a channel region, and the aforementioned channel region contains a concentration region, Its concentration is different from the impurity concentration in the channel region of the memory cell crystal. As shown in the description of the background of the invention, It is practically difficult to implement ion implantation in each channel region of the transistor and the selected transistor. At this time, the impurity concentration distribution in the channel region of the two will be substantially the same in the horizontal and vertical directions. However, the method of this embodiment is used The ion implantation step through the opening 16 is implemented for the selection of the gate transistor. Therefore, the channel area of the two will have different impurity concentration distributions in the horizontal and vertical directions. Also, in the selection of the transistor, when the channel ion implantation is implemented Part of the ions will remain in the gate insulating film 6. This area is the area containing the area directly below the opening 16. This embodiment can be an n-channel transistor or a p-channel transistor to control the memory cell. Transistors and impurities that are implanted for the purpose of ion implantation can be either boron or phosphorus. In addition, the gate-to-gate insulation film-28- This paper applies the Chinese National Standard (CNS) A4 specification (210X 297) 564548 Five invention descriptions (Ion implantation after forming the open π portion 16 in 25 15 can prevent the increase of lithographic printing steps. As described above, using this The semiconductor device and its manufacturing method can use the openings corresponding to the channel region of the selected transistor to implant the ions in the channel region. Therefore, it is possible to effectively suppress the deviation when the channel is implanted. In a state that the memory cell transistor is covered, ion implantation is performed on the channel region of the selected transistor. Therefore, the concentration of the channel region of the memory cell can be set separately from the channel concentration of the selected transistor. In addition, this embodiment mode Channel regions and the like are formed in the semiconductor substrate. However, it is also possible to form a recessed portion by implanting a low-concentration impurity in a device region of the semiconductor substrate. In addition, a channel region may be formed in the recessed portion. Also, the NAND cell may be Two selection gates are formed by sandwiching eight transistors. However, the number of NAND cell transistors is not limited to eight, and this number is not particularly limited. For example, it can be formed in any number of 8 to 32. In addition, when the distance between the gates of the neighboring memory cell transistor is 0 2 # m or less, the effect of this embodiment is even more significant. In the foregoing embodiment, the description is given when the semiconductor substrate 1 is p-type and the source / non-electrode region is n-type. However, the semiconductor substrate 1 may also be n-type, and the source-drain region 4 may also be? type. The structure of the selection transistor in this embodiment can also be applied to the MOS transistor included in the peripheral circuit. ° As mentioned earlier, channel implantation is not performed via the gate insulating film of the memory cell transistor. Therefore, in particular, it will not lead to a non-floating structure with a floating gate structure. • 29 · This paper is suitable for standardization (CNS) A4 specification (21GX 297 public love)

揮發性1己憶體的特性劣化。亦即,習、 性、資料:存牿成’但記憶胞電晶體之資料寫入刪除特 全:=:特性可能會劣化。然而,本實施形態時,完 曰有則处圮憶胞電晶體之特性劣化的問題。 為“=Γ態之製造方法時,不需要以形成通道區域 ==超微細圖案之石版印刷步驟。而只需要使用 :以連結選擇電晶體之浮動間極及控制閑極為目的必要 =Τ技術即可。因此,不會增加製造成本亦不會 二t 含有通道區域和記憶胞電晶體分開形成之選 二且具有高密度配置微細記憶胞電晶體之記憶胞 、、m裝置,只需追加離子佈植步騾即可實現。 又’本實施形態並非邊難型快閃記憶體必須以規則 万式配置選擇電晶體及記憶胞電晶體時才有效,亦可採用 、任何胞構造。例如,相鄰之閘極間距離及閘極之層積構 造的關係必須滿足以離子佈植為目的之特定幾何條件等, 因為完全沒有任何必須滿足前述類似條件之限制,故具有 相當大之自由度。 圖16A及圖16B係前述第丨實施形態第丨變形例之半導體 裝置製造步騾的剖面圖。NAND型快閃記憶體之、尤其是 沿著控制閘極線CG方向之剖面構造。 首先,利用前述第1實施形態說明之步騾,形成圖7八及 圖之構造,完成元件隔離區域22。其後,如圖16A所 不’例如,在浮動閘極層32及元件隔離區域22上層積捧雜 •30· 本紙張尺纽财關家群(CNS) A4規格(繼297公着) 564548The characteristics of the volatile 1A memory are deteriorated. In other words, Xi, Xing, and data: stored, but the characteristics of writing and deleting data of the memory cell: =: characteristics may be deteriorated. However, in this embodiment, there is a problem that the characteristics of the memory cell crystal are deteriorated. For the manufacturing method of "= Γ state", it is not necessary to form a lithographic printing step for forming a channel region == an ultra-fine pattern. Instead, it is only used: necessary to select the floating pole of the transistor and control the idle pole. = T technology Yes. Therefore, it will not increase the manufacturing cost nor will it contain the channel area and the memory cell crystal, which is the second choice. The memory cell and the m device with a high-density micro-memory cell crystal need only be added with an ion cloth. It can be realized by planting steps. Also, 'this embodiment is not an edge-hard flash memory that is only effective when a transistor and a memory cell are selected in a regular configuration, and any cell structure can also be used. For example, adjacent The relationship between the distance between the gates and the layered structure of the gates must meet the specific geometric conditions for the purpose of ion implantation, etc., because there are no restrictions that must meet the aforementioned similar conditions at all, so they have a considerable degree of freedom. And FIG. 16B is a cross-sectional view of the semiconductor device manufacturing steps of the aforementioned 丨 embodiment 丨 modification example. The NAND-type flash memory, especially along the control gate Sectional structure in the direction of line CG. First, using the steps described in the first embodiment, the structure of FIG. 7 and FIG. 7 is formed to complete the element isolation region 22. Thereafter, as shown in FIG. 16A, for example, in a floating gate Layer 32 and component isolation area 22 are stacked on top of each other. 30 · This paper ruler New Zealand Customs Group (CNS) A4 specification (after 297) 564548

鱗之多晶矽層4〇。然後再以CMP法實施多晶矽層40之平坦 化。 其次’如圖16B所示,利用光石版印刷技術及蚀刻實施 多晶秒層40之圖案化。結果,如圖所示,多晶矽層4〇沿著 控制閘極線CG方向會在元件隔離區域22上互相隔離,且 其端部會殘留於元件隔離區域22上。利用此方式,完成具 有浮動閘極層32及多晶矽層40之多層構造的電荷蓄積層。 其次’在多晶矽層40及元件隔離區域22上,層積如ΟΝΟ膜 等構成之閘極間絕緣膜35。 其後,實施本實施形態以圖9Α及圖9Β以後圖面說明之 步驟。 本變形例之製造方法,在去除遮罩材料33後,追加層積 多晶石夕層40 °利用此方式,電荷蓄積層之膜厚會大於第1 實施形態’電荷蓄積層之上面及元件隔離區域之上面的距 離會擴大。因此,和第i實施形態相比,和閘極間絕緣膜 相接之電荷蓄積層的表面積會增加。其詳細内容則是,只 有對應電荷蓄積層上面、及元件隔離區域上面之距離的面 積會增大。因此,記憶胞部之蓄積電容會增大。所以,控 制電荷蓄積層之膜厚亦即,控制多晶矽層40之膜厚,可以 調整記憶胞部之記憶電容。 圖16C及圖16D係前述第1實施形態第2變形例之半導體 裝置製造步驟的剖面圖。NAND型快閃記憶體之、尤其是 沿著位元線BL之剖面構造。 首先,以前述第1實施形態之步騾,形成圖9 A之構造。 -31- 本紙張尺度適用中國國家標準(CNS) A4規格(210X 297公董) 564548 A7 B7Scale of polycrystalline silicon layer 40. Then, the polycrystalline silicon layer 40 is planarized by the CMP method. Next, as shown in FIG. 16B, the patterning of the polycrystalline second layer 40 is performed using a light lithography technique and etching. As a result, as shown in the figure, the polycrystalline silicon layers 40 are isolated from each other on the element isolation region 22 along the direction of the control gate line CG, and the ends thereof remain on the element isolation region 22. In this manner, a multi-layered charge storage layer having a floating gate layer 32 and a polycrystalline silicon layer 40 is completed. Next, on the polycrystalline silicon layer 40 and the element isolation region 22, an inter-gate insulating film 35 composed of an ONO film is laminated. Thereafter, the steps described in this embodiment with reference to Figs. 9A and 9B and subsequent drawings are carried out. In the manufacturing method of this modification, after the masking material 33 is removed, a layer of polycrystalline stone is added at an additional 40 °. In this way, the film thickness of the charge storage layer is greater than that of the top of the charge storage layer and the device isolation in the first embodiment. The distance above the area will increase. Therefore, compared with the i-th embodiment, the surface area of the charge accumulation layer in contact with the inter-gate insulating film is increased. The details are that only the area corresponding to the distance between the upper surface of the charge accumulation layer and the upper surface of the device isolation region will increase. Therefore, the storage capacitance of the memory cell will increase. Therefore, controlling the film thickness of the charge accumulation layer, that is, controlling the film thickness of the polycrystalline silicon layer 40, can adjust the memory capacitance of the memory cell portion. Figs. 16C and 16D are cross-sectional views showing the steps of manufacturing a semiconductor device according to the second modification of the first embodiment. The NAND-type flash memory is particularly structured along a cross section along the bit line BL. First, in the steps of the first embodiment described above, the structure of FIG. 9A is formed. -31- This paper size applies to China National Standard (CNS) A4 (210X 297 public directors) 564548 A7 B7

其;人’以圖10A及圖11A說明之步驟 ’實施抗蝕劑37及遮It; a person 'performs the resist 37 and a mask using the steps illustrated in Figs. 10A and 11A.

