KR101853141B1 - Substrate processing method, substrate processing apparatus and storage medium - Google Patents

Abstract

An object of the present invention is to flatten the unevenness of the surface of a resist pattern with high in-plane uniformity in supplying a solvent to a substrate and improving the roughness of the surface of the resist pattern. The wafer W on which the resist pattern is formed is introduced into the processing vessel 11 and the wafer W is heated on the heating plate 21 in a solvent atmosphere and then heated by the lift pins 24 Is lifted from the plate (21), cooled, and the resist pattern surface (91) is swollen with a solvent. The wafer W is lowered on the heating plate 21 by the lift pins 24 and heated to volatilize the solvent to dry the resist pattern surface 91. [ These cooling and heating are repeated a plurality of times while forming a solvent atmosphere without exhausting the processing vessel 11.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a substrate processing method, a substrate processing apparatus,

The present invention relates to a substrate processing method and a substrate processing apparatus for improving the surface roughness of the resist pattern on a substrate on which a resist pattern is formed.

In the manufacturing process of a semiconductor device or an LCD substrate, a resist solution is applied to the surface of a substrate, for example, a semiconductor wafer (hereinafter referred to as " wafer "), exposed, (Hereinafter referred to as " resist pattern ") is formed. At this time, as described in Patent Document 1, when the surface of the resist pattern after development has fine irregularities, irregularities on the surface may adversely affect the pattern line width when etching is performed in a later process Is known. Therefore, a smoothing process for improving the roughness [LER (Linear Edge Roughness) and LWR (Line Width Roughness) of the resist pattern is proposed.

This smoothing treatment is performed by exposing the resist pattern to an organic solvent vapor which dissolves the resist pattern, and swelling the surface layer portion of the resist pattern with the organic solvent. As a result, the surface layer is dissolved in the organic solvent and smoothed to improve the roughness of the pattern surface, thereby correcting the pattern shape. Thereafter, the organic solvent is volatilized and removed by performing a heat treatment.

Patent Document 1 discloses a technique for improving the surface roughness of a treated film of a substrate by supplying the solvent gas from the nozzle to the substrate while solely moving the nozzle and the substrate and solving only the surface of the treated film of the substrate . In this method, since the solvent gas is supplied from the nozzle to the substrate in the state in which the nozzle is moved, in the region where the solvent gas is initially supplied and the region where the solvent gas is finally supplied, There is a concern that this may be different. Thus, there is a possibility that the degree of dissolution of the surface layer portion of the resist pattern is different between the region where the supply amount of the solvent gas is small and the region where the supply amount is large, and it becomes difficult to ensure high in-plane uniformity for the surface treatment.

Patent No. 4328667

The present invention has been made under such a background, and an object thereof is to provide a technique capable of improving the roughness of a resist pattern formed on a substrate to high in-plane uniformity.

A substrate processing method of the present invention is a substrate processing method for performing a process on a substrate on which a resist pattern is formed by using a solvent to improve the roughness of the surface of the resist pattern, A step of swelling the surface of the resist pattern with the solvent by bringing the substrate to a first temperature state in a state in which the vapor atmosphere of the solvent is formed in the processing container; Heating the substrate to a second temperature higher than the first temperature; and thereafter, taking the substrate out of the processing vessel.

The substrate processing apparatus of the present invention is a substrate processing apparatus for performing a process on a substrate on which a resist pattern is formed by using a solvent to improve the roughness of the surface of the resist pattern, 1. A process cartridge comprising: a container; a loading section for loading the substrate; a heating section for heating the substrate loaded in the loading section; and a gas containing the vapor of the solvent, A method of manufacturing a semiconductor device, the method comprising: a step of forming a resist pattern on a surface of the resist pattern by irradiating the surface of the resist pattern with a solvent And then heating the substrate to a second temperature higher than the first temperature is repeated And a control unit for outputting a control signal.

The storage medium of the present invention is a storage medium storing a computer program used in a substrate processing apparatus for performing a process for improving the roughness of the surface of the resist pattern on a substrate on which a resist pattern is formed, And is for carrying out a substrate processing method.

The present invention relates to a process for planarizing a roughness of a resist pattern formed on a surface of a substrate by a solvent in a state in which a vapor atmosphere of a solvent is formed in the process container, A step of swelling the surface of the resist pattern with a solvent and a step of heating the resist pattern to a second temperature higher than the first temperature in which swelling by the solvent of the surface of the resist pattern is suppressed are repeated. Thus, the substrate placed in the vapor atmosphere of the solvent is cooled to substantially (substantially) simultaneously swell the entire surface of the resist pattern, and the entire surface of the swollen resist pattern is substantially (substantially) simultaneously dried. A high in-plane uniformity treatment can be performed.

