JP5726637B2 - Liquid processing apparatus and liquid processing method - Google Patents

Description

  The present invention relates to a liquid processing apparatus and a liquid processing method for liquid processing a substrate.

  In a manufacturing process of a semiconductor device or a flat panel display (FPD), a liquid processing apparatus for liquid processing a substrate such as a semiconductor wafer or a glass substrate is used. Some liquid processing apparatuses support and rotate a substrate horizontally and supply a processing liquid to the rotating substrate.

  In this liquid processing apparatus, by rotating the substrate, the processing liquid supplied onto the substrate is spread outward to form a liquid film, and the processing liquid is released to the outside of the substrate. The processing liquid shaken off by the centrifugal force from the rotating substrate is collected in the cup.

  By the way, when the processing liquid is supplied to the substrate surface while the substrate is rotated, mist and vapor of the processing liquid are scattered above the substrate. The scattered mist and vapor adhere to the substrate again and cause particles to be generated on the substrate.

  In view of this, a liquid processing apparatus has been developed that exhausts the inside of the cup to form an airflow from above the substrate toward the cup and suppress the generation of mist and vapor above the substrate (see, for example, Patent Document 1). .

JP 2009-38083 A

  The optimal state of the airflow above the substrate differs for each liquid processing step. For example, in the liquid processing of a substrate, there are various processing liquid supply steps for supplying the processing liquid to the substrate and a drying step for rotating the substrate at high speed and shaking the processing liquid from the substrate by centrifugal force. In the supply process and the drying process, the optimum state of the airflow above the substrate is different.

  However, in the conventional configuration, it is difficult to change the conditions for optimizing the airflow state above the substrate for each liquid processing step.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a liquid processing apparatus and a liquid processing method capable of optimizing the state of the airflow above the substrate according to the liquid processing steps. To do.

In order to solve the above problems, the first aspect of the present invention is:
In a liquid processing apparatus for liquid processing a substrate,
A support member that supports the substrate horizontally and is rotatable;
A rotation mechanism for rotating the support member;
A liquid supply member for supplying a processing liquid from above to the substrate supported by the support member;
A gap forming member that is disposed above the support member, is rotatably coupled integrally with the support member, and forms an annular gap with an outer periphery of the support member;
Through the annular gap, and a cup for collecting the processing liquid shaken off from the substrate to be rotated,
An elevating mechanism for elevating and lowering the gap forming member,
The elevating mechanism rotates the rotation mechanism so that the state of the airflow above the substrate supported by the support member corresponds to the type of the processing liquid supplied to the substrate and / or the rotation speed of the substrate. By raising or lowering the gap forming member in a state where the support member and the gap forming member are integrally rotated by a mechanism, the kind of the processing liquid that supplies the annular gap to the substrate and / or the Provided is a liquid processing apparatus which adjusts the substrate according to the number of rotations .

In addition, the second aspect of the present invention includes
In a liquid processing method for liquid processing a substrate,
Supporting the substrate horizontally by a support member;
A step of integrally rotating a gap forming member that forms an annular gap between the support member, the substrate supported by the support member, and an outer peripheral portion of the support member;
From the liquid supply member disposed above the substrate to be rotated, a step of supplying the processing liquid to the substrate,
Through the annular gap, as well as collecting the processing liquid shaken off from the substrate to rotate the cup, a step of exhausting the inside of the cup,
Formation of the gap between the support member and the support member so that the state of the airflow above the substrate supported by the support member corresponds to the type of the processing liquid supplied to the substrate and / or the number of rotations of the substrate. The type of the processing liquid for supplying the annular gap to the substrate and / or the lowering the gap forming member relative to the support member while the member is rotated integrally with the member. And a step of adjusting the substrate according to the number of rotations of the substrate .

  ADVANTAGE OF THE INVENTION According to this invention, the liquid processing apparatus and liquid processing method which can optimize the state of the airflow above a board | substrate according to the process of a liquid processing can be provided.

The top view which shows the substrate processing apparatus containing the liquid processing apparatus by one Embodiment of this invention. Sectional drawing which shows the liquid processing apparatus by one Embodiment of this invention Sectional drawing which shows the principal part of FIG. A top view showing the positional relationship between the wafer support member 10 and the connecting pins 26 of the cover 20 Sectional drawing which shows the principal part of the liquid processing apparatus by a 1st modification Sectional drawing which expands and shows the cyclic | annular space | gap of the liquid processing apparatus by a 2nd modification Sectional drawing which shows the principal part of the liquid processing apparatus by a 3rd modification Top view showing liquid supply member 30C Sectional drawing which shows the liquid processing apparatus by a 4th modification

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. In each of the drawings, the same or corresponding components are denoted by the same or corresponding reference numerals, and description thereof is omitted.

  FIG. 1 is a top view showing a substrate processing apparatus including a liquid processing apparatus according to an embodiment of the present invention.

  The substrate processing apparatus 100 includes a carrier station S1 on which a plurality of (four in FIG. 1) wafer carriers C that accommodate a plurality of wafers W are placed, and a carrier station S1 and a liquid processing station S3 described later. A loading / unloading station S2 for delivering the wafer W and a liquid processing station S3 in which the liquid processing apparatus 1 according to the embodiment of the present invention is disposed.

