KR102037904B1 - Substrate treating apparatus and substrate treating method - Google Patents

Abstract

The present invention relates to a substrate processing apparatus and a substrate processing method. A substrate processing apparatus according to an embodiment of the present invention includes a plurality of housings, a support member positioned in the housing to support a substrate, and a sensing member sensing a notch direction of a substrate positioned in the support member. Process chambers; And comparing, in each of the process chambers, information on a location where process failure occurs mainly with a failure location of a defective substrate on which a process failure occurs after being processed via the plurality of process chambers. These include a controller that specifies the chamber that caused the process failure.

Description

Substrate treating apparatus and substrate treating method

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

In order to manufacture a semiconductor device or a liquid crystal display, various processes such as photolithography, etching, ashing, ion implantation, thin film deposition, and cleaning are performed on the substrate. Among these, a photographic process is a process for forming a desired circuit pattern on a substrate, and an application process, an exposure process, and a development process are sequentially performed. In the coating step, a photoresist such as a photoresist is applied onto the substrate. In the exposure step, a circuit pattern is exposed on the substrate on which the photoresist film is formed. In the developing step, the exposed area on the substrate is selectively developed.

The present invention is to provide a substrate processing apparatus and a substrate processing method for efficiently processing a substrate.

Another object of the present invention is to provide a substrate processing apparatus and a substrate processing method which are easily maintained.

According to one aspect of the invention, a plurality of process chambers provided to include a housing, a support member positioned in the housing for supporting a substrate, and a sensing member for sensing the notch direction of the substrate located in the support member; And comparing, in each of the process chambers, information on a location where process failure occurs mainly with a failure location of a defective substrate on which a process failure occurs after being processed via the plurality of process chambers. Among them, a substrate processing apparatus including a controller that specifies a chamber that caused a process failure can be provided.

In addition, when the processes performed on the substrates are different from each other, the process chambers may be formed in different positions where the process defects are mainly generated.

In addition, the controller compares the position where the process defect of each of the process chambers is mainly generated when the defective substrate is located in each of the process chambers, and compares the position where the defect substrate occurred to the defective substrate causes the process defect. The chamber can be specified.

The controller may detect a position when the defective substrate is positioned in each of the process chambers through a notch direction of the defective substrate provided by the sensing member.

In addition, the controller may specify the chamber causing the process failure for two or more defective substrates, and then specify the chambers that overlap in each particular as the chamber causing the failure.

According to another aspect of the present invention, a failure occurrence position of a defective substrate on which a process failure occurs after being processed in a plurality of process chambers is compared with information on a position where a process failure mainly occurs in each of the process chambers. A substrate processing method may be provided that specifies which of the fixed chambers has caused a process failure.

In addition, when the processes performed on the substrates are different from each other, the process chambers may be formed in different positions where the process defects are mainly generated.

In addition, when the defective substrate is located in each of the process chambers, the specification may be performed by comparing the position where the process defect of each of the process chambers is mainly generated with the defect position generated in the defective substrate.

In addition, the direction setting when the defective substrates are located in the process chambers may be performed by measuring the notch direction of the defective substrates in the process chambers.

In addition, the specification of the chamber that caused the process failure may be made by specifying the chamber that caused the process failure for two or more defective substrates, and then specifying the chambers that overlap in each particular.

According to one embodiment of the present invention, a substrate processing apparatus and a substrate processing method capable of efficiently processing a substrate may be provided.

In addition, according to an embodiment of the present invention, a substrate processing apparatus and a substrate processing method which can be easily maintained can be provided.

1 is a view of a substrate processing apparatus from above.
FIG. 2 is a view of the installation of FIG. 1 as viewed from the AA direction. FIG.
FIG. 3 is a view of the installation of FIG. 1 viewed in the BB direction. FIG.
4 is a view of the installation of FIG. 1 as viewed from the CC direction.
5 is a view illustrating a process chamber according to an example.
6 is a diagram illustrating a relationship between a sensing member and a controller.
7 is a diagram illustrating a process chamber according to another exemplary embodiment.
8 and 9 are views showing positions where a process failure of a substrate occurs in a process chamber.
10 is a diagram illustrating a substrate in which process failure occurs at one point.
FIG. 11 illustrates the position of the substrate of FIG. 10 in one of the process chambers.
12 is a view showing the position of the substrate of FIG. 10 in another of the process chambers.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be construed as being limited to the following embodiments. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shape of the elements in the drawings are exaggerated to emphasize a more clear description.

The equipment of this embodiment is used to perform a photolithography process on a substrate such as a semiconductor wafer or a flat panel display panel. In particular, the equipment of this embodiment is used to perform a coating process, a developing process, and a pre-exposure treatment process required before and after the liquid immersion exposure to the substrate. Hereinafter, a case where a wafer is used as a substrate will be described.

1 to 4 illustrate a substrate processing apparatus according to an embodiment of the present invention. 1 is a view of the substrate processing apparatus from above, FIG. 2 is a view of the installation of FIG. 1 viewed from the AA direction, FIG. 3 is a view of the installation of FIG. 1 viewed from the BB direction, and FIG. 4 is of the installation of FIG. Is a view from the CC direction.