1 is a longitudinal sectional view showing a substrate processing apparatus according to a first embodiment of the present invention.
2 is a cross-sectional plan view showing the substrate processing apparatus.
3 is a longitudinal sectional view for explaining the operation of the substrate processing apparatus.
4 is a longitudinal sectional view for explaining the operation of the substrate processing apparatus.
5 is a cross-sectional view for explaining a surface treatment performed in a treatment chamber provided in the substrate processing apparatus.
6 is a longitudinal sectional view for explaining the operation of the substrate processing apparatus.
7 is a longitudinal sectional view for explaining the operation of the substrate processing apparatus.
8 is a time chart for explaining the flow of processes of the substrate processing apparatus.
9 is a longitudinal sectional view of the substrate processing apparatus for explaining an operation of a modification according to the first embodiment of the present invention.
10 is a longitudinal sectional view for explaining the operation of the substrate processing apparatus.
11 is a longitudinal sectional view showing a substrate processing apparatus according to a second embodiment of the present invention.
12 is a longitudinal sectional view for explaining the operation of the substrate processing apparatus.
13 is a longitudinal sectional view for explaining the operation of the substrate processing apparatus.
14 is a longitudinal sectional view for explaining the operation of the substrate processing apparatus.
15 is a longitudinal sectional view showing a substrate processing apparatus according to a third embodiment of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a substrate processing method of the present invention will be described with reference to the drawings together with a substrate processing apparatus for carrying out this method. This substrate processing apparatus is an apparatus for performing a surface treatment method for improving the roughness of the resist pattern on a substrate on which a resist pattern is formed.

Fig. 1 is a processing module for performing substrate processing. As shown in Fig. 1, a processing chamber 11 and a cooling chamber 41 corresponding to the processing container are provided. The treatment chamber 11 and the cooling chamber 41 are provided so as to be arranged in the left-right direction (X-axis direction) in Figs.

In Fig. 1, a semi-entry / exit port 63 for the wafer W as a substrate is formed on the left side surface of the processing chamber 11, and a communication port 64 is formed between the processing chamber 11 and the cooling chamber 41 have. The exit port 63 and the communication port 64 are configured to be opened and closed by shutters 61 and 62, which are partitioning members for defining the atmosphere. A heating plate 21 serving as a heating unit for mounting the wafer W is provided at the bottom of the processing chamber 11. The heating plate 21 is provided with a heater 22 made of a resistance heating body so that the wafer W mounted on the heating plate 21 is heated.

Further, for example, three lift pins 24, which constitute a lift member for holding and lifting the wafer W, are installed to pass through the inside of the heating plate 21 from below the bottom of the treatment chamber 11 have. The lifting pin (24) is raised and lowered by the lifting mechanism (23). The lift pin 24 and the lift mechanism 23 are covered by a cover 27 in order to prevent the atmosphere inside the treatment chamber 11 from leaking through the through hole of the lift pin 24 to the outside.

A ceiling member 25 is provided at an upper portion of the treatment chamber 11 so as to face the entire surface of the wafer W placed on the heating plate 21. [ The ceiling member 25 is made of, for example, stainless steel and is configured such that a surface facing the wafer W is maintained at a temperature lower than the temperature of the wafer W on the heating plate 21. [ In this example, a temperature adjusting mechanism 26 constituted by, for example, a heater or a temperature control flow path is provided in the ceiling member 25, and the temperature of the ceiling member 25 is adjusted.

A process gas supply port 13 containing solvent vapor is extended in a direction perpendicular to the carrying direction of the wafer W (Y direction) and a length covering the diameter of the wafer W Shaped slit-shaped structure. The process gas supply port 13 is connected to the solvent supply source 71 through the gas supply pipe 76 and the gas supply control device group 75. The gas supply pipe 76 branches in the middle and is connected to the N ₂ gas supply source 72 through the gas supply control device group 75. V1 to V5 are valves, and f1 to f6 are flow meters. For the sake of simplicity of explanation, these are integrated and treated as the gas supply control device group 75. [ The gas supply control device group 75 is configured to be capable of heating the gas. Specifically, the gas supply control device group 75 is housed in a case body, and a heater is provided in the case body. The piping and gas supply pipe 76 in the gas supply control device group 75 may be covered with a heat insulating material or a tape heater may be wound to provide a heating mechanism so that the gas can be heated You can.

The treatment chamber (11), respectively from above and below by, N ₂ gas supply for supplying the N ₂ gas is substituted with gas so as to face oppositely at the same time being formed (14a, 15a), N ₂ gas supplied to these half doorway 63 The exhaust passages 14b and 15b are formed on the inner side (in the vicinity of the center of the process chamber 11) than the exhaust passages 14a and 15a. N ₂ gas supply passages 16a and 17a and exhaust passages 16b and 17b are similarly formed in the process chamber 11 so as to face the communication holes 64 from above and below.