  The loading / unloading station S2 has a transport mechanism 102 for unloading the wafer W from the wafer carrier C and placing it on the stage 101, and picking up the wafer W from the stage 101 and loading it into the wafer carrier C. The transfer mechanism 102 has a holding arm 103 that holds the wafer W. The transfer mechanism 102 can move the holding arm 103 along a guide 104 that extends in the arrangement direction of the wafer carriers C (X direction in the drawing). Further, the transport mechanism 102 can move the holding arm 103 in a direction perpendicular to the X direction (Y direction in the drawing) and in the vertical direction, and can rotate the holding arm 103 in a horizontal plane.

  The liquid processing station S3 includes a transfer chamber 105 extending in the Y direction, and a plurality of liquid processing apparatuses 1 provided on both sides of the transfer chamber 105. A transfer mechanism 106 is provided in the transfer chamber 105, and the transfer mechanism 106 has a holding arm 107 that holds the wafer W. The transport mechanism 106 can move the holding arm 107 along a guide 108 provided in the transport chamber 105 and extending in the Y direction. Further, the transport mechanism 106 can move the holding arm 107 in the X direction, and can rotate it in a horizontal plane. The transport mechanism 106 transports the wafer W between the delivery stage 101 of the carry-in / out station S <b> 2 and each liquid processing apparatus 1.

  In the substrate processing apparatus 100 having the above configuration, the wafer W is taken out from the wafer carrier C placed on the carrier station S1 by the transport mechanism 102 and placed on the stage 101. The wafer W on the stage 101 is carried into the liquid processing apparatus 1 by the transfer mechanism 106 in the liquid processing station S3, and the surface of the wafer W is subjected to liquid processing. After the liquid processing, the wafer W is returned to the wafer carrier C through a route (procedure) reverse to that at the time of loading. Further, while one wafer W is subjected to liquid processing, the other wafers W are sequentially transferred to the other liquid processing apparatus 1 and liquid processing is performed on the other wafers W. For this reason, the wafer W can be liquid-processed with high throughput.

  FIG. 2 is a cross-sectional view showing a liquid processing apparatus according to an embodiment of the present invention. FIG. 3 is a cross-sectional view showing a main part of FIG. FIG. 4 is a top view showing the positional relationship between the wafer support member 10 and the connecting pins 26 of the cover 20.

  The liquid processing apparatus 1 is connected to a wafer support member 10 that horizontally supports the wafer W, a motor M that rotates the wafer support member 10, and the wafer support member 10 so as to be rotatable integrally with the wafer support member 10. And a cover 20 that forms a processing chamber S for liquid processing of W. Further, the liquid processing apparatus 1 is formed between a liquid supply member 30 for supplying a processing liquid to the wafer W from above in the processing chamber S, and an outer peripheral portion 13 of the wafer support member 10 and an outer peripheral portion 23 of the cover 20. And a cup 40 surrounding the annular gap GP. The inside of the cup 40 is exhausted by an exhaust mechanism E provided as equipment on the factory side, for example. The flow rate of the gas exhausted from the liquid processing apparatus 1 by the exhaust mechanism E is constant.

  In the liquid processing apparatus 1, the motor M rotates the wafer support member 10, and thus the cover 20 and the wafer W, with the wafer support member 10 and the cover 20 forming the processing chamber S. The liquid supply member 30 supplies the processing liquid to the rotating wafer W from above. The processing liquid supplied to the rotating wafer W is spun off to the outside of the wafer W by centrifugal force, and is collected in the cup 40 through the annular gap GP. At this time, the exhaust mechanism E exhausts the inside of the cup 40, thereby forming an air flow from the upper space of the wafer W in the processing chamber S toward the cup 40 through the annular gap GP. This air current plays a role of conveying the processing liquid to the cup 40. Hereinafter, each structure of the liquid processing apparatus 1 is demonstrated.

  The wafer support member 10 supports the wafer W horizontally and can rotate together with the wafer W. The wafer support member 10 includes a plate-shaped plate portion 11 arranged horizontally, a rotary shaft portion 12 attached to the lower surface side of the plate portion 11, and a cylindrical outer peripheral portion 13 extending upward from the outer edge of the plate portion 11. have. The outer peripheral portion 13 is formed in a cylindrical shape, for example, and has an inner diameter slightly larger than the outer diameter of the wafer W.

  As shown in FIG. 4, a claw portion 14 extending inward is provided on the outer peripheral portion 13 of the wafer support member 10. A plurality (12 in FIG. 4) of claw portions 14 are provided at intervals along the inner edge of the outer peripheral portion 13. The claw portion 14 is in contact with the peripheral edge of the lower surface of the wafer W and supports the wafer W horizontally. The upper surface of the wafer W supported by the claw portion 14 and the upper surface of the outer peripheral portion 13 are located on substantially the same plane.

  As shown in FIG. 3, a guide portion 15 that guides the airflow extends obliquely downward and outward from the side portion of the outer peripheral portion 13 of the wafer support member 10. The guide part 15 has a substantially annular shape, and the guide part 15 is provided with a plurality of notches 16 at intervals (six in FIG. 4). When a connecting pin 26 of the cover 20 described later is inserted into the notch 16, the cover 20 and the wafer support member 10 can be rotated integrally.

  As shown in FIG. 2, the cover 20 is connected to the wafer support member 10 so as to be integrally rotatable, covers the upper portion of the wafer support member 10, and a processing chamber S for liquid processing the wafer W together with the wafer support member 10. Form. Since the processing chamber S is substantially sealed, the liquid processing can be performed stably. In addition, since the wafer support member 10 and the cover 20 constituting the wall surface of the processing chamber S rotate integrally with the wafer W, the processing liquid scattered from the wafer W is unlikely to bounce off the wall surface of the processing chamber S.

