JP4726173B2 - Liquid crystal matrix projection exposure apparatus and liquid crystal matrix projection exposure method - Google Patents

Description

[0001]
[Industrial field to which the invention pertains]
The present invention relates to an apparatus and a method for transferring a fine pattern such as a semiconductor integrated circuit, an optoelectronic element, a micromachine part or the like onto a substrate to be exposed such as a semiconductor wafer.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, projection exposure apparatuses and projection exposure methods have been widely used to form fine patterns such as semiconductor integrated circuits, optoelectronic elements, and micromachine parts on various substrates such as semiconductor wafers, metal substrates, and glass substrates.
[0003]
FIG. 16 is a block diagram of a conventional projection exposure apparatus. In order to perform projection exposure using this conventional projection exposure apparatus, a reticle formed with a light-shielding body such as chromium on a light transmission substrate such as synthetic quartz or glass, or a frame such as a silicon wafer is used. A stencil mask in which pattern-shaped holes to be an original drawing are formed in various thin films or thin metal plate plates provided is used as the original drawing substrate 83.
[0004]
Projection optical system 5 such as a projection lens, a projection mirror optical system, or an optical system in which the lens and the mirror are appropriately combined is irradiated with illumination light 4 on illumination source 3 composed of a light source and an illumination optical system. Is used to project the pattern on the original drawing substrate 83 onto the substrate 6 to be exposed.
[0005]
A photosensitive material 7 such as a resist is previously applied to the substrate 6 to be exposed, for example, a semiconductor wafer, a metal substrate, a glass substrate, or the like, by coating or spraying. Then, the photosensitive material 7 is exposed to a pattern shape corresponding to the shape of the transmission part of the original drawing substrate 83 by the illumination light beam 4 applied to the original drawing substrate 83.
[0006]
Accordingly, when development is performed after exposure, the photosensitive material 7 in the photosensitive part or the unexposed part is removed depending on whether the photosensitive material 7 is positive or negative, and the pattern shape on the original drawing substrate 83 is Transferred onto the substrate 6 to be exposed.
[0007]
As described above, the conventional projection exposure apparatus and projection exposure method are apparatuses and methods for transferring a pattern on the original drawing substrate 83 such as a reticle and a stencil mask to a photosensitive material on the substrate 6 to be exposed. An original drawing substrate 83 having a pattern corresponding to the pattern was indispensable.
[0008]
If there are any errors or defects in the fine pattern that is formed on the original drawing substrate 83, all products using the transferred pattern will be defective, so inspection and confirmation are important. Expensive. The pattern is not only a shape but also various precisions such as line width, hole size, and their position, so that the pattern becomes particularly expensive when the pattern becomes fine.
[0009]
On the other hand, with the diversification of social consumption trends, products tend to be produced in a variety of small quantities. For example, in semiconductor integrated circuit products, while ICs for specific applications are growing, examples of producing the same product in a very large amount are limited to a very small part such as a memory.
[0010]
In general, micromachine parts and the like, for which many general-purpose products have not yet been available, are produced in an extremely small amount compared to semiconductor integrated circuit products from the beginning.
[0011]
However, since the original drawing substrate 83 having the original pattern is required as long as projection exposure is performed regardless of the amount of production, the price of the original drawing substrate 83 greatly affects the product price in a small-volume product. .
[0012]
In addition, it is almost impossible to change or modify the pattern on the original drawing substrate 83 except in special cases, and it is necessary to recreate the original drawing substrate 83 for each product and each pattern change.
[0013]
Therefore, recently, instead of recreating the conventional original drawing substrate 83 for each product and pattern change, each liquid crystal cell of the liquid crystal panel is used as a matrix switch for controlling transmission and shading of the original drawing substrate 83. The usefulness of the liquid crystal matrix projection exposure apparatus shown in FIG. 17 and the exposure method using the same, in which projection exposure is performed by designating a transmissive part and a light-shielding part in a predetermined arrangement, for example, is the 46th Applied Physics Pp. 742 (1999), Related Journal Lecture Proceedings, Japan Journal of Applied Physics Vol. 38, pp. 324-329 (2000).
[0014]
According to the liquid crystal matrix projection exposure apparatus and the liquid crystal matrix projection exposure method described above, transmission and shading of each cell of the liquid crystal panel 1 can be easily specified from the pattern specifying unit 8 by a keyboard operation or the like. Reference numeral 9 denotes that the liquid crystal panel 1 and the pattern designating unit 8 are connected by a cable or the like.
