KR101704059B1 - Developing apparatus, developing method and storage medium - Google Patents

Abstract

And to provide a developing apparatus capable of forming a pattern with high uniformity in the plane of the substrate. A substrate holding portion for holding the substrate after the exposure, the substrate being held on the surface of the substrate after the exposure; a developer supply portion for supplying a developer to the surface of the substrate and developing the resist; A radiation light irradiating part for irradiating a radiation light including a wavelength absorbing area of the substrate material in order to increase the degree of reaction between the developer and the resist by heating the developing liquid; And a cleaning liquid supply unit.

Description

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

The present invention relates to a developing apparatus, a developing method, and a storage medium for developing a substrate on which a resist is coated and exposed.

In a photoresist process, which is one of the semiconductor manufacturing processes, a resist is applied to the surface of a semiconductor wafer (hereinafter referred to as a wafer), the developed resist film is exposed in a predetermined pattern, . As the developing apparatus, there is a process (rotation phenomenon) in which the wafer is rotated around the vertical axis with the center of the wafer as the rotation center, a developer is supplied from the nozzle to the rotation center, and the developer is diffused to the periphery of the wafer using centrifugal force. Is known. In addition, there is known a device for moving a nozzle from one end of a stationary wafer to the other end to perform a process (stationary phenomenon) of concentrating the developer on the entire wafer.

However, it is known that the reaction between the developer and the resist is promoted in a heated atmosphere, and the resolution of the resist pattern progresses quickly. Therefore, in each of the above-described developing apparatuses, the heated developing liquid may be supplied to the wafer. However, when such a method is applied to the apparatus for performing the above-described rotation, the developer is cooled by the atmosphere around the wafer until the developer is diffused from the central portion of the wafer to the peripheral portion, The temperature of the developer is lowered. As a result, the resolution is fluctuated in the plane of the wafer, so that the dimension of the resist pattern may be changed.

In order to reduce the temperature distribution of the developer in the surface of the wafer, it is conceivable to repeatedly move the supply position of the developer between the central portion and the peripheral portion of the wafer by moving the nozzle during the developer discharge. However, The load on the mechanism is increased, and the time required for the development processing becomes longer, and at the same time, the consumption of the developer is also increased. In addition, it is difficult to control the temperature in the surface of the wafer even if the supplying position of the developing solution is changed as described above, so that the in-plane uniformity of the resist pattern may not be sufficiently improved.

Further, in the apparatus for performing the above-described stop phenomenon, since the timings at which the developer is supplied at the one end side and the other end side of the wafer are different, the time for which the resist contacts the developer until the developer is removed from the resist, End side. Due to this time difference, the reaction between the resist and the developing solution proceeds significantly at one end side of the wafer than at the other end side of the wafer, and as a result, the dimension of the resist pattern in the plane of the wafer may fluctuate.

In this way, there is a possibility that the dimension of the pattern may be changed depending on the temperature difference or development time of the developer in the plane of the wafer. Further, the recipes such as the supply time of the material constituting the resist and the developer, the supply flow rate of the developer, and the like are different, and therefore the dimensions may vary within the plane of the wafer. From such circumstances, there has been a demand for a developing apparatus capable of uniformly forming a pattern in a plane of a wafer. Patent Document 1 discloses a developing device capable of controlling the temperature of a developing solution, but the above problem is not described, and the problem can not be solved.

Japanese Patent Application Laid-Open No. 2005-197321 (paragraph 0023, Fig. 4, etc.)

SUMMARY OF THE INVENTION The present invention has been made under such circumstances, and an object of the present invention is to provide a technique capable of forming a pattern with high uniformity in a plane of a substrate in a developing apparatus.

A developing apparatus of the present invention comprises a substrate holding portion for holding a substrate horizontally after a resist is coated on a surface thereof and exposed,

A developer supply part for supplying a developer to the surface of the substrate and developing the resist,

A radiation light irradiating unit for irradiating a predetermined region of the substrate with radiation light including a wavelength absorbing region of the substrate material in order to increase the degree of reaction between the developer and the resist by heating the developing liquid;

A cleaning liquid supply unit for supplying a cleaning liquid to the surface of the substrate and removing the developer,

And a control unit.

The following is a specific example of the developing apparatus of the present invention.

(a) The developer supply portion includes a nozzle for supplying a developer to a central portion of the substrate, and a heating portion for heating the developer supplied to the substrate from the nozzle to a temperature higher than the atmosphere around the substrate,

And a rotation drive mechanism for rotating the substrate held by the substrate holding portion about a vertical axis,

The specific region is the periphery of the substrate.

(b) a nozzle moving mechanism for moving the nozzle so that the supply position of the developer to the substrate moves between the periphery and the center of the substrate,

A developer supply mechanism for controlling the supply of the developer to the nozzle,

A first supplying step of supplying a developing solution to a central portion of the substrate while rotating the substrate; a step of moving the supplying position of the developing solution to the periphery of the substrate; 2 supply step, and outputs a control signal to irradiate the substrate with the radiation light from the radiation light irradiation unit when performing the first supply step.

