JP3916886B2 - Substrate processing equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a substrate processing device in which a resist film of uniform thickness can be formed on all substrates even when a plurality of substrates are processed continuously. SOLUTION: A carrying robot carries a plurality of substrates sequentially through an adhesion enhancing unit AH, a cooling unit CP1, a coating unit SC1, and a heating unit HP1 and the plurality of substrates are coated with resist sequentially. When a plurality of substrates are processed under the same processing conditions, a resist film being formed on the major surface of the last substrate becomes thinner as compared with a resist film being formed normally on the major surface of a substrate because the last substrate is not subjected to thermal effect when it is carried from the cooling unit to the coating unit. Processing conditions are thereby altered for the last substrate such that a resist film being formed on the major surface of the last substrate has the same thickness as that of a resist film being formed normally on the major surface of a substrate.

Description

[0001]
BACKGROUND OF THE INVENTION
In the present invention, a resist is sequentially applied to a plurality of semiconductor substrates, a glass substrate for a liquid crystal display device, a glass substrate for a photomask, a substrate for an optical disk (hereinafter simply referred to as “substrate”), and the main surface of each substrate. The present invention relates to a substrate processing apparatus for forming a resist film.
[0002]
[Prior art]
Products such as semiconductors and liquid crystal displays are manufactured by subjecting a substrate to a series of processes such as cleaning, resist coating, exposure, development, etching, formation of an interlayer insulating film, and heat treatment. Conventionally, these various processes are performed in a substrate processing apparatus incorporating a plurality of processing units such as a coating processing unit and a heat treatment unit. A series of substrate processing proceeds by transferring a substrate between a plurality of processing units in a predetermined order by a transfer robot in the substrate processing apparatus, and processing the substrate in each processing unit. Normally, a plurality of substrates, for example, 25 substrates are sequentially conveyed, and the processing of the next substrate is started before all the series of processing for the previous substrate is completed. That is, throughput is improved by continuously processing a plurality of substrates.
[0003]
[Problems to be solved by the invention]
However, when continuous processing is performed on a plurality of substrates, the film thickness of the resist film formed on the main surface of those final substrates tends to be thinner than the film thickness of the resist films on the substrates other than the final substrate. Such fluctuations in the resist film thickness affect subsequent exposure processing, development processing, and the like, and ultimately affect the quality of products such as semiconductors. In particular, in recent years, the miniaturization and complexity of semiconductors and the like have further progressed, and in the situation where the demand for quality control has become strict, slight fluctuations in the thickness of the resist film formed on the main surface of the substrate are also a problem. Become.
[0004]
The present invention has been made in view of the above problems, and provides a substrate processing apparatus capable of forming a resist film having a uniform film thickness on all substrates even when a plurality of substrates are continuously processed. The purpose is to provide.
[0005]
[Means for Solving the Problems]
  In order to solve the above problems, the invention of claim 1 is a substrate processing apparatus for sequentially applying a resist to a plurality of substrates to form a resist film on the main surface of each substrate, and supplying the resist to the main surface of the substrate. In addition, a resist coating processing unit that performs resist coating by rotating the substrate, an adhesion strengthening processing unit that performs heat treatment on the substrate to improve the adhesion between the substrate and the resist, and heat processing in the adhesion strengthening processing unit A cooling processing unit that performs cooling processing of the substrate that has been subjected to heat treatment, a heating processing unit that performs heating processing of the substrate on which the resist coating has been performed in the resist coating processing unit, and the adhesion enhancement of the plurality of substrates sequentially Concerning the transporting means for transporting the processing section, the cooling processing section, the resist coating processing section, and the heating processing section in this order, and the final substrate on which the resist coating is finally applied among the plurality of substrates, the final As the film thickness of the resist film formed on the main surface of the plate becomes a thickness substantially the same of the final substrate than the resist film usually formed on the main surface of the substrate among the plurality of substrates,In each processing unit for the final substrateProcessing condition changing means for changing the processing condition.
[0006]
According to a second aspect of the present invention, in the substrate processing apparatus according to the first aspect of the present invention, when the plurality of substrates are processed under the same processing conditions, a resist film formed on the main surface of the final substrate is provided. When the film thickness is thinner than the film thickness of the resist film formed on the main surface of the normal substrate, the processing temperature change unit is configured to set the processing temperature for the final substrate in the cooling processing unit to the normal substrate. About the processing temperature is made higher.
[0008]
  Claims3In the substrate processing apparatus according to the first aspect of the present invention, when the plurality of substrates are processed under the same processing conditions, the thickness of the resist film formed on the main surface of the final substrate is the normal thickness. When the thickness of the resist film formed on the main surface of the substrate is thinner, the processing condition changing means is configured to set the number of rotations for the final substrate in the resist coating processing unit to the number of rotations for the normal substrate. Less than.
[0010]
  Claims4In the substrate processing apparatus according to the first aspect of the present invention, when the plurality of substrates are processed under the same processing conditions, the thickness of the resist film formed on the main surface of the final substrate is the normal thickness. When the thickness of the resist film formed on the main surface of the substrate is smaller than the processing temperature for the final substrate, the processing temperature changing means is set to a processing temperature for the final substrate in the heat treatment unit. Is also low.
