JP2007134586A - Vacuum exhaust device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a vacuum exhaust device which can remove foreign matter such as dust within a load-lock chamber, and at the same time can prevent temperature drop due to adiabatic expansion of a gas. <P>SOLUTION: A charged particle beam apparatus for irradiating a specimen with a charged particle beam, has a vacuum-exhausted specimen chamber for holding the specimen irradiated with the charged particle beam, a specimen storage chamber kept at the atmospheric pressure for storing the specimen, and a specimen load-lock chamber connectable with the specimen chamber and the specimen storage chamber. The vacuum exhaust device is installed at the specimen load-lock chamber. The vacuum exhaust device has a vacuum pump for vacuumizing the specimen load-lock chamber from its one side, a gas leaking device for leaking a gas into the specimen load-lock chamber from the other side thereof, and a temperature adjusting device for heating or cooling the gas. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a vacuum exhaust apparatus suitable for being provided in a sample chamber or the like of an electron beam drawing apparatus, an electron microscope, a focused ion beam apparatus or the like.

  One of the processes for forming an LSI pattern among the processes for manufacturing a semiconductor and a thin film magnetic head is an electron beam lithography process.

  The circuit pattern formed by the electron beam lithography process is highly integrated year by year, and various apparatuses have been announced in response to the demand for miniaturization associated therewith.

  In an electron beam lithography apparatus that performs electron beam lithography, the substrate is once transferred into the load lock chamber before being transferred into the work chamber. When transporting the substrate into the load lock chamber, foreign matter such as dust enters the load lock chamber. For example, foreign matter adhering to a portion in contact with the substrate, generation of dust from a sliding portion, foreign matter floating in the atmosphere of a clean room, and the like.

When such foreign matters such as dust adhere to the drawing surface of the process wafer or mask reticle, the electron beam to be drawn is obstructed, leading to deterioration of drawing accuracy and yield reduction. Therefore, contamination of foreign matters such as dust, particularly foreign matters such as dust in the load lock chamber is a serious problem. Therefore, conventionally, various dust removal methods have been proposed.
JP 7-96259 A JP 2003-270774 A

  In the dust removal method described in Japanese Patent Application Laid-Open No. 7-96259, no measures are taken against a temperature drop due to adiabatic expansion of gas, so there is a concern that the productivity will drop. In the foreign matter removal method described in Japanese Patent Laid-Open No. 2003-270774, local foreign matters can be removed, but foreign matters accumulated in the vacuum chamber cannot be removed. Moreover, since the countermeasure against the temperature fall by adiabatic expansion of gas is not taken, a production efficiency fall is caused.

  An object of the present invention is to provide a vacuum evacuation device capable of removing foreign matters such as dust in a load lock chamber and at the same time preventing a temperature drop due to adiabatic expansion of gas.

  The vacuum evacuation apparatus of the present invention includes a charged particle beam apparatus that irradiates a charged particle beam on a sample, a sample chamber that is evacuated to hold a sample irradiated to the charged particle beam, and an atmospheric pressure that stores the sample. In a charged particle beam apparatus having a sample storage chamber and a sample load lock chamber connectable to the sample chamber and the sample storage chamber, the charged particle beam apparatus is provided in the sample load lock chamber.

  The vacuum exhaust apparatus includes a vacuum exhaust pump that evacuates the sample load lock chamber from one side, a gas leak device that leaks gas into the sample load lock chamber from the other side, and a temperature control device that heats or cools the gas And having.

  According to the present invention, it is possible to remove foreign matters such as dust in the load lock chamber and at the same time to prevent a temperature drop due to adiabatic expansion of gas.

  FIG. 1 shows an outline of the structure of an electron beam drawing apparatus provided with a vacuum exhaust apparatus of the present invention. The electron beam drawing apparatus includes an electron optical system 10, a work chamber 31, and a load lock chamber 35. In the work chamber 31, an XY stage 20, a positioning table 21, and an electrostatic chuck 22 are provided. The substrate 17 is held by the electrostatic chuck 22.

  The electron optical system 10 includes an electron gun 11, a diaphragm 13, a shaping polarizer 14, an electron lens 15, and a deflector 16, and draws on a substrate 17 with an electron beam 12.