  The cover 20 has an annular plate portion 21 having an opening 24 through which gas flows into the processing chamber S, and a cylindrical duct portion extending upward from the outer peripheral portion of the opening 24 (the inner peripheral portion of the plate portion 21). 22 and a cylindrical outer peripheral portion 23 extending downward from the outer edge of the plate portion 21. A plurality of connecting pins 26 that can be inserted into and removed from the plurality of notches 16 are fixed to the outer peripheral portion 23. The connecting pin 26 is attached to a guide portion 25 described later at a position corresponding to the notch 16.

  The duct portion 22 of the cover 20 has a cylindrical shape, and a gas supply mechanism F such as a fan filter unit (FFU) is provided above the duct portion 22. The flow rate of the gas supplied to the liquid processing apparatus 1 by the gas supply mechanism F is constant, and is substantially the same as the flow rate of the gas discharged from the liquid processing apparatus 1 by the exhaust mechanism E. In the present embodiment, in this way, the amount of gas flowing into and out of the liquid processing apparatus 1 is made constant, and the state of the airflow (including the flow rate and flow velocity) above the wafer W to be liquid processed in the processing chamber S is included. ).

  The gas from which impurities have been removed in the gas supply mechanism F becomes a downflow in the duct portion 22 and flows into the processing chamber S from the opening portion 24 of the plate portion 21 that is disposed horizontally. As shown in FIG. And flows out of the processing chamber S through an annular gap GP described later. The flow rate of the gas flowing into the processing chamber S is mainly determined by the flow rate of the gas flowing out of the processing chamber S through the annular gap GP, and is determined by the size of the annular gap GP.

  The outer peripheral portion 23 of the cover 20 is formed in a cylindrical shape, for example, and has an inner diameter slightly larger than the outer diameter of the wafer W. An annular gap GP is formed between the outer peripheral portion 23 and the outer peripheral portion 13 of the wafer support member 10. The annular gap GP has a shape along the outer periphery of the wafer W supported by the wafer support member 10.

  As shown in FIG. 3, a guide portion 25 that guides the airflow extends obliquely downward and outward from the side portion of the outer peripheral portion 23 of the cover 20. By the guide portion 25 and the guide portion 15 of the wafer support member 10, the airflow passing through the annular gap GP is guided obliquely outward and downward.

  As shown in FIG. 2, the cover 20 is connected to a cover lifting mechanism 122 via a cover support member 121 and can be moved up and down by the cover lifting mechanism 122. When the wafer W is loaded into the liquid processing apparatus 1, the cover 20 is raised to the standby position by the cover lifting mechanism 122, and the connecting pin 26 comes out of the notch 16. When the wafer W is supported by the wafer support member 10, the cover 20 is lowered by the cover elevating mechanism 122, the connecting pin 26 is inserted into the notch 16, and the wafer support member 10 and the cover 20 are integrally connected to be rotatable. Is done.

  The cover lifting mechanism 122 plays a role of adjusting the annular gap GP in a state where the cover 20 and the wafer support member 10 are integrally connected so as to be rotatable and the processing chamber S is formed. When the cover lifting mechanism 122 moves the cover 20 upward, the cover 20 is separated from the wafer support member 10 and the annular gap GP is widened. On the other hand, when the cover lifting mechanism 122 moves the cover 20 downward, the cover 20 approaches the wafer support member 10 and the annular gap GP becomes narrow. By adjusting the annular gap GP, it is possible to adjust the state (including the flow velocity, the flow rate, and the like) of the airflow flowing out from the processing chamber S through the annular gap GP.

  The motor M rotatably holds the rotating shaft portion 12 of the wafer support member 10. When the motor M is operated, the wafer support member 10, the wafer W supported by the wafer support member 10, and the cover 20 connected to the wafer support member 10 are integrally rotated.

  In the processing chamber S, the liquid supply member 30 is disposed above the wafer W supported by the wafer support 10 and supplies the processing liquid to the wafer W from above. As shown in FIG. 3, the liquid supply member 30 includes a disk-shaped main body 31 having a diameter larger than the diameter of the circular opening 24. The main body 31 is disposed to face the duct portion 22 (opening 24), and the airflow flowing into the processing chamber S from the opening 24 does not disturb the liquid film of the processing liquid formed on the wafer W. The role of changing the direction.

  As shown in FIG. 2, the liquid supply member 30 is connected to liquid supply sources S1 and S2 via a pipe P1 in which valves V1 and V2 are provided in the middle. The liquid supply source S1 supplies a chemical solution, and the liquid supply source S2 supplies a rinse solution for washing away the chemical solution. The chemical liquid and the rinsing liquid are supplied from the nozzle 32 (see FIG. 3) toward the wafer W in a switchable manner.

In the cleaning process of the wafer W, for example, SPM (H ₂ SO ₄ + H ₂ O ₂ ), SC1 (NH ₄ OH + H ₂ O ₂ + H ₂ O), SC2 (HCl + H ₂ O ₂ + H ₂ O), or DHF is used as a chemical solution. (Diluted hydrofluoric acid) or the like is used. A plurality of types of chemical solutions may be used, and a plurality of liquid supply sources S1 may be provided. For example, deionized water (DIW) is used as the rinse liquid.