1 to 4, the substrate processing apparatus 1 may include a load port 100, an index module 200, a first buffer module 300, a coating and developing module 400, and a second buffer module 500. ), Before and after the exposure processing module 600, the interface module 700, the purge module 800, the controller 1000. Load port 100, index module 200, first buffer module 300, coating and developing module 400, second buffer module 500, pre-exposure processing module 600, and interface module 700 Are sequentially arranged in one direction. The purge module 800 may be provided in the interface module 700. In contrast, the purge module 800 may be provided at a position at which the exposure apparatus 900 connected to the rear end of the interface module 700 is connected to the side of the interface module 700, or the like. It can be provided at various locations.

Hereinafter, the load port 100, the index module 200, the first buffer module 300, the coating and developing module 400, the second buffer module 500, the pre-exposure processing module 600, and the interface module ( The direction in which the 700 is disposed is called a first direction 12, and when viewed from the top, a direction perpendicular to the first direction 12 is called a second direction 14, and the first direction 12 and the second direction. A direction perpendicular to the direction 14 is referred to as a third direction 16.

The wafer W is moved in the state accommodated in the cassette 20. At this time, the cassette 20 has a structure that can be sealed from the outside. For example, as the cassette 20, a front open unified pod (FOUP) having a door in front may be used.

Hereinafter, the load port 100, the index module 200, the first buffer module 300, the coating and developing module 400, the second buffer module 500, the pre-exposure processing module 600, the interface module 700. ), And the purge module 800 will be described in detail.

(Load port)

The load port 100 has a mounting table 120 on which a cassette 20 containing wafers W is placed. The mounting table 120 may be provided in plural, and the mounting tables 120 may be arranged in a line along the second direction 14. In FIG. 1 four mounting blocks 120 are provided.

(Index module)

The index module 200 transfers the wafer W between the cassette 20 placed on the mounting table 120 of the load port 100 and the first buffer module 300. The index module 200 has a frame 210, an index robot 220, and a guide rail 230. The frame 210 is generally provided in the shape of an empty rectangular parallelepiped, and is disposed between the load port 100 and the first buffer module 300. The frame 210 of the index module 200 may be provided at a height lower than that of the frame 310 of the first buffer module 300 described later. The index robot 220 and the guide rail 230 are disposed in the frame 210. The index robot 220 drives four axes so that the hand 221 which directly handles the wafer W can be moved and rotated in the first direction 12, the second direction 14, and the third direction 16. This has a possible structure. Index robot 220 has a hand 221, an arm 222, a support 223, and a pedestal 224. The hand 221 is fixed to the arm 222. Arm 222 is provided in a stretchable and rotatable structure. The support 223 is disposed in the longitudinal direction along the third direction 16. Arm 222 is coupled to support 223 to be movable along support 223. The support 223 is fixedly coupled to the pedestal 224. The guide rail 230 is provided such that its longitudinal direction is disposed along the second direction 14. The pedestal 224 is coupled to the guide rail 230 to be linearly movable along the guide rail 230. In addition, although not shown, the frame 210 is further provided with a door opener for opening and closing the door of the cassette 20.

(First buffer module)

The first buffer module 300 has a frame 310, a first buffer 320, a second buffer 330, a cooling chamber 350, and a first buffer robot 360. The frame 310 is provided in the shape of an empty rectangular parallelepiped, and is disposed between the index module 200 and the application and development module 400. The first buffer 320, the second buffer 330, the cooling chamber 350, and the first buffer robot 360 are located in the frame 310. The cooling chamber 350, the second buffer 330, and the first buffer 320 are sequentially disposed along the third direction 16 from below. The first buffer 320 is located at a height corresponding to the coating module 401 of the coating and developing module 400 described later, and the second buffer 330 and the cooling chamber 350 are the coating and developing modules (described later). It is located at a height corresponding to the developing module 402 of 400. The first buffer robot 360 is positioned to be spaced apart from the second buffer 330, the cooling chamber 350, and the first buffer 320 in a second direction 14.

The first buffer 320 and the second buffer 330 temporarily store the plurality of wafers W, respectively. The second buffer 330 has a housing 331 and a plurality of supports 332. The supports 332 are disposed in the housing 331 and are spaced apart from each other along the third direction 16. One support W is placed on each support 332. In the housing 331, the index robot 220, the first buffer robot 360, and the developing unit robot 482 of the developing module 402 described later move the wafer W to the support 332 in the housing 331. It has openings (not shown) in the direction in which the index robot 220 is provided, the direction in which the first buffer robot 360 is provided, and the direction in which the developing unit robot 482 is provided so as to be able to carry in or take out. The first buffer 320 has a structure generally similar to that of the second buffer 330. However, the housing 321 of the first buffer 320 has an opening in the direction in which the first buffer robot 360 is provided and in the direction in which the applicator robot 432 located in the application module 401 described later is provided. The number of supports 322 provided in the first buffer 320 and the number of supports 332 provided in the second buffer 330 may be the same or different. According to an example, the number of supports 332 provided in the second buffer 330 may be greater than the number of supports 322 provided in the first buffer 320.