[0015]
Therefore, the original drawing substrate 83 having a fixed pattern such as a conventional reticle or stencil mask is not necessary.
[0016]
In addition, pattern design data can be easily converted automatically into control commands for each cell of the liquid crystal panel 1 by a personal computer or the like, so that transmission and non-transmission control of each cell of the liquid crystal panel 1 is automatically performed. It is also possible to do it manually.
[0017]
In addition, if the pattern design data is automatically converted into a control command to each cell of the liquid crystal panel 1 by a personal computer or the like, the pattern can be inspected using the design data. It can be greatly reduced, and pattern changes and modifications can be made very easily.
[0018]
[Problems to be solved by the invention]
However, the disclosed liquid crystal matrix projection exposure apparatus and liquid crystal matrix projection exposure method shown in FIG. 17 have the following problems.
[0019]
FIG. 18 is a schematic diagram of the liquid crystal panel 1. As shown in FIG. 18A, there is a boundary portion 84 between each liquid crystal cell 10 of the liquid crystal panel 1, and the boundary portion 84 is always non-transparent regardless of whether the cell portion is designated for transmission or light shielding. It is had.
[0020]
In the case of the simple matrix type liquid crystal panel 1, there is no obstacle in the liquid crystal cell 10, but in the case of the active matrix type liquid crystal panel 1, as shown in FIG. A thin film transistor (TFT) 19 is formed in the liquid crystal cell 10, and the TFT 19 portion is always impermeable in addition to the boundary portion 84.
[0021]
FIG. 19 is an explanatory diagram of a pattern shape formed by a conventional liquid crystal matrix projection exposure apparatus. Even when the simple matrix type liquid crystal panel 1 is used, even if an attempt is made to form a linear photosensitive portion by arranging continuous transmissive liquid crystal cells 86 in the light-shielding liquid crystal cell 85, the exposure amount of the portion corresponding to the boundary portion 84 is small. As a result, constrictions and protrusions were formed in the transfer pattern.
[0022]
For example, as shown in FIG. 19A, when projection exposure is performed by designating the shaded portion of the liquid crystal panel 1 as the light-shielded liquid crystal cell 85 and the white frame portion as the transmissive cell 86, originally a pattern on a straight line is required. When a negative resist is used as the photosensitive material 7, a resist pattern 87 as shown in FIG. 19B is formed, and a constriction 88 occurs in the transfer pattern. Further, when a positive resist is used as the photosensitive material 7, a resist pattern 89 as shown in FIG. 19C is formed, and a projection 90 is formed on the transfer pattern.
[0023]
In general, the resist pattern 87 and the resist pattern 89 are patterns having a size obtained by multiplying the projection exposure magnification with respect to the pattern designated as the transmission part and the light-shielding part of the liquid crystal cell in the liquid crystal panel 1, but the correspondence is difficult to understand. Therefore, in FIG. 19, the line widths of the resist pattern 87 and the resist pattern 89 are drawn in accordance with the size of the liquid crystal cell.
[0024]
In the case of the active matrix type liquid crystal panel 1, since the TFT 19 also becomes an obstacle, the constriction and the protrusion become more prominent.
[0025]
From the viewpoint of response speed, transmission and non-transmission contrast ratio, etc., most of the recent liquid crystal panels 1 use TFTs 19. Since the TFT 19 is generally arranged at the corner of the liquid crystal cell 10, the shape of the transmissive portion of the liquid crystal cell 10 is not rectangular or square when it is present. There is a problem that a larger non-transparent portion connected to this portion is formed, and the constriction 88 and the protrusion 90 of the transfer pattern are further deteriorated.
[0026]
For this reason, measures have been taken to minimize the constriction 88 and the protrusion 90 of the pattern to be formed by making the boundary portion 84 between the liquid crystal cells 10 as thin as possible or making the dimensions of the TFT 19 as small as possible.
[0027]
However, the boundary portion 84 and the TFT 19 in the active matrix type liquid crystal panel 1 are indispensable and cannot be completely eliminated, and there is a limit even if it is made as small as possible. It was difficult to make the protrusion 90 sufficiently small.