In the etching treatment, hydrofluoric acid (HF), buffered hydrofluoric acid (BHF), nitric acid (HNO ₃ ), or the like may be used as a treatment liquid.

  In the developing process, a developing solution is used as the chemical solution.

  The nozzle 32 may protrude downward from the main body 31 or may be embedded in the main body 31. The nozzle 32 opens toward the wafer W supported by the wafer support member 10 and supplies a chemical solution or a rinse solution to the upper surface of the wafer W. A plurality of nozzles 32 are provided at intervals along the radial direction of the wafer W (only two are shown in FIG. 3). The number of nozzles 32 may be one.

  Regardless of the number of nozzles 32, one nozzle 32 opens toward the center of the wafer W, and supplies a chemical solution or a rinse solution to the center of the wafer W. The processing liquid supplied to the central portion of the wafer W spreads outward and forms a liquid film.

  In the vicinity of the outlet of the pipe P1 connecting the liquid supply source S1 and the liquid supply member 30, a heating device H that heats the chemical liquid to a predetermined temperature is provided in order to increase the treatment capacity of the chemical liquid. The heating device H may be installed in the liquid supply source S1.

  The liquid supply member 30 is connected to a liquid supply source S3 via a pipe P3 provided with a valve V3 on the way. The liquid supply source S3 supplies alcohol such as isopropyl alcohol (IPA) to the liquid supply member 30 as a dry solvent for the rinse liquid. The dry solvent is supplied toward the wafer W from the nozzle 33 (see FIG. 3) of the liquid supply member 30.

  The nozzle 33 may protrude downward from the main body 31 or may be embedded in the main body 31. The nozzle 33 opens toward the wafer W supported by the wafer support member 10 and supplies a dry solvent to the upper surface of the wafer W. A plurality of nozzles 33 are provided at intervals along the radial direction of the wafer W (only two are shown in FIG. 3). The number of nozzles 33 may be one.

  Regardless of the number of nozzles 33, one nozzle 33 is open toward the center of the wafer W and supplies a dry solvent to the center of the wafer W. The processing liquid supplied to the central portion of the wafer W spreads outward and forms a liquid film.

  The liquid supply member 30 is connected to the liquid supply member elevating mechanism 132 via the support member 131, and can be moved up and down by the liquid supply member elevating mechanism 132. The liquid supply member 30 is raised to the standby position by the liquid supply member lifting mechanism 132 when the wafer W is carried into and out of the liquid processing apparatus 1, and the liquid supply member 30 is supported after the wafer W is supported by the wafer support member 10. It descends by the elevating mechanism 132 and stops at a position where the processing liquid is supplied to the wafer W.

  The liquid supply member elevating mechanism 132 raises or lowers the liquid supply member 30 in a state where the wafer support member 10 and the cover 20 form the processing chamber S so as to approach or separate from the plate portion 21 of the cover 20. Therefore, the state (flow rate, flow velocity, direction) of the airflow flowing into the processing chamber S from the opening 24 of the plate portion 21 can be adjusted.

  The processing liquid supplied to the wafer W from the liquid supply member 30 is spun off to the outside of the wafer W by centrifugal force, and is collected in the cup 40 together with the airflow passing through the annular gap GP. The processing liquid dropped on the plate portion 11 of the wafer support member 10 flows out from the outlet 17 (see FIG. 3) formed on the outer peripheral portion 13 of the wafer support member 10 by centrifugal force and is collected in the cup 40. .

  The cup 40 includes an annular plate portion 41, a cylindrical inner wall portion 42 extending upward from the inner edge of the plate portion 41, and a cylindrical outer wall portion 43 extending upward from the outer edge of the plate portion 41. Yes. The outer wall 43 surrounds the annular gap GP, and an annular flange 44 extends diagonally upward from the upper end of the outer wall 43.

  The cup 40 has a cylindrical partition 47 that partitions the lower space in the cup 40 into an outer annular space 45 and an inner annular space 46 in order to separate the processing liquid from the airflow. A drainage pipe 48 for discharging the processing liquid to the outside is connected to the outer annular space 45. An exhaust mechanism E is connected to the inner annular space 46 via an exhaust pipe 49.

  The exhaust mechanism E is configured by a vacuum pump or the like, and exhausts the interior of the cup 40 to generate an air flow from the upper space of the wafer W in the processing chamber S toward the outer wall 43 of the cup 40 through the annular gap GP. Form. This air current plays a role of collecting the processing liquid spun off from the rotating wafer W into the cup 40.

  A predetermined device (for example, motor M, valves V1 to V3, cover elevating mechanism 122, liquid supply member elevating mechanism 132) of the liquid processing apparatus 1 controls the operation of the liquid processing apparatus 1 as shown in FIG. The unit 60 is connected via a signal line. The control unit 60 is configured as a computer including a CPU, a recording medium, and the like. The control unit 60 causes the CPU to execute various programs stored in the recording medium, thereby controlling devices connected via the signal lines and causing various operations of the liquid processing apparatus 1 described later to be performed.

  Next, the operation (liquid processing method) of the liquid processing apparatus having the above configuration will be described.