The first buffer robot 360 transfers the wafer W between the first buffer 320 and the second buffer 330. The first buffer robot 360 has a hand 361, an arm 362, and a support 363. The hand 361 is fixed to the arm 362. The arm 362 is provided in a stretchable structure, allowing the hand 361 to move along the second direction 14. Arm 362 is coupled to support 363 so as to be linearly movable in a third direction 16 along support 363. The support 363 has a length extending from a position corresponding to the second buffer 330 to a position corresponding to the first buffer 320. The support 363 may be provided longer in the up or down direction. The first buffer robot 360 may simply be provided such that the hand 361 is only biaxially driven along the second direction 14 and the third direction 16.

The cooling chambers 350 cool the wafers W, respectively. The cooling chamber 350 has a housing 351 and a cooling plate 352. The cooling plate 352 has an upper surface on which the wafer W is placed and cooling means 353 for cooling the wafer W. As shown in FIG. As the cooling means 353, various methods such as cooling by cooling water or cooling using a thermoelectric element may be used. In addition, the cooling chamber 350 may be provided with a lift pin assembly (not shown) that positions the wafer W on the cooling plate 352. The housing 351 has an index robot 220 so that the developing robot 482 provided to the index robot 220 and the developing module 402 described later can load or unload the wafer W to the cooling plate 352. The provided direction and developing part robot 482 has an opening (not shown) in the provided direction. In addition, the cooling chamber 350 may be provided with doors (not shown) for opening and closing the above-described opening.

Application and development module

The coating and developing module 400 performs a process of applying a photoresist on the wafer W before the exposure process and a process of developing the wafer W after the exposure process. The application and development module 400 has a generally rectangular parallelepiped shape. The application and development module 400 has an application module 401 and a development module 402. The application module 401 and the developing module 402 are arranged to partition into each other in layers. In one example, the application module 401 is located on top of the development module 402.

The application module 401 includes a process of applying a photoresist such as a photoresist to the wafer W, and a heat treatment process such as heating and cooling of the wafer W before and after the resist application process. The application module 401 has a resist application chamber 410, a bake chamber 420, and a transfer chamber 430. The resist application chamber 410, the bake chamber 420, and the transfer chamber 430 are sequentially disposed along the second direction 14. Accordingly, the resist application chamber 410 and the bake chamber 420 are positioned to be spaced apart from each other in the second direction 14 with the transfer chamber 430 interposed therebetween. A plurality of resist coating chambers 410 are provided, and a plurality of resist coating chambers 410 are provided in the first direction 12 and the third direction 16, respectively. In the figure, an example in which six resist application chambers 410 are provided is shown. A plurality of baking chambers 420 may be provided in the first direction 12 and the third direction 16, respectively. In the figure, an example in which six bake chambers 420 are provided is shown. Alternatively, however, the bake chamber 420 may be provided in larger numbers.

The transfer chamber 430 is positioned side by side in the first direction 12 with the first buffer 320 of the first buffer module 300. An applicator robot 432 and a guide rail 433 are positioned in the transfer chamber 430. The transfer chamber 430 has a generally rectangular shape. The applicator robot 432 includes the baking chambers 420, the resist application chambers 400, the first buffer 320 of the first buffer module 300, and the first of the second buffer module 500 described later. The wafer W is transferred between the cooling chambers 520. The guide rail 433 is disposed such that its longitudinal direction is parallel to the first direction 12. The guide rail 433 guides the applicator robot 432 to move linearly in the first direction 12. The applicator robot 432 has a hand 434, an arm 435, a support 436, and a pedestal 437. The hand 434 is fixed to the arm 435. Arm 435 is provided in a flexible structure to allow hand 434 to move in the horizontal direction. The support 436 is provided such that its longitudinal direction is disposed along the third direction 16. Arm 435 is coupled to support 436 so as to be linearly movable in third direction 16 along support 436. The support 436 is fixedly coupled to the pedestal 437, and the pedestal 437 is coupled to the guide rail 433 so as to be movable along the guide rail 433.

The resist application chambers 410 all have the same structure. However, the types of photoresist used in each resist coating chamber 410 may be different from each other. As an example, a chemical amplification resist may be used as the photoresist. The resist coating chamber 410 applies a photo resist on the wafer W. As shown in FIG.

The bake chamber 420 heat-treats the wafer (W). For example, the bake chambers 420 may be a prebake process or a photoresist that heats the wafer W to a predetermined temperature and removes organic matter or moisture from the surface of the wafer W before applying the photoresist. A soft bake process or the like performed after coating on W) is performed, and a cooling process for cooling the wafer W after each heating process is performed. The bake chamber 420 has a cooling plate 421 or a heating plate 422. The cooling plate 421 is provided with cooling means 423 such as cooling water or thermoelectric elements. The heating plate 422 is also provided with heating means 424 such as hot wires or thermoelectric elements. The cooling plate 421 and the heating plate 422 may be provided in one bake chamber 420, respectively. Optionally, some of the baking chambers 420 may have only a cooling plate 421 and others may have only a heating plate 422.

