JPS5813009A - Method and device for manufacturing surface acoustic wave element - Google Patents

Method and device for manufacturing surface acoustic wave element

Info

Publication number
JPS5813009A
JPS5813009A JP11089781A JP11089781A JPS5813009A JP S5813009 A JPS5813009 A JP S5813009A JP 11089781 A JP11089781 A JP 11089781A JP 11089781 A JP11089781 A JP 11089781A JP S5813009 A JPS5813009 A JP S5813009A
Authority
JP
Japan
Prior art keywords
acoustic wave
piezoelectric
piezoelectric wafer
surface acoustic
wafer
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
JP11089781A
Other languages
Japanese (ja)
Inventor
Shigeyuki Kita
喜多 重之
Takuji Yamada
拓司 山田
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Toshiba Corp
Original Assignee
Toshiba Corp
Tokyo Shibaura Electric Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Toshiba Corp, Tokyo Shibaura Electric Co Ltd filed Critical Toshiba Corp
Priority to JP11089781A priority Critical patent/JPS5813009A/en
Publication of JPS5813009A publication Critical patent/JPS5813009A/en
Pending legal-status Critical Current

Links

Classifications

    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03HIMPEDANCE NETWORKS, e.g. RESONANT CIRCUITS; RESONATORS
    • H03H3/00Apparatus or processes specially adapted for the manufacture of impedance networks, resonating circuits, resonators
    • H03H3/007Apparatus or processes specially adapted for the manufacture of impedance networks, resonating circuits, resonators for the manufacture of electromechanical resonators or networks
    • H03H3/08Apparatus or processes specially adapted for the manufacture of impedance networks, resonating circuits, resonators for the manufacture of electromechanical resonators or networks for the manufacture of resonators or networks using surface acoustic waves

Landscapes

  • Physics & Mathematics (AREA)
  • Acoustics & Sound (AREA)
  • Engineering & Computer Science (AREA)
  • Manufacturing & Machinery (AREA)
  • Surface Acoustic Wave Elements And Circuit Networks Thereof (AREA)

Abstract

PURPOSE:To make a surface acoustic wave element of good quality of a piezoelectric wafer of great pyroelectricity at high manufacture yield, by forming thin metallic films on the surface, flank, and part of the reverse surface of the piezoelectric wafer, and etching the thin metallic film on the surface. CONSTITUTION:The top surface 111 of a piezoelectric wafer 11 is polished into a specular surface and after the reverse surface 112 is finished roughly, aluminum films 121, 123 and 122 are vapor-deposited on the top surface 111, flank 113, and part of the reverse surface 112 of the wafer 11. On the aluminum film 121, a photoresist film 13 is formed, and the wafer 11 is placed on a hot plate 26 for a baking treatment. Then, a photoetching method is employed for the exposure, development, and etching of the photoresist film 13 to form a number of surface acoustic wave elements 31, and the aluminum films 123 and 122 are removed. Then, those surface acoustic wave elements 31 are separated individually.

Description

【発明の詳細な説明】 本発嘴は弾性表面液素子O製造方法及び七〇@i!に係
)、轡に多数の弾性m1ii流素子を写真蝕刻1法によ
〉圧電ウェファ上に形成する製造方法及びその侠置く関
するものであるe 弾am爾波素子には弾性表面波フィルタ素子。
[Detailed description of the invention] The present beak includes a method for manufacturing an elastic surface liquid element O and 70@i! This relates to a manufacturing method for forming a large number of elastic flow elements on a piezoelectric wafer by a photolithography method, and its method.The elastic wave elements include surface acoustic wave filter elements.