(c) a nozzle moving mechanism for moving the nozzle so as to move the supply position of the substrate of the developer to between the periphery and the center of the substrate,

A developer supply mechanism for controlling the supply of the developer to the nozzle,

A first supplying step of supplying a developing solution to a central portion of the substrate while rotating the substrate; a step of moving the supplying position of the developing solution to the periphery of the substrate; 2 supply step, and outputs a control signal to irradiate the substrate with the radiation light from the radiation light irradiation unit when performing the second supply step.

(d) The developer supply portion includes a nozzle having a discharge port formed to have a length covering the width of the substrate,

And a nozzle moving mechanism for moving the nozzle from one end of the substrate to the other end when the developer is ejected from the nozzle to supply the developer to the surface of the substrate,

The specific region is the other end side of the substrate.

(e) The radiation light irradiating portion is provided on the back side of the substrate.

(f) The radiation light irradiating unit is constituted by a light emitting diode.

(g) a temperature adjusting unit for adjusting the temperature of the radiation light irradiating unit.

The developing method of the present invention includes the steps of holding a substrate after a resist is coated on the surface and exposed to the substrate holding portion horizontally,

Supplying a developer to a surface of the substrate by a developer supply unit and developing the resist;

A step of radiating radiant light including a wavelength absorbing region of a substrate material to a specific region predetermined on the substrate by the radiation irradiating portion to increase the degree of reaction between the developing liquid and the resist by heating the developing liquid;

A step of supplying the cleaning liquid to the surface of the substrate by the cleaning liquid supply unit to remove the developer

And a control unit.

A specific form of the developing method of the present invention is as follows, for example.

(h) developing the resist,

Heating the developer to a temperature higher than the atmosphere around the substrate by the heating unit,

Supplying the heated developing solution from the nozzle to a central portion of the substrate,

And rotating the substrate held by the substrate holding portion by a rotation driving mechanism around a vertical axis and diffusing the developer to the periphery of the substrate by centrifugal force,

The specific region is the periphery of the substrate.

(i) a first developer supplying step of supplying developer to a central portion of the substrate while rotating the substrate,

Subsequently, a step of moving the supply position of the developer to the periphery of the substrate,

Next, a second developer supply step of supplying the developer to the central portion of the substrate

And the step of irradiating the radiation light when performing the first developer supply step is performed.

(j) a first developer supplying step of supplying a developing solution to a central portion of the substrate while rotating the substrate,

Subsequently, a step of moving the supply position of the developer to the periphery of the substrate,

Next, a second developer supply step of supplying the developer to the central portion of the substrate

And the step of irradiating the radiation light when the second developer supply step is performed is performed.

(k) developing the resist,

Supplying a developer to a substrate from a nozzle having a discharge port formed to have a length covering a width of the substrate;

A step of moving the nozzle from one end side of the substrate to the other end side by a nozzle moving mechanism while supplying developer from the nozzle to the substrate

/ RTI >

The specific region is the other end side of the substrate.

A storage medium of the present invention is a storage medium storing a computer program used in a developing apparatus for performing development processing on a substrate,

The computer program is characterized by carrying out the above-described developing method.

The storage medium of the present invention is a storage medium storing a computer program used in a developing apparatus for performing development processing on a substrate,

The computer program is characterized in that it is for carrying out the above-described developing method.

The developing apparatus of the present invention irradiates a predetermined area on a substrate with radiation light including a wavelength absorbing region of the substrate material and heats the developer supplied to the surface of the substrate. As a result, the degree of reaction between the developer and the resist increases in a specific region, so that the uniformity of the resist pattern in the plane of the substrate can be increased.

1 is a longitudinal side view of a developing apparatus according to an embodiment of the present invention.
2 is a plan view of the developing apparatus.
3 is a plan view of a radiation light irradiation group provided in the developing apparatus.
4 is a longitudinal side view of a light irradiation part constituting the radiation light irradiation group.
5 is a perspective view of a developer supply nozzle provided in the developing apparatus.
6 is an operational view showing a developing process by the developing apparatus.
7 is an operational view showing a developing step by the developing apparatus.
8 is an operational view showing another developing process of the developing apparatus.
Fig. 9 is an operational view showing a developing process by the developing apparatus. Fig.
10 is an operational view showing a developing process by the developing apparatus.
11 is an operation diagram showing a developing process by the developing apparatus.
12 is an operation diagram showing a developing process by the developing apparatus.
13 is an operation diagram showing a developing process by the developing apparatus.
14 is an operation diagram showing a developing process by the developing apparatus.
15 is a longitudinal side view of a developing apparatus according to another embodiment;
16 is a plan view of the developing apparatus.
17 is a plan view of a radiation light irradiation group provided in the developing apparatus.
18 is an operation view showing a developing process by the developing apparatus.
19 is an operation view showing a developing step by the developing apparatus.
20 is an operational view showing a developing process by the developing apparatus.
21 is a configuration diagram of a control section according to still another embodiment;
22 is an explanatory view showing another example of a group of radiation light irradiation;
23 is an explanatory view showing another example of a group of radiation light irradiation;

(First Embodiment)

A description will be given of a developing apparatus 1 according to an embodiment of the present invention. The developing apparatus 1 is provided in a clean room controlled at a temperature of 23 占 폚, for example. 1 is a longitudinal side view of the developing apparatus 1, and Fig. 2 is a plan view thereof. Referring to these drawings, the developing apparatus 1 is provided with a spin chuck 11 serving as a substrate holding portion. The spin chuck 11 vacuum-adsorbs the central portion on the back side of the wafer W as a substrate , And holds the wafer W horizontally. The spin chuck 11 is connected to the rotary drive unit 13 via a rotary shaft 12 extending downward from the center thereof. The rotation driving unit 13 rotates the wafer W held by the spin chuck 11 around a vertical axis based on a control signal output from the control unit 10 to be described later.