The N ₂ gas supply passages 14a, 15a, 16a and 17a extend in the Y direction and are formed into a slit-like structure having a length dimension covering the diameter of the wafer W. A discharge port in the process chamber 11 is formed on the outer wall side So as to discharge the gas in an oblique direction into the container. The N ₂ gas supply passages 14a, 15a, 16a and 17a are connected to the N ₂ gas supply source 72 through the gas supply pipe 76 and the gas supply control device group 75.

The exhaust passages 14b, 15b, 16b, and 17b are also formed in a slit shape having a length dimension that extends in the Y direction and covers the diameter of the wafer W. These exhaust passages join outside the process chamber 11 through an exhaust pipe, and are connected to the exhaust mechanism 73 via a valve Vb.

In the cooling chamber 41, a cooling arm 51 serving as a holding member for cooling the wafer W is provided. The cooling arm 51 can be horizontally moved into the processing chamber 11 through the communication port 64 by the moving mechanism 52. [

2, a slit 54 extending in the moving direction of the cooling arm 51 is formed on the cooling arm 51 so as not to interfere with the lift pin 24 in a planar manner. A slit-shaped exhaust passage 18b extending in the Y direction is provided on the bottom surface of the cooling chamber 41. The exhaust passage 18b is connected to the exhaust mechanism 73 via a valve Vb via a pipe. An N ₂ gas supply port 18a is formed in the upper center of the cooling chamber 41 and formed in a slit structure having a length dimension extending in the Y direction and covering the diameter of the wafer W. The gas supply control And is connected to the N ₂ gas supply source 72 through the device group 75.

In this manner, it is possible to supply the process gas having the solvent concentration and the N ₂ concentration appropriately prepared to the entire process chamber 11 and to supply the N ₂ gas into the process chamber 11 and into the cooling chamber 41 .

As the solvent, a solvent having a property of dissolving a resist pattern is used. Examples of the solvent include acetone, propylene glycol monomethyl ether acetate (PGMEA), cyclohexanone, propylene glycol monomethyl ether (PGME), gamma -butyl lactone, pyridine N-methylpyrrolidinone (NMP), ethyl lactate, 2-heptanone, butyl acetate, methyl isobutyl ketone, diethyl ether, anisole, dimethyl sulfoxide (DMSO), m-cresol and the like are used.

The substrate processing apparatus described above is configured to be controlled by the control unit 100. [ The control unit 100 is composed of, for example, a computer, and includes a program, a memory, and a CPU. In the program, an instruction (each step) is embedded so that a control signal is sent from the control section 100 to each section of the substrate processing apparatus to perform a predetermined surface process by executing an operation to be described later. This program is stored in a storage unit such as a computer storage medium, for example, a flexible disk, a compact disk, a hard disk, and an M0 (magneto-optical disk), and is installed in the control unit 100. [

The program includes a heater 22, a lifting mechanism 23 of a lift pin, a temperature adjusting mechanism 26, a wafer transfer arm 31, a cooling arm moving mechanism 52, shutters 61 and 62, A program for controlling the supply source 71, the N ₂ gas supply source 72, the exhaust mechanism 73 and the gas supply control device group 75 is also included in the process recipe previously stored in the memory of the control unit 100 Accordingly, each of the above units is controlled.

Next, the surface (smoothing) processing method of the present invention will be described with reference to Figs. 1 and 3 to 7. Fig. The description of the solvent supply source 71, the N ₂ gas supply source 72, the exhaust mechanism 73, the gas supply control device group 75, the control unit 100, and the like may be omitted. Here, PGMEA is used as an example of the solvent, and the description proceeds.

First, the temperature in the processing chamber 11 including the heating plate 21 shown in Fig. 1 is measured by the heater 22 and the temperature adjusting mechanism 26 in the form of a resist pattern on the wafer W Is heated to a temperature higher by, for example, 1 占 폚 to 10 占 폚 than the temperature at which PGMEA is swollen. N ₂ gas is discharged from the N ₂ gas supply passages 14a and 15a on the side of the exit entrance 63 to form gas curtains and exhaust is started from the exhaust passages 14b and 15b on the side of the exit entrance 63 do.

An external wafer transfer arm 31 serving as a wafer transfer mechanism holding a wafer W at room temperature, for example, is carried into the processing chamber 11 from the transfer entrance 63. The lift pins 24 are raised and the wafers W are transferred from the wafer transfer arm 31 to the lift pins 24 by the cooperative operation of the lift pins 24 and the wafer transfer arm 31, After the transfer arm 31 is taken out from the transfer entrance 63, the transfer entrance 63 is sealed by the shutter 61.

Subsequently, the lift pin 24 is lowered, and the wafer W is loaded on the heating plate 21 heated as described above. After closing the shutter 63 by the shutter 61, the discharge from the symbols 14a and 15a of the N ₂ gas and the exhaust from the exhaust passages 14b and 15b are stopped.