  With reference to FIG. 2, the example of the vacuum exhaust apparatus of this invention is demonstrated. The vacuum exhaust apparatus of this example is provided in an electron beam drawing apparatus. The electron beam drawing apparatus includes an electron optical system 10, a work chamber 31, a load lock chamber 35, and a substrate storage box 39. The work chamber 31 and the load lock chamber 35 are connected to each other via a transfer path 33 provided with a transfer valve 32. The load lock chamber 35 and the substrate storage box 39 are connected to each other via a transfer path 37 having a transfer valve 36.

  The work chamber 31 is provided with an XY stage 20 that holds the substrate 17. In the load lock chamber 35, the substrate 17 is disposed on the positioning table 21. A substrate 17 (not shown) is stored in the substrate storage box 39.

  Above the load lock chamber 35, an atmospheric pressure sensor 53, a vacuum gauge 54, a temperature adjustment device 40, and a calculation unit 47 are provided.

  The atmospheric pressure sensor 53 detects that the pressure in the load lock chamber 35 has become atmospheric pressure. Therefore, the atmospheric pressure sensor 53 generates an ON signal when the pressure in the load lock chamber 35 becomes atmospheric pressure, and generates an OFF signal when the pressure in the load lock chamber 35 becomes lower than the atmospheric pressure. The vacuum gauge 54 measures the degree of vacuum in the load lock chamber 35. Accordingly, the vacuum gauge 54 generates an ON signal when the pressure in the load lock chamber 35 is lower than the atmospheric pressure, measures the degree of vacuum, and generates an OFF signal when the pressure in the load lock chamber 35 becomes equal to the atmospheric pressure. To do.

  The vacuum gauge 54 can measure the degree of vacuum but cannot measure atmospheric pressure. Therefore, both the atmospheric pressure sensor 53 and the vacuum gauge 54 are provided. However, in recent years, vacuum gauges that can measure to atmospheric pressure have been developed. Therefore, when using a vacuum gauge capable of measuring up to atmospheric pressure, the atmospheric pressure sensor 53 can be removed.

  The temperature adjusting device 40 and the load lock chamber 35 are connected to each other by a leak pipe 42 having a leak valve 41. A leak pipe 44 having a leak valve 43 is connected on the temperature adjusting device 40.

  A temperature measuring device 45 is provided in the load lock chamber 35. The temperature measuring device 45 and the calculation unit 47 are connected by a cable 46, and the calculation unit 47 and the temperature adjustment device 40 are connected by a cable 48.

  A vacuum pump 50 is provided under the load lock chamber 35. The load lock chamber 35 and the vacuum pump 50 are connected to each other by an exhaust pipe 52 having an exhaust valve 51.

  According to this example, the leak pipe 42 provided with the leak valve 41 is provided on the ceiling of the load lock chamber 35, and the exhaust pipe 52 provided with the exhaust valve 51 is provided on the bottom surface of the load lock chamber 35. When the load lock chamber 35 is evacuated by the vacuum pump 50, the gas leaks from the leak pipe 42 into the load lock chamber 35. The leaked gas collides with the substrate 17 and flows along the substrate 17 before being guided to the exhaust pipe 52. Thus, a gas flow from the leak pipe 42 through the load lock chamber 35 to the exhaust pipe 52 is generated. By this gas flow, foreign matters such as dust can be removed from the load lock chamber 35.

  In order to eliminate foreign matters such as dust by this gas flow, the direction of the gas flow should be from the top to the bottom. When the gas flows downward from above, foreign matter such as dust is prevented from flying up into the air.

  The leak pipe 42 and the exhaust pipe 52 are preferably provided at positions facing each other so that the gas flows smoothly and stagnation does not occur.

  In order to eliminate foreign matters such as dust in the load lock chamber 35, a gas flow that cuts through the load lock chamber 35 is preferable. However, when it is necessary to remove foreign matters such as dust from a specific region in the load lock chamber 35, a nozzle is provided at the tip of the leak pipe 42, and the tip of the nozzle is directed to a predetermined region. That's fine. For example, the upper surface of the substrate can be cleaned by directing the tip of the nozzle onto the substrate 17.

  With reference to FIG. 3, the operation of transporting the substrate in the electron beam drawing apparatus provided with the vacuum exhaust apparatus according to the present invention will be described. The substrate 17 stored in the substrate storage box 39 is transferred to the load lock chamber 35 and further transferred to the work chamber 31. Electron beam drawing is performed in the work chamber 31. The substrate 17 on which electron beam drawing has been performed is transferred from the work chamber 31 to the load lock chamber 35 and further to the substrate storage box 39. In the following, a description will be given of the process until the substrate 17 stored in the substrate storage box 39 is transferred to the load lock chamber 35 and further transferred to the work chamber 31.