A cup body 21 surrounding the side of the wafer W held by the spin chuck 11 is provided on the side of the spin chuck 11. The cup body 21 is composed of an upper cup 22 and a lower cup 23 fixed to a base 14 for fixing the developing apparatus 1. Further, a fan unit 15 for supplying a downward flow to the cup body 21 is provided on the ceiling of the developing apparatus 1.

The upper cup 22 includes a cylindrical portion 24 and an inclined portion 25 extending in an inclined manner from the upper edge of the cylindrical portion 24 toward the upper side in the entire circumference, And a bent portion 26 which is bent upward. In FIG. 1, reference numeral 16 denotes an elevating unit for elevating and lowering the upper cup 22. The upper cup 22 is located at an elevated position shown by the solid line in FIG. 1 when the developer is removed while supplying the cleaning liquid to the wafer W. The upper cup 22 is disposed on the inner circumferential surface of the wafer W so as not to scatter the developer or cleaning liquid, . The upper cup 22 is located at the lowered position shown by the chain line in Fig. 1 so as not to disturb the movement of each nozzle, except when this removal is performed.

The lower cup 23 includes an outer wall 27 extending in the vertical direction, a bottom 28 extending from the entire periphery of the lower end of the outer wall 27 toward the inner center, And has bent portions 29 protruding inward from the entire circumference and bent downward. The bent portion 29 is fitted with the bent portion 26 of the upper cup 22 to prevent the developer or the mist of the cleaning liquid from leaking to the outside of the cup body 21. Further, an opening portion and an upright cylindrical portion are provided in the bottom portion 28 of the lower cup 23. [ The opening portion is constituted by a drain port 2A for discharging a waste liquid in the cup body 21 and the inside of the tubular portion is constituted by an exhaust port 2B for exhausting the inside of the cup body 21.

An inner cup 31 is provided on the inner side of the cup body 21. The inner cup 31 has a function of guiding the waste liquid to the lower cup 23 and includes a cylindrical portion 32 rising from the inner peripheral end of the bottom 28 of the lower cup 23, And a vertical guide portion 34 extending in the downward direction from the end of the mountain-shaped portion 33. The vertical guide portion 34 extends in a downward direction from the end of the mountain-like portion 33. The mountain-

A temperature regulating section 41 is provided in the inner cup 31. The temperature regulating section 41 includes a first supporting section 42, a second supporting section 43, a temperature regulating plate 44, And a forming member 45. The first support portion 42 is formed to extend upward from the bottom portion 28 of the lower cup 23 and the second support portion 43 formed in a cup shape whose upper side is opened on the first support portion 42 ). The second support portion 43 is provided on the rotation drive portion 13 and the rotation shaft 12 is connected to the rotation drive portion 13 through the bottom portion of the second support portion 43. [ A circular ring-shaped temperature regulating plate 44 is provided so as to horizontally diffuse outwardly from the entire upper end of the second support portion 43. Further, the flow path forming member 45 is formed so as to face downward from the periphery of the temperature regulating plate 44.

In the temperature regulating plate 44, for example, a supply path 46 for regulating the temperature of water is formed in a spiral shape diffusing on a horizontal plane. A temperature control water supply path 47 connected to the upstream end of the supply path 46 is formed in the first support part 42 and the second support part 43, And a drain passage 48 connected to the other end of the passage 46 is formed. On the upstream side of the temperature control water supply path 47, a temperature control water supply unit 49 is provided. The temperature regulating water supply unit 49 includes a temperature regulating mechanism (not shown) for regulating the water to a predetermined temperature, a temperature regulating water supply path 47 and a supply path 46 in sequence And a pump (not shown) for discharging the liquid from the drain path 48 by press feeding. The temperature regulating plate 44 is adjusted to a predetermined temperature by the temperature regulating water supplied to the supply path 46, whereby the temperature of the radiation irradiating group 5 described later is adjusted. Also, the temperature of the second support portion 43 is controlled by the temperature control water, and the heating of the motor constituting the rotation driving portion 13 is also suppressed.