  First, when the cover elevating mechanism 122 raises the cover 20 to the standby position and the liquid supply member elevating mechanism 132 raises the liquid supply member 30 to the standby position, it is held by the holding arm 107 of the transport mechanism 106 shown in FIG. The wafer W is loaded into the liquid processing apparatus 1. When the wafer W is transferred to the wafer support member 10 and the holding arm 107 is withdrawn from the liquid processing apparatus 1, the liquid supply member 30 is lowered to a position near the upper surface of the wafer W by the liquid supply member elevating mechanism 132. Further, the cover 20 is lowered by the cover elevating mechanism 122, the connecting pin 26 of the cover 20 is inserted into the notch 16 of the wafer support member 10, and the cover 20 and the wafer support member 10 are integrally connected to be rotatable. The cover 20 covers the upper portion of the wafer support member 10 and forms a processing chamber S for liquid processing the wafer W together with the wafer support member 10. Subsequently, the motor M rotates the wafer support member 10, the cover 20, and the wafer W integrally.

  Next, the processing liquid is supplied from the liquid supply member 30 to the upper surface of the rotating wafer W. Specifically, for example, a chemical (for example, SPM) is supplied to the wafer W from the nozzle 32 of the liquid supply member 30 for a predetermined time. Subsequently, a rinse solution for washing away the chemical solution is supplied to the wafer W from the nozzle 32 of the solution supply member 30 for a predetermined time. Next, a dry solvent (for example, IPA) is discharged from the nozzle 33 of the liquid supply member 30 toward the upper surface of the wafer W for a predetermined time. After the supply of the dry solvent is stopped, the wafer W is rotated at a high speed, the rinse liquid is shaken off by a centrifugal force, and the rotation of the wafer W is stopped.

  Here, the processing liquid shaken off from the rotating wafer W is collected in the cup 40 through an annular gap GP formed between the outer peripheral portion 13 of the wafer support member 10 and the outer peripheral portion 23 of the cover 20. Is done. The exhaust mechanism E exhausts the inside of the cup 40 to form an air flow from the space above the wafer W in the processing chamber S toward the cup 40 through the annular gap GP. This air current plays a role of collecting the processing liquid spun off from the rotating wafer W into the cup 40.

  Finally, the wafer W is unloaded from the liquid processing apparatus 1 in the reverse procedure to when the wafer W is loaded into the liquid processing apparatus 1, and the liquid processing of the wafer W is completed.

  In the present embodiment, the wafer support member 10 and the cover 20 form a processing chamber S for liquid processing the wafer W. Since the processing chamber S is substantially sealed, the liquid processing can be performed stably. In addition, since the wafer support member 10 and the cover 20 constituting the wall surface of the processing chamber S rotate integrally with the wafer W, the processing liquid scattered from the wafer W is unlikely to bounce off the wall surface of the processing chamber S.

  In the present embodiment, the annular gap GP is adjusted according to the liquid processing step for the wafer W. Therefore, the state of the airflow flowing out from the processing chamber S to the outside through the annular gap GP can be optimized. When the exhaust amount of the exhaust mechanism E is constant, the flow rate of the airflow passing through the annular gap GP increases as the annular gap GP increases. The adjustment of the annular gap GP is realized, for example, by raising or lowering the cover 20 by the cover lifting mechanism 122.

  In this embodiment, the adjustment of the annular gap GP is realized by raising or lowering the cover 20, but may be realized by lowering or raising the wafer support member 10, and both the cover 20 and the wafer support member 10 may be adjusted. It may be realized by movement of.

  Further, in the present embodiment, the liquid supply member 30 and the cover 20 are moved closer to or away from each other according to the liquid processing step of the wafer W, and the main body portion 31 of the liquid supply member 30 and the plate portion 21 of the cover 20 The gap OG (see FIG. 2) formed between the two is adjusted. Therefore, the state of the airflow flowing into the processing chamber S from the opening 24 of the plate portion 21 can be optimized. When the flow rate of the airflow flowing into the processing chamber S is constant (that is, when the flow rate of the airflow flowing out from the processing chamber S is constant), the closer the opening 24 and the liquid supply member 30 are, that is, the gap OG is. The narrower the airflow, the higher the airflow velocity. The approach or separation between the opening 24 and the liquid supply member 30 is realized, for example, by raising or lowering the liquid supply member 30 by the liquid supply member lifting mechanism 132.

  Next, an example of adjusting the gap OG and the annular gap GP will be described. Here, a case will be described in which a chemical solution, a rinse solution, and a dry solvent are supplied in this order to the rotating wafer W, and then the wafer W is rotated at a high speed in order to shake off the dry solvent.

  First, in the process of supplying SPM, which is a chemical solution, since SPM is used at a higher temperature than other chemical solutions, fumes are likely to be generated above the rotating wafer W. Therefore, in order to prevent the generated fumes from flowing back upward from the opening 24, the gap OG is set narrower than the reference.

  In the SPM supply process, the wafer W is rotated at a low speed so that the SPM is not cooled by the swirling airflow generated in the vicinity of the rotating wafer W. In this state, the annular gap GP is set to be narrower than the reference in order to efficiently discharge fumes from the annular gap GP to the outside. This is because when the annular gap GP is narrowed, the flow velocity of the airflow passing through the annular gap GP is increased, and the flow of the airflow from the processing chamber S to the outside through the annular gap GP is stabilized.

  In the subsequent rinsing liquid supply step, the gap OG and the annular gap GP are returned to the standard size in order to quickly replace the atmosphere in the processing chamber S with the clean atmosphere from the atmosphere containing the chemical liquid.

  In the subsequent step of supplying IPA, which is a dry solvent, it is important to increase the IPA concentration in the processing chamber S in order to improve the efficiency of rinsing liquid replacement with IPA. Therefore, the gap OG and the annular gap GP are set to be narrower than when the SPM is supplied.