−***波共振子素子などが1、いずれ%L1丁−偽L
IN塾0..水晶、七ツ5ツタスなどからなる圧電ウェ
ファ上にアル々エクムなどの金属被膜を所定厚に一着衣
と9手段によ)被着形成したのち、この金属被膜に写真
蝕刻1法などを利用して参数の弾性*W波素子を形成し
たのち、各素子を分割して使用するようになっている・ これb弾性lI!爾波素子管形成する圧電ウェファとし
では前述のように種々のものが使用されているが、との
うちLINbOsは電気機械給金係数が大で且つ貴意性
でh1丸め高性能弾性表面波素子o14造に多く用−ら
れている・ 然るにこOLINbOsは電気機械締金係数が大である
ばか)ではな(焦電性も大き−ため、LINIeOsク
エファから弾性表面波素子を形成する工IIK行なわれ
為加熱冷却工@09に表′rMに電荷が発生する。
- **** wave resonator element etc. is 1, eventually %L1 piece - false L
IN Juku 0. .. After forming a metal coating such as Alto Ecum to a predetermined thickness on a piezoelectric wafer made of crystal, 75 tsutas, etc., using a method such as photo-etching 1, etc. After forming a number of elastic * W wave elements, each element is divided and used. This b elastic lI! As mentioned above, various types of piezoelectric wafers are used to form the wave element tube, but among them, LINbOs has a large electromechanical feed coefficient and is highly valuable, so it is suitable for h1 rounding high performance surface acoustic wave elements o14. However, since OLINbOs has a large electromechanical clamping coefficient (it has a large pyroelectric property), it is difficult to conduct a process to form a surface acoustic wave element from LINIeOs. A charge is generated on the table 'rM in the heating and cooling process @09.

?−O表面電荷は例えば菖tgOように圧電ウェファ(
1) 0−主面上にアルミニウムなどO金属被膜(2)
を蒸着したのち、ホットプレート(萄上に載置して加熱
する工程において、ξのホットグレート(3)と金属被
膜(2)の端部(2烏)間に放電(4)を起しえ〉、金
属被膜(匂にはζ)(S)を吸着する場合があ)、次工
程であるフォトレジスト膜の形成工程での歩留を低下さ
せたり、圧電ウェファ(1) 0端部近傍を軍JLKす
る原因となっている。
? -O surface charge is caused by a piezoelectric wafer (for example, irises tgO).
1) O metal coating such as aluminum on the 0-main surface (2)
After vapor-depositing, in the step of heating by placing on a hot plate (on the grapes), an electric discharge (4) is generated between the hot plate (3) of ξ and the end (2) of the metal coating (2). 〉, the metal film (smell may adsorb ζ) (S) may reduce the yield in the next process of forming a photoresist film, or the vicinity of the 0 end of the piezoelectric wafer (1) may be This is the cause of the military JLK.

また、との圧電ウェファが蕾電していると7オトレジス
ト膜O形成工程後のぺiキンダニ程、露光工程、エツチ
ング工程などにおいて、ウェファがこれら工11K使用
する装置の金属部分に静電吸着し、これら工程の操作が
困11になる問題があった・ このため従来は第2図Oように圧電クエンチ(1)上の
金属被膜(乃を上にして平坦な金属板(勾玉に煩絡片(
7)によ)固定させると共に圧電ウェファ(1) 0表
面の金属被膜(2)金金属板(@)K短編させることに
よ)11111電荷を防止しホラ)プレート(3)など
に載置し、べ一命ンダエ11t行なって−る0が現状で
番る。
In addition, if the piezoelectric wafer is electrostatically charged, the wafer will electrostatically adsorb to the metal part of the equipment used in these processes during the peeling process, exposure process, etching process, etc. after the photoresist film O formation process. , there was a problem that the operation of these processes was difficult. For this reason, conventionally, as shown in Fig. (
7)) and fix the piezoelectric wafer (1) 0 metal coating on the surface (2) gold metal plate (@)K by shortening) 11111 to prevent electric charges, and then place it on a plate (3) etc. , 0, which is currently running, is the current count.