[0028]
In the conventional liquid crystal matrix projection exposure apparatus and liquid crystal matrix projection exposure method, the minimum size of the pattern that can be transferred is approximately the size of one liquid crystal cell 10. Therefore, the smaller the size of the liquid crystal cell 10 is preferable for transferring a fine pattern. However, even if the size of the liquid crystal cell 10 is reduced, it is difficult to reduce the size of the boundary portion 84 and the TFT 19 in proportion thereto. Therefore, the smaller the size of the liquid crystal cell 10, the smaller the constriction 88 and the protrusion 90. The problem was difficult to solve.
[0029]
Further, in the conventional liquid crystal matrix projection exposure apparatus and liquid crystal matrix projection exposure method, the unit dimension of the pattern that can be transferred is approximately the size of one liquid crystal cell 10, and therefore, the width of an integral multiple of the size of the liquid crystal cell 10 Only a pattern with a size could be formed. Therefore, a pattern having a width and size smaller than the size of the liquid crystal cell 10 cannot be formed.
[0030]
Further, in the conventional liquid crystal matrix projection exposure apparatus and liquid crystal matrix projection exposure method, since the pattern is transferred according to the arrangement of the liquid crystal cells 10, it is difficult to form the oblique line pattern.
[0031]
[Means for Solving the Problems]
  In order to solve the above-described problems, the present invention provides a liquid crystal panel that designates a pattern shape as a transmissive portion or a non-transmissive portion, an illuminating device that illuminates the liquid crystal panel, and the liquid crystal panel. In a liquid crystal matrix projection exposure apparatus having a projection optical system for projecting a designated pattern onto an exposure substrate,
  Similar to a circle, oval, or a circle or oval with a circular shape, an oval shape, or an arbitrary straight line and / or a curved line, which is close to or in close contact with the liquid crystal panel and restricts the transmission region of the liquid crystal cell of the liquid crystal panel to only a part. The shape of the openingFor all liquid crystal cellsAn opening control plate having,
  The substrate to be exposed is projected and exposed as the first exposure to the extent that the exposed portions of the dotted or adjacent liquid crystal cells that are the transmission portions on the liquid crystal panel slightly overlap with each other through the aperture control plate. ,
  The liquid crystal panel is moved with respect to the position of the liquid crystal panel at the time of the first exposure, or the position of the substrate to be exposed is moved with respect to the position of the substrate to be exposed at the time of the first exposure, and a pattern shape is formed on the liquid crystal panel. Is designated as a transmissive part or a light shielding part, and the exposed substrate is projected and exposed to the designated pattern shape through the aperture control plate.It is characterized by that.
[0032]
The diameter or opposite length or diagonal length of the opening of the opening control plate may be 80% or more of the liquid crystal cell pitch and less than or equal to the liquid crystal cell pitch in each of the x and y directions. As shown in Item 3, when m is an integer of 3 or more in each of the x and y directions, the liquid crystal cell pitch may be set to 2 / m or within a range of -20% to + 20%.
[0033]
Further, as shown in claim 4, it is more preferable that a retracting / entry mechanism for attaching and detaching the opening control plate is provided so that it can be used by switching from conventional exposure. It is further preferable to provide a plurality of opening control plates having different shapes and / or dimensions of the openings, and to have a mechanism for selecting and attaching / detaching an arbitrary opening control plate.