[0012]
  Claims5In the substrate processing apparatus according to the first aspect of the present invention, when the plurality of substrates are processed under the same processing conditions, the thickness of the resist film formed on the main surface of the final substrate is the normal thickness. When the thickness of the resist film formed on the main surface of the substrate is thinner, the processing condition changing means includes the rotation time for the final substrate in the resist coating processing unit as the rotation time for the normal substrate. Make it shorter.
[0014]
  Claims6In the substrate processing apparatus according to the first aspect of the present invention, when the plurality of substrates are processed under the same processing conditions, the thickness of the resist film formed on the main surface of the final substrate is the normal thickness. When the thickness of the resist film formed on the main surface of the substrate is thinner than the heating time for the normal substrate, the heating time for the final substrate in the heat treatment unit is set in the processing condition changing means. Is also shortened.
[0016]
  Claims7The invention ofThe invention according to any one of claims 1 to 6In substrate processing equipment,Film thickness measuring means for measuring the film thickness of the resist film formed on the main surface of the substrate, film thickness of the resist film formed on the main surface of the final substrate measured by the film thickness measuring means, and the normal substrate A film thickness difference calculating means for obtaining a film thickness difference with the film thickness of the resist film formed on the main surface of the substrate, and the processing condition changing means is configured to process the final substrate based on the film thickness difference. Changing the conditions.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0018]
<1. Configuration of substrate processing apparatus>
FIG. 1 is a plan view showing the overall configuration of a substrate processing apparatus 1 according to the present invention. 1 and the subsequent drawings are provided with an XYZ orthogonal coordinate system in which the Z-axis direction is a vertical direction and the XY plane is a horizontal plane as necessary in order to clarify the directional relationship.
[0019]
The substrate processing apparatus 1 is a device that performs resist coating processing and development processing on a substrate, and includes an indexer ID that loads and unloads the substrate, and a first processing unit group PG1, which includes a plurality of processing units that perform processing on the substrate. It includes an interface IF for transferring the substrate between the second processing unit group PG2, an exposure apparatus (stepper) (not shown), and a transfer robot TR.
[0020]
  The indexer ID is equipped with a carrier (not shown) that can store a plurality of substrates and includes a transfer robot. The indexer ID pays out an unprocessed substrate from the carrier to the transport robot TR and removes a processed substrate from the transport robot TR. Receive and store in carrier. As a form of the carrier, an OC (open cas that exposes the storage board to the outside air).sette), or a FOUP (front opening unified pod) or SMIF (Standard Mechanical Interface) pod that accommodates the substrate in a sealed space. In this embodiment, it is assumed that 25 substrates are stored in the carrier.
[0021]
The interface IF has a function of receiving a resist-coated substrate from the transport robot TR and passing it to an exposure apparatus (not shown), and receiving an exposed substrate and passing it to the transport robot TR. Further, the interface IF has a buffer function for temporarily stocking the substrate before and after the exposure in order to adjust the delivery timing with the exposure apparatus. Although not shown, the interface IF is connected to the transfer robot TR. A robot for delivering the substrate and a buffer cassette on which the substrate is placed.
[0022]
The substrate processing apparatus 1 includes a plurality of processing units (processing units) for processing a substrate, some of which constitute the first processing unit group PG1, and the remaining part of the second processing unit group PG2. Constitute. FIG. 2 is a diagram illustrating configurations of the first processing unit group PG1 and the second processing unit group PG2. The first processing unit group PG1 is configured by arranging a plurality of heat treatment units above the coating processing units SC1 and SC2 (resist coating processing units) which are liquid processing units. In FIG. 2, the processing units are arranged in a plane for convenience of illustration, but in actuality these are stacked in the height direction (Z-axis direction).
[0023]
The coating processing units SC1 and SC2 are so-called spin coaters that apply a uniform resist by supplying a photoresist to the main surface of the substrate and rotating the substrate. Three rows of heat treatment units stacked in three stages are provided above the coating processing units SC1 and SC2. That is, in order from the bottom, the cooling unit CP1, the adhesion strengthening unit AH (adhesion strengthening processing unit), the row in which the heating unit HP1 is laminated, the row in which the cooling unit CP2, the heating unit HP2, and the heating unit HP3 are laminated, and the cooling unit. CP3, a heating unit HP4, and a row in which the heating units HP5 are stacked are provided.
[0024]
Similarly, the second processing unit group PG2 is configured by arranging a plurality of heat treatment units above the development processing units SD1 and SD2 which are liquid processing units. The development processing units SD1 and SD2 are so-called spin developers that perform development processing by supplying a developer onto the exposed substrate. Three rows of heat treatment units stacked in three stages are provided above the development processing units SD1 and SD2. That is, the cooling unit CP4, the post-exposure bake unit PEB, and the heating unit HP6 are stacked in order from the bottom, the cooling unit CP5, the heating unit HP7, and the heating unit HP8 are stacked, the cooling unit CP6, and the heating unit HP9. And a row in which the heating units HP10 are stacked.
[0025]
The heating units HP1 to HP10 are so-called hot plates that heat a substrate and raise the temperature to a predetermined temperature. Further, the adhesion strengthening unit AH and the post-exposure bake unit PEB are heating units for heating the substrate before the resist coating process and immediately after the exposure, respectively. The cooling units CP1 to CP6 are so-called cool plates that cool the substrate to a predetermined temperature and maintain the substrate at the predetermined temperature.