然るにこOような方法によると、金属板(句と圧電クエ
ンチ(1) 01に爾が充分Kl!触し難いので表面電
荷を完全KIIE)除くことができないし、まえ金属被
膜(=及びフォトレジスト膜の一部に欠陥が生し易く、
製造歩留)も悪くなる欠点があった・ζO対策として、
嬉3図に示すように圧電ウェファ(i)o表面と裏11
に!工程でアルミニウムなどO金属被膜 (zt) 、
 (zt)を被着形成する方法が考えもれて−るが、こ
の方法は圧電クエンチ(1) (0表面と裏面に2工程
でアルζニウムなどの金属被II (2,)(−)を被
着形成するため、製造工程が長く、また圧電クエンチo
*TMの電極形成のための金属被膜(2s)K自ず中汚
れが発生し易く、こOような圧電クエンチ(1)から弾
性表面波素子を形成すると、素子として04P性1悪く
し易i欠点が番る・本発明は前述しえ従来O諸欠点に―
みなされえ    1“もO″cToats圧電クエ7
アに一工りで焦電性によるウェファ側壁O放電や表面に
ほこ)などが吸着することが極めて少な−ようにアルミ
ニウムなどの金属被膜を形成するととができ、この圧電
クエンチから製造歩留よく、品質のよい弾性表面波素子
を得ることが可能な弾性表面波素子O製造方法及びそO
装置を提供することを目的としている・次に本発明の一
実施例を図に従い説明する・先ず初めに第4図のような
所定直径、厚さを有するLiN15Osの単結晶からな
る圧電ウェファaa’を用意する・次に第5図に示すよ
うにこの圧電ウェファ1の表面(l11)を鏡面研磨す
ると共に裏1j(山)をm*に仕上げる・゛このような
圧電ウェファa1)を第6図に示すようにとO圧電ウェ
ファ(11)の直径よ)中子径小1央出部Cut有する
蒸着用プラネタリ−勾玉に圧電ウェファ(10の裏面(
111)の外周部(ttsa)が尚接しな一様に載置す
る・次に第7図に示すようにプラネタリ−(2)を蒸着
装置(至)内に導入し、所定真空度まで減圧したのち圧
電ウェファ@1)の表1j (11*)に対設するアル
賓ニウム蒸着源(財)をフィラメント(ハ)によシ加熱
すると、圧電ウェファalO1!藺Qt、)、mlj 
(11m)こ0111ifKil接する裏面(n章)の
一部(n□)にアルンニク^が蒸着するこの蒸着時0雰
囲気の真空度は2 X 1 G”’Torr以下温度は
200〜300℃、要用1m締高さ即ちプラネタリ−治
具と裏面との間隔は通常数μ〜数lO■あればよいが実
用上は数100J1〜数■一度が望ましい・ ヒのよ51に蒸着によ〉第8図に示すように圧電クエン
チ(11)の表面(tb)上には弾性表面波素子のイン
ターデジタル電極やダレ−ディング電極形成用に最適な
厚さのアルミニウム被膜(121)側m (tts)裏
面の一部には表面(111)のアルミニウム被膜(12
1)より命中薄目のアルミニウム被膜(t2m) 、 
(tzt)が被着形成される〇 このようにアルミニウム被膜(t2s) 、 (12t
) 、 (12i)を着着形成した圧電ウェファ00は
次の工IIKより主としてアル電具りム被膜(tzt)
上にフォトレジスト膜(I3を形成し、第9図に示すよ
うにホットプレート(至)上に載置しベーキング工程を
行なうコこの場合本実施例のように圧電ウェファIの裏
[(11,)の一部にまでアルミニウム被膜(12m)
を形成するととにより、圧電クエファ@IO表面に電荷
が発生してもアル1=ウム被膜(1&) e (12a
) e 02m )を介してこの電荷がホットプレート
(2)に流れることKe!のでフォトレジスト膜UKf
iヒ)が付着しぇ〉放電がシこつえ)することがtk%
A、冷却時も同様である0 次に写真蝕刻法を使用して7オ)シジスト膜の露光・現
像・蝕刻を行ない第10!IK示すように多数O弾性表
面波素子61が形成されるし、iえアル1=ウム被膜Q
zm)、 (tち)は蝕刻工程で除去される◎ 次に多数O弾性表面波素子OI)を分離すればよ−・本
夾總例のように圧電ウェファO表面・側聞及びζO@爾
に隣接する裏面の一部に一工程でアルミニウムなどの金
属被膜を形成することによ)焦電性の大きな圧電基板か
ら弾性*両波素子tI11造する工程においてもζO焦
竜゛性によるフォトレジスト膜の形成1穫での歩留%1
jL好となるし、まえ圧電ウェファの端部近傍における
放電による不実も全くなくなるし、ζO金属薄膜O彫成
は従来O圧電クエファo@IHo金属薄膜の形成時KI
I用する菖着用プラネタ菅−を変更することによって春
sK実施することが可能である。
However, with this method, it is impossible to completely remove the surface charge from the metal plate (because it is difficult to touch the metal plate), and the metal film (= and photoresist) cannot be removed completely. Defects are likely to occur in some parts of the film,
There was a drawback that the manufacturing yield (manufacturing yield) also deteriorated.As a countermeasure for ζO,
As shown in Figure 3, piezoelectric wafer (i) o front and back 11
To! O metal coating (zt) such as aluminum in the process,
(zt) has been thought of, but this method involves piezoelectric quenching (1) (2,) (2,) (-) The manufacturing process is long and piezoelectric quenching is required.
*Metal coating (2s) for forming TM electrodes is naturally prone to contamination, and if a surface acoustic wave element is formed from such a piezoelectric quench (1), the element's 04P properties are likely to deteriorate. Defects count - The present invention overcomes the aforementioned drawbacks of the conventional O.
Regarded 1 “MoO” cToats piezoelectric quest 7
It is possible to form a metal coating such as aluminum to minimize adsorption of wafer side wall O discharge due to pyroelectricity and adsorption of dust on the surface. , A method for manufacturing a surface acoustic wave device O that can obtain a surface acoustic wave device of good quality, and the method thereof