The developing module 402 is a developing process of removing a part of the photoresist by supplying a developing solution to obtain a pattern on the wafer W, and a heat treatment process such as heating and cooling performed on the wafer W before and after the developing process. It includes. The developing module 5402 has a developing chamber 460, a baking chamber 470, and a conveying chamber 480. The developing chamber 460, the baking chamber 470, and the conveying chamber 480 are sequentially disposed along the second direction 14. Therefore, the developing chamber 460 and the baking chamber 470 are positioned to be spaced apart from each other in the second direction 14 with the transfer chamber 480 therebetween. A plurality of developing chambers 460 may be provided, and a plurality of developing chambers 460 may be provided in the first direction 12 and the third direction 16, respectively. In the figure, an example in which six developing chambers 460 are provided is shown. A plurality of baking chambers 470 may be provided in the first direction 12 and the third direction 16, respectively. In the figure, an example in which six bake chambers 470 are provided is shown. However, the baking chamber 470 may alternatively be provided in larger numbers.

The transfer chamber 480 is positioned side by side in the first direction 12 with the second buffer 330 of the first buffer module 300. The developer robot 482 and the guide rail 483 are positioned in the transfer chamber 480. The transfer chamber 480 has a generally rectangular shape. The developing unit robot 482 includes the bake chambers 470, the developing chambers 460, the second buffer 330 and the cooling chamber 350 of the first buffer module 300, and the second buffer module 500. The wafers W are transferred between the second cooling chambers 540. The guide rail 483 is disposed so that its longitudinal direction is parallel to the first direction 12. The guide rail 483 guides the developing unit robot 482 to linearly move in the first direction 12. The developing unit robot 482 has a hand 484, an arm 485, a support 486, and a base 487. The hand 484 is fixedly mounted to the arm 485. Arm 485 is provided in a flexible structure to allow hand 484 to move in the horizontal direction. The support 486 is provided such that its longitudinal direction is disposed along the third direction 16. Arm 485 is coupled to support 486 such that it is linearly movable in third direction 16 along support 486. The support 486 is fixedly coupled to the pedestal 487. The pedestal 487 is coupled to the guide rail 483 so as to be movable along the guide rail 483.

The developing chambers 460 all have the same structure. However, the types of the developer used in each of the developing chambers 460 may be different from each other. The developing chamber 460 removes the light irradiated region of the photoresist on the wafer W. At this time, the area irradiated with light in the protective film is also removed. Depending on the kind of photoresist that is optionally used, only the regions of the photoresist and the protective film to which light is not irradiated may be removed.

The developing chamber 460 has a housing 461, a support plate 462, and a nozzle 463. The housing 461 has a cup shape with an open top. The support plate 462 is located in the housing 461 and supports the wafer (W). The support plate 462 is rotatably provided. The nozzle 463 supplies the developer onto the wafer W placed on the support plate 462. The nozzle 463 has a circular tubular shape and can supply the developer to the center of the wafer W. As shown in FIG. Optionally, the nozzle 463 has a length corresponding to the diameter of the wafer W, and the discharge port of the nozzle 463 may be provided as a slit. In addition, the developing chamber 460 may further be provided with a nozzle 464 for supplying a cleaning solution such as deionized water to clean the surface of the wafer W to which the developing solution is supplied.

The bake chamber 470 heat-treats the wafer (W). For example, the bake chambers 470 are heated after each bake process and a hard bake process that heats the wafer W after the post-baking process that heats the wafer W before the developing process is performed, and after the developing process is performed. And a cooling step of cooling the finished wafer. The bake chamber 470 has a cooling plate 471 or a heating plate 472. The cooling plate 471 is provided with cooling means 473, such as cooling water or thermoelectric elements. Alternatively, the heating plate 472 is provided with heating means 474, such as a hot wire or a thermoelectric element. The cooling plate 471 and the heating plate 472 may each be provided in one bake chamber 470. Optionally, some of the baking chambers 470 may have only a cooling plate 471 and others may have only a heating plate 472.

As described above, in the application and development module 400, the application module 401 and the development module 402 are provided to be separated from each other. In addition, the application module 401 and the developing module 402 may have the same chamber arrangement when viewed from the top.

(Second buffer module)

The second buffer module 500 is provided as a passage through which the wafer W is transported between the application and development module 400 and the pre-exposure processing module 600. In addition, the second buffer module 500 performs a predetermined process on the wafer W, such as a cooling process or an edge exposure process. The second buffer module 500 controls the frame 510, the buffer 520, the first cooling chamber 530, the second cooling chamber 540, the edge exposure chamber 550, and the second buffer robot 560. Have The frame 510 has a rectangular parallelepiped shape. The buffer 520, the first cooling chamber 530, the second cooling chamber 540, the edge exposure chamber 550, and the second buffer robot 560 are located in the frame 510. The buffer 520, the first cooling chamber 530, and the edge exposure chamber 550 are disposed at a height corresponding to the application module 401. The second cooling chamber 540 is disposed at a height corresponding to the developing module 402. The buffer 520, the first cooling chamber 530, and the second cooling chamber 540 are sequentially arranged along the third direction 16. As viewed from the top, the buffer 520 is disposed along the conveyance chamber 430 and the first direction 12 of the application module 401. The edge exposure chamber 550 is disposed spaced apart from the buffer 520 or the first cooling chamber 530 in a second distance 14.