  Finally, in the step of rotating the wafer W at a high speed and drying, the gap OG and the annular gap GP are returned to the standard size in order to quickly replace the atmosphere in the processing chamber S.

  In the process of supplying DHF, which is a chemical solution, the oxide film on the wafer W is removed by DHF, and the wafer W becomes hydrophobic. Therefore, it is necessary to rotate the wafer W at a high speed so that a good liquid film is formed, and the swirling airflow generated in the vicinity of the wafer W becomes faster. In order to discharge the high-speed swirling air flow from the annular gap GP to the outside, the annular gap GP is set to a reference size. Further, in the DHF supply process, the gap OG is set narrower than the reference so that the chemical solution does not flow backward from the opening 24.

  Thus, according to the present embodiment, the annular gap GP and / or the gap OG is adjusted according to the process of the processing liquid of the wafer W. Therefore, the state of the airflow flowing into and out of the processing chamber S can be optimized, and the state of the airflow above the wafer W can be optimized.

  The adjustment of the annular gap GP and the gap OG may be performed during the rotation of the wafer W or may be performed before the rotation.

[First Modification]
FIG. 5 is a cross-sectional view showing a main part of a liquid processing apparatus according to a first modification.

  As shown in FIG. 5, the liquid processing apparatus 1 </ b> A includes an annular partition wall 71 </ b> A that partitions the annular gap GP in the vertical direction. From the outer peripheral portion of the partition wall 71A, a guide portion 73A for guiding the airflow extends obliquely downward and outward with respect to the processing chamber S.

  Further, the liquid processing apparatus 1 </ b> A includes a connecting member 72 </ b> A that connects the partition wall 71 </ b> A and the outer peripheral portion 13 of the wafer support member 10. A plurality of connecting members 72A are provided at intervals in the circumferential direction of the annular gap GP.

  A gap G1 that communicates the processing chamber S with the outside is formed between the outer peripheral portion 13 of the wafer support member 10 and the partition wall 71A. The airflow passing through the gap G1 is guided outward and obliquely downward with respect to the processing chamber S by the guide portion 73A of the partition wall 71A and the guide portion 15 of the wafer support member 10.

  In addition, a gap G2 is formed between the outer peripheral portion 23 of the cover 20 and the partition wall 71A to communicate the processing chamber S with the outside. The airflow passing through the gap G2 is guided outward and obliquely downward by the guide portion 73A of the partition wall 71A and the guide portion 25 of the cover 20.

  As shown in FIG. 2, the cover 20 is connected to a cover lifting mechanism 122 via a cover support member 121. Therefore, it is possible to adjust the upper gap G2 in the annular gap GP by raising and lowering the cover 20 by the cover raising and lowering mechanism 122. Therefore, the state of the airflow from the upper space of the wafer W in the processing chamber S toward the cup 40 can be optimized via the annular gap GP.

  Further, in this modification, when the annular gap GP is adjusted, the lower gap G1 does not change, so that a predetermined amount or more of gas or processing liquid flows out of the processing chamber S through the annular gap GP. be able to.

  In this modification, the connecting member 72A connects the partition wall 71A and the outer peripheral portion 13 of the wafer support member 10, but the partition wall 71A and the outer peripheral portion 23 of the cover 20 may be connected. In this case, the lower gap G1 of the annular gap GP changes as the cover 20 moves up and down.

[Second Modification]
FIG. 6 is an enlarged cross-sectional view of the annular gap of the liquid processing apparatus according to the second modification.

  The liquid processing apparatus 1B includes an annular partition wall 71B that partitions the annular gap GP in the vertical direction as in the first modification. From the outer periphery of the partition wall 71B, a guide portion 73B that guides the airflow extends obliquely outward and downward with respect to the processing chamber S.

  In addition, the liquid processing apparatus 1B includes a connecting member (not shown) that connects the partition wall 71B and the wafer support member 10 as in the first modification. A plurality of connecting members are provided at intervals in the circumferential direction of the annular gap GP.

  In the second modification, the partition wall 71B and the outer peripheral portion 23B of the cover 20B form a labyrinth structure that restricts the airflow flowing through the gap G1.

  For example, an annular protrusion 74B is formed on the upper surface of the partition wall 71B, and an annular groove 27B is formed on the lower surface of the outer peripheral portion 23B. The distal end portion of the annular protrusion 74B is inserted into the annular groove 27B and is separated from the wall surface of the annular groove 27B to form a labyrinth structure together with the annular groove 27B. A plurality (three in FIG. 6) of the annular protrusions 74B and the annular grooves 27B are provided concentrically.

  Since the labyrinth structure restricts the airflow flowing through the gap G1, the labyrinth structure is effective for a liquid processing process in which the amount of airflow flowing out from the processing chamber S to the outside is small, for example, a liquid processing process using the processing chamber S as a nitrogen atmosphere.

  In this modification, the partition wall 71B and the outer peripheral portion 23B of the cover 20B form a labyrinth structure. However, the partition wall 71B and the outer peripheral portion 13 of the wafer support member 10 form a labyrinth structure. You may do it. Further, the labyrinth structure may be applied to the annular gap shown in the liquid processing apparatus 1 shown in FIG. 2 and the like, and the outer peripheral portion 13 of the wafer support member 10 and the outer peripheral portion 23 of the cover 20 form a labyrinth structure. Also good.