[0026]
In this specification, the processing unit (heating unit and cooling unit) for adjusting the temperature of these substrates is referred to as a heat treatment unit. In addition, processing units that perform predetermined processing by supplying a processing liquid to the substrate, such as the coating processing units SC1 and SC2 and the development processing units SD1 and SD2, are referred to as liquid processing units. The liquid processing unit and the heat treatment unit are collectively referred to as a processing unit.
[0027]
Note that a filter fan unit FFU that forms a downflow of clean air whose temperature and humidity are controlled is provided immediately below the heat treatment unit on the liquid treatment unit side. Although not shown, a filter fan unit that forms a downflow of clean air toward the transfer space is also provided at an upper position where the transfer robot TR is disposed.
[0028]
A controller CR is provided inside the substrate processing apparatus 1. The controller CR is configured using a computer including a memory, a CPU, and the like. The controller CR controls the transfer operation of the transfer robot TR according to a predetermined processing program, and gives an instruction to each processing unit to set processing conditions.
[0029]
FIG. 3 is an external perspective view of the transfer robot TR. The transfer robot TR is provided with an arm stage 35 having transfer arms 31 a and 31 b on the upper part of the telescopic body 40, and a telescopic multi-stage nested structure is realized by the telescopic body 40.
[0030]
The stretchable body 40 is configured by four divided bodies 40a, 40b, 40c, and 40d in order from the top. The divided body 40a can be accommodated in the divided body 40b, the divided body 40b can be accommodated in the divided body 40c, and the divided body 40c can be accommodated in the divided body 40d. The stretchable body 40 contracts by sequentially storing the divided bodies 40a to 40d, and conversely, the stretchable body 40 expands by sequentially pulling out the divided bodies 40a to 40d. That is, when the telescopic body 40 is contracted, the divided body 40a is accommodated in the divided body 40b, the divided body 40b is accommodated in the divided body 40c, and the divided body 40c is accommodated in the divided body 40d. On the other hand, when the telescopic body 40 is extended, the divided body 40a is pulled out from the divided body 40b, the divided body 40b is pulled out from the divided body 40c, and the divided body 40c is pulled out from the divided body 40d.
[0031]
The expansion / contraction operation of the expansion / contraction body 40 is realized by an expansion / contraction lifting mechanism provided therein. For example, a mechanism that drives a combination of a plurality of belts and rollers by a motor can be employed as the expansion / contraction lifting mechanism. The transport robot TR can move the transport arms 31a and 31b up and down by such an extendable lift mechanism.
[0032]
Further, the transfer robot TR can also perform horizontal advance / retreat movement and rotation operation of the transfer arms 31a, 31b. Specifically, an arm stage 35 is provided on the upper part of the divided body 40a, and the arm stage 35 performs the horizontal advance / retreat movement and the rotation operation of the transfer arms 31a, 31b. That is, when the arm stage 35 bends and extends the arm segments of the transfer arms 31a and 31b, the transfer arms 31a and 31b move horizontally, and the arm stage 35 itself rotates with respect to the telescopic body 40. The transfer arms 31a and 31b rotate.
[0033]
Therefore, the transfer robot TR can move the transfer arms 31a and 31b up and down in the height direction, rotate the transfer arms 31a and 31b, and move the transfer arms 31a and 31b back and forth in the horizontal direction. That is, the transfer robot TR can move the transfer arms 31a and 31b three-dimensionally. Then, the transfer arms 31a and 31b holding the substrate W move three-dimensionally to transfer the substrate W to and from the plurality of processing units, thereby transferring the substrate W to the plurality of processing units. Various treatments can be performed on the substrate W.
[0034]
<2. Substrate processing procedure>
Next, a substrate processing procedure in the substrate processing apparatus 1 will be described. FIG. 4 is a diagram illustrating an example of a substrate processing procedure in the substrate processing apparatus 1. First, the unprocessed substrate W paid out from the indexer ID to the transport robot TR is carried into the adhesion strengthening unit AH. The adhesion strengthening unit AH is an adhesion strengthening processing unit that performs a heat treatment on the substrate W to improve the adhesion between the substrate W and the resist. Methyl Di Silazan) enhances adhesion by spraying. Next, the transport robot TR transports the substrate W that has been subjected to the adhesion strengthening process from the adhesion strengthening unit AH to the cooling unit CP1. The cooling unit CP1 is a cool plate that performs a cooling process on the substrate W that has been subjected to the heating process in the adhesion strengthening unit AH.
[0035]
The substrate W that has been cooled is transferred from the cooling unit CP1 to the coating processing unit SC1 by the transfer robot TR. The coating processing unit SC1 supplies a resist to the main surface of the substrate W and rotates the substrate to perform a resist coating process. The supplied resist spreads over the entire main surface of the substrate W by centrifugal force to form a resist film.
[0036]
Next, the substrate W on which the resist coating process has been completed is transported from the coating processing unit SC1 to the heating unit HP1 by the transport robot TR. The heating unit HP1 is a hot plate that heats the substrate W on which the resist coating is performed in the coating processing unit SC1. This heat treatment is a heat treatment referred to as “pre-bake”, which evaporates excess solvent components in the resist applied to the substrate W, strengthens the adhesion between the resist and the substrate W, and has a resist film with stable sensitivity. Is a process of forming
[0037]
The pre-baked substrate W is transported from the heating unit HP1 to the cooling unit CP2 by the transport robot TR. The cooling unit CP2 performs a cooling process for the substrate W after pre-baking.