・Next, an embodiment of the present invention will be explained according to the drawings. ・First of all, a piezoelectric wafer aa' made of a single crystal of LiN15Os having a predetermined diameter and thickness as shown in FIG.・Next, as shown in FIG. 5, the front surface (l11) of this piezoelectric wafer 1 is polished to a mirror finish, and the back side 1j (mountain) is finished to m*. ・Such a piezoelectric wafer a1) is prepared as shown in FIG. As shown in Figure 1, the back side of the piezoelectric wafer (10) is attached to the planetary magatama for evaporation, which has a core diameter of 1 (small diameter) and a central protrusion cut.
Place the planetary (2) uniformly so that the outer periphery (ttsa) of 111) is still not in contact. Next, as shown in Figure 7, the planetary (2) was introduced into the vapor deposition apparatus (to) and the pressure was reduced to a predetermined degree of vacuum. Later, when the aluminum evaporation source installed opposite Table 1j (11*) of the piezoelectric wafer @1) is heated by the filament (c), the piezoelectric wafer alO1!藺Qt, ), mlj
(11m) Arunnik^ is deposited on a part (n□) of the back surface (chapter n) in contact with this 0111ifKil.During this deposition, the degree of vacuum in the zero atmosphere is 2 x 1 G'''Torr or less, and the temperature is 200 to 300℃, required. The tightening height of 1 m, that is, the distance between the planetary jig and the back surface, is usually from several microns to several 100, but in practice it is preferably from several 100 J to several times. As shown in the figure, on the surface (tb) of the piezoelectric quench (11), there is an aluminum coating (121) side (m) (tts) on the back surface of the optimal thickness for forming interdigital electrodes and daring electrodes of the surface acoustic wave element. Some parts have an aluminum coating (12) on the surface (111).
1) Aluminum coating with a thinner hit (t2m),
(tzt) is deposited 〇 In this way, aluminum coating (t2s), (12t
), (12i) was deposited on the piezoelectric wafer 00, which was mainly coated with Aldentrium coating (tzt) from the next process IIK.
A photoresist film (I3) is formed on the top, and as shown in FIG. 9, it is placed on a hot plate and a baking process is performed. ) Aluminum coating (12m)
Even if a charge is generated on the surface of the piezoelectric Quafer@IO, the Al1 = U film (1 &) e (12a
) e 02m ) that this charge flows to the hot plate (2) Ke! So the photoresist film UKf
It is tk% that the discharge sticks)
A. The same goes for cooling. 0 Next, use the photo-etching method to perform 7 e) exposure, development, and etching of the sydist film. 10. As shown in IK, a multi-O surface acoustic wave element 61 is formed, and I
zm), (tchi) are removed in the etching process ◎ Next, the multi-O surface acoustic wave element OI) is separated - As in this example, the piezoelectric wafer O surface, side surface and ζO Photoresist due to ζO pyro-resistance is also used in the process of fabricating an elastic*double-wave element tI11 from a piezoelectric substrate with large pyroelectric properties (by forming a metal film such as aluminum on a part of the back surface adjacent to the pyroelectric substrate in one step). Film formation yield in 1 harvest %1
The ζO metal thin film O engraving is different from conventional ζO metal thin film formation when forming the piezoelectric wafer O@IHo metal thin film.
It is possible to carry out spring SK by changing the irises wearing planetary tube.