Thereafter, as shown in Fig. 3, the process gas is supplied from the process gas supply port 13 into the process chamber 11. Then, In Fig. 3, the arrow indicates the flow of the gas. Here, the process gas is supplied at a temperature higher than the dew point of the PGMEA. If the temperature of the process gas is below the dew point of PGMEA, the resist pattern will be dissolved by condensation of PGMEA. The concentration of PGMEA in the process gas is set to a sufficient concentration such that PGMEA can swell the resist pattern surface on the wafer W at a temperature higher than the dew point of the process gas, for example, 10 DEG C or more higher than the dew point. do.

As the order of the process gas supply, first, the PGMEA is supplied from the solvent supply source 71 to the pipe in the vaporized state. And mixed with the N ₂ gas from the N ₂ gas source 72 and supplied into the process chamber 11 from the process gas supply port 13. This process gas is prepared so as to satisfy the above-described temperature condition and concentration condition by the gas supply control device group 75. The exhaust gas is exhausted from the exhaust passages 14b, 15b, 16b, and 17b at the same time as shown in Fig. 3 so that the process chamber is uniformly replaced with the process gas. The arrows are the flow of process gas and exhaust.

During the replacement of the process gas, the wafer W on the heating plate 21 is heated by the heater 22 to a temperature higher than the dew point temperature of the PGMEA and lower than the boiling point, for example, 50 占 폚. Further, the ceiling member 25 is heated to a temperature lower than that of the heating plate 21, for example, 40 占 폚 by the temperature adjusting mechanism 26. After the inside of the processing chamber 11 is uniformly replaced with the process gas, the supply and exhaust of the process gas are stopped. As shown by the broken line in Fig. 4, the lift pins 24 are raised to raise the wafer W from the heating plate 21 to a predetermined height position.

The temperature of the wafer W is lowered due to the separation from the heating plate 21 so that the PGMEA around the wafer W condenses and permeates the surface of the resist pattern of the wafer W, Becomes swollen by PGMEA. When the wafer W is cooled, the vapor atmosphere of the solvent is already formed in the treatment chamber 11. When the PGMEA is cooled to a temperature at which the surface of the resist pattern of the wafer W can be swollen, The swelling of the resist pattern occurs at about the same time. If the wafer W is cooled in this way, the PGMEA may penetrate into the inside of the resist pattern, causing the resist pattern to over swell and break or dissolve. Therefore, as shown by the solid line in FIG. 4, before the wafer swells, the wafer W is lowered by the heating plate 21 and heated. By heating the wafer W, the PGMEA on the surface of the resist pattern is volatilized to dry the resist pattern.

Thereafter, the wafer W is cooled again by lifting the wafer W by a lift pin, the surface of the resist pattern is swollen with PGMEA, and then the wafer W is heated again to heat the resist pattern, do. Fig. 4 shows this repeated process.

By repeating this cooling and heating, the unevenness of the surface of the resist pattern is improved. This action is shown in Fig. In Fig. 5, (a) shows the state before the resist pattern surface is processed, and the resist pattern surface 91 shows irregularities. The wafer W is heated and cooled, and the resist pattern surface 91 is swelled with PGMEA (b). In this state, the PGMEA is absorbed by the resist pattern surface 91, but does not penetrate into the resist pattern due to the heat of the wafer W. The wafer W is reheated and the solvent is volatilized before the resist pattern surface 91 is dissolved in the solvent. The state after reheating is (c). (a), the difference in unevenness is reduced.

The reason why the unevenness is improved is that the resist pattern surface 91 is swollen with the solvent once, the surface of the resist pattern is softened by the solvent at the area, and the viscosity of the resist pattern is reduced during reheating of the wafer W, The fluidity of the resist pattern surface 91 is temporarily improved. As a result, only fine irregularities on the surface of the resist pattern are flattened to improve the roughness of the surface of the pattern, and the deviation of the pattern line width is reduced.

This concave-convex improvement phenomenon exhibits the effect of a uniformity by repeating the cooling and heating of the wafer. 5 (c), after the wafer W is cooled again, the resist pattern surface 91 is swollen with the solvent (d), and the wafer W is heated again after (d) , And the solvent is volatilized (e). (c) and (e), the unevenness of the surface is further flattened.

In order to flatten the surface of the resist pattern in this way, for example, cooling and heating of the wafer W are repeated three times. Finally, the wafer W is sufficiently heated on the heating plate 21 to completely volatilize the PGMEA from the resist pattern.