[0038]
After completion of the cooling process, the transport robot TR transports the substrate W from the cooling unit CP2 to the interface IF. The interface IF passes the substrate W on which the resist film received from the transfer robot TR is formed to the exposure apparatus (stepper). The exposure apparatus performs an exposure process on the substrate W. The substrate W after the exposure processing is returned to the interface IF again.
[0039]
The substrate W returned to the interface IF is transported to the post-exposure bake unit PEB by the transport robot TR. The post-exposure bake unit PEB performs a heat treatment (post-exposure bake) for uniformly diffusing the product generated by the photochemical reaction in the resist film. By this heat treatment, the resist undulation at the boundary between the exposed portion and the unexposed portion is eliminated, and a good pattern is formed.
[0040]
The substrate W that has been post-exposure baked is transported from the post-exposure bake unit PEB to the cooling unit CP3 by the transport robot TR. The cooling unit CP3 performs a cooling process on the substrate W after post-exposure baking. Thereafter, the substrate W is transported from the cooling unit CP3 to the development processing unit SD1 by the transport robot TR. The development processing unit SD1 performs development processing of the substrate W after exposure.
[0041]
The developed substrate W is transported from the development processing unit SD1 to the heating unit HP2 by the transport robot TR. The heating unit HP2 heats the substrate W after development. Thereafter, the substrate W is transported from the heating unit HP2 to the cooling unit CP4 by the transport robot TR and cooled.
[0042]
The substrate W cooled by the cooling unit CP4 is returned to the indexer ID by the transport robot TR and stored in the carrier.
[0043]
As described above, the transport robot TR transports the substrate W according to the procedure shown in FIG. 4, whereby a series of processes including the resist coating process, the development process, and the heat treatment associated therewith are performed on the substrate W. In FIG. 4, instead of the coating processing unit SC1, a coating processing unit SC2 having the same function may be used. Either the coating processing unit SC1 or the coating processing unit SC2 is free. You may make it perform what is called parallel processing of carrying in the board | substrate W. FIG. This is the same for other processing units having equivalent functions such as the development processing unit SD1, the heating unit HP1, and the cooling unit CP1.
[0044]
<3. Processing conditions>
In the above description, the processing procedure for one substrate W has been described. However, in the substrate processing apparatus 1 of the present embodiment, the procedure shown in FIG. 4 continuously for one lot consisting of a plurality of substrates W. Is being processed. Specifically, 25 substrates W are accommodated in the carrier placed on the indexer ID, and these 25 substrates W are continuously processed as one lot. In the following description, the first to 24th substrates out of the 25 substrates W to be processed successively are referred to as substrates W1 to W24 (normal substrates), respectively, and the final substrate is a substrate WL (final substrate). ), And when there is no need to distinguish between them, they are simply referred to as the substrate W.
[0045]
As a continuous processing method, first, the transfer robot TR uses the transfer arm 31a to load the first substrate W1 of the lot into the adhesion strengthening unit AH. While the first substrate W1 is being heated in the adhesion strengthening unit AH, the transfer robot TR uses the transfer arm 31a to transfer the next substrate W2 in the lot to the adhesion enhancing unit AH. Here, the transfer robot TR exchanges the substrate W using the two transfer arms 31a and 31b. That is, after the first substrate W1 that has been subjected to the heat treatment in the adhesion strengthening unit AH is taken out by the transport arm 31b, the unprocessed substrate W2 is carried into the adhesion strengthening unit AH by the transport arm 31a. Thereafter, the transfer robot TR uses the transfer arm 31b to carry the first substrate W1 for which the heat treatment in the adhesion enhancing unit AH has been completed into the cooling unit CP1. Thereafter, by repeating the same procedure as this, the processing of FIG. 4 is continuously performed on 25 substrates W.
[0046]
By the way, when the process of FIG. 4 is continuously performed on a plurality of substrates W, the following phenomenon occurs. FIG. 5 is a diagram illustrating a state in which the substrates W1 to W24 other than the final one among the plurality of substrates W are carried into and out of the cooling unit CP1.
[0047]
FIG. 5A shows a state where the transfer arm 31b holds the substrate W2 that has been subjected to the heat treatment in the adhesion strengthening unit AH, and the cooling processing of the substrate W1 in the cooling unit CP1 has been completed. From this state, the transfer robot TR causes the transfer arm 31a to access the cooling unit CP1 and takes out the substrate W1 after the cooling process. At this moment, the transfer arm 31a holds the substrate W1 after the cooling process, and the transfer arm 31b holds the substrate W2 after the heating process (state shown in FIG. 5B).
[0048]
From the state of FIG. 5B, the transport robot TR causes the transport arm 31b to access the cooling unit CP1, and carries the substrate W2 into the cooling unit CP1 (the state of FIG. 5C). As a result, the substrate W1 and the substrate W2 are exchanged in the cooling unit CP1. When the normal substrates W1 to W24, which are substrates other than the final substrate WL among the plurality of substrates W, are taken out of the processing unit, the same replacement operation as shown in FIG. 5 is performed.