The second buffer robot 560 transfers the wafer W between the buffer 520, the first cooling chamber 530, and the edge exposure chamber 550. The second buffer robot 560 is located between the edge exposure chamber 550 and the buffer 520. The second buffer robot 560 may be provided in a structure similar to that of the first buffer robot 360. The first cooling chamber 530 and the edge exposure chamber 550 perform subsequent processing on the wafers W on which the processing is performed in the coating module 401. The first cooling chamber 530 cools the wafer W on which the process is performed in the application module 401. The first cooling chamber 530 has a structure similar to the cooling chamber 350 of the first buffer module 300. The edge exposure chamber 550 exposes an edge of the wafers W on which the cooling process is performed in the first cooling chamber 530. The buffer 520 temporarily stores the wafer W before the wafers W having been processed in the edge exposure chamber 550 are transferred to the pretreatment module 601 described later. The second cooling chamber 540 cools the wafers W before the wafers W having been processed in the post-processing module 602 described later are transferred to the developing module 402. The second buffer module 500 may further have a buffer added to a height corresponding to the developing module 402. In this case, the wafers W processed in the post-processing module 602 may be temporarily stored in the added buffer and then transferred to the developing module 402.

(Before and After Exposure Processing Module)

When the exposure apparatus 900 performs the liquid immersion exposure process, the exposure before and after processing module 600 may process a process of applying a protective film that protects the photoresist film applied to the wafer W during the liquid immersion exposure. In addition, the pre and post-exposure processing module 600 may perform a process of cleaning the wafer W after the exposure. In addition, when the coating process is performed using the chemically amplified resist, the pre-exposure treatment module 600 may process the post-exposure bake process.

The pre- and post-exposure processing module 600 includes a pretreatment module 601 and a post-processing module 602. The pretreatment module 601 performs a process of processing the wafer W before performing the exposure process, and the post-processing module 602 performs a process of processing the wafer W after the exposure process. The pretreatment module 601 and the aftertreatment module 602 are arranged to partition into one another. In one example, the pretreatment module 601 is located on top of the aftertreatment module 602. The pretreatment module 601 is provided at the same height as the application module 401. The post-processing module 602 is provided at the same height as the developing module 402. The pretreatment module 601 has a protective film applying chamber 610, a baking chamber 620, and a transfer chamber 630. The protective film applying chamber 610, the transfer chamber 630, and the bake chamber 620 are sequentially disposed along the second direction 14. Therefore, the protective film applying chamber 610 and the baking chamber 620 are positioned to be spaced apart from each other in the second direction 14 with the transfer chamber 630 interposed therebetween. A plurality of protective film applying chambers 610 may be provided and disposed along the third direction 16 to layer each other. Optionally, a plurality of protective film applying chambers 610 may be provided in the first direction 12 and the third direction 16, respectively. A plurality of baking chambers 620 may be provided and disposed along the third direction 16 to layer each other. Optionally, a plurality of baking chambers 620 may be provided in the first direction 12 and the third direction 16, respectively.

The transfer chamber 630 is positioned side by side in the first direction 12 with the first cooling chamber 530 of the second buffer module 500. The pretreatment robot 632 is located in the transfer chamber 630. The transfer chamber 630 has a generally square or rectangular shape. The pretreatment robot 632 is provided between the protective film applying chambers 610, the bake chambers 620, the buffer 520 of the second buffer module 500, and the first buffer 720 of the interface module 700 described later. The wafer W is transferred. The preprocessing robot 632 has a hand 633, an arm 634, and a support 635. The hand 633 is fixed to the arm 634. Arm 634 is provided in a stretchable and rotatable structure. Arm 634 is coupled to support 635 to be linearly movable in a third direction 16 along support 635.

The protective film applying chamber 610 applies a protective film on the wafer W to protect the resist film during the liquid immersion exposure. The protective coating chamber 610 has a housing 611, a support plate 612, and a nozzle 613. The housing 611 has a cup shape with an open top. The support plate 612 is located in the housing 611 and supports the wafer (W). The support plate 612 is provided to be rotatable. The nozzle 613 supplies a protective liquid for forming a protective film onto the wafer W placed on the support plate 612. The nozzle 613 has a circular tubular shape and can supply a protection liquid to the center of the wafer W. As shown in FIG. Optionally, the nozzle 613 has a length corresponding to the diameter of the wafer W, and the discharge port of the nozzle 613 may be provided as a slit. In this case, the support plate 612 may be provided in a fixed state. The protective liquid includes a foamable material. As the protective liquid, a material having a low affinity with the photoresist and water may be used. For example, the protective liquid may contain a fluorine-based solvent. The protective film applying chamber 610 rotates the wafer W placed on the support plate 612 and supplies the protective liquid to the center area of the wafer W. FIG.