  The inside of the work chamber 31 is always a vacuum. The inside of the substrate storage box 39 is always at atmospheric pressure. Initially, the transfer valves 32 and 36 are closed, and the leak valve 41 and the exhaust valve 51 are closed. The pressure in the load lock chamber 35 is atmospheric pressure.

  In step S101, the transfer valve 36 is opened. In step S <b> 102, the substrate 17 is transferred from the substrate storage box 39 to the load lock chamber 35. In step S103, the transfer valve 36 is closed.

  In step S104, the vacuum pump 50 is activated, and in step S105, the exhaust valve 51 is opened. Thereby, evacuation of the load lock chamber 35 is started. In step S106, the temperature adjustment device 40 is activated. The function of the temperature adjusting device 40 will be described later with reference to FIG.

  In step S107, the leak valves 41 and 43 are opened. Thereby, gas is introduced into the load lock chamber 35 during evacuation. The gas introduced into the load lock chamber 35 may be air, but is preferably a dry inert gas. By using the inert gas, the resist applied to the substrate 17 is prevented from being affected. Further, by using the dried gas, moisture contained in the gas is prevented from being adsorbed on the inner wall surface of the load lock chamber 35.

  The gas guided from the leak pipe 42 to the load lock chamber 35 collides with the substrate 17, flows along the substrate 17, and then is guided to the exhaust pipe 52. Thus, a gas flow from the leak pipe 42 through the load lock chamber 35 to the exhaust pipe 52 is generated. Due to this gas flow, foreign matters such as dust in the load lock chamber 35 are discharged from the exhaust pipe 52 to the outside. In particular, dust adhering to the substrate 17 can be eliminated by this gas flow.

  In step S108, the waiting time of 10 seconds is measured. After 10 seconds, the leak valves 41 and 43 are closed in step S109. The waiting time is a time sufficient for removing foreign matters such as dust in the load lock chamber 35. Here, the waiting time is set to 10 seconds. However, since the effect of removing foreign matter increases or decreases depending on the shape and structure of the load lock chamber 35, it is desirable to set the waiting time for achieving the effect individually.

  In step S110, it is determined whether or not the atmospheric sensor 53 has been turned off. The atmospheric pressure sensor 53 generates an on signal when the pressure in the load lock chamber 35 is equal to the atmospheric pressure, and generates an off signal when the pressure in the load lock chamber 35 becomes smaller than the atmospheric pressure.

  If the atmospheric sensor 53 is not turned off, the process proceeds to step S111, and it is determined whether or not 10 minutes have elapsed since the leak valves 41 and 43 were closed. If 10 minutes have already passed, the process proceeds to step S112, where an error is determined, and this process is terminated.

  If the atmospheric sensor 53 is turned off before 10 minutes have passed since the leak valves 41 and 43 were closed, the process proceeds to step S113.

  In step S113, the vacuum gauge 54 is turned on. The vacuum gauge 54 generates an on signal when the pressure in the load lock chamber 35 is lower than the atmospheric pressure, and generates an off signal when the pressure in the load lock chamber 35 becomes equal to the atmospheric pressure. Therefore, here, since the atmospheric sensor 53 is off, the vacuum gauge 54 should be on.

  In step S114, it is determined whether or not the degree of vacuum measured by the vacuum gauge 54 has become a set value or less. That is, it is determined whether or not the degree of vacuum in the load lock chamber 35 has become a set value or less. If the degree of vacuum is not less than or equal to the set value, the process proceeds to step S115, where it is determined whether 10 minutes have elapsed since the vacuum gauge 54 was turned on. If 10 minutes have already passed, the process proceeds to step S116, where an error is determined, and this process is terminated.

  If the degree of vacuum measured by the vacuum gauge 54 becomes less than the set value before 10 minutes have passed since the vacuum gauge 54 was turned on, the process proceeds to step S117.

  In step S117, the transport valve 32 is opened. In step S 118, the substrate 17 is transferred together with the positioning table 21 from the load lock chamber 35 onto the XY stage 20 in the work chamber 21. In step S119, the conveyance valve 32 is closed. In step S <b> 120, electronic drawing is performed on the substrate 17 by the electron optical system 10.

  When the electronic drawing is completed, the substrate 17 is transferred from the XY stage 20 in the work chamber 21 to the load lock chamber 35 and further transferred into the substrate storage box 39. The processing after the completion of the electronic drawing is the same as in the prior art.