[0049]
On the other hand, FIG. 6 is a diagram illustrating a state in which the final substrate WL of the plurality of substrates W is carried in and out of the cooling unit CP1. Since there is no substrate to be processed immediately after the final substrate WL of the lot, the two transfer arms 31a and 31b both hold the substrate W when the cooling processing of the final substrate WL in the cooling unit CP1 is completed. No (state shown in FIG. 6A).
[0050]
From this state, the transfer robot TR makes the transfer arm 31a access the cooling unit CP1 and takes out the final substrate WL after the cooling process. At this moment, the transfer arm 31a holds the final substrate WL after the cooling process, while the transfer arm 31b does not hold the substrate (the state shown in FIG. 6B). As described above, when the final substrate WL of the plurality of substrates W is taken out from the processing unit, the replacement work is not performed.
[0051]
As a result of the above, in the case of FIG. 5, the substrate W1 after the cooling process held by the transfer arm 31a is affected by heat from the substrate W2 after the heating process held by the transfer arm 31b and the transfer arm 31b itself. It will be warmed up a little. This is the same for the normal substrates W1 to W24 other than the final substrate WL. On the other hand, in the case of FIG. 6, there is no thermal influence from the other substrate W on the final substrate WL after the cooling process held by the transfer arm 31a. Accordingly, even when the substrate W is similarly cooled by the cooling unit CP1, the temperatures of the normal substrates W1 to W24 are slightly higher than the temperatures of the final substrate WL when they are carried into the coating processing unit SC1. .
[0052]
When the resist coating process is performed in the coating processing unit SC1, the supplied resist is difficult to spread when the temperature of the substrate W is high, and conversely, when the temperature of the substrate W is low, the dropped resist is easily spread. As a result, with respect to the final substrate WL having a low temperature, the resist spreads more easily than the normal substrates W1 to W24, and the film thickness of the resist film becomes somewhat thin. Conventionally, it has been recognized that the thickness of the resist film formed on the main surface of the final substrate W tends to be thinner than the thickness of the resist film of the substrate W other than the final substrate.
[0053]
Therefore, in this embodiment, the film thickness variation is suppressed by changing any of the processing conditions for the final substrate WL in the processing unit as follows.
[0054]
<3-1. Processing temperature in cooling unit CP1>
As described above, the direct cause of the film thickness variation of the resist film thickness is the presence or absence of thermal influence in the process of transporting from the cooling unit CP1 to the coating processing unit SC1. Here, if the processing temperature in the cooling unit CP1 for the final substrate WL that is not affected by heat is higher than the processing temperature for the normal substrates W1 to W24 that are affected by heat, the final substrate WL is also affected by heat. Will be the same.
[0055]
Specifically, the controller CR controls the cooling unit CP1 so that the processing temperature for the final substrate WL is higher than the processing temperatures for the normal substrates W1 to W24. As a result, the final substrate WL that is not affected by heat is also isothermal with the normal substrates W1 to W24 at the time when it is carried into the coating processing unit SC1. As a result, at the time of resist coating processing in the coating processing unit SC1, the resist spreads to the same extent on all the substrates W (25 substrates W) included in one lot, and a resist having a uniform film thickness on all the substrates W. A film can be formed.
[0056]
Note that the temperature difference (offset temperature) between the processing temperature of the cooling unit CP1 for the final substrate WL and the processing temperatures of the normal substrates W1 to W24 is determined beforehand by an experiment so that a uniform resist film is formed. It may be calculated and stored in the controller CR. The controller CR changes the processing temperature in the cooling unit CP1 for the final substrate WL based on the stored offset temperature.
[0057]
<3-2. Number of revolutions in coating processing unit SC1>
Even when the temperature of the normal substrates W1 to W24 is slightly higher than the temperature of the final substrate WL at the time of loading into the coating processing unit SC1, the number of rotations of the final substrate WL in the coating processing unit SC1 is set to the normal substrate. If the rotational speed is less than W1 to W24, the centrifugal force is weakened and the supplied resist is difficult to spread, and the thickness of the resist film on the final substrate WL is increased.
[0058]
Specifically, the controller CR controls the coating processing unit SC1 so that the number of rotations for the final substrate WL in the coating processing unit SC1 is less than the number of rotations for the normal substrates W1 to W24. As a result, the resist is difficult to spread, and the film thickness of the resist film formed on the final substrate WL is increased. As a result, a resist film having a uniform film thickness is formed on all the substrates W included in one lot. Can do.
[0059]
Note that the rotational speed difference (offset rotational speed) between the rotational speed in the coating processing unit SC1 for the final substrate WL and the rotational speed for the normal substrates W1 to W24 is an offset rotational speed at which a uniform resist film is formed. May be calculated in advance by experiments and stored in the controller CR. The controller CR changes the number of revolutions in the coating processing unit SC1 for the final substrate WL based on the stored offset number of revolutions.
[0060]
<3-3. Pre-baking temperature>
Even if the resist film thickness of the final substrate WL at the time when the resist coating process is completed is slightly thinner than the normal substrates W1 to W24, the pre-bake temperature for the final substrate WL in the heating unit HP1 is set to the normal substrates W1 to W24. If the temperature is lower than the pre-bake temperature, the evaporation of the solvent component is reduced, and the film thickness of the resist film formed on the final substrate WL is increased.
[0061]
Specifically, the controller CR controls the heating unit HP1 so that the processing temperature for the final substrate WL in the heating unit HP1 is lower than the processing temperature for the normal substrates W1 to W24. As a result, the evaporation of the solvent component is suppressed and the film thickness of the resist film formed on the final substrate WL is increased. As a result, a resist film having a uniform film thickness is formed on all the substrates W included in one lot. can do.