Thereafter, the shutter 62 shown in Fig. 1 is opened and the wafer W is lifted by the lifting pin 24. At the same time as the wafer W rises, N ₂ gas is discharged from the N ₂ gas supply passages 16a and 17a at the upper process gas supply port 13 and the communication port 64 side. N ₂ N ₂ gas from the gas supply (16a, 17a) is to act as a gas curtain of the communication port 64 of the processing chamber 11, the degree that the extrusion rate does not flow into the cooling chamber (41) Respectively. At the same time, for example, exhaust is started from the exhaust passages 14b, 15b, 16b, and 17b.

The cooling arm moving mechanism 52 moves the cooling arm 51 along the guide rail 53 and brings it into the processing chamber 11 from the communication port 64. [ When the cooling arm 51 reaches the transfer position of the wafer W in the processing chamber 11, the lift pin 24 is lowered and the wafer W is transferred onto the cooling arm 51. Thereafter, the cooling arm 51 is stored in the cooling chamber 41 from the communication port 64 as shown in Fig. 6, and the communication port 64 is sealed by the shutter 62. Fig.

The reason why the N ₂ gas is discharged from the process gas supply port 13 in the process of storing the wafer W in the cooling chamber is that the wafer W is caught between the process chamber 11 and the cooling chamber 41 This is for the purpose of eliminating the possibility that the atmosphere in contact with the resist pattern is matched to cause nonuniformity of the surface treatment. Therefore, the N ₂ gas is discharged from the process gas supply port 13 and exhausted from the exhaust passages 14b and 15b on the side of the exit port 63 so that the N ₂ gas is uniformly applied to the surface of the wafer W , And the solvent is removed from the surface of the wafer W.

After the wafer W is stored in the cooling chamber, the atmosphere in the processing chamber 11 is replaced with N ₂ gas in the processing chamber 11, and the solvent vapor is discharged from the inside of the processing chamber 11. Process from the gas supply port 13 is at the same time for supplying the N ₂ gas, N ₂ gas supplied to the, evacuated from (14a, 15a, 16a, 17a ) supplied to Fig N ₂ gas (14b, 15b, 16b, 17b The exhaust gas is exhausted.

On the other hand, in the cooling chamber 41, the wafer W is cooled by the cooling arm 51, N ₂ gas is supplied from the N ₂ gas supply port 18a, and the exhaust gas is exhausted from the exhaust path 18b . By doing so, the atmosphere in the cooling chamber 41 is replaced with N ₂ gas, and the solvent is discharged from the inside of the cooling chamber 41.

The shutter 62 is opened and the wafer W is transferred to the processing chamber 11 by the cooling arm 51 through the communication port 64. Then, the processing chamber 11 and the cooling chamber 41 are replaced with N ₂ gas, . As shown in Fig. 7, the lifting pin 24 is lifted and the wafer W is transferred from the cooling arm 51 to the lifting pin 24. Thereafter, the cooling arm 51 is stored in the cooling chamber 41, and the communication hole 64 is closed by the shutter 62. [

Then, the shutter 61 is opened, the N ₂ gas is discharged from the N ₂ gas supply lines 14a and 15a on the side of the entrance / exit 63, and the exhaust is started from the exhaust passages 14b and 15b. The wafer transfer arm 31 is carried into the processing chamber 11 from the transfer entrance 63. At this time, the N ₂ gas N _2, which is discharged from a gas supply (14a, 15a) is, and is discharged to the wafer carrying arm 31, and acts as a gas curtain of the treatment chamber (11).

After the wafer transfer arm 31 is inserted to the predetermined transfer position, the lift pins 24 are lowered to transfer the wafer W to the wafer transfer arm 31. Subsequently, the wafer transfer arm 31 is transferred to the half Out from the entrance 63. Then, the shutter 61 closes the exit port 63 to stop the discharge from the symbols 14a and 15a of the N ₂ gas and the exhaust from the exhaust passages 14b and 15b.

The time chart is shown in Fig. 8 for the operation described above.

In the embodiment described above, the surface roughness of the resist pattern surface is gradually improved by repeating the swelling of the surface of the resist pattern by the solvent and the volatilization of the solvent, as shown in the description of Fig. As a result, the swelling proceeds excessively and the pattern shape is prevented from deteriorating. Then, the wafer W is cooled to swell the surface of the resist pattern in a state in which the vapor atmosphere of the solvent is formed in the treatment vessel. Subsequently, the swell is stopped by heating the wafer W. Therefore, the entire surface of the resist pattern swells substantially simultaneously, and the entire surface of the resist pattern is dried at substantially the same time, so that the surface treatment proceeds in a state where the in-plane uniformity is high. As a result, the surface roughness (LER: Line Edge Roughness) of the resist pattern can be improved with high in-plane uniformity, and as a result, a good resist pattern can be obtained. As a result, the etching process can be performed by using a highly precise pattern shape in subsequent steps. As a result, occurrence of line width roughness (LWR) is suppressed.