The baking chamber 620 heat-treats the wafer W on which the protective film is applied. The bake chamber 620 has a cooling plate 621 or a heating plate 622. The cooling plate 621 is provided with cooling means 623, such as cooling water or thermoelectric elements. Alternatively, the heating plate 622 is provided with heating means 624 such as hot wire or thermoelectric element. The heating plate 622 and the cooling plate 621 may each be provided in one bake chamber 620. Optionally, some of the bake chambers 620 may have only a heating plate 622 and others may have only a cooling plate 621.

The aftertreatment module 602 has a cleaning chamber 660, a post exposure bake chamber 670, and a transfer chamber 680. The cleaning chamber 660, the transfer chamber 680, and the post-exposure bake chamber 670 are sequentially disposed along the second direction 14. Accordingly, the cleaning chamber 660 and the post-exposure bake chamber 670 are positioned to be spaced apart from each other in the second direction 14 with the transfer chamber 680 interposed therebetween. The cleaning chamber 660 may be provided in plural and may be disposed along the third direction 16 to layer each other. Optionally, a plurality of cleaning chambers 660 may be provided in the first direction 12 and the third direction 16, respectively. A plurality of bake chambers 670 may be provided after the exposure, and may be disposed along the third direction 16 to layer each other. Optionally, a plurality of post-exposure bake chambers 670 may be provided in the first direction 12 and the third direction 16, respectively.

The transfer chamber 680 is positioned side by side in the first direction 12 with the second cooling chamber 540 of the second buffer module 500 when viewed from the top. The transfer chamber 680 has a generally square or rectangular shape. The post-processing robot 682 is located in the transfer chamber 680. The post-processing robot 682 includes cleaning chambers 660, post-exposure bake chambers 670, a second cooling chamber 540 of the second buffer module 500, and a second of the interface module 700 described below. The wafer W is transported between the buffers 730. The post-processing robot 682 provided to the post-processing module 602 may be provided in the same structure as the pre-processing robot 632 provided to the pre-processing module 601.

The cleaning chamber 660 cleans the wafer W after the exposure process. The cleaning chamber 660 has a housing 661, a support plate 662, and a nozzle 663. The housing 661 has a cup shape with an open top. The support plate 662 is located in the housing 661 and supports the wafer W. As shown in FIG. The support plate 662 is provided to be rotatable. The nozzle 663 supplies the cleaning liquid onto the wafer W placed on the support plate 662. As the cleaning liquid, water such as deionized water may be used. The cleaning chamber 660 supplies the cleaning liquid to the center region of the wafer W while rotating the wafer W placed on the support plate 662. Optionally, while the wafer W is being rotated, the nozzle 663 can be moved linearly or rotationally from the center region of the wafer W to the edge region.

The post-exposure bake chamber 670 heats the wafer W on which the exposure process is performed using far ultraviolet rays. The post-exposure bake process heats the wafer W to amplify an acid generated in the photoresist by exposure to complete the property change of the photoresist. The post-exposure bake chamber 670 has a heating plate 672. The heating plate 672 is provided with heating means 674, such as a hot wire or a thermoelectric element. The post-exposure bake chamber 670 may further include a cooling plate 671 therein. The cooling plate 671 is provided with cooling means 673, such as cooling water or thermoelectric elements. In addition, a bake chamber may optionally be provided with only the cooling plate 671.

As described above, the pretreatment module 601 and the post-treatment module 602 are provided to be completely separated from each other in the pre- and post-exposure processing module 600. In addition, the transfer chamber 630 of the pretreatment module 601 and the transfer chamber 680 of the post-treatment module 602 may be provided in the same size so as to completely overlap each other when viewed from the top. In addition, the protective film applying chamber 610 and the cleaning chamber 660 may be provided in the same size to each other when completely overlapping each other when viewed from the top. In addition, the bake chamber 620 and the post-exposure bake chamber 670 may be provided in the same size, so as to completely overlap each other when viewed from the top.

(Interface module)

The interface module 700 transfers the wafer W between the pre-exposure processing module 600, the purge module 800, and the exposure apparatus 900. The interface module 700 has a frame 710, a first buffer 720, a second buffer 730, and an interface robot 740. The first buffer 720, the second buffer 730, and the interface robot 740 are located in the frame 710. The first buffer 720 and the second buffer 730 are spaced apart from each other by a predetermined distance and disposed to be stacked on each other. The first buffer 720 is disposed higher than the second buffer 730. The first buffer 720 is positioned at a height corresponding to the preprocessing module 601, and the second buffer 730 is disposed at a height corresponding to the postprocessing module 602. As viewed from the top, the first buffer 720 is arranged in a line along the conveyance chamber 630 and the first direction 12 of the pretreatment module 601, and the second buffer 730 is the post-processing module 602. Are positioned to be arranged in a line along the conveyance chamber 630 and the first direction 12.

The interface robot 740 is positioned to be spaced apart from the first buffer 720 and the second buffer 730 in the second direction 14. The interface robot 740 carries the wafer W between the first buffer 720, the second buffer 730, the purge module 800, and the exposure apparatus 900. The interface robot 740 has a structure generally similar to that of the second buffer robot 560.