[0062]
Note that the temperature difference (offset temperature) between the processing temperature in the heating unit HP1 for the final substrate WL and the processing temperature for the normal substrates W1 to W24 is determined beforehand by an experiment so that a uniform resist film is formed. It may be calculated and stored in the controller CR. The controller CR changes the processing temperature in the heating unit HP1 for the final substrate WL based on the stored offset temperature.
[0063]
<3-4. Rotation time in coating processing unit SC1>
Even when the temperature of the normal substrates W1 to W24 is slightly higher than the temperature of the final substrate WL at the time of loading into the coating processing unit SC1, the rotation time for the final substrate WL in the coating processing unit SC1 is set to the normal substrate. If it is shorter than the rotation time for W1 to W24, the spread of the supplied resist is suppressed, and the film thickness of the resist film on the final substrate WL is increased.
[0064]
  Specifically, the controller CR controls the coating processing unit SC1 so that the rotation time for the final substrate WL in the coating processing unit SC1 is shorter than the rotation time for the normal substrates W1 to W24. This makes the resistofThe spread is suppressed and the film thickness of the resist film formed on the final substrate WL is increased, and as a result, a resist film having a uniform film thickness can be formed on all the substrates W included in one lot.
[0065]
Note that the time difference (offset time) between the rotation time in the coating processing unit SC1 for the final substrate WL and the rotation time for the normal substrates W1 to W24 is determined in advance by an experiment so that a uniform resist film is formed. It may be calculated and stored in the controller CR. The controller CR changes the rotation time in the coating processing unit SC1 for the final substrate WL based on the stored offset time.
[0066]
<3-5. Pre-baking time>
Further, even if the resist film thickness of the final substrate WL at the time when the resist coating process is completed is slightly smaller than the normal substrates W1 to W24, the pre-bake time for the final substrate WL in the heating unit HP1 is set for the normal substrates W1 to W24. If the pre-bake time is shorter than this, the evaporation of the solvent component is reduced, and the film thickness of the resist film formed on the final substrate WL is increased.
[0067]
Specifically, the controller CR controls the heating unit HP1 so that the heating time for the final substrate WL in the heating unit HP1 is shorter than the heating time for the normal substrates W1 to W24. As a result, the evaporation of the solvent component is suppressed and the film thickness of the resist film formed on the final substrate WL is increased. As a result, a resist film having a uniform film thickness is formed on all the substrates W included in one lot. can do.
[0068]
Note that the time difference (offset time) between the heating time for the final substrate WL in the heating unit HP1 and the heating time for the normal substrates W1 to W24 is calculated in advance by an experiment so that a uniform resist film is formed. The value may be stored in the controller CR. The controller CR changes the heating time in the heating unit HP1 for the final substrate WL based on the stored offset time.
[0069]
As described above, in this embodiment, the transport robot TR sequentially transports the plurality of substrates W in the order of the adhesion strengthening unit AH, the cooling unit CP1, the coating processing unit SC1, and the heating unit HP1, and the plurality of substrates. A resist is sequentially applied to W to form a resist film on the main surface of each substrate W. If the plurality of substrates W are processed under the same processing conditions, the final substrate WL is not affected by heat in the process of transporting from the cooling unit CP1 to the coating processing unit SC1. The film thickness of the resist film formed on the main surface of the substrate WL is usually smaller than the film thickness of the resist film formed on the main surface of the substrates W1 to W24.
[0070]
Therefore, in the present embodiment, with respect to the final substrate WL to which the resist coating is finally applied among the plurality of substrates W, the film thickness of the resist film formed on the main surface of the final substrate WL is such that the plurality of substrates W Among them, the processing conditions are changed so as to be the same as the film thickness of the resist film formed on the main surfaces of the normal substrates W1 to W24 other than the final substrate WL. The contents of the specific processing conditions to be changed when the film thickness of the resist film formed on the main surface of the final substrate WL is usually smaller than the film thickness of the resist film formed on the main surface of the substrates W1 to W24,
(1) The processing temperature for the final substrate WL in the cooling unit CP1 is set higher than the processing temperatures for the normal substrates W1 to W24.
(2) The rotational speed for the final substrate WL in the coating processing unit SC1 is made smaller than the rotational speed for the normal substrates W1 to W24.
(3) The processing temperature for the final substrate WL in the heating unit HP1 is made lower than the processing temperatures for the normal substrates W1 to W24.
(4) The rotation time for the final substrate WL in the coating processing unit SC1 is made shorter than the rotation time for the normal substrates W1 to W24.
(5) The heating time for the final substrate WL in the heating unit HP1 is made shorter than the heating time for the normal substrates W1 to W24.
That's it. By changing the processing conditions of any of these, the film thickness of the resist film formed on the final substrate WL is increased, and as a result, the film thickness is uniform on all the substrates W included in one lot. A resist film can be formed.
[0071]
Further, compared with a case where a dedicated transport arm for transporting the substrate W from the cooling unit CP1 to the coating processing unit SC1 is provided in order to make the heat effect uniform, no special hardware is required, so that the cost can be reduced. In addition, an increase in footprint can be suppressed.