次に本実WAO他O実施例に適応する蒸着用プ2ネタツ
ーtjllt1図によ)説明する。
Next, an explanation will be given with reference to FIG.

則ち、蒸着用プラネタリ一一は圧電ウェファ■の直後よ
*aO小さな突岨11)と圧電クエ7アIO直負よ)1
&0大me周縁穣体−を残すようにはff1ll状O!
!I壽部−を設けである・前記実施例ではアル1=クム
蒸着g(財)及びアイツメン)(至)を1ケ所に設けた
が、これに限定されるものではなく圧電ウェファalの
側聞及びヒの儒両に隣接する裏面の一部に%金属被膜が
被着し鳥iように複数側設けてもよいし、ま九プラネタ
リーO突山部t2珍*1*o辱状も、圧電ウェファIよ
り径小なほぼ円柱状に限定されるものではなく、圧電ク
エファalOa厘の一部に金属薄膜が被着し得j1 :bll状!111状)7 vs−*tkど0B″1i
t−Jiij!El、?     。
In other words, the evaporation planetary 11 is immediately after the piezoelectric wafer *aO small ridge 11) and the piezoelectric cube 7a IO direct negative) 1
&0 large me peripheral body - to leave ff1ll-like O!
!・In the above embodiment, the aluminum 1 = cum vapor deposition (G) and AITSUMEN) (TO) were provided in one place, but the invention is not limited to this, and the side surface of the piezoelectric wafer AL is provided. A metal coating may be applied to a part of the back side adjacent to the upper part of the back side, and multiple sides may be provided as shown in the figure. It is not limited to a substantially cylindrical shape with a smaller diameter than the piezoelectric wafer I, and a metal thin film may be adhered to a part of the piezoelectric wafer I. 111) 7 vs-*tkd0B″1i
t-Jiij! El,? .

もよいことは勿論である0Of course it's good too0

【図面の簡単な説明】 JI1図は焦電特性によ)放電中ごみ0被着が起った状
態の説明図、第2図は従来0電荷短絡構造を示す要部断
面図、lts図は従来の電荷短絡用として両側に金属被
I[を形成しえ構造を示す断面図、1s4aI7!Fj
llI第4aIは本発明の弾性表面波素子の111Ii
方法〇一実施例を示す図で69、第4図は圧電クエ7ア
O斜視図、第5図は圧電クエ7アの表両及び裏面を仕上
げえ状態を示す断面図、第6図は蒸着用プラネタリ−に
圧電クエ7アを載量し良状態を示す断面図、菖7図は蒸
着工St示す断面図、第8図は金属被膜0形成状態管示
す断面図蔦嬉9図はフォトレジスト膜を形成しベーキン
グを行なって−る状sIを示す断w図、第10図は圧電
クエ71に多数O弾性表面波素子を形成した状態を示す
斜視図1第11図は本発明O弾性表面波素子の製造方法
の他の実施例に適応するプラネタリ−に圧電クエ7アを
載量し免状態管示す断面図である。 1 、11・・・圧電クエ7ア 2.21.2置、 12. 、12奮、12.・・・ア
ル1=ウム被膜S 、 2ト−・ホットプレート 7・
・・短絡片22 、42・・・蒸着用プラネタリ−21
、41・・・央山部 側人知士井上−男
[Brief explanation of the drawings] Figure JI1 is an explanatory diagram of the state in which zero dust adhesion occurs during discharge (due to pyroelectric characteristics), Figure 2 is a sectional view of the main part showing the conventional zero charge short circuit structure, and the lts diagram is 1s4aI7! is a cross-sectional view showing a conventional structure in which metal coatings I[ are formed on both sides for charge short circuiting. Fj
llI 4aI is 111Ii of the surface acoustic wave element of the present invention
Figure 4 is a perspective view of the piezoelectric square 7A O, Figure 5 is a sectional view showing the finished state of both front and back surfaces of the piezoelectric square 7A, and Figure 6 is a diagram showing an example of method 〇. Figure 7 is a cross-sectional view showing a good state of piezoelectric square 7a loaded on a planetary. Figure 8 is a cross-sectional view showing a tube with no metal coating formed. Figure 9 is a photoresist. FIG. 10 is a perspective view showing a state in which a large number of O surface acoustic wave elements are formed on a piezoelectric square 71. FIG. FIG. 7 is a cross-sectional view showing a stateless tube in which a piezoelectric square 7a is loaded on a planetary adapted to another embodiment of the method for manufacturing a wave element. 1, 11...Piezoelectric square 7A2.21.2, 12. , 12, 12. ... Al 1=um coating S, 2-tone hot plate 7.
...Short-circuiting pieces 22, 42...Planetary for deposition 21
, 41...Inoue, a man on the side of Oyamabe

Claims (2)