The first buffer 720 temporarily stores the wafers W processed in the pretreatment module 601 before they are moved to the exposure apparatus 900. The second buffer 730 temporarily stores the wafers W processed in the exposure apparatus 900 before moving to the post-processing module 602. The first buffer 720 has a housing 721 and a plurality of supports 722. The supports 722 are disposed in the housing 721 and are provided spaced apart from each other along the third direction 16. One support W is placed on each support 722. The housing 721 is a direction and pretreatment robot provided with an interface robot 740 so that the interface robot 740 and the pretreatment robot 632 can bring the wafer W into or out of the support 722 into the housing 721. 632 has an opening (not shown) in the direction provided. The second buffer 730 has a structure generally similar to that of the first buffer 720. However, the housing 4531 of the second buffer 730 has openings (not shown) in the direction in which the interface robot 740 is provided and in the direction in which the post-processing robot 682 is provided. The interface module may be provided with only the buffers and the robot as described above without providing a chamber for performing a predetermined process on the wafer.

(Fuzzy module)

The purge module 800 may be disposed in the interface module 700. In detail, the purge module 800 may be disposed at a position facing the first buffer 720 about the interface robot 740. Alternatively, the purge module 800 may be provided at various positions such as a position at which the exposure apparatus 900 at the rear of the interface module 700 is connected or a side of the interface module 700. The purge module 800 performs a gas purge process and a rinse process on a wafer coated with a protective film for protecting the photoresist in the pre- and post-exposure processing module 600.

The controller 950 of FIG. 6 controls the configuration of the substrate processing apparatus 10.

5 is a diagram illustrating a process chamber according to an example, and FIG. 6 is a diagram illustrating a relationship between a sensing member and a controller.

5 and 6, the process chamber 1000 includes a housing 1100, a support member 1200, and a sensing member 1300.

The process chamber 1000 performs a setting process on the substrate. The process chamber 1000 includes the cooling chamber 350, the resist coating chamber 410, the baking chamber 420, the developing chamber 460, the baking chamber 470, the first cooling chamber 530, and the second cooling described above. The chamber 540, the edge exposure chamber 550, the protective film coating chamber 610, the bake chamber 620, the cleaning chamber 660, and the post exposure bake chamber 670 may be used. In the drawings, illustration of the configuration for performing the setting process on the substrate is omitted.

The housing 1100 provides a processing space in which the substrate is processed. An opening 1110 is formed at one side of the housing 1100 to provide a path through which the substrate is moved. The opening 1110 may be opened and closed by a door.

The support member 1200 is positioned inside the housing 1100 to support the substrate. The support member 1200 may be a chuck supporting the substrate, a plate for heating or cooling the substrate when the processing liquid such as a developing solution, a photoresist and the like are applied to the substrate.

The sensing member 1300 senses the location of the notch (n of FIG. 10) formed on the substrate. The substrate is formed with a notch n in which a triangular or arc-shaped cutout is formed at a point where the outer edge region of the lower position to assist the direction setting. The sensing member 1300 may be positioned on an inner side surface of the housing 1100 or adjacent to an inner upper surface of the housing 1100 to be adjacent to the opening. The sensing member 1300 may sense the direction of the notch n formed in the substrate when the substrate is carried in or taken out of the housing 1100. The controller 950 may set a direction in which the notch n faces in the process chamber 1000 through a signal provided by the sensing member 1300.

7 is a diagram illustrating a process chamber according to another exemplary embodiment.

Referring to FIG. 7, the process chamber 1000 may include a housing 1100, a support member 1200, and a sensing member 1300.

The sensing member 1300 senses the location of the notch n formed on the substrate. The sensing member 1300 is positioned on the bottom surface of the inner upper wall of the housing 1100 to detect the substrate positioned on the supporting member 1200. The support member 1200 may detect the notch n direction of the substrate positioned on the support member 1200.

Since the configuration of the process chamber 1000 except for the sensing member 1300 is the same as the process chamber 1000 of FIG. 5, repeated descriptions thereof will be omitted.

8 and 9 are views showing positions where a process failure of a substrate occurs in a process chamber.

Referring to FIGS. 7 and 8, process defects may occur in the process of processing the substrate in the process chamber 1000. When it is confirmed that a process failure occurs in the substrate to be taken out after the process is completed in the substrate processing apparatus 1, a maintenance operation must be performed on the process chamber 1000 causing the failure. However, as two or more processes are performed while moving the substrate through the series of process chambers 1000, it is difficult to specify the process chamber 1000 that causes the process failure among the process chambers 1000 via the substrate.

The direction based on the type of process (or type of process chamber 1000) that the process chamber 1000 performs on the substrate and the position (P1, P2, or opening) in which the process defect mainly occurs in the process chamber 1000. ) Has a correlation. For example, when the process chamber 1000 is a chamber for performing a bake process, the process chamber 1000 may have a problem in that a piping configuration exhausting the inside of the housing 1100 is blocked by the fume, and the process chamber 1000 The position where the process failure is mainly generated within) becomes a portion where the piping configuration is connected with the housing 1100 (for example, the process chamber 1000a of FIG. 8). In addition, when the process chamber 1000 is a chamber that performs a process of applying a processing liquid such as a photosensitive liquid, the process chamber 1000 may have a problem due to an abnormality in the nozzle configuration for applying the chemical liquid, and the process chamber 1000 The position P2 in which the process defect mainly occurs in the inside is one side of the supporting member 1200 where the nozzle configuration is located (for example, the process chamber 1000b of FIG. 8. Information regarding a location where a process failure is mainly generated at may be in a state stored in the controller 950.