經由開口部38將雜質導入半導體基板丨中。結果,在半導 體基板1中形成複數之通道擴散層19。 其後,經由圖13A、圖14A所示步驟, 選擇電晶體的閘極13。如圖所示,閘相 驟,完成圖16D所示之 閘極13具有3個連結部 16、16、16 〇 如上面所述,連結部16可以為複數個。又,圖16]〇中, 有複數個通道擴散層19。然而,因為經過多數熱步騾,故 通#會一體化。結果,通道區域之雜質濃度分佈大致如圖 2B所示。 圖Π係弟1實施形態第3變形例之半導體裝置的剖面圖, 為NAND型快閃1己憶體之、尤其是沿著控制閘極線方向 之剖面構造。 前述第1實施形態之圖10A及圖10B所示步騾中,開口部 小於閘極1 3。然而,在本變形例中,如圖丨7所示,開口 部38和選擇電晶體之電極同樣大小。因而,形成具有閘 極間絕緣膜35全部被除去之閘極46的選擇電晶體47。又, 形成長度和閘極46長度相同之通道區域45。 其次,以圖18說明本發明第2實施形態之半導體裝置。 圖18係AND型快閃記憶體之記憶胞列的電路圖。本實施形 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐) 564548 A7 B7 五、發明説明(29 ) 態係以前述第1實施形態之NAND型快閃記憶體取代前述第 1實施形態之半導體裝置,並應用於AND型快閃記憶體 上。 如圖所示,記憶胞列具有複數之記憶塊MB (AND胞)。 記憶塊MB含有η (η為自然數,圖面為n-4時)個申聯之記憶 胞電晶體MC、汲極侧選擇電晶體ST1、及源極侧選擇電晶 體ST2。記憶胞電晶體MC、MC、…含有分別連結於控制 閘極線CG1〜CG4 (WL1〜WL4)之閘極、共同連結於局部汲 極線LD之汲極、以及共同連結於局部源極線LS之源極。 汲極侧選擇電晶體ST1具有連結於選擇閘極線SGD之閘 極、連結於位元線BL1、BL2、…之汲極、以及連結於局 部汲極線LD之源極。又,源極侧選擇電晶體ST2具有連結 於選擇閘極線SGS之閘極、連結於局部源極線LS之汲極、 以及連結於共用源極線SL之源極。其次,汲極侧及源極侧 之選擇電晶體ST1、ST2具有和前述第1實施形態說明之選 擇電晶體相同的構成。 如前面所述之AND型快閃記憶體的記憶胞電晶體MC及 選擇電晶體ST1、ST2,亦可採用前述第1實施形態說明之 圖2、圖17所示構造。又,圖4A、圖4B至圖16A、圖16B所 示製造方法亦可直接適用。因此,本實施形態之快閃記憶 體,亦和前述第1實施形態相同,不但可提升選擇電晶體 之截止特性,亦可實現快閃記憶體之微細化。 又,前述第1、第2實施形態適合於含有選擇電晶體之非 揮發性半導體記憶裝置全體。不但可應用於半導體記憶裝 -3 3 - 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐) 564548 A7 B7 五、發明説明(30 ) 置,亦可應用於構成周邊電路之MOS電晶體。更可廣泛地 應用於具有半導體記憶裝置之記憶體混載型半導體裝置。 以NAND型快閃記憶體EEPROM為例,說明本發明第3實 施形態之半導體裝置。圖19A係NAND型快閃記憶體 EEPROM之概略構成方塊圖。圖19B貝U係記憶胞列及列系 核心部之電路圖。 如圖所示,NAND型快閃記憶體EEPROM60具有記憶胞 列61、輸出入(1/ 〇)電路62、讀取放大器63、位址存放器 64、行解碼器65、列解碼器66、及高電壓產生電路67等。 記憶胞列61分割成m個記憶胞塊BLK1〜BLKm。各記憶胞 塊BLK1〜BLKm中,有圖19B所示之NAND胞的矩陣配置。 各NAND胞含有複數個(此處為16個,但數量並未限定)記 憶胞MC、MC、…。相鄰之各記憶胞MC、MC、…以共用 源極、汲極方式進行串聯。NAND胞内之一端侧的沒極’ 會分別經由選擇電晶體ST1連結至位元線(資料線) BL1〜BLn。NAND胞内之另一端侧的源極,則經由選擇電 晶體ST2連結至源極線SL。沿著記憶胞列61之列方向設置 的選擇閘極線SGD、SGS,分別連結於同一列之選擇電晶 體ST1、ST2的閘極。相同的,沿著記憶胞列61之列方向設 置的字元線WL卜WL16,分別連結於同一列之記憶胞MC、 MC、…之控制閘極線CG1〜CG16。NAND型快閃記憶體 EEPROM時,利用連結於1條字元線WL之η位元記憶胞 MC、MC、…即可構成1頁,而16頁份會構成記憶胞塊 BLK1〜BLKm當中之1塊。會以1頁單位實施對記憶胞列61 -34- 本紙張尺度適用中國國家標準(CNS) A4規格(210X 297公釐)An impurity is introduced into the semiconductor substrate 丨 through the opening 38. As a result, a plurality of channel diffusion layers 19 are formed in the semiconductor substrate 1. Thereafter, the gate 13 of the transistor is selected through the steps shown in FIGS. 13A and 14A. As shown in the figure, the gate phase is completed, and the gate 13 shown in FIG. 16D has three connecting portions 16, 16, and 16. As described above, the connecting portion 16 may be plural. 16], there are a plurality of channel diffusion layers 19. However, because of the majority of hot steps, Tong # will be integrated. As a result, the impurity concentration distribution in the channel region is roughly shown in FIG. 2B. FIG. 11 is a cross-sectional view of a semiconductor device according to a third modification of the first embodiment, which is a cross-sectional structure of the NAND flash memory, especially along the direction of the control gate line. In the step shown in Figs. 10A and 10B of the first embodiment, the opening is smaller than the gate electrode 13. However, in this modification, as shown in FIG. 7, the opening portion 38 is the same size as the electrode of the selection transistor. Therefore, a selection transistor 47 having a gate electrode 46 in which the inter-gate insulating film 35 is completely removed is formed. A channel region 45 having the same length as the gate electrode 46 is formed. Next, a semiconductor device according to a second embodiment of the present invention will be described with reference to FIG. 18. FIG. 18 is a circuit diagram of a memory cell of an AND flash memory. The paper size of this embodiment applies the Chinese National Standard (CNS) A4 specification (210 X 297 mm) 564548 A7 B7 5. Description of the invention (29) The NAND-type flash memory of the first embodiment is used in place of the first. The semiconductor device of the first embodiment is applied to an AND flash memory. As shown in the figure, the memory cell array has a plurality of memory blocks MB (AND cells). The memory block MB contains η (where η is a natural number and n-4 is shown in the drawing) memory cells MC, a drain-side selection transistor ST1, and a source-side selection transistor ST2. The memory cell transistors MC, MC, ... include a gate connected to the control gate lines CG1 to CG4 (WL1 to WL4), a drain connected in common to the local drain line LD, and a local source line LS in common. Source. The drain-side selection transistor ST1 has a gate connected to the selection gate line SGD, a drain connected to the bit lines BL1, BL2, ..., and a source connected to the local drain line LD. The source-side selection transistor ST2 includes a gate connected to the selection gate line SGS, a drain connected to the local source line LS, and a source connected to the common source line SL. Next, the selection transistors ST1 and ST2 on the drain and source sides have the same configuration as the selection transistors described in the first embodiment. As described above, the memory cell MC and the selection transistors ST1 and ST2 of the AND-type flash memory can also adopt the structures shown in Figs. 2 and 17 described in the first embodiment. The manufacturing methods shown in Figs. 4A, 4B to 16A, and 16B can also be directly applied. Therefore, the flash memory of this embodiment is also the same as the first embodiment described above. Not only can the cut-off characteristics of the selected transistor be improved, but also the miniaturization of the flash memory can be realized. The first and second embodiments are suitable for the entire nonvolatile semiconductor memory device including a selective transistor. Not only can be applied to semiconductor memory devices-3 3-This paper size is applicable to Chinese National Standard (CNS) A4 specifications (210 X 297 mm) 564548 A7 B7 V. Description of the invention (30), can also be used to form peripheral circuits MOS transistor. It can be widely applied to a memory-mixed semiconductor device having a semiconductor memory device. A NAND flash memory EEPROM is taken as an example to describe a semiconductor device according to a third embodiment of the present invention. Fig. 19A is a block diagram showing a schematic configuration of a NAND-type flash memory EEPROM. FIG. 19B is a circuit diagram of the U-series memory cell array and the core of the series. As shown, the NAND-type flash memory EEPROM 60 includes a memory cell 61, an input / output (1/0) circuit 62, a read amplifier 63, an address storage 64, a row decoder 65, a column decoder 66, and High voltage generating circuit 67 and the like. The memory cell array 61 is divided into m memory cell blocks BLK1 to BLKm. Each memory cell block BLK1 to BLKm has a matrix arrangement of NAND cells as shown in FIG. 19B. Each NAND cell contains a plurality of (here, 16 but the number is not limited) memory cells MC, MC, .... Adjacent memory cells MC, MC, ... are connected in series with a common source and drain. One end side of the NAND cell is connected to the bit lines (data lines) BL1 to BLn via the selection transistor ST1, respectively. The source on the other end side of the NAND cell is connected to the source line SL via the selection transistor ST2. The selection gate lines SGD and SGS provided along the column direction of the memory cell row 61 are respectively connected to the gates of the selection transistor ST1 and ST2 in the same row. Similarly, the word lines WL and WL16 arranged along the column direction of the memory cell row 61 are connected to the control gate lines CG1 to CG16 of the memory cells MC, MC, ... in the same row, respectively. For NAND-type flash memory EEPROM, one page is formed by n-bit memory cells MC, MC, ... connected to one word line WL, and 16 pages constitute one of the memory cell blocks BLK1 to BLKm. Piece. Will implement the memory cell sequence in units of 1 page 61 -34- This paper size applies the Chinese National Standard (CNS) A4 specification (210X 297 mm)

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線 564548 A7 _______ B7__ 五、發明説明(31 ) 之窝入及讀取,刪除之實施則以塊為單位。 會對輸出入電路62輸入各種指令、位址信號、以及執行 寫入之胞資料等。又,輸出入電路62會輸出從記憶胞列61 讀取並閂鎖於讀取放大器63之資料。輸入至輸出入電路62 的列位址信號及列位址信號,會提供給位址存放器64。 閂鎖於位址存放器64之列位址信號,會提供給行解碼器 65並解碼。又,閂鎖於位址存放器64之列位址信號(塊位 址信號、頁位址信號)會提供給列解碼器66並解碼。 讀取放大器63會閂鎖寫入時輸入至輸出入電路62之胞資 料。讀取時,從記憶胞列61中選取之記憶胞塊 BLK1〜BLKm讀取至各位元線的胞資料亦會被閂鎖。 列解碼器66具有分別對應記憶胞塊BLK1〜BLKm之列主 解碼器電路(圖上未標示)及列系核心部(列輔助解碼器電 路)68。列系核心部68係對選取之塊内選擇閘極線SGD、 SGS、及16條字元線WL1〜WL16提供特定電壓之電路。具 有傳輸閘極電晶體TGTD、TGTS、TGT、TGT、…。這些 傳輸閘極電晶體TGTD、TGTS、TGT、TGT、…之閘極TG 係共同連結。又,各汲極連結於選擇閘極線SGD、SGS、 及控制閘極線CG1〜CG16。列主解碼器電路會對各源極施 加對應頁位址信號之電壓。 高電壓產生電路67會依據輸入之指令信號對前述列解碼 器66及記憶胞列61提供高電壓。 其次’以圖19C至圖19G說明前述記憶胞列及列系核心 部之平面圖案及剖面構成。圖19C係核心部及NAND胞之 _ -35- 本紙張尺度適用中國國家標準(CNS) A4規格(21〇 X 297公釐) 564548 A7 B7 五、發明説明(32 ) 平面圖。圖19D及圖19E係NAND胞之剖面圖,圖19D係圖 19C之19D-19D線、圖19E係圖19C之19E-19E線方向的剖面 構造。又,圖19F及圖19G係核心部之剖面圖,圖19F係圖 19C之19F-19F線、圖19G係圖19C之19G-19G線方向的剖面 構造。 首先,針對記憶胞列之構造進行說明。如圖19C至圖 19E所示,矽基板70上有帶狀之複數活性區域AA,相鄰之 活性區域AA間則設有元件隔離區域STI。活性區域AA上, 經由閘極絕緣膜71形成多晶矽層72,前述多晶矽層72係記 憶胞MC之浮動閘極FG、及選擇電晶體STI、ST2之選擇閘 極SGD、SGS的一部份。閘極絕緣膜71所使用之材料,例 如矽氧化膜或氮氧化合物膜等。又,活性區域AA及元件 隔離區域STI上,沿著和活性區域AA交差之方向,設有多 晶矽層74。多晶矽層74為覆蓋多晶矽層72之形狀,且經由 閘極間絕緣膜73沿設於多晶矽層72上。閘極間絕緣膜73例 如為矽氧化膜、矽氮化膜、矽氧化膜之3層構造的ΟΝΟ 膜、矽氧化膜之單層膜、以及矽氧化膜及矽氮化膜之2層 構造的ON膜或NO膜等。多晶矽層74係記憶胞MC、…之位 元線WL1〜WL16、選擇電晶體STI、ST2之選擇閘極線 S GD、SGS的一部份。因碎基板70内設有成為源極及沒極 之雜質擴散層75,故形成記憶胞MC及選擇電晶體ST1、 ST2。又,選擇電晶體STI、ST2之多晶矽層72、74會在如 圖上未標示之分流區域等實施電性連結。 又,矽基板70上,以覆蓋記憶胞MC及選擇電晶體ST1、 -3 6 - 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐) 564548 A7 丨 B7 五、發明説明(33 ) ST2方式設置層間絕緣膜76。層間絕緣膜76内,具有選擇 閘門線SGD之選擇電晶體ST1的汲極區域,經由連結孔C1 連結之金屬配線層77。金屬配線層77具有位元線BL之機 能。又,層間絕緣膜76上,以覆蓋位元線BL方式設有層 間絕緣膜78。 如上面所述,16個記憶胞MC.....及含有選擇電晶體 ST1、ST2之η個NAND胞,會以夾著元件隔離區域STI、且 沿著字元線方向配置,而構成一個記憶胞塊BLK。記憶胞 列具有m個記憶胞塊BLK1〜BLKm。 前述構成之記憶胞列内的字元線WL1〜WL16,連結於控 制閘極線CG1〜CG16,此控制閘極線CG1〜CG16及選擇閘極 線SGD、SGS會延伸至列系核心部68。 其次,以圖19C、圖19F、及圖19G說明列系核心部68之 構成。 如圖所示,石夕基板7 0上,和前述記憶胞列相鄰之區域, 以矩陣狀配置著複數個活性區域AA,相鄰之活性區域AA 間則設有元件隔離區域STI。電性隔離之各活性區域AA, 都會形成傳輸閘極電晶體TGTD、TGTS、TGT、 TGT、…。這些傳輸閘極電晶體之構成上,具有設於活性 區域AA上之閘極絕緣膜71、設於閘極絕緣膜71上之閘極 間絕緣膜73、設於閘極間絕緣膜73上之多晶矽層74、及設 於活性區域AA内之雜質擴散層75。又,多晶矽層72、74 為傳輸閘極電晶體之閘極TG,兩者在活性區域AA上進行 電性連結。 -37- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐) 564548 A7 B7 五、發明説明(34 ) 前述核心部68之活性區域AA的行數,例如為4行。設於 同一列之活性區域AA的4個傳輸閘極電晶體閘極TG為共同 連結。 前述各傳輸閘極電晶體TGTD、TGTS、TGT、TGT、… 之雜質擴散層(汲極區域)75上,分別連結著對應之選擇閘 極線SGD、SGS、或控制閘極線CG1〜CG16。亦即,選擇閘 極線SGD、SGS、及控制閘極線CG1〜CG16,利用設置於層 間絕緣膜76内的分流配線79 (M0),延伸至設有對應之傳 輸閘極電晶體的活性區域AA上。