  That is, the transfer valve 32 is opened. The substrate 17 and the positioning table 21 are transferred from the XY stage 20 in the work chamber 31 to the load lock chamber 35. The transfer valve 32 is closed.

  The exhaust valve 51 is closed and the leak valves 41 and 43 are opened. Air enters from the leak valves 41 and 43, and the load lock chamber 35 becomes atmospheric pressure. The leak valves 41 and 43 are closed, and the transfer valve 36 is opened. The substrate 17 is transferred from the load lock chamber 35 into the substrate storage box 39.

  The example of FIG. 3 is a case where both the atmospheric pressure sensor 53 and the vacuum gauge 54 are used. As described above, when a vacuum gauge capable of measuring up to atmospheric pressure is used, the atmospheric pressure sensor 53 can be removed. In this case, in step S109, it is determined whether or not the vacuum gauge is turned on, and the process in step S112 may be deleted.

  Referring to FIG. 2 again, the temperature adjustment function in the vacuum exhaust apparatus according to the present invention will be described. In step S107, when the leak valves 41 and 43 are opened and gas is introduced into the load lock chamber 35 during evacuation, the gas adiabatically expands and the temperature in the load lock chamber 35 rapidly decreases. As a result, the temperature of the substrate 17 decreases. When the positioning table 21 is installed on the XY stage 20 in the work chamber 21 together with the substrate 17, if the temperature difference between the positioning table 21 and the XY stage 20 is large, thermal distortion occurs. Therefore, the temperature of the substrate 17 and the positioning table 21 should be as close as possible to the temperature of the XY stage 20.

  The temperature measuring instrument 45 measures the temperature of the substrate 17 and the positioning table 21 and supplies it to the calculation unit 47. The calculation unit 47 compares the temperature of the substrate 17 and the positioning table 21 with the temperature of the XY stage 20 obtained in advance, and calculates the temperature difference between them. The calculation unit 47 generates a heating command signal or a cooling command signal corresponding to the temperature difference, and supplies it to the temperature adjustment device 40. The temperature adjustment device 40 heats or cools the leaked gas based on a command from the calculation unit 47.

  In this example, it is assumed that the temperature in the load lock chamber 35 is lowered due to the adiabatic expansion of the leak gas, and the temperatures of the substrate 17 and the positioning table 21 are considerably lowered as compared with the temperature of the XY stage 20.

  The vertical axis in FIG. 4 is the temperature of the substrate 17 and the positioning table 21, and the horizontal axis is time. The straight line 141 is the temperature of the XY stage 20, and the solid straight line 142 is the temperature of the substrate 17 and the positioning table 21 when the substrate 17 is transferred into the load lock chamber 35. The solid curve 143 is the temperature of the substrate 17 and the positioning table 21 after the leakage gas is introduced when the temperature is adjusted, and the broken curve 144 is a leakage gas introduced when the temperature is not adjusted. It is the temperature of the board | substrate 17 and the positioning stand 21 after having performed. The temperature of the XY stage 20 is 23 + Δt degrees and is constant. It is assumed that Δt is sufficiently small. The temperature of the substrate 17 and the positioning table 21 when being carried into the load lock chamber 35 from the substrate storage box 39 is set to 23 degrees. At time t = t0, the leak valves 41 and 43 are opened, and the leak gas is introduced into the load lock chamber 35. When temperature adjustment is not performed, the temperature in the load lock chamber 35 rapidly decreases due to adiabatic expansion of the leak gas, and the temperatures of the substrate 17 and the positioning table 21 decrease as indicated by the dashed curve 144. However, when the temperature is adjusted according to this example, the leak gas is heated by the temperature adjusting device 40. Therefore, the amount of decrease in the temperature in the load lock chamber 35 due to the adiabatic expansion of the leak gas is small, and the amount of decrease in the temperatures of the substrate 17 and the positioning table 21 is small as shown by the solid curve 143.

  According to this example, the temperature of the substrate 17 and the positioning table 21 measured by the temperature measuring device 45 is sent to the calculation unit 47, and the heating command signal generated by the calculation unit 47 is sent to the temperature adjustment device 40. Accordingly, the temperatures of the substrate 17 and the positioning table 21 are optimally adjusted by feedback control.

  Although it is preferable to directly measure the temperature of the substrate 17 and the positioning table 21 by the temperature measuring device 45, when the temperature of the substrate 17 and the positioning table 21 cannot be directly measured, the temperature in the load lock chamber 35 is measured. May be. In this case, it is necessary to obtain in advance a conversion formula or table between the temperature in the load lock chamber 35 and the temperature of the substrate 17 and the positioning table 21.