A radiation light irradiation group 5 is formed on the temperature control plate 44. The radiation light irradiation group 5 is composed of a plurality of light irradiation portions 51. [ As shown in Fig. 3, the light irradiation portions 51 are arranged in five concentric circles so as to surround the spin chuck 11, and are arranged so as to radially diffuse from the inside to the outside of the temperature control plate 44 as a whole have. 52a, 52b, 52c, 52d, and 52e in this order from the inner side toward the outer side with respect to the concentric arrangement. These irradiation columns 52a to 52e are provided below the wafer W placed on the spin chuck 11 from the vicinity of the outer side of the spin chuck 11 to the periphery of the wafer W. [

4, the light irradiating unit 51 includes a tubular body 53, a light emitting diode (hereinafter, referred to as an LED) 54, And a transmitting portion 55, as shown in Fig. The upper side of the tubular body 53 is opened, and an LED 54 is provided therein. The LED 54 radiates infrared rays, and this infrared ray is an absorption wavelength band of silicon which is a material (substrate material) of the wafer W. The transmissive portion 55 is provided so as to cover the upper side of the cylindrical body 53. The tubular body 53 does not transmit the infrared ray, and the transmitting portion 55 is configured to transmit infrared rays. The infrared ray emitted from the LED 54 of the light irradiation unit 51 is irradiated to the position directly above the light irradiation unit 51 on the back surface of the wafer W and is absorbed. Thereby, the vibration of the molecules of silicon constituting the wafer W is amplified at the immediately above position, and the wafer W is locally heated.

Each LED 54 is connected to a lighting controller 56. 3, only one light irradiation part 51 of each irradiation column 52a to 52e is shown connected to the lighting controller 56. Actually, the LED 54 of each light emission part is connected to the lighting controller 56. However, (Not shown). The lighting controller 56 includes a not-shown setting section and a power source section, and the user of the developing apparatus 1 can control the current value supplied from the power source section to the LED 54 by the setting section.

In the first embodiment, the current values can be set for each irradiation column 52a to 52e. As the current value is set larger, the intensity of infrared rays radiated from the LED 54 increases, and the position of the wafer W corresponding to each of the irradiation rows 52a to 52e can be heated to a high temperature. In the first embodiment, when the infrared light is not irradiated from the LED 54, the developer supplied to the wafer W is cooled down toward the periphery of the wafer W, The wafer W is heated to a higher temperature from the central portion of the wafer W to the peripheral portion because the reaction between the developer and the resist on the peripheral portion side is slower. That is, the current value is set to be larger in the order of irradiation rows (52e > 52d > 52c > 52b > The on-off signal is transmitted to the on-off controller 56 by the control section 10 to be described later and based on the on-off signal, the turn-on controller 56 sets the turn-on signal to the irradiation column 52a to 52e The current is supplied.

1, for example, three lift pins 35 (only two are shown in FIG. 1) are provided so as to be surrounded by the second support portions 43, (Not shown). The transfer of the wafer W is performed between the spin chuck 11 and the transfer mechanism of the wafer W via the lifting pin 35. [

The developing apparatus 1 is provided with a developer supply nozzle 61. As shown in Fig. 5, a slit-shaped discharge port 62 having a length L1 of 8 to 15 mm and a width L2 of 0.1 to 1 mm, for example, is provided at the lower end thereof. 2, the developer supply nozzle 61 is held at one end of the nozzle arm 63 extending in the horizontal direction, and the other end of the nozzle arm 63 is held at the outer side of the cup body 21 And is connected to the installed nozzle moving mechanism 64. The nozzle moving mechanism 64 is guided by the guide member 65 and is movable in the horizontal direction, and the nozzle arm 63 can be moved up and down. The developer supply nozzle 61 can move along the longitudinal direction of the discharge port 62 between the standby position 66 provided on the outer side of the cup body 21 and the cup body 21, The developer can be supplied to each position along the radial direction of the wafer W between the peripheral portion and the central portion of the wafer W.

1, one end of the developer supply pipe 67 is connected to the developer supply nozzle 61, and the other end of the developer supply pipe 67 is connected to the developer supply source 68. As shown in Fig. The developer supply pipe 67 is provided with a heating portion 69, which is formed by, for example, a heat exchanger. The developer supply source 68 controls the supply of the developer to the developer supply nozzle 61 based on the control signal output from the control unit 10. [ The heating unit 69 heats the developer supplied to the developer supply nozzle 61 to a desired temperature higher than the temperature in the clean room. As a result, a developing solution heated to a preset temperature can be supplied to the wafer W from the developing solution supply nozzle 61. [

Further, the developing apparatus 1 has a cleaning liquid supply nozzle 71 constituting a cleaning liquid supply portion, and the cleaning liquid supply nozzle 71 discharges pure water as a cleaning liquid from a discharge opening opened vertically downward. In FIG. 1, reference numeral 72 denotes a pure water supply source, which supplies pure water to the cleaning liquid supply nozzle 71. 2, the cleaning liquid supply nozzle 71 is held at one end of a nozzle arm 73 extending in the horizontal direction, and the other end of the nozzle arm 73 is supported by a nozzle moving mechanism 64 And is connected to a similarly configured nozzle moving mechanism 74. The guide member 75 in FIG. 2 guides the nozzle moving mechanism 74 like the guide member 65. The cleaning liquid supply nozzle 71 moves between the standby position 76 provided on the outside of the cup body 21 and the central portion of the wafer W by the nozzle moving mechanism 74.