且,經由連結孔C2連結 至對應之傳輸閘極電晶體的雜質擴散層75上《又,傳輸閘 極電晶體TGTD、TGTS、TGT、TGT、…之雜質擴散層(源 極區域)75,則以金屬配線層80連結至列主解碼器電路。 其次,經由此金屬配線層80,由列主解碼器電路對傳輸閘 極電晶體之源極區域施加電壓。 前述構成之列系核心部68上在核心部内位於最端部之行 的活性區域AA内,會形成連結於選擇閘極線SGD、SGS之 傳輸閘極電晶體TGTD、TGTS。圖19C之實例中,位於核 心部63内最靠近列主解碼器之行上的活性區域AA内,設 有傳輸閘極電晶體TGTD、TGTS。位於最靠近列主解碼器 之行上的活性區域AA的集合,即為活性區域群AA (ST)。 靠近記憶胞列61之第1行至第3行的活性區域AA上,只 設有連結於控制閘極線CG1〜CG16之傳輸閘極電晶體 TGT、TGT、···。亦即,從列主解碼器之第2〜4行的活性區 域AA内,並未形成傳輸閘極電晶體TGTD、TGTS。此由列 -38- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐) 564548 A7 B7 五、發明説明(35 ) 主解碼器所形成之弟2〜4行活性區域aa的各個集合即為活 性區域群AA (MC)。 活性區域群AA (ST)及相鄰之活性區域群aa (MC)間的元 件隔離區域STI寬度dl,會大於相鄰之活性區域群aA (MC) 間之元件隔離區域STI寬度(dl>d2)。 如上面所述,除了構成列系核心部68以外,尚將其連結 至記憶胞列61及列主解碼器。 其次,以圖20對前述NAND型快閃記憶體EEPROM之動 作進行簡單說明。圖20係寫入、讀取、及刪除時之選擇閘 極線及控制閘極線之電位關係。如前面所述,記憶胞列6 i 之寫入及讀取係以1頁為單位實施,删除則以塊為單位。 資料之窝入,係從距離位元線BL最遠之記憶胞MC開始 依序實施。首先,會對對應選取之記憶胞塊BLKi〜BLKm 的全部傳輸閘極電晶體閘極TG施加電壓Vpgm(例如20 V)。 利用此方式,傳輸閘極電晶體TGTD、TGTS、及TGT、 TGT、…會處於導通狀態。其次,列主解碼器會對連結於 選取之任一記憶胞MC之傳輸閘極電晶體TGT、TGT、…源 極區域,施加寫入電壓Vpgm(例如20 V)。又,對其他(未 選取之)傳輸閘極電晶體之源極區域施加中間電位Vppm(例 如7 V) °而對傳輸閘極電晶體tgTD及TGTS之源極區域分 別施加Vdd(例如5 V)及0 V。如上面所述,在對選取之選 擇電晶體ST 1的選擇閘極線SGD施加Vdd、對選取之記憶胞 的控制閘極線CG施加Vpgm、對未選取之記憶胞的控制閘 極線施加Vppm、對選擇電晶體ST2之選擇閘極線SGS施加0 -39- 本紙張尺度適用中國國家棣準(CNS) A4規格(21〇X297公釐)Line 564548 A7 _______ B7__ V. The description of the invention (31) is inserted and read, and the implementation of the deletion is in units of blocks. Various instructions, address signals, and cell data to be written are input to the input / output circuit 62. In addition, the input / output circuit 62 outputs data read from the memory cell 61 and latched in the read amplifier 63. The column address signal and the column address signal input to the input / output circuit 62 are provided to the address register 64. The column address signals latched in the address register 64 are provided to the row decoder 65 and decoded. Furthermore, the column address signals (block address signals, page address signals) latched to the address register 64 are supplied to the column decoder 66 and decoded. The sense amplifier 63 latches the cell data input to the input / output circuit 62 during writing. When reading, the cell data read from the memory cell block BLK1 ~ BLKm selected from the memory cell row 61 to each element line will also be latched. The column decoder 66 includes a column main decoder circuit (not shown in the figure) and a column core (column auxiliary decoder circuit) 68 corresponding to the memory cell blocks BLK1 to BLKm, respectively. The column core portion 68 is a circuit that provides a specific voltage to the selected gate lines SGD, SGS, and 16 word lines WL1 to WL16 in the selected block. With transmission gate transistors TGTD, TGTS, TGT, TGT, ... The gate TG of these transmission gate transistors TGTD, TGTS, TGT, TGT, ... are connected together. Each drain is connected to the selection gate lines SGD and SGS and the control gate lines CG1 to CG16. The column master decoder circuit applies a voltage corresponding to the page address signal to each source. The high voltage generating circuit 67 supplies a high voltage to the aforementioned column decoder 66 and the memory cell 61 according to the input command signal. Next, FIG. 19C to FIG. 19G are used to describe the planar pattern and cross-sectional structure of the core portion of the aforementioned memory cell array and column system. Figure 19C is the core part of the NAND cell. _ -35- This paper size is applicable to the Chinese National Standard (CNS) A4 specification (21 × 297 mm) 564548 A7 B7 V. Description of the plan (32). 19D and 19E are cross-sectional views of a NAND cell, FIG. 19D is a cross-sectional structure taken along a line 19D-19D of FIG. 19C, and FIG. 19E is a cross-sectional structure taken along a line 19E-19E of FIG. 19C. 19F and 19G are sectional views of the core portion, FIG. 19F is a sectional structure taken along the line 19F-19F of FIG. 19C, and FIG. 19G is a sectional structure taken along the line 19G-19G of FIG. 19C. First, the structure of the memory cell is described. As shown in FIGS. 19C to 19E, the silicon substrate 70 has a plurality of strip-shaped active regions AA, and an element isolation region STI is provided between adjacent active regions AA. On the active area AA, a polycrystalline silicon layer 72 is formed through a gate insulating film 71. The polycrystalline silicon layer 72 is a part of the floating gate FG of the memory cell MC and the selection gates SGD and SGS of the selection transistors STI and ST2. The material used for the gate insulating film 71 is, for example, a silicon oxide film or a nitrogen oxide film. A polysilicon layer 74 is provided on the active region AA and the device isolation region STI along a direction intersecting with the active region AA. The polycrystalline silicon layer 74 has a shape covering the polycrystalline silicon layer 72 and is disposed on the polycrystalline silicon layer 72 along the inter-gate insulating film 73. The gate-to-gate insulating film 73 is, for example, a silicon oxide film, a silicon nitride film, a three-layer structure of a silicon oxide film, a single-layer film of a silicon oxide film, and a two-layer structure of a silicon oxide film and a silicon nitride film. ON film or NO film. The polycrystalline silicon layer 74 is part of the memory cell MC,... Bit lines WL1 to WL16, and the selection gate lines S GD, SGS of the selection transistors STI, ST2. Since the impurity diffusion layer 75 serving as a source and an electrode is provided in the broken substrate 70, a memory cell MC and select transistors ST1 and ST2 are formed. In addition, the polycrystalline silicon layers 72 and 74 of the selected transistors STI and ST2 are electrically connected in a shunt region or the like not shown in the figure. In addition, the silicon substrate 70 covers the memory cell MC and the selection transistors ST1, -3 6-This paper size applies the Chinese National Standard (CNS) A4 specification (210 X 297 mm) 564548 A7 丨 B7 V. Description of the invention ( 33) The interlayer insulating film 76 is provided in the ST2 manner. The interlayer insulating film 76 has a metal wiring layer 77 connected to the drain region of the selection transistor ST1 of the selection gate line SGD through the connection hole C1. The metal wiring layer 77 has a function of a bit line BL. An interlayer insulating film 78 is provided on the interlayer insulating film 76 so as to cover the bit lines BL. As described above, 16 memory cells MC ..... and n NAND cells containing the selection transistors ST1 and ST2 are arranged along the word line with the element isolation region STI sandwiched therebetween. Memory cell block BLK. The memory cell array has m memory cell blocks BLK1 to BLKm. The word lines WL1 to WL16 in the memory cell array of the foregoing configuration are connected to the control gate lines CG1 to CG16, and the control gate lines CG1 to CG16 and the selection gate lines SGD and SGS will extend to the column core portion 68. Next, the configuration of the column core portion 68 will be described with reference to Figs. 19C, 19F, and 19G. As shown in the figure, on the Shi Xi substrate 70, a plurality of active regions AA are arranged in a matrix in a region adjacent to the aforementioned memory cell array, and an element isolation region STI is provided between adjacent active regions AA. The electrically isolated active regions AA all form transmission gate transistors TGTD, TGTS, TGT, TGT, .... These transmission gate transistors have a gate insulating film 71 provided on the active region AA, a gate insulating film 73 provided on the gate insulating film 71, and a gate insulating film 73 provided on the gate insulating film 71. A polycrystalline silicon layer 74 and an impurity diffusion layer 75 provided in the active region AA. In addition, the polycrystalline silicon layers 72 and 74 are gate TGs of transmission gate transistors, and the two are electrically connected to each other in the active region AA. -37- This paper size is in accordance with Chinese National Standard (CNS) A4 (210 X 297 mm) 564548 A7 B7 V. Description of the invention (34) The number of rows of the active area AA of the aforementioned core section 68 is, for example, 4 rows. The four transmission gate transistors TG provided in the active area AA of the same row are connected in common. The impurity diffusion layers (drain regions) 75 of the aforementioned transmission gate transistors TGTD, TGTS, TGT, TGT, ... are connected to corresponding selection gate lines SGD, SGS, or control gate lines CG1 to CG16, respectively. That is, the gate lines SGD, SGS, and control gate lines CG1 to CG16 are selected, and the shunt wiring 79 (M0) provided in the interlayer insulating film 76 is extended to the active area where the corresponding transmission gate transistor is provided. AA. Moreover, the impurity diffusion layer 75 (the source region) 75 of the corresponding transmission gate transistor TGTD, TGTS, TGT, TGT, ... is connected to the impurity diffusion layer 75 of the corresponding transmission gate transistor through the connection hole C2. A metal wiring layer 80 is connected to the column master decoder circuit. Next, a voltage is applied to the source region of the transmission gate transistor by the column master decoder circuit via the metal wiring layer 80. The above-mentioned structure is formed in the core region 68 in the active region AA located at the end of the core region, and the transmission gate transistors TGTD and TGTS connected to the selected gate lines SGD and SGS are formed. In the example of Fig. 19C, the transmission gate transistors TGTD and TGTS are provided in the active area AA on the row closest to the column main decoder in the core portion 63. The set of active areas AA on the row closest to the column main decoder is the active area group AA (ST). On the active area AA of the first to third rows near the memory cell 61, only the transmission gate transistors TGT, TGT, ... connected to the control gate lines CG1 to CG16 are provided. In other words, the transmission gate transistors TGTD and TGTS are not formed in the active area AA of the second to fourth rows of the slave master decoder. This column -38- This paper size applies the Chinese National Standard (CNS) A4 specification (210 X 297 mm) 564548 A7 B7 V. Description of the invention (35) The main decoder 2 to 4 rows of active area aa Each