  As the temperature measuring device 45, a type in which the temperature sensing unit is in direct contact with the substrate 17 and the positioning table 21 may be used, but a non-contact type temperature measuring device such as a radiation thermometer may be used.

  In the above example, the vacuum evacuation apparatus of the present invention is installed in the electron beam drawing apparatus, but the vacuum evacuation apparatus of the present invention is provided in other apparatuses that require evacuation, such as an electron beam microscope or a focused ion beam apparatus. It is also possible.

  The example of the present invention has been described above, but the present invention is not limited to the above-described example, and various modifications can be made by those skilled in the art within the scope of the invention described in the claims. Easy to understand.

It is the schematic of the electron beam drawing apparatus provided with the vacuum exhaust apparatus by this invention. It is a figure which shows the detail of the vacuum exhaust apparatus by this invention provided in the electron beam drawing apparatus. It is a figure explaining the operation | movement in the vacuum exhaust apparatus by this invention. It is a figure for demonstrating the temperature control function of the vacuum exhaust apparatus by this invention.

Explanation of symbols

10: Electron optical system. 11 ... Electron gun. 12 ... Electron beam. 13: Aperture. 14 ... Molded polarizer. 15 ... Electronic lens. 16: Deflector. 17 ... Substrate. 20 ... XY stage. 21: Positioning table. 22: Electrostatic chuck. 31 ... Work chamber. 32 ... Conveying valve. 35 ... Load lock room. 36 ... Conveying valve. 39: Substrate storage box. 40 ... Temperature control device. 41 ... Leak valve. 43 ... Leak valve. 45. Temperature measuring instrument. 47. Calculation unit. 50 ... Vacuum pump. 51. Exhaust valve. 53 ... Atmospheric pressure sensor. 54 ... Vacuum gauge

Claims (8)

In a vacuum evacuation device provided in a sample load lock chamber connectable to both a vacuum evacuated sample chamber holding a sample irradiated with a charged particle beam and a sample storage chamber under atmospheric pressure for storing the sample,
An evacuation pump that evacuates the sample load lock chamber from one side, a gas leak device that leaks gas into the sample load lock chamber from the other side, and a temperature control device that heats or cools the gas. An evacuation apparatus comprising:   2. The evacuation apparatus according to claim 1, wherein the evacuation pump is provided on a bottom surface side of the sample load lock chamber, and the gas leak device is provided on a ceiling side of the sample load lock chamber. Vacuum exhaust device.   2. The vacuum evacuation apparatus according to claim 1, wherein a temperature measuring device provided in the sample load lock chamber, and a calculation unit that inputs a signal from the temperature measuring device and transmits a control signal to the temperature adjusting device. An evacuation apparatus comprising:   2. The vacuum evacuation apparatus according to claim 1, wherein when the sample from the sample storage chamber is transported into the sample load lock chamber and the sample load lock chamber is sealed, evacuation is started by the vacuum pump. A vacuum evacuation device characterized in that gas is leaked from the gas leak device. A charged particle beam device for irradiating a charged particle beam on the sample, a vacuum evacuated sample chamber for holding the sample irradiated to the charged particle beam, a sample storage chamber under atmospheric pressure for storing the sample, and the sample A charged particle beam apparatus having a sample load lock chamber connectable to a chamber and a sample storage chamber, and a vacuum exhaust device provided in the sample load lock chamber.
The vacuum evacuation device includes a vacuum evacuation pump that evacuates the sample load lock chamber from one side, a gas leak device that leaks gas from the other side into the sample load lock chamber, and heats or cools the gas. A charged particle beam device comprising: a temperature control device;   6. The charged particle beam apparatus according to claim 5, wherein the evacuation pump is provided on a bottom surface side of the sample load lock chamber, and the gas leak device is provided on a ceiling side of the sample load lock chamber. Charged particle beam device.   The charged particle beam device according to claim 5, wherein a temperature measuring device provided in the sample load lock chamber, a calculation unit that inputs a signal from the temperature measuring device and transmits a control signal to the temperature adjusting device, A charged particle beam apparatus comprising:   6. The charged particle beam apparatus according to claim 5, wherein when the sample from the sample storage chamber is transported into the sample load lock chamber and the sample load lock chamber is sealed, evacuation is started by the vacuum pump. A charged particle beam device for leaking gas from the gas leak device.

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