【特許請求の範囲】[Claims] (1)圧電クエファollt側藺及びζ01m1mK隣
接する裏面の一部に一工程で金属薄膜を彫威する工程と
、前記表面に形成され、−に金属薄膜を写真蝕刻法によ
)蝕刻し、前記圧電クエ77に多数の弾性表面波素子を
形成する工1と、前記弾性表面波素子を分離するl1と
を具備すること10黴とする弾性聚爾波素子am造方法
(1) A step of engraving a metal thin film on a part of the piezoelectric quaffa ollt side wall and the adjacent back surface of ζ01m1mK in one step, etching the metal thin film formed on the surface (by photolithography), and etching the metal thin film on the A method for manufacturing an elastic acoustic wave element, comprising step 1 for forming a large number of surface acoustic wave elements on a piezoelectric cube 77, and step 1 for separating the surface acoustic wave elements.
(2)、圧電ウェファO冑11KII接する裏藺O少く
とも一部と非接触である原着用プラネタリ−と、前記蒸
着用プラネタリ−に載置された前記圧電ウェファの表面
、11面及びとの間両に隣接する裏面の一部に一工楊で
金属薄*1*成可能な蒸着装置とを少くとも具備するこ
とt41I冑とする弾性lI!菖波素子O1l造装置0
(2) between the surface of the piezoelectric wafer placed on the evaporation planetary, and the surface of the piezoelectric wafer placed on the evaporation planetary, which is in non-contact with at least a part of the back surface of the piezoelectric wafer; A part of the back surface adjacent to both sides should be equipped with at least a vapor deposition device capable of forming a metal thin *1* in a single process. Iris wave element O1l manufacturing equipment 0
JP11089781A 1981-07-17 1981-07-17 Method and device for manufacturing surface acoustic wave element Pending JPS5813009A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP11089781A JPS5813009A (en) 1981-07-17 1981-07-17 Method and device for manufacturing surface acoustic wave element

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP11089781A JPS5813009A (en) 1981-07-17 1981-07-17 Method and device for manufacturing surface acoustic wave element

Publications (1)

Publication Number Publication Date
JPS5813009A true JPS5813009A (en) 1983-01-25

Family

ID=14547453

Family Applications (1)

Application Number Title Priority Date Filing Date
JP11089781A Pending JPS5813009A (en) 1981-07-17 1981-07-17 Method and device for manufacturing surface acoustic wave element

Country Status (1)

Country Link
JP (1) JPS5813009A (en)

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS61206316U (en) * 1985-06-14 1986-12-26
JPH01319935A (en) * 1988-06-21 1989-12-26 Matsushita Electric Ind Co Ltd Dry-etching device for pyroelectric material
JPH02260907A (en) * 1989-03-31 1990-10-23 Hoya Corp Manufacture of surface acoustic wave device
JPH03293808A (en) * 1990-04-11 1991-12-25 Fujitsu Ltd Production of surface acoustic wave element
JP2002009569A (en) * 2000-06-26 2002-01-11 Toshiba Corp Manufacturing method for surface acoustic wave device
US7389570B2 (en) * 2004-06-28 2008-06-24 Kyocera Corporation Surface acoustic wave device manufacturing method, surface acoustic wave device, and communications equipment
US20090205177A1 (en) * 2008-02-15 2009-08-20 Mitsuo Tomiyama Method of fabricating piezoelectric vibrating piece, piezoelectric vibrating piece, piezoelectric vibrator, oscillator, electronic apparatus, radiowave timepiece, wafer and jig for wafer

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS61206316U (en) * 1985-06-14 1986-12-26
JPH01319935A (en) * 1988-06-21 1989-12-26 Matsushita Electric Ind Co Ltd Dry-etching device for pyroelectric material
JPH02260907A (en) * 1989-03-31 1990-10-23 Hoya Corp Manufacture of surface acoustic wave device
JPH03293808A (en) * 1990-04-11 1991-12-25 Fujitsu Ltd Production of surface acoustic wave element
JP2002009569A (en) * 2000-06-26 2002-01-11 Toshiba Corp Manufacturing method for surface acoustic wave device
US7389570B2 (en) * 2004-06-28 2008-06-24 Kyocera Corporation Surface acoustic wave device manufacturing method, surface acoustic wave device, and communications equipment
US20090205177A1 (en) * 2008-02-15 2009-08-20 Mitsuo Tomiyama Method of fabricating piezoelectric vibrating piece, piezoelectric vibrating piece, piezoelectric vibrator, oscillator, electronic apparatus, radiowave timepiece, wafer and jig for wafer
US8104154B2 (en) * 2008-02-15 2012-01-31 Seiko Instruments Inc. Method of manufacturing a piezoelectric vibrating piece

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