set is the active area group AA (MC). The element isolation region STI width dl between the active region group AA (ST) and the adjacent active region group aa (MC) is larger than the element isolation region STI width (dl > d2) between the adjacent active region groups aA (MC). ). As described above, in addition to constituting the column core portion 68, it is connected to the memory cell 61 and the column master decoder. Next, the operation of the aforementioned NAND flash memory EEPROM will be briefly described with reference to FIG. Figure 20 shows the potential relationship between the selected gate line and the control gate line when writing, reading, and deleting. As mentioned earlier, the writing and reading of the memory cell array 6 i is performed in units of one page, and the deletion is performed in units of blocks. The entry of data is implemented sequentially from the memory cell MC farthest from the bit line BL. First, a voltage Vpgm (for example, 20 V) is applied to all the transmission gate transistors TG corresponding to the selected memory cell blocks BLKi to BLKm. In this way, the transmission gate transistors TGTD, TGTS, and TGT, TGT, ... will be in a conducting state. Secondly, the column master decoder applies a write voltage Vpgm (for example, 20 V) to the source regions of the transmission gate transistors TGT, TGT, ... connected to any selected memory cell MC. In addition, an intermediate potential Vppm (for example, 7 V) is applied to the source regions of other (unselected) transmission gate transistors, and Vdd (for example, 5 V) is applied to the source regions of the transmission gate transistors tgTD and TGTS, respectively. And 0 V. As described above, Vdd is applied to the selected gate line SGD of the selected selection transistor ST 1, Vpgm is applied to the control gate line CG of the selected memory cell, and Vppm is applied to the control gate line of the unselected memory cell. 3. Apply 0 -39 to the selection gate line SGS of the selection transistor ST2. This paper size is applicable to China National Standard (CNS) A4 specification (21 × 297 mm)

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線 564548 A7 B7 五、發明説明(36 ) V的狀態下,對位元線BL施加對應資料之Ο V或中間電位 Vm(例如7 V)。對位元線BL施加0V時,此電位會被傳送至 記憶胞之汲極,並使電子流入浮動閘極FG。利用此方 式,選取之記憶胞電晶體的臨界值電壓會朝正向移動。此 狀態為寫入’’ 〇π資料之狀態。另一方面,對位元線BL施加 中間電位Vm時,因不會流入電子,臨界值電壓不會改變 而保持負值。此狀態為寫入” Γ資料之狀態。又,資料寫 入係同時針對共用控制閘極線CG之全部記憶胞MC、 MC、…實施。 資料之刪除係針對塊内之全部位元整體實施。首先,針 對對應選取之任一記憶胞塊BLK1〜BLKm的全部傳輸閘極 電晶體閘極TG施加電壓Vpgm(例如20 V)。利用此方式,傳 輸閘極電晶體TGTD、TGTS、及TGT、TGT、…會處於導 通狀態。接著,列主解碼器會對連結於記憶胞MC、 MC、…之傳輸閘極電晶體TGT、TGT、…的全部源極區域 施加0 V,並對傳輸閘極電晶體TGTD及TGTS之源極區域 分別施加寫入電壓Vpgm(例如20 V)。利用此方式,在全部 控制閘極CG1〜CG16之電位為0 V狀態下,對前述NAND胞 形成之矽基板中的p型凹部(圖上未標示)施加20 V。利用此 方式,全部記憶胞MC、MC、…之浮動閘極FG的電子會釋 放至p型凹部。結果,記憶胞MC之臨界值電壓會朝負方向 移動,而執行資料刪除。 資料讀取時,和寫入及刪除時相同,首先,對對應選取 之任一記憶胞塊BLK1〜BLKm之全部傳輸閘極電晶體閘極 -40- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐) 564548 A7 B7 五、發明説明(37 ) TG施加電壓Vpgm(例如20 V)。使傳輸閘極電晶體TGTD、 TGTS及TGT、TGT、…處於導通狀態。接著,列主解碼器 對連結於選取之記憶胞MC的傳輸閘極電晶體TGT源極區 域施加0 V。同時,對連結於未選取之記憶胞MC、 MC、…的傳輸閘極電晶體TGT、TGT、…源極區域,施加 讀取電位Vdd(例如、5 V)。又,對傳輸閘極電晶體TGTD 及TGTS之源極區域分別施加電壓Vdd(例如5 V)。如此,在 對選擇電晶體ST1、ST2之選擇閘極線SGD、SGS、及未選 取之記憶胞控制閘極線施加Vdd、以及對選取之記憶胞控 制閘極線施加0 V的狀態下,依據檢測選取之記憶胞是否 流過電流,執行讀取動作。 如上面所述,利用本實施形態之NAND型快閃記憶體 EEPROM,會以行方式,在歹J系核心部68内之端部,形成 必須形成之傳輸閘極電晶體TGTD、TGTS的活性區域AA。 亦即,將連結於選擇閘極線之傳輸閘極電晶體TGTD、 TGTS、以及連結於控制閘極線之傳輸閘極電晶體TGT相鄰 之區域,設置於列系核心部68内受到限定的區域内(圖19C 之區域XI)。因此,傳輸閘極電晶體TGTD、TGTS、以及 傳輸閘極電晶體TGT間之耐壓,只需考慮此區域XI即可。 因此,只要使區域XI之寬度dl大於相鄰傳輸閘極電晶體 TGT間之區域X2寬度d2,則可充份維持核心部内之元件隔 離。換言之,為了維持傳輸閘極電晶體間之耐壓而必須擴 大寬度之元件隔離區域STI,只限於區域XI而已。 以圖21A及圖21B針對前述諸點進行更具體之說明。圖 -41- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐)Line 564548 A7 B7 V. Description of the invention (36) In the state of V, apply 0 V or an intermediate potential Vm (for example, 7 V) of corresponding data to the bit line BL. When 0V is applied to the bit line BL, this potential is transferred to the drain of the memory cell, and electrons flow into the floating gate FG. In this way, the threshold voltage of the selected memory cell transistor will move forward. This state is a state in which '' 0π data is written. On the other hand, when an intermediate potential Vm is applied to the bit line BL, since no electrons flow in, the threshold voltage does not change and remains negative. This state is the state of writing "Γ" data. In addition, data writing is simultaneously performed on all the memory cells MC, MC, ... of the common control gate line CG. Data is deleted as a whole for all bits in the block. First, a voltage Vpgm (for example, 20 V) is applied to all the transmission gate transistors TG corresponding to any of the selected memory cell blocks BLK1 to BLKm. In this way, the transmission gate transistors TGTD, TGTS, and TGT, TGT , ... will be in a conducting state. Next, the column master decoder applies 0 V to all source regions of the transmission gate transistors TGT, TGT, ... connected to the memory cells MC, MC, ..., and applies the transmission gate voltage In the source regions of the crystals TGTD and TGTS, respectively, a write voltage Vpgm (for example, 20 V) is applied. In this way, under the condition that the potentials of all the control gates CG1 to CG16 are 0 V, the 20 V is applied to the p-type recess (not shown). In this way, all the electrons of the floating gate FG of the memory cells MC, MC, ... will be released to the p-type recess. As a result, the threshold voltage of the memory cell MC will be toward Move in negative direction while executing data Except when data is read, it is the same as when writing and deleting. First of all, the transmission gate transistor -40 of all the corresponding memory cell blocks BLK1 ~ BLKm is selected.-This paper standard applies Chinese national standard (CNS ) A4 specification (210 X 297 mm) 564548 A7 B7 V. Description of the invention (37) TG applies voltage Vpgm (for example, 20 V). The transmission gate transistors TGTD, TGTS and TGT, TGT, ... are in the conducting state. Then The main decoder applies 0 V to the source region of the transmission gate transistor TGT connected to the selected memory cell MC. At the same time, the transmission gate transistor TGT, connected to the unselected memory cell MC, MC, ... In the TGT, ... source region, a read potential Vdd (for example, 5 V) is applied. In addition, a voltage Vdd (for example, 5 V) is applied to the source regions of the transmission gate transistors TGTD and TGTS. In the state where the selected gate lines SGD, SGS of the crystals ST1 and ST2 and the unselected memory cell control gate line are applied with Vdd, and the selected memory cell control gate line is applied with 0 V, whether the selected memory cell is detected A current flows to perform a read operation. Using the NAND-type flash memory EEPROM of this embodiment, the active region AA of the transmission gate transistor TGTD, TGTS, which must be formed, is formed in the end portion of the JJ core portion 68 in a row manner. The adjacent areas of the transmission gate transistors TGTD, TGTS connected to the selected gate line, and the transmission gate transistors TGT connected to the control gate line are arranged in a limited area within the column core portion 68 (Area XI in Figure 19C). Therefore, the withstand voltage between the transmission gate transistor TGTD, TGTS, and the transmission gate transistor TGT only needs to consider this area XI. Therefore, as long as the width d1 of the region XI is larger than the width d2 of the region X2 between adjacent transmission gate transistors TGT, the isolation of the elements in the core portion can be sufficiently maintained. In other words, in order to maintain the withstand voltage between the transmission gate transistors, the element isolation region STI, which has to be widened, is limited to the region XI. The foregoing points will be described more specifically with reference to FIGS. 21A and 21B. Figure -41- This paper size applies to China National Standard (CNS) A4 (210 X 297 mm)

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線 564548 A7 ___B7 1、發明説明(38 ) _ 21A係NAND型快閃記憶體EEPROM之核心部平面圖,圖 21B係圖21A之21B-21B的剖面圖。又,核心部内位於同一 列之各傳輸閘極電晶體’不必全部對應同一記憶胞塊。如 前面所述,連結於設置在同一列内之傳輸閘極電晶體TGT 的控制閘極線之設計上,必須使控制閘極線不會發生選 取、未選取狀態相鄰的情形。 圖21A中,選擇閘極線SGD10連結於未選取之塊内的線 電晶體。所以,會對設有連接於選擇閘極線SGD10之傳輸 閘極電晶體TGTD10的活性區域AA10(雜質擴散層75)内施 加0 V。又,連結於位於和傳輸閘極電晶體TGTD10同一列 之傳輸閘極電晶體TGT11〜TGT13的控制閘極線CG11〜CG13 會被選擇寫入。因此,會對設有傳輸閘極電晶體 TGT11〜TGT13之活性區域AA11〜AA13(雜質擴散層)施加高 電壓Vpgm。 故如圖21B所示,活性區域AA10及AA11間會產生Vpgm 之電位差。所以,活性區域AA10及AA11間之元件隔離區 域STI的寬度dl,必須大於活性區域AA11及AA12、及活性 區域AA12及AA13間之元件隔離區域STI的寬度d2。 其次,連結於設於和前述活性區域AA10不同列之活性 區域AA20上之傳輸閘極電晶體TGTD20的選擇閘極線 SGD,亦為未選取塊。所以,會對此活性區域AA20施加0 V。又,連接於和傳輸閘極電晶體TGTD20同一列之傳輸閘 極電晶體TGT21〜TGT23的控制閘極線CG21〜CG23會被選擇 寫入。故,也會對設有傳輸閘極電晶體TGT21〜TGT23之活 -42- 本紙張尺度適用中國國家標準(CNS) A4規格(210X 297公釐) 564548 A7 B7 五、發明説明(39 ) 性區域AA21〜AA23施加高電壓Vpgm。 因此,和圖21B相同,在活性區域AA20及AA21間會產生 Vpgm之電位差。所以,活性區域AA20及AA21間之元件隔 離區域STI的寬度dl,必須大於活性區域AA21及AA22、及 活性區域AA22及AA23間之元件隔離區域STI的寬度d2。 因此,如發明背景之說明所示,連結於選擇閘極線之傳 輸閘極電晶體、及連結於控制閘極線之傳輸閘極電晶體間 的元件隔離區域,若其寬度不大於連結於控制閘極線之傳 輸閘極電晶體間的元件隔離區域時,則無法維持元件隔 離。如前面所述,習知方法時,連結於此選擇閘極線之傳 輸閘極電晶體、及連結於控制閘極線之傳輸閘極電晶體間 的元件隔離區域,會以隨機方式出現於核心部内。 然而,本實施形態中,只有位於核心部内之端部的同一 行活性區域(AA10、AA20)内,才設有連結於選擇閘極線 SGD、SGS之傳輸閘極電晶體TGTD、TGTS。所以,只要 擴大核心部内最靠近列主解碼器電路之行的活性區域 (AA10、AA20、AA30、…)、及第2行之活性區域(AA11、 AA21、AA31、…)間之元件隔離區域的寬度即可。其他區 域之元件隔離區域則無擴大寬度之必要。所以,可以將核 心部内之面積增加控制在最小,亦可充份維持元件隔離區 域之絕緣耐性。 其次,以圖22A至圖22C說明本實施形態第4實施形態之 半導體裝置。圖22A係列系核心部之平面圖。圖22B及圖 22C貝J為圖22A之22B-22B線及22C-22C線的剖面圖。 -43- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐) 564548 A7 B7 五、發明説明(40 ) 如圖所示,本實施形態中,習知構成(參照圖1A及圖1B) 上,位於同一列内之傳輸閘極電晶體的閘極TG會以傳輸 閘極電晶體為單位進行隔離。而且,利用高於閘極TG之 水平的金屬配線層TGMETAL,對同一列内之各傳輸閘極 電晶體的閘極TG實施電性共同連結。 亦即,如圖22A至圖22C所示,傳輸閘極電晶體閘極TG 之一部份的多晶矽層74,在隔離活性區域AA之列間的元 件隔離區域STI上,到閘極間絕緣膜73為止都會被去除。 結果,以各傳輸閘極電晶體為單位進行隔離之多晶矽層 72、74即可形成閘極TG。而且,選擇閘極線SGD、SGS、 及控制閘極線CG之分流配線79所在的水平層間絕緣膜76 内,設有金屬配線層82。此金屬配線層82利用同一列内之 傳輸閘極電晶體的閘極TG及插頭接點8 1連結。亦即,金 屬配線層具有共同連結同一列内之傳輸閘極電晶體閘極 TG的配線TGMETAL機能。 利用前述構成,隔離活性區域AA之列間的元件隔離區 域STI上,沒有閘極TG。所以,即使對該閘極TG施加高電 壓Vpgm時,亦不會對元件隔離區域STI施加高電壓Vpgm。 故,可防止元件隔離區域STI周邊之矽基板70内形成反轉 區域。結果,未增加元件隔離區域寬度亦可維持元件隔 離。 其次,以NAND型快閃記憶體EEPROM為例,說明本發 明第5實施形態之半導體裝置。圖23 A係列系核心部之平面 圖。圖23B係圖23A之23B-23B線的剖面圖。 -44- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐)Line 564548 A7 ___B7 1. Description of the invention (38) _ 21A is a plan view of the core part of a NAND flash memory EEPROM, and FIG. 21B is a cross-sectional view of 21B-21B of FIG. 21A. Moreover, the transmission gate transistors' in the same row in the core need not all correspond to the same memory cell block. As mentioned above, the design of the control gate lines connected to the transmission gate transistors TGT arranged in the same row must prevent the control gate lines from being adjacent to each other in the selected or unselected state. In Fig. 21A, a gate transistor SGD10 is connected to a wire transistor in an unselected block. Therefore, 0 V is applied to the active region AA10 (impurity diffusion layer 75) provided with the transmission gate transistor TGTD10 connected to the selected gate line SGD10. The control gate lines CG11 to CG13 connected to the transmission gate transistors TGT11 to TGT13 in the same column as the transmission gate transistor TGTD10 are selected for writing. Therefore, a high voltage Vpgm is applied to the active regions AA11 to AA13 (impurity diffusion layers) provided with the transfer gate transistors TGT11 to TGT13. Therefore, as shown in FIG. 21B, a potential difference of Vpgm occurs between the active regions AA10 and AA11. Therefore, the width dl of the element isolation region STI between the active regions AA10 and AA11 must be larger than the width d2 of the element isolation region STI between the active regions AA11 and AA12 and the active regions AA12 and AA13. Secondly, the selected gate line SGD connected to the transmission gate transistor TGTD20 on the active region AA20 in a different row from the aforementioned active region AA10 is also an unselected block. Therefore, 0 V is applied to this active region AA20. In addition, the control gate lines CG21 to CG23 connected to the transmission gate transistors TGT21 to TGT23 in the same row as the transmission gate transistor TGTD20 are selected for writing. Therefore, it will also be used for the transmission gate transistor TGT21 ~ TGT23 -42- This paper size applies the Chinese National Standard (CNS) A4 specification (210X 297 mm) 564548 A7 B7 V. Description of the invention (39) AA21 to AA23 apply a high voltage Vpgm. Therefore, as in FIG. 21B, a potential difference of Vpgm occurs between the active regions AA20 and AA21. Therefore, the width dl of the element isolation region STI between the active regions AA20 and AA21 must be larger than the width d2 of the element isolation region STI between the active regions AA21 and AA22 and the active regions AA22 and AA23. Therefore, as shown in the description of the background of the invention, if the width of the element isolation area between the transmission gate transistor connected to the selected gate line and the transmission gate transistor connected to the control gate line is not greater than that connected to the control When a gate line transmits a device isolation region between gate transistors, the device isolation cannot be maintained. As mentioned above, in the conventional method, the isolation region between the transmission gate transistor connected to the selected gate line and the transmission gate transistor connected to the control gate line will appear at the core in a random manner. Inside. However, in this embodiment, the transmission gate transistors TGTD and TGTS connected to the selection gate lines SGD and SGS are provided only in the same row of active regions (AA10, AA20) located at the ends in the core portion. Therefore, as long as the active area (AA10, AA20, AA30, ...) of the row closest to the column main decoder circuit in the core is enlarged, the element isolation area between the active area of the second row (AA11, AA21, AA31, ...) is expanded. Just the width. Element isolation areas in other areas are not necessary to increase the width. Therefore, the area increase in the core portion can be controlled to a minimum, and the insulation resistance of the device isolation area can be sufficiently maintained. Next, a semiconductor device according to a fourth embodiment of the present embodiment will be described with reference to Figs. 22A to 22C. Figure 22A is a plan view of the core. 22B and 22C are cross-sectional views taken along lines 22B-22B and 22C-22C of FIG. 22A. -43- This paper size is in accordance with Chinese National Standard (CNS) A4 (210 X 297 mm) 564548 A7 B7 V. Description of the invention (40) As shown in the figure, in this embodiment, the conventional structure (refer to Figure 1A and In Figure 1B), the gate TG of the transmission gate transistors located in the same column is isolated by the transmission gate transistor as a unit. Furthermore, the metal wiring layer TGMETAL, which is higher than the gate TG level, is used to electrically connect the gates TG of the transmission gate transistors in the same column to each other. That is, as shown in FIG. 22A to FIG. 22C, the polycrystalline silicon layer 74 that transmits a part of the gate transistor TG is on the element isolation region STI between the columns of the isolation active region AA to the inter-gate insulating film Will be removed until 73. As a result, the gates TG can be formed by the polycrystalline silicon layers 72, 74 which are isolated by each transmission gate transistor as a unit. Further, a metal wiring layer 82 is provided in the horizontal interlayer insulating film 76 where the shunt wiring 79 of the selected gate line SGD, SGS, and the control gate line CG is located. The metal wiring layer 82 is connected by the gate TG of the transmission gate transistor and the plug contact 81 in the same column. That is, the metal wiring layer has a function of wiring TGMETAL which connects the transmission gate transistors TG in the same column in common. With the foregoing configuration, the gate isolation electrode TG is not provided on the element isolation region STI between the columns of the isolation active region AA. Therefore, even when a high voltage Vpgm is applied to the gate TG, a high voltage Vpgm is not applied to the element isolation region STI. Therefore, it is possible to prevent a reverse region from being formed in the silicon substrate 70 around the element isolation region STI. As a result, the element isolation can be maintained without increasing the width of the element isolation region. Next, a NAND-type flash memory EEPROM is used as an example to describe a semiconductor device according to a fifth embodiment of the present invention. Figure 23 A Series is a plan view of the core. FIG. 23B is a sectional view taken along line 23B-23B of FIG. 23A. -44- This paper size applies to China National Standard (CNS) A4 (210 X 297 mm)

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線 564548 A7 B7 五、發明説明(41 ) 如圖所示,本實施形態之NAND型快閃記憶體EEPROM 的列系核心部68,係在第4實施形態說明之構造中,在沿 著控制閘極線CG方向相鄰之傳輸閘極電晶體間,增設模 擬閘極83。亦即,隔離活性區域AA之列間的元件隔離區 域STI上,會沿著位元線BL方向形成多晶矽膜33。此多晶 矽膜33會沿著控制閘極線CG方向通過相鄰之閘極TG間。 多晶石夕.膜33和閘極TG會以層間絕緣膜73形成電性隔離。 不論傳輸閘極電晶體之動作狀態為何,都會對多晶矽膜33 施加Ο V或-Vdd。 利用上述構成,會對模擬閘極83施加Ο V或負電位。所 以,模擬閘極83、元件隔離區域STI、及矽基板70構成之 寄生MOS電晶體會隨時保持斷開。因此,可防止元件隔離 區域STI周邊之矽基板内形成反轉區域。結果,未增加元 件隔離區域寬度亦可維持元件隔離。又,對模擬閘極施加 0 V或-Vdd,係寄生MOS電晶體為η通道時。寄生MOS電晶 體為Ρ通道時,亦可對模擬閘極施加+ Vdd。 其次,以NAND型快閃記憶體EEPROM為例,說明本發 明第6實施形態之非揮發性半導體記憶體。圖24係列系核 心部之平面圖。 如圖所示,本實施形態之NAND型快閃記憶體EEPROM 的列系核心部,係在第4實施形態說明圖22A之構造中,將 傳輸閘極電晶體TGTD、TGTS、TGT、…實施90度(旋轉。 亦即,各活性區域AA内,閘極TG沿著控制閘極線CG方向 (位元線方向)形成。 -45- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐) 564548 A7 _ B7 五、發明説明(42 ) 利用本構造,可以獲得和第4實施形態相同的效果。 又,本實施形態亦和第5實施形態相同,可在控制閘極線 方向相鄰之活性區域AA間設置模擬電極。 其次,以NAND型快閃記憶體EEPROM為例,說明本發 明第7實施形態之非揮發性半導體記憶體。圖25係列系核 心部之平面圖。 如圖.所示,本實施形態之NAND型快閃記憶體EEPROM 的列系核心部,係在第4實施形態說明圖22A之構造中,使 將選擇閘極線及控制閘極線延伸至列系核心部之配線位於 和記憶胞之字元線相同水平。利用設於其上方之2條金屬 配線層TGMETAL1 (MO)、TGMETAL2 (Ml),實施各傳輸閘 極電晶體之閘極TG的共同連結。又,例如,將金屬配線 層TGMETAL1設於層間絕緣膜76内,而將金屬配線層 TGMETAL2設於層間絕緣膜78内。 本實施形態之金屬配線層TGMETAL1、TGMETAL2,和 前述第3至第6實施形態不同,係對配置於不同列之傳輸閘 極電晶體的電極TG實施共同連結。例如,如圖25所示,2 條金屬配線層TGMETAL1、TGMETAL2係交互連結於2個設 置於列内之傳輸閘極電晶體的電極TG。 如前面所述,將對傳輸閘極電晶體之閘極TG實施共同 連結的複數金屬配線層,以跨越不同列之方式配置,除了 具有前述第4實施形態之效果外,尚可抑制傳輸閘極電晶 體間之相互作用,可提高傳輸閘極電晶體的動作信賴度。 又,本實施形態中,若將選擇閘極線SGD (SGS)、控制 -46- 本紙張尺度適用中國國家榡準(CNS) A4規格(21〇 X 297公釐) 564548 A7 B7 五、發明説明(43 ) 閘極線CG、CG、…之延伸線、及金屬配線層 TGMETAL1、TGMETAL2分另J設於各向上一層之層間絕緣 膜内,則亦可設置第5實施形態說明之模擬閘極。此時, 可以再提高元件隔離區域STI之絕緣耐壓。 如前面所述,本發明之第3至第7實施形態時,在NAND 型快閃記憶體EEPROM之列系核心部,會將連結於選擇閘 極線SGD、SGS之傳輸閘極電晶體集合於核心部内之端部 的一行。因此,只有位於此1行之活性區域、及和此區域 鄰接之活性區域間,連結於選擇閘極線之傳輸閘極電晶 體、及連結於控制閘極線之傳輸閘極電晶體才會相鄰接。 亦即,只有本區域之元件隔離區域才需要高耐壓。此處所 指之耐壓,係指對利用寄生MOS電晶體在元件隔離區域周 圍形成通道區域時之耐壓。所以,只需擴大該區域之元件 隔離區域STI的寬度,其他區域則為原有之元件隔離區域 STI寬度,即可獲得活性區域之行間的元件隔離。因此, 可以將核心部内之面積增加抑制於最小,且可提高元件隔 離區域之絕緣耐壓。 又,以各傳輸閘極電晶體為單位實施傳輸閘極電晶體之 閘極的隔離。所以,對同一列内相鄰傳輸閘極電晶體之行 間上的元件隔離區域,不會施加使傳輸閘極電晶體成為導 通狀態之高電壓。所以,不會導致核心部面積增加,但可 提升元件隔離區域之耐壓。又,同一列内相鄰之元件隔離 區域上會形成模擬閘極。而且,模擬閘極之電位為可以使 寄生MOS電晶體成為斷開狀態之電位。因而可更進一步提 -47- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐) 564548 五、發明説明(44 ) 高元件隔離區域之耐壓。 又’第3實施形態中,係以連处认 丨了 乂逆〜於選擇閘極線之僂輪關 極電晶體位於最靠近列主解碼器之 „ , . ^ ^ ^詻又位置為例。然而,亦可 乂為最靠近記憶胞列之位置。又,第3實施形態中,只要 將j結於選擇閘線之全部傳輸閘極電晶體集合於核心部内 之端部的同一行即可〇因士卜 了各 、你认 U此不會妨礙連結於控制閘極線 <傳輸,閘極電晶體的任一和連社私 和運〜於選擇閘極線之傳輸閘極 電晶體位於同一行内。 又,前述第4至第7實施形態中,亦以連結於選擇間極線 之傳輸間極電晶體位於最靠近列主解碼器之位置為例。然 而,第4至第7實施形態中,以除去元件隔離區域上之間極 TG來提升元件隔離區域之耐壓。所以,不必將連結於選 擇閘極線之傳輸閘極電晶體配置於核心部内之端部的同一 订上。連結於選擇閘極線之傳輸間極電晶體,亦可以隨機 方式配置於核心部内。 又,第7實施形態中,金屬配線層TGMETAL係跨越2列 活性區域AA間,但亦可跨越更多列數。 又,則述第3至第7實施形態中,係以NAND型快閃記憶 體EEPROM為例進行說明,但是,可應用於所有有相鄰活 性區域間絕緣問題之半導體記憶裝置上。 在技術上’可以進行各種嚐試及修正。因此,本發明之 觀點並不限於此處之特定說明或實施。相對的,只要不背 離專利申請及其類似之本發明所定義之精神及範疇,可以 進行各種修正。 -48- 本紙張尺度適用中國國家標準(CNS)八^^297公Line 564548 A7 B7 V. Description of the Invention (41) As shown in the figure, the column core portion 68 of the NAND flash memory EEPROM of this embodiment is in the structure described in the fourth embodiment, and is along the control gate. An analog gate 83 is added between the transmission gate transistors adjacent to the pole line CG. That is, on the element isolation region STI between the columns of the isolation active region AA, a polycrystalline silicon film 33 is formed along the bit line BL direction. The polycrystalline silicon film 33 passes through the gates TG in the direction of the control gate line CG. The polycrystalline stone film 33 and the gate electrode TG are electrically separated by an interlayer insulating film 73. Regardless of the operating state of the transmission gate transistor, 0 V or -Vdd is applied to the polycrystalline silicon film 33. With the above configuration, 0 V or a negative potential is applied to the analog gate 83. Therefore, the parasitic MOS transistor formed by the analog gate 83, the element isolation region STI, and the silicon substrate 70 is kept off at any time. Therefore, it is possible to prevent the formation of the inverted region in the silicon substrate around the device isolation region STI. As a result, component isolation can be maintained without increasing the width of the component isolation region. In addition, 0 V or -Vdd is applied to the analog gate when the parasitic MOS transistor is η channel. When the parasitic MOS transistor is a P-channel, + Vdd can also be applied to the analog gate. Next, a non-volatile semiconductor memory according to the sixth embodiment of the present invention will be described using a NAND flash memory EEPROM as an example. Figure 24 is a plan view of the core of the series. As shown in the figure, the core of the column system of the NAND flash memory EEPROM of this embodiment is the structure shown in FIG. 22A of the fourth embodiment. The transmission gate transistors TGTD, TGTS, TGT, ... (Rotation. That is, in each active area AA, the gate TG is formed along the direction of the control gate line CG (bit line direction). -45- This paper size applies to the Chinese National Standard (CNS) A4 specification (210 X 297 mm) 564548 A7 _ B7 V. Description of the invention (42) With this structure, the same effect as that of the fourth embodiment can be obtained. In addition, this embodiment is also the same as the fifth embodiment, and can control the direction of the gate line. Analog electrodes are arranged between adjacent active areas AA. Next, a NAND-type flash memory EEPROM is taken as an example to explain the non-volatile semiconductor memory of the seventh embodiment of the present invention. Figure 25 is a plan view of the core part. As shown, the column core of the NAND flash memory EEPROM of this embodiment is the structure of FIG. 22A that explains the fourth embodiment, so that the selection gate line and the control gate line are extended to the column core. Wiring The word lines are at the same level. Using two metal wiring layers TGMETAL1 (MO) and TGMETAL2 (Ml) provided above them, the gate TG of each transmission gate transistor is connected in common. For example, the metal wiring layer TGMETAL1 is provided in the interlayer insulating film 76, and metal wiring layer TGMETAL2 is provided in the interlayer insulating film 78. The metal wiring layers TGMETAL1 and TGMETAL2 of this embodiment are different from the aforementioned third to sixth embodiments in that they are arranged differently The electrodes TG of the transmission gate transistors in the column are connected in common. For example, as shown in FIG. 25, two metal wiring layers TGMETAL1 and TGMETAL2 are alternately connected to two electrodes TG of the transmission gate transistor provided in the column. As described above, a plurality of metal wiring layers that are commonly connected to the gate TG of the transmission gate transistor are arranged in a manner that spans different columns. In addition to the effects of the fourth embodiment described above, the transmission gate can be suppressed. The interaction between the transistors can increase the reliability of the operation of the transmission gate transistor. In addition, in this embodiment, if the gate line SGD (SGS) is selected, the control -46- This paper is applicable to this paper China National Standards (CNS) A4 specification (21 × 297 mm) 564548 A7 B7 V. Description of the invention (43) Extension lines of the gate lines CG, CG, ..., and metal wiring layers TGMETAL1, TGMETAL 2 points separately In the interlayer insulating film that is one layer above, the analog gate described in the fifth embodiment can also be provided. At this time, the insulation withstand voltage of the device isolation region STI can be further increased. As described above, the third to third aspects of the present invention In the seventh embodiment, in the core portion of the NAND-type flash memory EEPROM, the transmission gate transistors connected to the selection gate lines SGD and SGS are collected in a row at the end portion in the core portion. Therefore, only the active region located in this row and the active region adjacent to this region, the transmission gate transistor connected to the selected gate line and the transmission gate transistor connected to the control gate line will be in phase with each other. Adjacency. That is, only the element isolation region in this region needs a high withstand voltage. The withstand voltage here refers to the withstand voltage when a parasitic MOS transistor is used to form a channel region around the element isolation region. Therefore, by simply increasing the width of the element isolation region STI in this region, the other regions are the original element isolation region STI width to obtain the element isolation between the rows of the active region. Therefore, the increase in the area in the core portion can be suppressed to a minimum, and the insulation withstand voltage of the device isolation region can be improved. The gates of the transmission gate transistors are isolated in units of transmission gate transistors. Therefore, a high voltage is not applied to an element isolation region between rows of adjacent transmission gate transistors in the same column to make the transmission gate transistors into a conductive state. Therefore, it does not cause the core area to increase, but it can increase the withstand voltage of the component isolation area. In addition, an analog gate is formed on an isolated area of adjacent elements in the same column. In addition, the potential of the analog gate is a potential at which the parasitic MOS transistor can be turned off. Therefore, it can be further mentioned that -47- This paper size is applicable to Chinese National Standard (CNS) A4 specification (210 X 297 mm) 564548 V. Description of the invention (44) High voltage in the isolation area of the component. In the third embodiment, the inverse-recognition method is used to select the gate transistor of the gate line, which is located closest to the main decoder of the column. ^ ^ ^ 詻 is another example. However, it may be the position closest to the memory cell array. Also, in the third embodiment, all transmission gate transistors j connected to the selection gate line may be collected in the same row at the end of the core. Because of the various factors, do you think that this will not prevent the connection to the control gate line < transmission, any one of the gate transistor and the company's private business ~ the transmission gate transistor is selected in the same gate line In addition, in the aforementioned fourth to seventh embodiments, the transmission pole transistor connected to the selection pole line is located closest to the column main decoder as an example. However, in the fourth to seventh embodiments, In order to improve the withstand voltage of the element isolation area by removing the pole TG on the element isolation area, it is not necessary to arrange the transmission gate transistor connected to the selected gate line on the same end of the core. Link to Select the transmission line transistor of the gate line. In the seventh embodiment, the metal wiring layer TGMETAL spans between two rows of active regions AA, but it can also span more rows. In the third to seventh embodiments, The NAND flash memory EEPROM is taken as an example for description, but it can be applied to all semiconductor memory devices having insulation problems between adjacent active regions. Technically, various attempts and corrections can be made. Therefore, the present invention Views are not limited to the specific description or implementation here. On the contrary, as long as it does not depart from the spirit and scope defined by the patent application and similar inventions, various modifications can be made. Eight) ^^ 297

Claims (1)

564548564548 1. 一種半導體裝置,其特徵為··含有 半導體基板; 在則述半導體基板中形成,含有第1導電電型之第1雜 質的源極•汲極區域; 在前述源極•沒極區域間之前述半導體基板中形成, 含有第2導電型之第2雜質的通道區域; 在則述半導體基板上形成,至少在前述通道區域之部 份區域的正上方區域含有第2雜質之閘極絕緣膜; 在前述通道區域上方之前述閘極絕緣膜上形成的電荷 蓄積層;以及 設於前述電荷蓄積層上之控制閘極,此控制閘極係利 用設於前述電荷蓄積層上之連結部和前述電荷蓄積層實 施電性連結,而前述電荷蓄積層係至少位於含有第2雜 質之閘極絕緣膜區域中部份區域的正上方。 2.如申请專利範圍第1項之半導體裝置,其中 前述通道區域含有 同〉辰度通道區域、以及 設於前述高濃度通道區域之周圍,其雜質濃度低於前 述面;辰度通道區域之低濃度通道區域。 3·如申請專利範圍第1項之半導體裝置,其中 前述電荷蓄積層係浮動閘極。 4.如申請專利範圍第1項之半導體裝置,其中 更包含閘極間絕緣膜,其係設於前述電荷蓄積展上 於設有前述連結部之區域以外的區域,連結前述啦^ _ -51-1. A semiconductor device characterized in that it contains a semiconductor substrate; a source / drain region formed on the semiconductor substrate and containing a first impurity of a first conductivity type; and between the source and non-electrode regions A channel region containing the second impurity of the second conductivity type formed in the aforementioned semiconductor substrate; and a gate insulating film containing the second impurity at least in a region directly above a portion of the channel region A charge storage layer formed on the gate insulation film above the channel region; and a control gate provided on the charge storage layer, the control gate uses a connection portion provided on the charge storage layer and the foregoing The charge storage layer is electrically connected, and the charge storage layer is located at least directly above a part of the gate insulating film area containing the second impurity. 2. The semiconductor device according to item 1 of the patent application range, wherein the aforementioned channel region contains the same channel region and the surrounding region of the high-concentration channel region, the impurity concentration of which is lower than the aforementioned surface; Concentration channel area. 3. The semiconductor device according to item 1 of the patent application range, wherein the charge storage layer is a floating gate. 4. The semiconductor device according to item 1 of the scope of the patent application, which further includes an inter-gate insulating film, which is provided on the charge accumulation and development area other than the area where the connection portion is provided, and connects the foregoing ^ _ -51 - 本紙張尺度適用中國國家標準(CNS) Α4規格(210X297公釐) 564548 A8 B8 C8 -------- —__D8___ 六、申請專利範圍 積層及前述控制閘極者。 5.如申請專利範圍第4項之半導體裝置,其中 前述閘極間絕緣膜係矽氧化膜、矽氮化膜、及矽氧化 膜之層積膜。 6·如申請專利範圍第丨項之半導體裝置,其中 前述閘極絕緣膜係矽氧化膜及氮氧化合物膜之其一。 7·如申請專利範圍第丨項之半導體裝置,其中 前述通道區域内,沿著前述源極區域、通道區域、及 沒極區域之方向的雜質濃度分布,係取前述連結部正下 方區域之雜質濃度的最大值。 8·如申請專利範圍第2項之半導體裝置,其中 前述高濃度通道區域係設於前述半導體基板内,且其 係设於至少含有前述閘極絕緣膜中佈植有前述第2雜質 之區域的正下方的區域。 