Further, there are many substances which are harmful to the environment, such as a solvent used in substrate processing. In addition, from the viewpoint of working efficiency, it is also necessary to control the concentration of the residual solvent. In the present embodiment, a gas curtain made of N ₂ gas is provided in each of the semi-entry / exit port 63 and the communication port 64 of the process chamber 11 during the smoothing process, and after the smoothing process, 41 are all purged with N ₂ gas. By these processes, it is possible to suppress the amount of solvent vapor that leaks to the external environment when the wafer is taken out of the apparatus.

Subsequently, a modified example in which the apparatus of the first embodiment is used and the smoothing process is performed by another procedure will be described with reference to Figs. 9 and 10. Fig.

Prior to the smoothing process, for example, the wafer W is heated by a module provided with a heating plate (not shown) before the wafer W is carried into the processing chamber 11. [ The heating temperature of the wafer W at this time is set so that the temperature of the wafer W in the course of the transportation is controlled so that the surface of the resist pattern is not swelled by the solvent when the carrier W is carried into the treatment chamber 11 by the carrier arm. Is set in anticipation of a fall. The temperature in the processing chamber 11 is set to be, for example, about 1 占 폚 to 10 占 폚 higher than the temperature at which the resist pattern on the wafer W is swelled by the solvent in the process gas atmosphere, Heat it to the temperature. The heated wafer W is carried into the processing chamber 11 by the wafer transfer arm 31 and transferred to the lift pins 24 as shown in Fig. At the time of loading the wafer W, temperature-controlled N ₂ gas is discharged from the N ₂ gas supply passages 14a and 15a on the side of the entrance / exit port 63 to suppress the temperature drop of the wafer W.

After the wafer transfer arm 31 is taken out, the shutter 61 is closed and the N ₂ gas supply is stopped. The wafer W is held at a position above the heating plate 21 by the lift pin 24 and the process gas is supplied from the process gas supply port 13 in this state as shown in Fig. . Exhaust from the exhaust passages 14b, 15b, 16b, and 17b is performed to replace the atmosphere in the process chamber 11 with the process gas. The gas supply and exhaust are stopped when the process gas concentration in the process chamber 11 is uniform and the concentration becomes a predetermined concentration. Subsequently, the wafer W is placed on the heating plate 21. In this case, since the temperature of the wafer W is higher than the temperature of the heating plate 21, the temperature of the wafer W is lowered due to the loading on the heating plate 21. [

The timing of replacement of N ₂ gas into the process gas may be a state in which the wafer W is mounted on the heating plate 21. Even in this case, gas supply and exhaust are stopped when the concentration of the process gas in the process chamber 11 becomes uniform and reaches a predetermined concentration.

4, the wafer W is moved up and down, and the surface of the resist pattern of the wafer W is swollen with the solvent by the temperature change and dried. Finally, the wafer W is sufficiently heated to vaporize the solvent to dry the wafer W. Thereafter, the cooling of the wafer W, the purging procedure by the N ₂ gas in the processing chamber 11 and the cooling chamber 41, and the carrying out of the wafer W to the outside of the apparatus are the same as those in the above example.

This modification is characterized in that the surface of the resist pattern is not swollen at first by bringing the wafer W into the treatment chamber 11 at a temperature higher than the smoothing treatment temperature. The effect obtained by the smoothing processing is the same as the above-described example.

[Second Embodiment]

Next, an apparatus according to the second embodiment will be described with reference to Figs. 11 to 14. Fig. In Figs. 11 to 14, parts corresponding to those of the first embodiment are denoted by the same reference numerals, and description thereof is omitted. 12 to 14, description will be given of the elevation mechanism 23, the wafer transfer arm 31, the shutter 61, the solvent supply source 71, the exhaust mechanism 73, the control unit 100, Are omitted.

In Fig. 11, the process chamber 12 corresponds to the process chamber 11 in the first embodiment, and a cooling chamber is not provided. An N ₂ gas supply port 13a is formed in the bottom surface of the process chamber 12 and N ₂ gas supply passages 14a and 15a are formed in the exit port 63.

First, as in the first embodiment, the interior of the processing chamber 12 is heated to a temperature higher than the temperature during the smoothing process. It discloses an exhaust gas from a N ₂ gas supplied from (14a, 15a) to exhaust when discharging the N ₂ gas (14b, 15b) which faces the exit half 63. The

The wafer W at room temperature is carried into the processing chamber 12 by the external wafer transfer arm 31 through the entrance / exit port 63 and the wafer W is transferred to the processing chamber 12 by the cooperative operation of the lift pins 24 and the wafer transfer arm 31 , The wafer W is loaded on the heating plate 21. After the wafer transfer arm 31 is taken out, the shutter 61 is closed and the exit port 63 is closed and the gas discharge from the N ₂ gas supply passages 14a and 15a and the gas discharge from the exhaust passages 14b , 15b are also stopped.