In this developing apparatus 1, for example, a control section 10 composed of a computer is provided. The control unit 10 sends control signals to the respective units of the developing apparatus 1 from the control unit 10 and supplies the control signals to the respective units of the developing apparatus 1 to supply the developing liquid and the wafers W of pure water, The irradiation of light from the radiant irradiation group 5, the movement of each nozzle, and the lifting and lowering of the upper cup 22 to control the processing of the wafers W (Each step). This program (including a program for inputting and displaying processing parameters) is stored in a storage medium such as a computer storage medium, such as a flexible disk, a compact disk, a hard disk, an MO (magneto-optical disk) memory card, (10).

Next, the operation of the developing apparatus 1 will be described. The wafer W is conveyed from the outside of the developing apparatus 1 by the conveying mechanism 79 as shown in Fig. 6 in the state where the temperature regulating plate 44 is supplied with the temperature control water and the temperature of the light irradiating unit 51 is adjusted, And transferred onto the spin chuck 11. A resist film exposed in accordance with a predetermined pattern is formed on the surface of the wafer W. However, the illustration of the resist film is omitted for convenience. The spin chuck 11 adsorbs the central portion of the back surface of the wafer W by the cooperative operation of the lift pins 35 and the transport mechanism 79. When the wafer W is held by the spin chuck 11, And moves from the standby position 76 onto the central portion of the wafer W. [ The pure water is supplied to the central portion of the wafer W from the cleaning liquid supply nozzle 71 and the wafer W is rotated around the vertical axis so that the pure water 70 is supplied to the wafer W by centrifugal force, . Thereby, a so-called prewetting process is carried out in which the wettability of the developer on the surface of the wafer W can be enhanced (step S1).

The supply of pure water from the cleaning liquid supply nozzle 71 is stopped and the cleaning liquid supply nozzle 71 is returned to the standby position 76. [ Subsequently, the developer supply nozzle 61 is moved from the standby position 66 onto the central portion of the wafer W, and at the same time, as shown by the dotted arrow in Fig. 8, W irradiate the back surface of the wafer W so that the irradiation intensity of the irradiation portion 51 of the irradiation column 52 located on the peripheral side of the wafer W becomes higher. Thereby, the wafer W is heated so that the temperature is increased from the region on the irradiation column 52a toward the region on the irradiation column 52e. That is, as the temperature of the wafer W gradually increases from the central portion of the spin chuck 11 toward the peripheral portion of the wafer W, the wafer W is heated.

A developing solution 60 heated to, for example, 35 占 폚 is supplied from the developer supply nozzle 61 to the center of the wafer W and diffused toward the periphery of the wafer W by centrifugal force (step S2). The cooling action of the atmosphere in the clean room with respect to the developer 60 is canceled by the heat supplied from the wafer W and the developer 60 is supplied with pure water 70 in a state where the temperature is maintained at, The surface of the wet wafer W that has been wetted by the pure water 70 flows and spreads to the periphery of the wafer W (FIG. 9). Thereby, the thin film of the developing solution is formed on the wafer surface, and the wafer W is pre-wetted by the developer so that the wettability of the developer is further increased when the developer is supplied in the following step S3. Thereafter, the supply of the developer 60 from the developer supply nozzle 61 is temporarily stopped, and at the same time, the irradiation of the infrared rays from each light irradiation section 51 is temporarily stopped (Fig. 10).

When the developer supply nozzle 61 moves onto the periphery of the wafer W and a developer is supplied to the periphery of the wafer W (Fig. 11), the developer supply nozzle 61 is moved toward the central portion of the wafer W Whereby the supply position of the developer is moved toward the central portion of the wafer W as shown in Fig. 12 (step S3). The developer supplied to the wafer W is quickly diffused to the periphery of the wafer due to the centrifugal force by the surface of the wafer W having increased wettability due to the supply of the developer. When the developer supply nozzle 61 is positioned on the central portion of the wafer W, the movement of the wafer W is stopped and the back side of the wafer W is irradiated with infrared rays from the irradiation portion 51 of each irradiation column 52. As in the case of step S2, as the irradiation part 51 of the irradiation column 52 located on the outer side of the wafer W irradiates the infrared ray so that the irradiation intensity becomes stronger, as the wafer W moves from its central part toward its peripheral part , And is heated so that the temperature is raised (FIG. 13). Thereby, the developing solution is uniformly distributed from the central portion of the wafer W to the peripheral portion, for example, at a temperature of 35 DEG C, and the reaction between the developing solution and the resist proceeds (Step S4).

Thereafter, the supply of the developer from the developer supply nozzle 61 is stopped, and the irradiation of the infrared ray, which is the radiation light, is stopped from the rows of the irradiation 52. The developer supply nozzle 61 returns to the standby position 66 and the cleaning liquid supply nozzle 71 moves from the standby position 76 onto the central portion of the wafer W to supply pure water to the center portion of the wafer W (Fig. 14). The supplied pure water flows to the outer periphery of the wafer W to be removed, the reaction of the resist to the developing solution is stopped, and the resist dissolved in the developing solution is removed from the surface of the wafer W to resolve the resist pattern S5). Thereafter, the supply of pure water is stopped, the cleaning liquid supply nozzle 71 returns to the standby portion 76, the pure water is removed by the rotation of the wafer W, and the wafer W is dried. Thereafter, the rotation of the wafer W is stopped, and the wafer W is transferred to the transport mechanism 79 by the lifting and lowering pin 35, and retracted from the developing apparatus 1.