9· 一種半導體裝置,其特徵為:含有 半導體基板; 設於前述半導體基板上之記憶胞電晶體;及 設於前述半導體基板上之選擇電晶體,且 前述記憶胞電晶體含有 在則述半導體基板中形成且含有第1導電型第1雜質之 第1源極•汲極區域; 在前述第1源極·汲極區域間之前述半導體基板中形 成且含有第i雜質濃度之第2導電型第2雜質的第1通道區 域; -52-This paper size is applicable to China National Standard (CNS) A4 specification (210X297 mm) 564548 A8 B8 C8 -------- —__ D8___ 6. Scope of patent application The layered and the aforementioned control gate. 5. The semiconductor device according to item 4 of the scope of patent application, wherein the inter-gate insulating film is a laminated film of a silicon oxide film, a silicon nitride film, and a silicon oxide film. 6. The semiconductor device according to the first item of the patent application scope, wherein the gate insulating film is one of a silicon oxide film and a nitrogen oxide compound film. 7. The semiconductor device according to item 丨 of the patent application range, wherein the impurity concentration distribution in the channel region along the direction of the source region, the channel region, and the non-electrode region is based on the impurities in the region directly below the connection portion. The maximum concentration. 8. The semiconductor device according to item 2 of the scope of patent application, wherein the high-concentration channel region is provided in the semiconductor substrate, and it is provided in a region containing at least the gate impurity film in which the second impurity is implanted. The area directly below. 9. A semiconductor device, comprising: a semiconductor substrate; a memory cell crystal provided on the semiconductor substrate; and a selection transistor provided on the semiconductor substrate, and the memory cell crystal is contained on the semiconductor substrate A first source / drain region formed in the semiconductor substrate and containing a first conductivity type first impurity; a second conductivity type second semiconductor layer formed in the semiconductor substrate between the first source and drain regions and containing an i-th impurity concentration 2 impurity 1st channel region; -52- 叹於則述第1通道區域上之第1閘極絕緣膜; P又於如述第1閘極絕緣膜上之第1電荷蓄積層; 又於則述第1電荷蓄積層上之第1閘極間絕緣膜;及 "又於則述第1閘極間絕緣膜上之第1控制閘極,且 前述選擇電晶體含有: ^在前述半導體基板中形成且含有第1導電型第3雜質之 第2源極•汲極區域; 、在前述第2源極·汲極區域間之前述半導體基板中形 成且含有高於前述第丨雜質濃度之第2雜質濃度的第2導 電型第4雜質之第2通道區域; ^設於前述第2通道區域上且至少有部份區域含有前述 第4雜質之第2閘極絕緣膜; 在前述第2閘極絕緣膜上形成之第2電荷蓄積層;及 設於前述第2電荷蓄積層上之第2控制閘極,且 々前述第2控制閘極和前述第2電荷蓄積層係以設於前述 第2電荷蓄積層上之連結部實施電性連結,前述第2電荷 蓄積層至少有部份區域係位於前述第2閘極絕緣膜含前 述第4雜質之區域的正上方。 10·如申請專利範圍第9項之半.導體裝置,其中 前述第2通道區域含有高濃度通道區域、以及 設於前述高濃度通道區域·之周圍,其雜質濃度低於前 述高濃度通道區域之低濃度通道區域。 11.如申請專利範圍第9項之半導體裝置,其中 前述第1、第2閘極絕緣膜、前述第1、第2電荷蓄積 -53-本紙張尺度適用中國國家梂準(CNS) Α4規格(210X297公釐) 564548Sighing about the first gate insulating film on the first channel region; P about the first charge storage layer on the first gate insulating film; and about the first gate on the first charge storage layer The inter-electrode insulation film; and the first control gate electrode on the first inter-gate insulation film, and the selection transistor contains: ^ formed in the semiconductor substrate and contains a first conductivity type third impurity A second source-drain region; a second conductivity-type fourth impurity formed on the semiconductor substrate between the second source-drain region and containing a second impurity concentration higher than the second impurity concentration A second channel region; a second gate insulating film provided on the second channel region and at least a part of which contains the fourth impurity; a second charge accumulation layer formed on the second gate insulating film ; And a second control gate provided on the second charge storage layer, and the second control gate and the second charge storage layer are electrically connected to each other by a connection portion provided on the second charge storage layer; Connection, at least part of the area of the second charge accumulation layer is located in the second gate Immediately above said fourth impurity region of the front-containing insulating film. 10. The conductor device according to item 9 of the scope of the patent application, wherein the second channel region contains a high-concentration channel region and is provided around the high-concentration channel region. Its impurity concentration is lower than that of the high-concentration channel region. Low concentration channel area. 11. The semiconductor device according to item 9 of the scope of the patent application, wherein the aforementioned first and second gate insulating films and the aforementioned first and second charge accumulations -53- This paper standard is applicable to China National Standards (CNS) A4 specifications ( 210X297 mm) 564548 及前述第!、第2控制間極分別具有實質相同之膜 12·如申請專利範圍第9項之半導體裝置,其中 則述第2通道區域之通道長度大於前述第丨通道區 通道長度。 ’ 13·如申請專利範圍第9項之半導體裝置,其中 削述第2電荷蓄積層係浮動閘極。 14·如申請專利範圍第9項之半導體裝置,其中 吏l έ第2閘極間絕緣膜,其係設於前述第2電荷蓄積 層上,於設有前述連結部之區域以外的區域,連結前述 第2電荷蓄積層及前述第2控制閘極者。 15. 如申请專利範圍第9項之半導體裝置,其中 前述、選擇電晶體之臨界值電壓的通道長度依存性,不 同於前述記憶胞電晶體之臨界值電壓的通道長度依存 性。 16. 如申請專利範圍第14項之半導體裝置,其中 前述第1、第2閘極間絕緣膜係矽氧化膜、矽氮化膜、 及矽氧化膜之層積膜。 ~ 17·如申請專利範圍第9項之半導體裝置,其中 前述第1、第2閘極絕緣膜係矽氧化膜及氮氧化合物膜 之其一。 18·如申請專利範圍第9項之半導體裝置,其中 前述第2通道區域内,沿著前述第2源極區域、第2通 道區域、及第2汲極區域之方向的雜質濃度分布,係取 -54- 本紙張尺度適用中國國家標準(CNS) Α4規格(210X297公羡) 564548 六、申請專利範圍 月’j述連結部正下方區域之雜質濃度的最大值。 19. 如申凊專利範圍第1〇項之半導體裝置,其中 則述尚濃度通道區域係設於前述半導體基板内,且其 係。又於至少含有前述第2閘極絕緣膜中佈植有前述第4雜 質之區域的正下方的區域。 ” 20. —種半導體裝置製造方法,其特徵為: 對半導體基板表面佈植第i濃度之第丨導電型雜質; 在前述半導體基板表面形成閘極絕緣膜;~ 在前述閘極絕緣膜形成電荷蓄積層; 在前述半導體基板中及前述閘極絕緣膜中形成元件隔 離區域; 在前述元件隔離區域及前述電荷蓄積層上形成閘極間 絕緣膜; 在如述閘極間絕緣膜上形成具有至少露出部份前述閘 極間絕緣膜表面之開口部的遮罩材; _經由前述遮罩材之開口部,對前述半導體基板中佈植 第1導電型雜質,其濃度為高於前述第丨濃度之第2濃 度; 在前述閘極間絕緣朦上形成控制閘極,且此控制閘極 經由已除去前述閘極間絕緣膜之區域和前述電荷蓄積層 相連結; 以前述電荷蓄積層、前述閘極間絕緣膜、及前述控制 閘極之圖案化來形成層積閘極;以及 對前述閘極周圍之前述半導體基板中佈植第2導電型 -55- 本紙張尺度適用巾關家樣準(CNS) A4規格(210X 297公董)And the aforementioned section! The second control electrode has substantially the same film, respectively. 12. For the semiconductor device in the ninth scope of the patent application, the channel length of the second channel region is greater than the channel length of the aforementioned channel region. 13. The semiconductor device according to item 9 of the scope of patent application, wherein the second charge accumulation layer is a floating gate. 14. The semiconductor device according to item 9 of the scope of patent application, wherein the second inter-gate insulation film is provided on the second charge storage layer and is connected in a region other than the region where the connection portion is provided. The second charge storage layer and the second control gate. 15. The semiconductor device according to item 9 of the patent application scope, wherein the channel length dependency of the threshold voltage of the transistor is different from the channel length dependency of the threshold voltage of the memory cell. 16. The semiconductor device according to item 14 of the scope of patent application, wherein the first and second inter-gate insulating films are laminated films of silicon oxide film, silicon nitride film, and silicon oxide film. ~ 17. The semiconductor device according to item 9 of the scope of patent application, wherein the first and second gate insulating films are one of a silicon oxide film and a nitrogen oxide film. 18. The semiconductor device according to item 9 of the scope of patent application, wherein the impurity concentration distribution in the second channel region along the direction of the second source region, the second channel region, and the second drain region is taken from -54- This paper size applies the Chinese National Standard (CNS) A4 specification (210X297). 564548 6. The scope of patent application: The maximum impurity concentration in the area directly below the connection section. 19. For a semiconductor device in the scope of claim 10 of the patent, the above-mentioned concentration channel region is provided in the aforementioned semiconductor substrate and is of the same type. A region immediately below the region containing the fourth impurity is implanted in at least the second gate insulating film. 20. A method for manufacturing a semiconductor device, comprising: implanting an i-th conductive impurity of the i-th concentration on the surface of a semiconductor substrate; forming a gate insulating film on the surface of the aforementioned semiconductor substrate; ~ forming a charge on the aforementioned gate insulating film An accumulating layer; forming an element isolation region in the semiconductor substrate and the gate insulating film; forming an inter-gate insulating film on the element isolating region and the charge accumulating layer; forming, on the inter-gate insulating film, at least A masking material that exposes the openings on the surface of the inter-gate insulation film; _ through the openings of the masking material, the first conductive impurity is implanted in the semiconductor substrate, the concentration of which is higher than the first concentration A second concentration; a control gate is formed on the inter-gate insulation layer, and the control gate is connected to the charge storage layer through a region where the inter-gate insulation film has been removed; and the charge storage layer and the gate are connected An inter-electrode insulating film and the patterning of the control gate to form a laminated gate; and in the semiconductor substrate around the gate Planting the second conductive type -55- This paper size is suitable for towel family standard (CNS) A4 (210X 297) 申請專利範Patent application 雜質’形成源極•汲極區域。 21·如=請專利範圍第2G項之半導體裝置製造方法,其中 二:相極間絕緣膜上形成前述遮罩材料係包括 在則述閘極間絕緣膜上形成前述遮罩材料.及 在前述遮罩材料中形成前述開口部。 22·種半導體裝置製造方法,其特徵為: 對:導體基板表面佈植第i濃度之幻導電型雜質,· 在則述半導體基板表面形成閘極絕緣膜; 在前述閘極絕緣膜形成電荷蓄積層j 、在則述半導體基板中及前述閘極絕緣膜中形成元件隔 離區域; 在則述7C件㉟g區域及前述電荷蓄積層上形成閉極間 絕緣膜;· 、 在第1第2電晶體預定形成區域之前述閘極間絕緣膜 上形成遮罩材料,此遮罩材料具有開口部,而從此開口 部至少會露出部份前述第丨電晶體預定形成區域之前述 閘極間笮緣膜表面; 經由前述遮罩材料之開口部,對前述半導體基板中伟 植第1導電型雜質,其濃度為高於前述第1濃度之第2濃 度; 除去則述遮罩材料開口部露出之前述閘極間絕緣膜; 在纟述閘極間絕緣膜上形成控制閘極,且此控制閘極 經由已除去前述閘極間絕緣膜之區域和前述電荷蓄積層 相連結; '56- 本紙張尺度適用中國國家標準(CNS) A4規格[21〇><297公着了 564548 A8 B8 C8The impurity 'forms a source-drain region. 21 · If = Please request a method for manufacturing a semiconductor device in the 2G item of the patent, wherein the second step: forming the aforementioned masking material on the inter-phase insulating film includes forming the aforementioned masking material on the inter-gate insulating film; The aforementioned opening is formed in the mask material. 