[Third Modification]
FIG. 7 is a cross-sectional view showing a main part of a liquid processing apparatus according to a third modification. FIG. 8 is a top view showing the liquid supply member 30C.

  The liquid processing apparatus 1C is different from the liquid processing apparatus 1 shown in FIG. 2 in the configuration of the liquid supply member. Since the configuration other than the liquid supply member 30C is the same, the description thereof is omitted.

  As shown in FIGS. 7 and 8, the liquid supply member 30 </ b> C further includes two extension portions 34 </ b> C and 35 </ b> C that extend from the outer peripheral surface of the main body portion 31. The extensions 34C and 35C extend in parallel with the radial direction of the wafer W, and the tip is located above the outer edge of the wafer W. The extension portions 34C and 35C are provided with a plurality of nozzles 32 and 33 at intervals along the extending direction. Therefore, the processing liquid can be supplied uniformly from the center portion of the wafer W to the outer edge portion.

[Fourth Modification]
FIG. 9 is a cross-sectional view showing a liquid processing apparatus according to a fourth modification.

  The liquid processing apparatus 1D supports the wafer W horizontally, is rotatably coupled together with the wafer support member 10D and the wafer support member 10D, and is coupled to the outer peripheral portion 10Da of the wafer support member 10D. A gap forming member 20D that forms an annular gap GPD therebetween.

  In the liquid processing apparatus 1D, the motor M rotates the wafer support member 10D, and thus the gap forming member 20D and the wafer W. The liquid supply member 30 supplies the processing liquid to the rotating wafer W from above. The processing liquid supplied to the rotating wafer W is spun off to the outside of the wafer W by centrifugal force, and is collected in the cup 40 through the annular gap GPD. At this time, the exhaust mechanism 50 exhausts the inside of the cup 40, thereby forming an air flow from the upper space of the wafer W toward the cup 40 through the annular gap GPD. This air current plays a role of conveying the processing liquid to the cup 40. Hereinafter, although each structure of liquid processing apparatus 1D is demonstrated, since structures other than wafer support member 10D and gap | interval formation member 20D are the same as that of FIG. 2, description is abbreviate | omitted.

  The wafer support member 10 </ b> D is a member that supports the wafer W horizontally and can rotate together with the wafer W. The wafer support member 10 </ b> D includes a plate-shaped plate portion 11 that is horizontally disposed, a rotary shaft portion 12 that is attached to the lower surface side of the plate portion 11, and a claw portion 14 </ b> D that is attached to the upper surface side of the plate portion 11.

  The claw portion 14 </ b> D extends upward from the plate portion 11, and contacts the lower surface peripheral portion of the wafer W at the tip portion to support the wafer W horizontally. A step portion having a height substantially the same as the thickness of the wafer W is formed at the tip portion of the claw portion 14D, and the peripheral portion of the lower surface of the wafer W is in contact with a portion having a low height. A plurality of the claw portions 14D are provided at intervals along the circumferential direction with the extension line of the axis of the rotary shaft portion 12 as the center.

  A plurality of connecting holes 16 </ b> D parallel to the rotating shaft portion 12 are provided in the outer peripheral portion of the plate portion 11 at intervals in the circumferential direction centering on the rotating shaft portion 12. A plurality of connecting pins 26D attached to the lower surface side of the gap forming member 20D are supported in the plurality of connecting holes 16D so as to be movable up and down, and the wafer support member 10D and the gap forming member 20D can rotate integrally. It is connected to.

  The gap forming member 20D is a member that is disposed above the wafer support member 10D, is rotatably connected integrally with the wafer support member 10D, and forms an annular gap GPD with the outer peripheral portion 10Da of the wafer support member 10D. is there.

  The gap forming member 20D is formed in an annular shape so as to surround the outer periphery of the wafer W supported by the wafer support member 10D. The gap forming member 20 </ b> D has an inner diameter slightly larger than the outer diameter of the wafer W. Therefore, the entire upper surface of the wafer W is opened upward, and the gas from which impurities have been removed by a gas supply mechanism such as a fan filter unit is supplied to the entire upper surface of the wafer W in a down flow.

  The gap forming member 20 </ b> D is inclined downward as it goes outward, and guides the processing liquid shaken off from the rotating wafer W and the airflow carrying the processing liquid obliquely downward into the cup 40. Lead.

  The gap forming member 20 </ b> D is connected to the lifting mechanism 122 via a support member 121 </ b> D that supports the gap forming member 20 </ b> D so as to be rotatable about the extension line of the rotating shaft 12, and can be moved up and down by the lifting mechanism 122. It is.

  The elevating mechanism 122 serves to adjust the annular gap GPD by raising or lowering the gap forming member 20D. When the lifting mechanism 122 moves the gap forming member 20D upward, the annular gap GPD increases. On the other hand, when the lifting mechanism 122 moves the gap forming member 20D downward, the annular gap GPD becomes narrower. By adjusting the annular gap GPD, it is possible to adjust the state of the airflow (including the flow velocity and the flow rate) flowing from the inside to the outside via the annular gap GPD.

  Therefore, similarly to the liquid processing apparatus 1 shown in FIG. 2, the annular gap GPD can be adjusted according to the process of the processing liquid on the wafer W, and the state of the airflow above the wafer W can be optimized. The optimization of the airflow state may be performed during the rotation of the wafer W, or may be performed before the rotation.

  Note that the liquid processing apparatus 1D may have an annular partition wall that divides the annular gap GPD vertically as in the first modification, and has a labyrinth structure as in the second modification. May be.