[0034]
  In transferring the pattern, as shown in claim 6, the transmission region of the liquid crystal cell in the liquid crystal panel is formed into a circular shape, an oval shape, or a circular shape or an oval shape formed of an arbitrary straight line and / or curved line. An opening having a similar shape and a diameter or opposite side length or diagonal length in the x and y directions of 80% or more of the liquid crystal cell pitch and less than or equal to the liquid crystal cell pitch in each of the x and y directions.Is limited by the opening control plate corresponding to all the liquid crystal cells, leaving only a part of each liquid crystal cell as a transmission part,
  Designate the pattern shape on the liquid crystal panel as a transmission part or a light-shielding part.While passing the opening of the opening control plateA first step of projecting and exposing the substrate to be exposed in the designated pattern shape;
  The position of the liquid crystal panel is moved in the x direction by ½ of the x direction pitch of the liquid crystal cell with respect to the position of the liquid crystal panel or the substrate to be exposed in the first step, or the position of the substrate to be exposed is changed to the x direction (x direction). (Liquid crystal cell pitch) x (projection exposure magnification) ½, move in the x direction,
  Respecify the pattern shape on the liquid crystal panel as a transmissive part or a light shielding part,While passing through the opening of the opening control plateA second step of projecting and exposing the substrate to be exposed to the designated pattern shape;
  The position of the liquid crystal panel is moved in the y direction by a half of the y direction pitch of the liquid crystal cell with respect to the position of the liquid crystal panel or the exposed substrate in the first step, or the position of the exposed substrate is changed to the y direction (y direction). (Liquid crystal cell pitch) x (projection exposure magnification) ½ in the y direction,
  Respecify the pattern shape on the liquid crystal panel as a transmissive part or a light shielding part,While passing through the opening of the opening control plateA third step of projecting and exposing the substrate to be exposed to the specified pattern shape;
  With respect to the position of the liquid crystal panel or the substrate to be exposed in the first step, the position of the liquid crystal panel is set to the x direction pitch of the liquid crystal cell with respect to the position of the liquid crystal panel or the substrate to be exposed in the first step. Move the half of the y-direction pitch of the liquid crystal cell in the 1/2 and y directions, or move the position of the substrate to be exposed in the x direction (x direction liquid crystal cell pitch) × 1/2 (projection exposure magnification), y direction (X-direction liquid crystal cell pitch) x (projection exposure magnification) ½,
  Respecify the pattern shape on the liquid crystal panel as a transmissive part or a light shielding part,While passing through the opening of the opening control plateAnd a fourth step of projecting and exposing the substrate to be exposed in the designated pattern shape.
[0035]
  According to a seventh aspect of the present invention, the transmission region of the liquid crystal cell in the liquid crystal panel has a circular shape, an oval shape, a circular shape constituted by an arbitrary straight line and / or a curved line, a shape similar to an elliptical shape, and m When the integer is 3 or more, the diameter, the opposite side length, or the diagonal length of the opening in the x and y directions is set to 2 / m of the liquid crystal cell pitch or within the range of -20% to + 20%, respectively.Is limited by the opening control plate corresponding to all the liquid crystal cells, leaving only a part of each liquid crystal cell as a transmission part,
  Designate the pattern shape on the liquid crystal panel as a transmission part or a light-shielding part.While passing the opening of the opening control plateA first step of projecting and exposing the substrate to be exposed in the designated pattern shape;
  When n is an arbitrary positive integer smaller than 0 or m with respect to the position of the liquid crystal panel or the substrate to be exposed in the first step, the position of the liquid crystal panel is set to x with respect to the first exposure position. Move the liquid crystal cell pitch n / m in the direction and / or y direction, or move the substrate to be exposed by a distance corresponding to (cell pitch n / m) × (projection exposure magnification),
  Respecify the pattern shape on the liquid crystal panel as a transmissive part or a light shielding part,While passing through the opening of the opening control plateAnd an arbitrary step of projecting and exposing the substrate to be exposed in the designated pattern shape.
[0036]
DETAILED DESCRIPTION OF THE INVENTION
As described above, the liquid crystal matrix projection exposure apparatus and the liquid crystal matrix projection exposure method of the present invention have a shape and size suitable for forming a pattern in a conventional liquid crystal cell using an aperture control plate. Therefore, setting a small transmission part is an embodiment for solving the problem. It is characterized by changing the way of thinking and increasing the number of opaque parts in the cell.
[0037]
At the same time as limiting the opening of the liquid crystal cell, multiple exposure is performed to form a pattern, thereby forming a smooth transfer pattern with almost no protrusions or constriction, and a pattern finer than the size of the liquid crystal cell. A pattern having a pitch smaller than the liquid crystal cell pitch can be formed. Further, it is possible to form an oblique line pattern that is difficult to form with the conventional liquid crystal matrix projection exposure apparatus and liquid crystal matrix projection exposure method.
[0038]
【Example】
Embodiments of the present invention will be described in detail with reference to the drawings.
1 and 2 are block diagrams of a liquid crystal matrix projection exposure apparatus of the present invention. Proceedings of the 46th Applied Physics Related Conference Lecture 742 (1999) and Japan Journal of Applied Physics Vol. 38, pp. The biggest difference from the conventional apparatus disclosed in 324-329 (2000) is that the liquid crystal panel 1 is brought into close contact with or close to the exit surface as shown in FIG. 1, or the liquid crystal panel 1 as shown in FIG. The aperture control plate 2 is provided in such a manner that only a part of the cell is left as a transmission part of a predetermined shape in close contact with or close to the incident surface and corresponding to the position of each liquid crystal cell.