According to the developing apparatus 1, when the developing solution is supplied to the central portion of the rotating wafer W, the developing unit 1 is positioned on the peripheral edge side of the wafer W from each light irradiation unit 51 constituting the radiant light irradiation group 5 The infrared rays are irradiated so that the irradiation intensity becomes stronger so that the temperature on the periphery side of the wafer W becomes higher than the temperature on the side of the center portion. As a result, the developer that diffuses to the periphery of the wafer W is suppressed from being cooled by the atmosphere around the wafer W, and the uniformity of the temperature of the developer in the surface of the wafer W is increased. Therefore, since the reaction between the resist and the developing solution proceeds with high uniformity in the plane of the wafer W, the uniformity of the dimension of the resist pattern can be increased. As a result, deterioration of the yield can be suppressed. Further, by heating by infrared rays, the wafer W can be heated more quickly than in the case of heating by using, for example, heat emitted from the heat generating resistor, so that the reduction of the throughput can be suppressed. Further, as described in the background section, the amount of developer to be supplied and the amount of developer to be supplied and the amount of developer to be supplied from the nozzle moving mechanism 64 can be suppressed.

In the developing apparatus 1, since the temperature control plate 44 for controlling the temperature of the light irradiating unit 51 is provided, the light irradiating unit 51 is excessively heated, the temperature of the wafer W fluctuates . Therefore, since the temperature of the wafer W can be controlled with high accuracy by heating by infrared rays, the uniformity of the dimension of the resist pattern can be more reliably increased in the plane of the wafer W. [

Even if the irradiation with infrared rays is performed in either step S2 or step S4, fluctuation of the reaction between the developer and the resist is suppressed, so that the uniformity of the pattern dimension is increased. However, in steps S2 and S4 By irradiating infrared rays from both sides, the uniformity of the dimension of the pattern can be further increased.

The temperature of the developing solution required for forming a uniform pattern in each part of the wafer W depends on the time the resist contacts the developing solution, that is, the flow rate of the developing solution supplied to the wafer W in each step, And the moving speed of the nozzle when the developer supply nozzle 61 is moved in step S3. Therefore, in the above example, the output of each light irradiating unit 51 is controlled so that the temperature of the developer supplied to the wafer W is the same within the plane of the wafer W. However, For example, the wafer W may be heated so that the temperature of the developer on the periphery side of the wafer W is higher than the temperature of the developer on the center side. Concretely, for example, each part of the wafer W may be heated such that the temperature of the developer is 35 ° C at the center of the wafer W and the temperature of the developer is 40 ° C at the periphery of the wafer W. It is also possible to locally heat only the periphery of the wafer W by irradiating infrared rays from the irradiation column 52e without irradiating the infrared rays from the irradiation columns 52a to 52d, for example.

At least the periphery of the wafer W must be heated when the developer is supplied to the wafer W in steps S2 and S4 and therefore the timing for starting the irradiation of the infrared rays is not limited to that of the wafer W The irradiation of the infrared rays may be started before the start of the supply of the developer, and the irradiation of the infrared rays may be delayed to start the supply of the developer.

(Second Embodiment)

Next, the developing device 8 according to the second embodiment will be described mainly with respect to the differences from the developing device 1 according to the first embodiment. 15 and 16 are a longitudinal side elevational view and a plan view of the developing device 8 and the same parts as those of the developing device 1 are denoted by the same reference numerals as those of the developing device 1. The developing apparatus 8 is provided with a developer supply nozzle 81 and a slit-shaped developer discharge port 82 formed to have substantially the same length as the diameter of the wafer W is provided below the developer supply nozzle 81 have. The developer supply pipe 67 is not provided with the heating portion 69, and the developer at the room temperature is supplied from the developer supply nozzle 81, for example. The developer supply nozzle 81 moves away from the standby position 66 when supplying the developer to the wafer W. [ Further, on the top of the upper cup 22, there is provided a liquid receiving portion 83 which is angularly opened corresponding to the developer supply nozzle 81.

The radiation irradiating group 5 of the developing apparatus 8 is controlled such that output is adjusted for every five irradiation regions 84a to 84e set along the moving direction of the developer supply nozzle 61 as shown in Fig. do. In Fig. 17, the irradiation regions 84b and 84d are hatched in order to clearly distinguish each irradiation region. These irradiation regions 84 are provided near the standby positions 66 of the developer supply nozzles 81 in the order of the regions 84a, 84b, 84c, 84d and 84e. In this developing apparatus 8, when the irradiation from the radiant light irradiation group 5 is not performed, since the contact time of the resist with the developing liquid is shorter toward the irradiation regions 84a to 84e, It becomes difficult to proceed. Therefore, the intensity of the infrared ray output from the light irradiation unit 51 is set to be strong in the order of the irradiation areas 84e, 84d, 84c, 84b, and 84a.