[0073]
    <4. Modification>
  While the embodiments of the present invention have been described above, the present invention is not limited to the above examples. For exampleThe contents of the processing conditions to be changed are not limited to those shown in the above embodiment, and may be the temperature and humidity in the coating processing unit SC1 or the temperature and viscosity of the resist to be coated. When the film thickness of the resist film formed on the main surface of the final substrate WL is usually smaller than the film thickness of the resist film formed on the main surface of the substrates W1 to W24,
(6)The temperature of the coating processing unit SC1 for the final substrate WL is made lower than the normal substrates W1 to W24.
(7)The humidity of the coating processing unit SC1 for the final substrate WL is higher than that of the normal substrates W1 to W24.
(8)The temperature of the resist applied to the final substrate WL is set higher than that of the normal substrates W1 to W24.
(9)The viscosity of the resist applied to the final substrate WL is usually higher than that of the substrates W1 to W24.
As a result, the film thickness of the resist film formed on the final substrate WL is increased, and as a result, a resist film having a uniform film thickness is formed on all the substrates W included in one lot. Can do.
[0075]
However, since the five processing conditions described in the above embodiment are superior to these processing conditions in terms of control responsiveness and accuracy, the controller CR can be easily changed.
[0076]
As for the processing conditions to be changed, any one of the above may be adopted alternatively, or a plurality of them may be combined. For example, for the final substrate WL, the processing temperature in the cooling unit CP1 may be increased and the number of rotations in the coating processing unit SC1 may be decreased.
[0077]
The method for changing the processing conditions for the final substrate WL is based on the cooling process described above in which the film thickness difference between the final substrate WL and the normal substrates W1 to W24 is predicted based on the results of experiments and the like, and the film thickness difference is compensated. Of course, it is also possible to previously store the offset value of the processing parameter in at least one of the unit CP1, the coating processing unit SC1, and the heating unit HP1 in the controller CR, and change the processing conditions of the final substrate WL by the controller CR. For example, a film thickness measuring means is provided at any location in the substrate processing apparatus 1, and the film thickness of the resist film applied by the coating processing unit SC1 on the final substrate WL is measured by the film thickness measuring means, and the final measured The film thickness of the resist film for the substrate WL and the desired resist to be formed by the normal substrates W1 to W24 The difference between the thickness of the film (usually the thickness of the resist film formed on any one of the substrates W1 to W24 may be actually measured by the film thickness measuring means) is obtained by the controller CR, and the actual film If there is a thickness difference, the controller CR obtains an offset value of the processing parameter in at least one of the cooling processing unit CP1, the coating processing unit SC1, and the heating unit HP1 corresponding to the thickness difference, and the controller CR The processing conditions for the final substrate WL may be automatically changed by the controller CR afterwards.
[0078]
Summarizing the above contents, when a plurality of substrates W are processed under the same processing conditions, the thickness of the resist film formed on the main surface of the final substrate WL is normally formed on the main surfaces of the substrates W1 to W24. In the case where the film thickness varies with respect to the thickness of the resist film, the processing conditions of the final substrate WL may be changed so as to compensate for the variation.
[0079]
【The invention's effect】
  As described above, claim 1And claim 7According to the invention, with respect to the final substrate on which the resist coating is finally applied among the plurality of substrates, the film thickness of the resist film formed on the main surface of the final substrate is the final substrate of the plurality of substrates. To be substantially the same as the film thickness of the resist film formed on the main surface of the normal substrate other thanIn each processing unit for the final substrateSince the processing conditions are changed, a resist film having a uniform film thickness can be formed on all the substrates even when a plurality of substrates are successively processed.
[0080]
According to the invention of claim 2, if a plurality of substrates are processed under the same processing conditions, the film thickness of the resist film formed on the main surface of the final substrate is formed on the main surface of the normal substrate. When the thickness of the resist film is thinner, the processing temperature for the final substrate in the cooling processing unit is set higher than the processing temperature for the normal substrate, so that the resist on the final substrate is difficult to spread in the resist coating processing unit. As a result, the resist film thickness of the final substrate is increased, and a resist film having a uniform film thickness can be formed on all the substrates.
[0082]
  Claims3According to the invention, assuming that a plurality of substrates are processed under the same processing conditions, the thickness of the resist film formed on the main surface of the final substrate is the thickness of the resist film formed on the main surface of the normal substrate. In the case where the thickness is smaller than that of the normal substrate, the number of rotations of the final substrate in the resist coating processing unit is less than that of the normal substrate. The resist film thickness of the final substrate is increased, and a resist film having a uniform film thickness can be formed on all the substrates.
[0084]
  Claims4According to the invention, assuming that a plurality of substrates are processed under the same processing conditions, the thickness of the resist film formed on the main surface of the final substrate is the thickness of the resist film formed on the main surface of the normal substrate. If it is thinner than that, the processing temperature for the final substrate in the heat treatment unit is lower than the processing temperature for the normal substrate, so that the solvent component of the resist on the final substrate is less likely to evaporate in the heat treatment unit, As a result, the resist film thickness of the final substrate is increased, and a resist film having a uniform film thickness can be formed on all the substrates.