FIG. 10 is a diagram illustrating a substrate in which a process failure occurs at one point, FIG. 11 is a diagram illustrating a position of the substrate of FIG. 10 in one of the process chambers, and FIG. 12 is a diagram of FIG. 10 in another of the process chambers. It is a figure which shows the position of a board | substrate.

Referring to FIGS. 10 to 12, process defects among the plurality of process chambers 1000a and 1000b are identified through a relationship between the notch n formed on the defective substrate WT and the position P at which the process defect occurs on the substrate. The process chamber 1000 that caused it may be specified. In the case of the defective substrate WT of FIG. 10 illustrated as an example, a process defect P has occurred in the left region based on the notch n. The controller 950 has information regarding a path in which the bad substrate WT is moved. The controller 950 has information about which direction the notch n of the defective substrate WT is positioned in each process chamber 1000 through the information provided by the sensing member 1300. In the case of FIG. 11, when the defective substrate WT is positioned in the process chamber 1000a, the relationship between the direction of the notch n and the position P1 at which the process defect occurs in the process chamber 1000a is determined. It matches the position of process defect P which generate | occur | produced in the board | substrate WT. In contrast, in FIG. 12, when the substrate is positioned in the process chamber 1000b, the relationship between the direction of the notch n and the position P2 at which the process defect occurs in the process chamber 1000b corresponds to the defective substrate (FIG. 10). It does not coincide with the position of the process defect P generated in WT). Accordingly, the process chamber 1000 causing the process failure of the defective substrate WT is a process chamber 1000a having the same positional relationship as that of FIG. 11 among the process chambers 1000 via the defective substrate WT. Is specified.

In addition, the substrate may have two or more process chambers 1000 performing similar processes in the substrate processing apparatus 11. At this time, the controller 950 may perform the process chamber 1000 specification that causes the above-described process defects for two or more substrates on which process defects occur. In addition, the process chambers 1000 selected through the specific processes may be compared with each other, and the process chambers 1000 commonly included in the two specific processes may be identified as the process chambers 1000 in which the abnormality has occurred.

The foregoing detailed description illustrates the present invention. In addition, the foregoing description shows and describes preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications, and environments. That is, changes or modifications may be made within the scope of the concept of the invention disclosed in the present specification, the scope equivalent to the disclosures described above, and / or the skill or knowledge in the art. The described embodiments illustrate the best state for implementing the technical idea of the present invention, and various modifications required in the specific application field and use of the present invention are possible. Thus, the detailed description of the invention is not intended to limit the invention to the disclosed embodiments. Also, the appended claims should be construed to include other embodiments.

100: load port 200: index module
300: first buffer module 400: application and development module
500: second buffer module 600: before and after exposure processing module
700: interface module

Claims (10)

A plurality of process chambers provided to include a housing, a support member positioned in the housing to support a substrate, and a sensing member configured to sense a notch direction of the substrate positioned on the support member; And
In each of the process chambers, by comparing the information about the position where the process failure occurs according to the process chambers and the defective position of the defective substrate after the process failure after processing through the plurality of process chambers, A controller for specifying a chamber causing a process failure among the plurality of process chambers,
The information on the position where the process failure occurs is formed so that the position where the process failure occurs if the process performed on the substrate is different,
The controller may determine the process failure based on a correlation between the notch direction and a position where a process failure occurs in accordance with the process chambers and a correlation between a notch direction of the defective substrate and a defective position of the defective substrate. A substrate processing apparatus for specifying the chamber that caused the. delete The method of claim 1,
The controller identifies the chamber that caused the process failure by comparing the position where a process failure of each of the process chambers occurs when the defective substrate is located in each of the process chambers and a defective position generated on the defective substrate. Substrate processing apparatus. delete The method of claim 1,
And the controller specifies a chamber that causes process failure for two or more defective substrates, and then specifies the chambers that overlap in each particular as the chamber that caused the failure. The process chamber is compared with a position where a defect occurs in a defective substrate which is processed in a plurality of process chambers and where a process defect occurs according to the process chambers in each of the process chambers. Of the chambers that caused the process failure,
The information on the position where the process failure occurs is formed so that the position where the process failure occurs if the process performed on the substrate is different,
The identification of the chamber that causes the process failure may include whether the correlation between the notch direction of the substrate and the position where the process failure occurs according to the process chambers and the correlation between the notch direction of the defective substrate and the defective position of the defective substrate A substrate processing method carried out based on. delete The method of claim 6,
And the identification is performed by comparing the position where the process defect of each of the process chambers is generated with the defect position generated on the defective substrate when the defective substrate is located in each of the process chambers. delete The method of claim 6,
The specification of the chamber that caused the process failure is made by specifying the chamber that caused the process failure for two or more defective substrates, and then specifying the chambers that overlap in each particular.

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