[0039]
The liquid crystal panel 1 is illuminated by an illuminating device 3 including a light source and an illumination optical system, and the pattern shape on the liquid crystal panel 1 is projected onto the exposure substrate 6 via the projection optical system 5 by the illumination light 4, and the exposure object is exposed. The photosensitive material 7 applied on the substrate 6 is exposed in a shape in which the aperture shape of the aperture control plate 2 is superimposed on the pattern of the transmission portion designated on the liquid crystal panel 1.
[0040]
Reference numeral 8 denotes a pattern designating unit for designating a pattern shape on the liquid crystal panel 1. It comprises a display that displays pattern data as a pattern shape, a keyboard for giving instructions, a computer that processes, stores, and inspects pattern data. A line 9 connecting the liquid crystal panel 1 and the pattern designating portion 8 means that both are connected by a cable or the like.
[0041]
An example of the liquid crystal cell arrangement of the liquid crystal panel 1 and the opening arrangement of the opening control plate 2 is shown in FIG. In order to make the transfer pattern substantially the same in the vertical and horizontal directions, the liquid crystal cell pitch on the liquid crystal panel 1 is preferably equal in the x and y directions, and the liquid crystal cell 10 is preferably square. Therefore, FIG. 3A shows an example of the liquid crystal cell arrangement of the liquid crystal panel 1 when the liquid crystal cell pitch is the same in the x direction and the y direction and the liquid crystal cell 10 is square. On the other hand, FIG. 3B is an example of the opening control plate 2 to which it fits. A circular opening 12 having a diameter of not less than 80% of the liquid crystal cell pitch and not more than the liquid crystal cell pitch is provided in the substrate 11 that does not transmit illumination light.
[0042]
FIG. 4 is a diagram showing in detail the relative positional relationship between the circular aperture 12 of the aperture control plate 2 shown in FIG. 3 and the liquid crystal cell 10, in which 10 is an arbitrary liquid crystal cell having a square shape, 13, 14 , 15, 16 are square liquid crystal cells adjacent to the liquid crystal cell 10, and alternate long and short dash lines 17, 18 are center lines of boundaries between the arbitrary liquid crystal cell 10 and the adjacent liquid crystal cells 13, 14, 15, 16. The circular opening 12 may protrude from the liquid crystal cell 10 as shown in FIG. 4A, or may be accommodated in the liquid crystal cell 10 as shown in FIG.
[0043]
When the TFT 19 exists in the liquid crystal cell 10, as shown in FIG. 4C, the circular opening 12 is prevented from overlapping with the TFT 19 as much as possible. The center of the circular opening 12 is not necessarily coincident with the center of the liquid crystal cell 10.
[0044]
FIG. 5 shows an example of an opening shape other than a circle of the opening control plate 2 in which the liquid crystal cell pitch is equal in the x and y directions and the liquid crystal cell 10 is square. 5A is an example of an opening 20 having an arbitrary curve similar to a circle, FIG. 5B is an example of an opening 21 having chamfered corners of a square, and FIG. 4C is an example of a polygonal opening 22. FIG. 5D, FIG. 5E, and FIG. 5F are examples of the openings 23, 24, and 25 having arbitrary rounded corners of the polygonal openings.
[0045]
Note that the number of corners in the case of a polygonal opening or an opening in which a corner of a polygon is rounded may be arbitrary.
[0046]
Moreover, the curve for giving roundness does not necessarily need to be a circular arc, and may be arbitrary. The side and the curve forming the rounded corner may intersect or touch each other.
[0047]
The aperture control plate 2 may form a hole-like opening in a thin plate or thin film that does not transmit illumination light, and a light-shielding film is provided on a transmissive substrate such as glass or quartz that transmits the illumination light 4. You may remove in the shape of an opening.
[0048]
With the opening control plate 2 having an opening as shown in FIGS. 3, 4, and 5 inserted, the pattern designating unit 8 designates transmission and shading of each liquid crystal cell of the liquid crystal panel 1, and the illumination device 3 The illumination panel 4 illuminates the liquid crystal panel 1 to project a pattern shape designated by transmission and non-transmission of the liquid crystal cell 10 through the projection optical system 5 onto the substrate 6 to be exposed. The attached photosensitive material 7 is exposed.