[0086]
  Claims5According to the invention, assuming that a plurality of substrates are processed under the same processing conditions, the thickness of the resist film formed on the main surface of the final substrate is the thickness of the resist film formed on the main surface of the normal substrate. In the case where the thickness is thinner, the rotation time for the final substrate in the resist coating processing unit is shorter than the rotation time for the normal substrate, so that the resist on the final substrate is difficult to spread in the resist coating processing unit. The resist film thickness of the final substrate is increased, and a resist film having a uniform film thickness can be formed on all the substrates.
[0088]
  Claims6According to the invention, assuming that a plurality of substrates are processed under the same processing conditions, the thickness of the resist film formed on the main surface of the final substrate is the thickness of the resist film formed on the main surface of the normal substrate. If it is thinner than that, the heating time for the final substrate in the heat treatment unit is shorter than the heating time for the normal substrate, so that the resist solvent component of the final substrate is less likely to evaporate in the heat treatment unit, As a result, the resist film thickness of the final substrate is increased, and a resist film having a uniform film thickness can be formed on all the substrates.
[Brief description of the drawings]
FIG. 1 is a plan view showing the overall configuration of a substrate processing apparatus according to the present invention.
2 is a diagram showing a configuration of a first processing unit group and a second processing unit group of the substrate processing apparatus of FIG. 1; FIG.
3 is an external perspective view of a transfer robot of the substrate processing apparatus of FIG. 1. FIG.
4 is a diagram showing an example of a substrate processing procedure in the substrate processing apparatus of FIG. 1; FIG.
FIG. 5 is a diagram illustrating a state in which a substrate other than the final substrate among a plurality of substrates is carried into and out of the cooling unit.
FIG. 6 is a diagram illustrating a state in which a final substrate among a plurality of substrates is carried into and out of the cooling unit.
[Explanation of symbols]
1 Substrate processing equipment
31a, 31b Transfer arm
AH adhesion strengthening unit
CP1 to CP6 Cooling unit
CR controller
HP1 to HP10 heating unit
ID indexer
IF interface
PG1 first processing unit group
PG2 second processing unit group
SC1, SC2 coating unit
TR transfer robot
W substrate

Claims (7)

A substrate processing apparatus for sequentially applying a resist to a plurality of substrates to form a resist film on the main surface of each substrate,
A resist coating processing unit for supplying a resist to the main surface of the substrate and applying the resist by rotating the substrate;
An adhesion-strengthening treatment unit that heat-treats the substrate to improve the adhesion between the substrate and the resist;
A cooling processing unit that performs cooling processing of the substrate that has been heat-treated in the adhesion strengthening processing unit;
A heat treatment unit for performing heat treatment of the substrate on which the resist coating is performed in the resist coating unit;
Transport means for sequentially transporting the plurality of substrates in the order of the adhesion strengthening processing section, the cooling processing section, the resist coating processing section, and the heating processing section;
Of the plurality of substrates, the final substrate on which resist coating is finally applied, the thickness of the resist film formed on the main surface of the final substrate is usually other than the final substrate of the plurality of substrates. A processing condition changing means for changing a processing condition in each processing unit for the final substrate so as to be substantially the same as the film thickness of the resist film formed on the main surface of the substrate;
A substrate processing apparatus comprising: The substrate processing apparatus according to claim 1,
If the plurality of substrates are processed under the same processing conditions, the thickness of the resist film formed on the main surface of the final substrate is smaller than the thickness of the resist film formed on the main surface of the normal substrate. In this case, the processing condition changing means makes the processing temperature for the final substrate in the cooling processing unit higher than the processing temperature for the normal substrate. The substrate processing apparatus according to claim 1,
Smaller than the thickness of the plurality resist film substrate that have been processed in the same processing conditions are formed on the main surface of the final substrate thickness is the normal resist film formed on the principal surface of the substrate In this case, the processing condition changing means reduces the number of rotations for the final substrate in the resist coating processing unit to be less than the number of rotations for the normal substrate . The substrate processing apparatus according to claim 1,
If the plurality of substrates are processed under the same processing conditions, the thickness of the resist film formed on the main surface of the final substrate is smaller than the thickness of the resist film formed on the main surface of the normal substrate. In this case, the processing condition changing means lowers the processing temperature for the final substrate in the heat processing unit to be lower than the processing temperature for the normal substrate . The substrate processing apparatus according to claim 1,
Smaller than the thickness of the plurality resist film substrate that have been processed in the same processing conditions are formed on the main surface of the final substrate thickness is the normal resist film formed on the principal surface of the substrate In this case, the processing condition changing means makes the rotation time for the final substrate in the resist coating processing unit shorter than the rotation time for the normal substrate . The substrate processing apparatus according to claim 1,
If the plurality of substrates are processed under the same processing conditions, the thickness of the resist film formed on the main surface of the final substrate is smaller than the thickness of the resist film formed on the main surface of the normal substrate. In this case, the processing condition changing means shortens the heating time for the final substrate in the heat processing unit to be shorter than the heating time for the normal substrate . In the substrate processing apparatus in any one of Claims 1-6 ,
A film thickness measuring means for measuring the film thickness of the resist film formed on the main surface of the substrate;
A film thickness difference for obtaining a film thickness difference between a film thickness of the resist film formed on the main surface of the final substrate and a film thickness of the resist film formed on the main surface of the normal substrate, measured by the film thickness measuring unit. A calculation means;
Further comprising
Said processing condition changing means, a substrate processing apparatus, characterized in that to change the process conditions for the final substrate on the basis of the thickness difference.

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