Subsequently, as shown in Fig. 12, the process gas is supplied from the process gas supply port 13. Fig. The conditions of the temperature and the concentration of the process gas are the same as those of the first example of the first embodiment. On the other hand, after the exhaust gas is exhausted from the exhaust passages 14b, 15b, 16b, and 17b to uniformly replace the atmosphere in the process chamber 12 with the process gas, the heated wafer W And the surface of the resist pattern of the wafer W is cooled to be swelled by the solvent. Subsequently, the wafer W is lowered and placed on the heating plate 21, heated and dried. After repeating these two states, for example, three times, the wafer W is heated sufficiently on the heating plate 21 to vaporize the solvent and dry the wafer W. The action in the resist pattern surface treatment is the same as that in the first embodiment shown in Fig.

After the above surface treatment, as shown in Fig. 14, the wafer W is held by the lifting pin 24 at a position above the heating plate 21. As shown in Fig. And a process gas supply port 13 and the N ₂ gas supply port (13a), ie the treatment chamber and from above and below the 12 supplies a N ₂ gas of the temperature-controlled state, the exhaust (14b, 15b, 16b, 17b ) So that the inside of the processing chamber 12 is purged with N ₂ gas.

The reason why the N ₂ gas is controlled in temperature is to prevent dropletization of the solvent gas in the processing chamber 12. Further, the reason for supplying the N ₂ gas from the top and bottom surfaces, if only N ₂ gas supplied from the one surface in the center, the volatilization rate of the solvent varies depending on the area on the wafer (W), that is because the first solvent is volatilized from the central portion to be. As a result, the improvement efficiency of the unevenness of the surface of the resist pattern is high at the center, but becomes lower at the outer peripheral portion. Therefore, by supplying N ₂ gas from the back surface, the volatilization of the solvent in the peripheral portion is promoted, and the volatilization amount of the solvent is averaged over the entire wafer W.

Finally, the wafer W is carried out from the inside of the processing chamber 12 by the cooperative operation of the lift pins 24 and the wafer transfer arm 31, similarly to the procedure described in the first embodiment.

The above-described modification example shown in the first embodiment can also be applied to this second embodiment.

[Third embodiment]

Next, an apparatus according to the third embodiment will be described with reference to Fig. 15, the same reference numerals are assigned to the components having the same configurations as those of the first and second embodiments, and a description thereof will be omitted. The description of the solvent supply source 71, the N ₂ gas supply source 72, the control unit 100, and the like is omitted.

15, the processing chamber 12 transfers the wafer W to and from an external mechanism (not shown) by the same lift pin 24 as in Fig. An exhaust passage 16b and an exhaust passage 15b are formed in the upper portion and the lower portion in the wall surface of the processing chamber 12 and an exhaust passage 16b and an exhaust passage 16b are formed in the upper portion and the lower portion, respectively, And a process gas supply port 13 is formed at the center of the upper surface of the lid. Each exhaust path and the process gas supply port 13 are in a slit shape extending in the Y direction.

An LED (Light Emitting Diode) module 81 is mounted on the bottom surface of the processing chamber 12. The LED module 81 emits infrared rays by a combination of a plurality of LED lamps. The process gas is prepared in the gas supply control device group 75 and supplied from the process gas supply port 13, similarly to the above-described embodiment.

The processing method in this apparatus is as follows. First, the wafer W is held by the lift pin 24 above the LED module 81 after the wafer W is transferred from the external transport mechanism (not shown) to the lift pins 24. As a substitute for the lift pin 24, a base of quartz that covers the LED module 81 may be provided in the processing chamber 12, and the wafer W may be mounted thereon.

Then, the LED module 81 is turned on to heat the wafer W. The process gas is supplied from the process gas supply port 13 at the time when the wafer W is heated to a temperature at which the wafer W is not swelled by the solvent and simultaneously the exhaust gas is exhausted from the exhaust passages 14b, 15b, 16b, Thereby forming the same process gas atmosphere as in one embodiment. When the process gas condition is satisfied, the gas supply and exhaust are stopped.

Thereafter, the LED module 81 is turned off, and the wafer W is cooled. When the temperature of the wafer W is lowered to a certain temperature or lower that allows the surface of the resist pattern of the wafer W to swell with the solvent, the state of FIG. 5 (b) Is swollen by the solvent. When the LED module 81 is again turned on at this point, the infrared rays are supplied again to the wafer W, so that the temperature of the wafer is raised. Then, the solvent in the surface of the resist pattern is volatilized, and the surface of the resist pattern in Fig. 5C is in a dry state.