22 · A method for manufacturing a semiconductor device, characterized in that: a surface of a conductor substrate is implanted with an i-th concentration of a phantom conductive impurity, and a gate insulating film is formed on the surface of the semiconductor substrate; a charge accumulation is formed on the gate insulating film; Layer j, forming an element isolation region in the semiconductor substrate and the gate insulating film; forming a closed-electrode insulating film on the 7C element ㉟g region and the charge accumulation layer; and, on the first and second transistors A masking material is formed on the aforementioned inter-gate insulating film in the predetermined formation region, and the masking material has an opening portion, and at least a part of the surface of the inter-gate marginal film in the aforementioned predetermined region of the transistor is exposed from this opening ; Through the opening portion of the masking material, the first conductive type impurity in the semiconductor substrate has a concentration higher than the second concentration of the first concentration; except for the gate electrode exposed by the opening portion of the masking material Inter-insulation film; a control gate is formed on the inter-gate insulation film, and the control gate passes through the region where the inter-gate insulation film has been removed and the charge accumulation Coupled; '56 - This applies China National Standard Paper Scale (CNS) A4 size [21〇 > < 297 with a well-564548 A8 B8 C8 以則述電荷蓄積層、前述閘極間絕緣膜、及前述 閘極心圖案化來形成前述第丨、第2電晶體之層積 以及 對前述閘極周圍之前述半導體基板中怖植第2導 雜質,形成前述第i、帛2電晶體之源極.沒極區域。 k 23·如申^專利範圍第22項之半導體裝置製造方法,其中 在前述閘極間絕緣膜上形成前述遮罩材料係包括 在前述閘極間絕緣膜上形成前述遮罩材料;及 在前述遮罩材料中形成前述開口部。 24. —種半導體裝置,其特徵為: 以元件隔離區域實施電性隔離,且含有沿著第1方向 設置之複數活性區域的第丨活性區域群; " 以兀件隔離區域實施電性隔離,且含有沿著第i方向 訂 之垂直方向設置之複數前述活性區域的第2活性 群;以及 巧The charge accumulation layer, the inter-gate insulation film, and the gate core are patterned to form a layer of the first and second transistors and to implant a second guide in the semiconductor substrate around the gate. The impurities form the source and non-electrode regions of the i-th, thorium-second transistors. k 23. The method of manufacturing a semiconductor device according to item 22 of the patent application, wherein forming the aforementioned masking material on the inter-gate insulating film includes forming the aforementioned masking material on the inter-gate insulating film; and The aforementioned opening is formed in the mask material. 24. A semiconductor device, characterized in that: an electrical isolation is performed by an element isolation region, and an active region group including a plurality of active regions arranged along a first direction; " an electrical isolation is performed by an element isolation region And contains a second active group of a plurality of the aforementioned active regions arranged in a vertical direction ordered along the i-th direction; and 分別設置於前述活性區域之M〇s電晶體,此M〇s電晶 體具有複數之前述第1活性區域群間共同連結之閘極、曰 連結於記憶胞之控制閘極及選擇電晶體之選擇閘極其— 的第1雜質擴散層、以及由承受列解碼器提供之電壓的 第2雜處擴散層,此選擇閘極上連結之前述%⑽電晶 體,只設置於前述第2活性區域群内之端部的前述活2 區域内,含有此選擇閘極上連結之M〇s電晶體的前述第 1 一活性區域群、以及相鄰之前述第丨活性區域aa群間的 兀件隔離區域寬度,大於只含有連結於控制閘極之 57-Mos transistors provided in the foregoing active regions, respectively. The Mos transistors have a plurality of gates connected together among the aforementioned first active region groups, a control gate connected to a memory cell, and a selection of a transistor. The gate is the first impurity diffusion layer and the second miscellaneous diffusion layer that withstands the voltage provided by the column decoder. The above-mentioned% pseudo-transistor connected to the gate is selected only at the end in the second active region group. The width of the element isolation region between the first active region group containing the Mos transistor connected to this selection gate and the adjacent first active region aa group within the aforementioned active 2 region is larger than only Contains 57- 564548 A8 B8564548 A8 B8 電士體的前述㈣性區域群間的元件隔離區域寬度。 •如印專利範園第24項之半導體裝置,其中 則述MOS私晶體之閘極,係由各第i活性區域群之同 一列内MOS電晶體共用。 26·如申請專利範圍第%項之半導體裝置,其中 月逑第2活性區域群係列系核心部,此列系核心部且 有列解碼器對NAND連結之記憶胞的選擇閘極線、或控 制閘極線提供電壓時之開關機能。 27. —種半導體裝置,其特徵為: 以元件隔離區域實施電性隔離,且含有沿著第丨方向 汉置之複數活性區域的第i活性區域群; 以元件隔離區域實施電性隔離,且含有沿著第1方向 之垂直方向设置之複數前述活性區域的第2活性區域 群; — 分別設置於前述活性區域之M〇s電晶體,此MOS電晶 月豆具有以前述活性區域為單位實施隔離之閘極、連結於 記憶胞之控制閘極及選擇電晶體之選擇閘極其一的第i 雜質擴散層、以及由承受列解碼器提供之電壓的第2雜 質擴散層; 覆蓋纟!]述Μ 0 S電晶體之層間絕緣膜;以及 設於前述層間絕緣膜上,電性連結於複數之前述第i 活性區域群各自含有之前述活性區域内的前述閘極,且 為複數該閘極之共同連結的配線層。 28·如申請專利範圍第27項之半導體裝置,其中 -58- 本紙張尺度適用中國國家標準(CNS) A4規格(210X297公釐;Γ 564548 A8 B8 C8The width of the element isolation region between the aforementioned flexible region groups of the electric signal. • The semiconductor device in Item 24 of the Indian Patent Park, where the gate of the MOS private crystal is shared by the MOS transistors in the same column of each i-th active area group. 26. If the semiconductor device of the item% of the scope of the patent application, the second active area group series is the core part, which is the core part and the decoder selects the gate line or control of the NAND-connected memory cells. The gate line provides switching function when voltage is applied. 27. A semiconductor device, characterized in that: the element isolation region is electrically isolated, and an i-th active region group including a plurality of active regions arranged along the first direction; and the element isolation region is electrically isolated, and A second active region group including a plurality of the aforementioned active regions arranged in a vertical direction along the first direction;-Mos transistors respectively disposed in the aforementioned active regions, and this MOS transistor crystal is implemented in units of the aforementioned active regions The isolation gate, the control gate connected to the memory cell and the selection gate of the selection transistor are the i-th impurity diffusion layer, and the second impurity diffusion layer withstands the voltage provided by the column decoder; covering 纟!] An interlayer insulating film of the M 0 S transistor; and the gate electrode in the active region contained in each of the plurality of the i-th active region groups, which is provided on the interlayer insulating film, and is the gate electrode of the plurality of gate electrodes. Commonly connected wiring layers. 28. If the semiconductor device under the scope of patent application No. 27, -58- This paper size applies to the Chinese National Standard (CNS) A4 specification (210X297 mm; Γ 548548 A8 B8 C8 的前述元件隔離區域 ,且沿著前述第丨方向 位於相鄰之前述活性區域群間 上,具有和前述閘極為電性隔離 設置之模擬閘極, 對前述模擬閘極施加電壓 以前述元件隔離區域為閘極 於斷開狀態。 ’使以該模擬閘極為閘極、 絕緣膜之寄生MOS電晶體處 29·如申請專利範圍第27項之半導體裝置,其中 則述閘極係沿著縱向覆蓋於前述活性區域上,且其兩 端部分別延伸至前述元件隔離區域之部份區域上。 30·如申請專利範圍第27項之半導體裝置,其中 前述第2活性區域群係列系核心部,此列系核心部具 有列解碼器對NAND連結之記憶胞的選擇閘極線、或控 制閘極線提供電壓時之開關機能。 31. —種半導體裝置,其特徵為: 矩陣狀配置、互相電性隔離之複數活性區域;及 各活性區域内分別設有MOS電晶體,此MOS電晶體之 閘極在同一列内時為共同連結,此MOS電晶體各具有連 結於列解碼器之源極•汲極區域侧、及連結於記憶胞之 控制閘極及選擇電晶體之選擇閘極之其一的源極•沒極 區域侧,此連結於選擇閘極之MOS電晶體,只配置於前 述矩陣端部的同一行内,此鄰接之活性區域的行間距 離,含有連結於選擇閘極之活性區域的行間距離,大於 只含連結於控制閘極之活性區域的行間距離。 32. —種半導體裝置,其特徵為··包含 -59- 本紙張尺度適用中國國家搮準(CNS) A4規格(210X297公釐) 564548 A8 B8 C8 D8 申請專利範圍 矩陣狀配置、互相電性隔離之複數活性區域; 各活性區域内分別設有MOS電晶體,此MOS電晶體各 具有連結於列解碼器之源極•汲極區域侧、及連結於記 憶1包之控制閘極及選擇電晶體之選擇閘極之其一的源 極·沒極區域侧;及 設於和前述閘極不同之水平,且和位於不同行之前述 閘極實施電性連結的配線層。 -60- 本紙張尺度適用中國國家標準(CNS) A4規格(210 X 297公釐)The aforementioned device isolation region is located between the adjacent active region groups along the first direction, and has an analog gate that is electrically isolated from the gate electrode. A voltage is applied to the analog gate to separate the element isolation region. The gate is in the off state. 'The parasitic MOS transistor with the gate and the insulating film of the analog gate is applied. 29. For a semiconductor device with the scope of patent application No. 27, the gate is covered on the active area along the longitudinal direction, and the two The end portions respectively extend to a part of the aforementioned component isolation region. 30. The semiconductor device according to item 27 of the patent application scope, wherein the aforementioned second active area group series is the core part, and the core part has a selection gate line or a control gate line of a column decoder for a NAND-linked memory cell. Switching function when the line provides voltage. 31. A semiconductor device, characterized in that: a plurality of active regions arranged in a matrix and electrically isolated from each other; and each active region is provided with a MOS transistor, and the gates of the MOS transistors are common when they are in the same column. Connection, each of the MOS transistors has a source-drain region side connected to a column decoder, and a source-animated region side of one of a control gate connected to a memory cell and a selection gate of a selection transistor The MOS transistor connected to the selection gate is only arranged in the same row at the end of the matrix. The inter-row distance of this adjacent active area contains the inter-row distance connected to the active area of the selection gate. Controls the inter-row distance of the active area of the gate. 32. A type of semiconductor device, characterized in that it contains -59- This paper size is applicable to China National Standard (CNS) A4 specification (210X297 mm) 564548 A8 B8 C8 D8 Patent application Matrix configuration, electrically isolated from each other Multiple active regions; each active region is provided with a MOS transistor, each of which has a source-drain region side connected to a column decoder, and a control gate and a selection transistor connected to a memory pack One of the gates is selected from one of the source and the non-electrode region side; and a wiring layer provided at a level different from that of the gates and electrically connected to the gates located in different rows. -60- This paper size applies to China National Standard (CNS) A4 (210 X 297 mm)
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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
TWI497694B (en) * 2010-06-15 2015-08-21 Macronix Int Co Ltd A high density mem0ry device based 0n phase change memory materials andmanufacturing method thereof

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
TWI497694B (en) * 2010-06-15 2015-08-21 Macronix Int Co Ltd A high density mem0ry device based 0n phase change memory materials andmanufacturing method thereof

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