  As mentioned above, although embodiment and the modification of this invention were described, this invention is not restrict | limited to said embodiment and the modification. Various modifications and substitutions can be made without departing from the scope of the present invention.

  For example, the liquid processing apparatuses 1 to 1D described above are apparatuses that supply the processing liquid to the upper surface of the wafer W and perform liquid processing on the upper surface of the wafer W. The processing liquid is simultaneously applied to each of the upper and lower surfaces of the wafer W. An apparatus for supplying and simultaneously liquid-treating both the upper surface and the lower surface of the wafer W may be used.

  The wafer W is not limited to a semiconductor wafer, and may be a glass substrate for FPD, for example.

1 Liquid processing apparatus 10 Wafer support member 13 Outer peripheral part 20 Cover (gap forming member)
23 Peripheral part 24 Opening part 30 Liquid supply member 40 Cup 50 Exhaust mechanism 71A Partition wall 72A Connection member 122 Cover lifting mechanism W Wafer (substrate)
M motor (rotating mechanism)
GP annular gap

Claims (10)

In a liquid processing apparatus for liquid processing a substrate,
A support member that supports the substrate horizontally and is rotatable;
A rotation mechanism for rotating the support member;
A liquid supply member for supplying a processing liquid from above to the substrate supported by the support member;
A gap forming member that is disposed above the support member, is rotatably coupled integrally with the support member, and forms an annular gap with an outer periphery of the support member;
Through the annular gap, and a cup for collecting the processing liquid shaken off from the substrate to be rotated,
An elevating mechanism for elevating and lowering the gap forming member,
The elevating mechanism rotates the rotation mechanism so that the state of the airflow above the substrate supported by the support member corresponds to the type of the processing liquid supplied to the substrate and / or the rotation speed of the substrate. By raising or lowering the gap forming member in a state where the support member and the gap forming member are integrally rotated by a mechanism, the kind of the processing liquid that supplies the annular gap to the substrate and / or the A liquid processing apparatus that adjusts the substrate according to the number of rotations .   The liquid processing apparatus according to claim 1, wherein a guide portion that guides an airflow flowing outward through the annular gap is provided on an outer peripheral portion of the support member. The liquid supply member is sequentially supplies a plurality of types of the treatment liquid on the substrate,
The liquid processing apparatus has a control device for controlling the lifting mechanism,
The control device controls the lifting mechanism so that the state of the airflow above the substrate supported by the support member is in accordance with the type of the processing liquid supplied to the substrate. The annular gap is adjusted to one corresponding to the type of the processing liquid by raising or lowering the gap forming member in a state where the support member and the gap forming member are integrally rotated by a mechanism. 3. The liquid processing apparatus according to 1 or 2. The liquid supply member sequentially supplies a chemical liquid and a rinsing liquid for removing the chemical liquid to the substrate,
The annular gap when the chemical liquid having a temperature higher than that of the rinse liquid is supplied to the substrate is set narrower than the annular gap when the rinse liquid is supplied to the substrate. Liquid processing equipment. An annular partition wall that vertically partitions the annular gap;
And further comprising a connecting member that connects the partition wall and the outer peripheral portion of the support member or the gap forming member,
The liquid processing apparatus according to any one of claims 1 to 4, wherein a gap through which an airflow passes is formed between the partition wall and an outer peripheral portion of the support member or the gap forming member. In a liquid processing method for liquid processing a substrate,
Supporting the substrate horizontally by a support member;
A step of integrally rotating a gap forming member that forms an annular gap between the support member, the substrate supported by the support member, and an outer peripheral portion of the support member;
From the liquid supply member disposed above the substrate to be rotated, a step of supplying the processing liquid to the substrate,
Through the annular gap, as well as collecting the processing liquid shaken off from the substrate to rotate the cup, a step of exhausting the inside of the cup,
Formation of the gap between the support member and the support member so that the state of the airflow above the substrate supported by the support member corresponds to the type of the processing liquid supplied to the substrate and / or the number of rotations of the substrate. The type of the processing liquid for supplying the annular gap to the substrate and / or the lowering the gap forming member relative to the support member while the member is rotated integrally with the member. And a step of adjusting the substrate according to the number of rotations .   The liquid processing method according to claim 6, wherein a guide portion that guides an airflow flowing outward through the annular gap is provided on an outer peripheral portion of the support member. The liquid supply member, sequentially supplies a plurality of types of the treatment liquid on the substrate,
The support member and the gap forming member are rotated together so that the state of the airflow above the substrate supported by the support member corresponds to the type of the processing liquid supplied to the substrate. The liquid processing according to claim 6 or 7, wherein the annular gap is adjusted according to the type of the processing liquid by raising or lowering the gap forming member relative to the support member in a state where the liquid is formed. Method. The liquid supply member sequentially supplies a chemical liquid and a rinsing liquid for removing the chemical liquid to the substrate,
The annular gap when the chemical liquid having a temperature higher than that of the rinse liquid is supplied to the substrate is set to be narrower than the annular gap when the rinse liquid is supplied to the substrate. Liquid processing method. An annular partition wall that vertically partitions the annular gap;
A connecting member that connects the partition wall and the outer peripheral portion of the support member or the gap forming member is used.
The liquid processing method according to any one of claims 6 to 9, wherein a gap for allowing an air flow to pass is formed between the partition wall and an outer peripheral portion of the support member or the gap forming member.

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