After the wafer W is loaded on the spin chuck 11, the developer supply nozzle 81 moves from the standby position 66 toward the one end side of the wafer W Infrared rays are irradiated from the irradiation areas 84a to 84e of the radiation irradiation group 5 and the respective sub areas of the wafers W corresponding to the irradiation areas 84e to 84d are heated The temperature of the wafer W increases from one end of the wafer W corresponding to the irradiation region 84a toward the other end of the wafer W corresponding to the irradiation region 84e.

When the developer supply nozzle 81 reaches one end of the wafer W, the developer 60 is discharged from the developer discharge port 82 (Fig. 18), and the developing solution is supplied from one end side of the wafer W, The reaction of the resist is started. The developer supply nozzle 81 is moved on the other end of the wafer W in a state where the discharge of the developer 60 is continued and each of the portions from the one end to the other end of the wafer W And the reaction between the resist and the developing solution proceeds (FIG. 19). When the developer 60 strikes the entire surface of the wafer W, the supply of the developer 60 is stopped and the developer supply nozzle 81 returns to the standby position 66. [ On the surface of the wafer W, the reaction between the developer and the resist advances more rapidly toward the other end of the temperature, and the degree of reaction of the developer and resist in the surface of the wafer W gradually becomes equal. Thereafter, the rotation of the wafer W is started, and pure water 70 is supplied from the cleaning liquid supply nozzle 71 to the central portion of the wafer W as in step S5 of the first embodiment, (60) is removed, and the reaction of the resist is stopped (Fig. 20).

In this developing apparatus 8, the contact time with the developing solution is shortened toward the other end side of the wafer W. However, the irradiation of the infrared rays of the radiation light irradiation group 5 causes the developing solution and the resist The reaction proceeds quickly. Therefore, the deviation of the degree of the reaction due to the time difference in contact with the developer within the surface of the wafer W becomes uniform. As a result, it is possible to suppress the fluctuation of resist resolution in the plane of the wafer W, and it is possible to increase the in-plane uniformity of the dimension of the resist pattern.

In this second embodiment, similarly to the first embodiment, heated developer can be supplied to the wafer W. [ Further, only the other end of the wafer W having a short contact time with the developing solution may be locally heated without heating one end of the wafer W. The irradiation of the infrared ray may be started until the developer is concentrated on the entire surface of the wafer W, and then the developer is removed.

(Third Embodiment)

Even if a developer at room temperature is used in the first embodiment, depending on the type of resist to be used and the recipe of the treatment, when the irradiation of infrared rays from the radiation light irradiation group 5 is not performed, . In the developing apparatus of the third embodiment, the variation of the pattern caused by the kind of the resist and the recipe of the treatment is corrected in this way. Note that the recipe herein refers to the flow rate and supply time of the developer to be supplied to the center of the wafer W when performing the prewetting in the step S2 and to move the developer supply nozzle 61 to the center of the wafer W in step S3 The time required for the nozzle to move from the periphery to the central portion, and the flow rate and supply time of the developer supplied to the central portion of the wafer W in step S4.

In the third embodiment, the developing apparatus 1 of the first embodiment is used, but the developing solution at room temperature is supplied from the developing solution supplying nozzle 61. In the developing apparatus 1 of the third embodiment, for example, an on-off signal is transmitted from the control section 10 so that any one of the irradiation columns 52a to 52e is emitted, and the light irradiation sections 51 ) Is set equal to each column.

Fig. 21 shows a configuration example of the control unit 10 of the developing apparatus 1 described above. In the drawing, 80 is a bus, 82 is a CPU, and 83 is a program. Reference numeral 84 is a memory and includes a table 85. [ The table 85 will be described. In the third embodiment, the types of the resist and the recipe are changed in advance, the wafers W are processed in the developing apparatus 1, and the resist pattern formed is irradiated to the respective wafers W in the radial direction of each wafer W A region having a low resolution of the pattern of the pattern is specified. However, in this process, infrared radiation from the radiation light irradiation group 5 is not performed. Data corresponding to the kind of the resist thus tested, the recipe, and the irradiation column 52 corresponding to the low resolution region are stored as the table 85. [

The operation of the developing apparatus 1 according to the third embodiment will be described with respect to the difference from the first embodiment in that before the processing by the apparatus, And the recipe to be executed, the control unit 10 searches the table 85 for the irradiation column 52 corresponding to the type and recipe of the selected resist. At the time of execution of the steps S2 and S4, infrared rays are irradiated from the searched irradiation column 52 and irradiated to the area of the wafer W where the resolution of the pattern irradiated by the experimental step is lowered. As a result, the area is heated, and the pattern is uniformly formed in the plane of the wafer W similarly to the first embodiment.

In this third embodiment, the radiation columns 52 constituting the radiation light irradiation group 5 are not limited to five rows in the radial direction of the wafer W, but may be five or more rows, do. Further, for example, a plurality of rows may be lit depending on the type and recipe of the resist. Specifically, when the irradiation column from the central portion of the wafer W is the first column and the irradiation column from the outermost side is the 50th column, for example, the 45th column to the 50th column are lighted (FIG. 22) The 46th column is turned on (Fig. 23). In Fig. 22 and Fig. 23, light is irradiated to irradiate the infrared ray. As described above, a plurality of irradiation columns may be provided, and the resolution of the device may be improved by lighting a plurality of irradiation columns. Such a configuration can also be applied to the first embodiment and the second embodiment, and when the peripheral edge or the end of the wafer W is locally heated, it is possible to heat the plurality of irradiation rows by heating .