Thereafter, the LED module 81 is turned off and turned on a plurality of times to repeat the swelling and drying of the surface of the resist pattern by the solvent as in the above-described embodiment. The action in the resist pattern surface treatment is the same as that in the first embodiment shown in Fig. Finally, the LED module 81 is turned on, and the surface of the resist pattern of the wafer W is dried. N ₂ gas is supplied from the process gas supply port 13 and exhausted from the exhaust passages 14b, 15b, 16b and 17b to purge the atmosphere in the process chamber 12 with N ₂ gas, 12 from the wafer W.

In the above embodiments and examples, the processing of the wafer W is carried out by first bringing the wafer W into the processing chamber at room temperature, supplying the process gas in this state to swell the resist pattern on the wafer W, As described in the first to third embodiments, the heating and cooling of the wafer W may be repeated, for example, after the wafer W is heated at the end, the wafer W may be taken out from the processing chamber.

In the case where the wafer W is cooled in the cooling chamber as in the first embodiment, the wafer W may be cooled and then directly taken out from the cooling chamber.

In each embodiment, when the wafer is continuously processed, a process of purging the inside of the processing container is performed for each wafer, from the viewpoint of reducing the leakage amount of the solvent when the wafer is taken out of the apparatus . That is, it is carried out each time to process the N ₂ gas spreads, one piece of wafer in the process chamber 11 and the cooling chamber, and N ₂ gas purge chamber 12 of 41 is desired.

In each of the embodiments, after the wafer is loaded into the processing container and before the process gas is supplied into the apparatus, the vacuum evacuation may be performed once. By performing the vacuum evacuation in advance, the time for replacing the atmosphere of the processing chamber by the process gas can be shortened, and the concentration of the process gas in the processing chamber is also easily stabilized.

W: Wafer
11: Treatment room
12: Treatment room
13: Process gas supply port
21: Heating plate
22: heater
24: Lift pin
31: Wafer carrying plate
41: cooling chamber
51: cooling arm
71: solvent supply source
72: N ₂ gas source
73: Exhaust mechanism
81: LED module
91: resist pattern surface
100:

Claims (10)

A substrate processing method for performing a process on a substrate on which a resist pattern is formed by using a solvent to improve the roughness of the surface of the resist pattern,
(a) bringing a substrate into a processing container,
(b) swelling the surface of the resist pattern with the solvent by bringing the substrate to a first temperature state in a state in which the vapor atmosphere of the solvent is formed in the processing container; and A step of repeating the step of heating to a second temperature higher than the first temperature,
(c) a movable cooling holding member provided in a cooling chamber connected to the processing vessel through a partition member is carried into the processing vessel to move the substrate to the holding member, and thereafter, To a cooling chamber to cool the substrate,
(d) carrying out the substrate out of the processing vessel. The method according to claim 1,
There is a state in which the substrate is heated to a temperature at which the solvent does not swell on the surface of the resist pattern between the step of (a) and the step of (b). 3. The method of claim 2,
Wherein the step of swelling the surface of the resist pattern comprises a step of swelling the surface of the resist pattern to a temperature at which the solvent does not swell on the surface of the resist pattern, Wherein the cooling step is a cooling step. 4. The method according to any one of claims 1 to 3,
Wherein the step of heating the substrate is a step of heating the substrate to the second temperature while maintaining a state in which a vapor atmosphere of the solvent is formed. 4. The method according to any one of claims 1 to 3,
In the processing container, there is provided a lifting and lowering member relatively lifting and lowering relative to the heating plate and the heating plate,
Wherein the heating of the substrate is performed by loading the substrate on the heating plate and the cooling of the substrate is carried out by holding the substrate above the heating plate by the elevating member. 1. A substrate processing apparatus for performing a process for improving a surface roughness of a resist pattern on a substrate on which a resist pattern is formed by using a solvent,
A processing vessel for forming a vapor atmosphere of the solvent,
A loading section provided in the processing container for loading the substrate,
A heating unit for heating the substrate placed on the loading unit,
A solvent supply unit for supplying a gas containing the vapor of the solvent into the processing vessel;
An exhaust part for exhausting the solvent vapor in the processing vessel,
A cooling chamber which is connected to the processing vessel through an atmospheric partitioning member and provided with a movable holding member for cooling,
A step of swelling the surface of the resist pattern with a solvent by bringing the substrate into a state of a first temperature in a state in which the vapor atmosphere of the solvent is formed in the processing container; And the step of heating to a second high temperature is repeated. Next, the holding member for cooling is carried into the processing container to move the substrate to the holding member, and then the holding member is moved to the cooling chamber And a control unit for outputting a control signal to cool the substrate. The method according to claim 6,
Further comprising: a lift portion that is relatively moved up and down relative to the heating portion in the processing container. There is provided a computer program for use in processing a substrate on which a resist pattern is formed to carry out a process for improving the roughness of the surface of the resist pattern,
Wherein the computer program is for carrying out the substrate processing method according to any one of claims 1 to 3. delete delete

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