As the temperature of the wafer W increases, the temperature of the developer becomes higher and the reaction with the resist tends to progress. However, when the temperature is excessively high, the developer becomes deteriorated and the reaction hardly progresses. For example, 23 占 폚 to 50 占 폚.

W: Wafer
1, 8: developing device
10:
11: Spin chuck
21: Cup body
41:
44: Temperature control plate
5: Radiation light irradiation group
51:
52a to 52e: irradiation column
56: Lighting controller
61: Developer supply nozzle
71: cleaning liquid supply nozzle

Claims (14)

A substrate holding portion to which a resist is applied on the surface and which horizontally holds the central portion of the substrate after exposure,
A developer supply part including a nozzle for supplying a developer to the surface of the substrate and developing the resist;
In order to improve the degree of reaction between the developer and the resist by heating the developer on the back side of the substrate held on the substrate holding portion and along the circumferential direction of the substrate on the side of the central portion and the peripheral portion of the substrate respectively A plurality of radiation light irradiating units for radiating radiant light including a wavelength absorbing region of the substrate material along a concentric circle with respect to the center of the substrate held by the substrate holding portion on the back surface of the substrate,
A cleaning liquid supply unit for supplying a cleaning liquid to the surface of the substrate to remove the developer,
A nozzle moving mechanism for moving the nozzle so that the supply position of the developer to the substrate moves between the periphery and the center of the substrate;
A rotation driving mechanism for rotating the substrate held by the substrate holding portion about a vertical axis;
A developer supply mechanism for controlling the supply of the developer to the nozzle,
A first supplying step of supplying the developing solution to the central portion of the substrate while rotating the substrate, a step of subsequently moving the supplying position of the developing solution to the periphery of the substrate, and a step of supplying the developing solution to the central portion of the substrate while rotating the substrate Irradiating the substrate with radiation light from each of the radiation light irradiating portions to irradiate the back surface of the substrate with radiation light so that the temperature of the periphery side of the substrate becomes higher than the temperature of the central portion side when the first supply step is performed, And a control section for outputting a control signal for heating the developing section. The method according to claim 1,
Wherein the developing solution supply unit includes a heating unit for heating the developer supplied from the nozzle to the substrate to a temperature higher than the atmosphere around the substrate. 3. The method according to claim 1 or 2,
The control unit irradiates the back surface of the substrate with the radiant light from each of the radiant light irradiating units so as to heat the substrate so that the temperature of the periphery side of the substrate becomes higher than the temperature of the center side when the second supplying step is performed, And outputs a signal. 3. The method according to claim 1 or 2,
Characterized in that the radiation light irradiating portion is constituted by a light emitting diode. 3. The method according to claim 1 or 2,
And a temperature control unit for controlling the temperature of the radiation light irradiating unit. A step of holding a central portion of the substrate after the exposure with the resist on the surface thereof horizontally on the substrate holding portion,
Supplying a developer to a surface of the substrate by a developer supply portion including a nozzle and developing the resist;
A plurality of radiation light irradiating portions provided along the circumferential direction of the substrate on the center side and the peripheral side of the substrate held on the back side of the substrate held by the substrate holding portion, Irradiating the substrate with a radiant ray along a concentric circle with respect to the center of the substrate held by the substrate holding portion and heating the developer to increase the degree of reaction between the developer and the resist,
Supplying a cleaning liquid to the surface of the substrate by the cleaning liquid supply unit to remove the developer,
And a step of rotating the substrate held by the substrate holding portion by the rotation driving mechanism around the vertical axis and diffusing the developer to the periphery of the substrate by centrifugal force,
The step of developing the resist includes:
Irradiating the back surface of the substrate with the radiation light in each of the radiation light irradiating portions so as to heat the substrate so that the temperature on the peripheral portion side of the substrate becomes higher than the temperature on the central portion side;
A first developer supplying step of supplying developer to a central portion of the substrate while rotating the substrate,
Subsequently, a step of moving the supply position of the developer to the periphery of the substrate by moving the nozzle by the nozzle moving mechanism,
And a second developer supply step of moving the supply position of the developer to the center of the substrate by moving the nozzle by the nozzle moving mechanism and supplying the developer to the central part,
Wherein the step of irradiating the back surface of the substrate with the radiation light and heating the radiation is performed when the first developer supplying step is performed. The method according to claim 6,
The step of developing the resist includes:
Heating the developer to a temperature higher than the atmosphere around the substrate by the heating unit,
And supplying the heated developing solution from the nozzle to a central portion of the substrate. 8. The method according to claim 6 or 7,
Wherein the step of irradiating the back surface of the substrate with the radiation light for heating when performing the second developer supply step is performed. A storage medium storing a computer program for use in a developing apparatus for performing development processing on a substrate,
Wherein the computer program is for carrying out the developing method according to claim 6 or 7. delete delete delete delete delete

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