[0049]
FIG. 6 is a diagram for explaining the liquid crystal matrix projection exposure method of the present invention, and illustrates the relationship between the designation of transmission and light shielding on the liquid crystal panel 1 and the transfer pattern on the substrate 6 to be exposed. For example, as shown in FIG. 6A, the first exposure is performed with the shaded portion as the light-shielding liquid crystal cell 26 and 27 as the transmissive liquid crystal cell in which the transmissive area is limited by the aperture control plate 2. The scale of the liquid crystal matrix is arbitrary, the x-axis and y-axis are taken as shown in the figure, and the distances from the y-axis and x-axis to the illustrated liquid crystal matrix are a and b, respectively.
[0050]
As shown in FIG. 6B, the photosensitive material 7 applied on the substrate 6 to be exposed is exposed to the extent that the exposed portions of the dotted or adjacent transmissive liquid crystal cells 27 slightly overlap each other. Reference numeral 28 denotes an exposed portion of the photosensitive material 7. How the exposed portions overlap and leave depends on the size, shape and exposure amount of the aperture of the aperture control plate 2, the type and thickness of the photosensitive material 7, and the like.
[0051]
In general, the exposure portion 28 of the photosensitive material 7 has a projection exposure magnification with respect to the transmissive liquid crystal cell 27 whose transmission region is limited by the aperture control plate 2, but it is difficult to understand the correspondence. In (b), the size of the exposed portion 28 of the photosensitive material 7 is drawn in accordance with the size of the transmissive liquid crystal cell 27 in which the transmissive region is limited by the aperture control plate 2.
[0052]
Next, the liquid crystal panel 1 is moved by ½ of the liquid crystal cell pitch p, or the exposed substrate 6 is moved by a distance corresponding to (½ of the liquid crystal cell pitch p) × (projection exposure magnification). The second exposure is performed by resetting the transmission and light shielding of the liquid crystal cell. For example, as shown in FIG. 6 (c), the liquid crystal panel 1 is moved in the y direction by ½ of the liquid crystal cell pitch p, the shaded portion is used as the light-shielded liquid crystal cell 29, and 30 is used as the transmission area by the aperture control plate 2. A second exposure is performed as a limited transmissive liquid crystal cell. As a result, reference numeral 31 in FIG. 6D becomes an exposed portion of the photosensitive material 7 by the second exposure. A portion 28 drawn in an overlapping manner is a portion exposed by the first exposure.
[0053]
Next, the liquid crystal panel 1 is moved by a half of the liquid crystal cell pitch p in the direction perpendicular to the second exposure with respect to the position for the first exposure or the substrate 6 to be exposed is ( The third exposure is performed by moving the distance corresponding to ½ of the liquid crystal cell pitch p) × (projection exposure magnification) and resetting the transmission and light shielding of the liquid crystal cell of the liquid crystal panel 1. For example, as shown in FIG. 5 (e), the liquid crystal panel 1 is now moved by ½ of the liquid crystal cell pitch p in the x direction, the shaded portion is used as the light-shielded liquid crystal cell 32, and 33 is transmitted through the aperture control plate 2. The third exposure is performed as a transmissive liquid crystal cell with a limited area. As a result, 34 in FIG. 6 (f) becomes an exposed portion of the photosensitive material 7 by the third exposure. An overlapping portion 35 is a portion exposed by the first exposure and the second exposure.
[0054]
Further, the liquid crystal panel 1 is 1 / of the liquid crystal cell pitch p in both the direction moved during the second exposure and the direction moved during the third exposure with respect to the position of the first exposure. Or the substrate 6 to be exposed is moved by a distance corresponding to (1/2 of the liquid crystal cell pitch p) × (projection exposure magnification) to reset the transmission and non-transmission of the liquid crystal cell of the liquid crystal panel 1. 4 exposure is performed. For example, as shown in FIG. 5 (g), the liquid crystal panel 1 is moved in the x direction and the y direction by ½ of the liquid crystal cell pitch p, the shaded portion is used as the light-shielded liquid crystal cell 36, and 37 is opened. The fourth exposure is performed as a transmissive liquid crystal cell in which the transmissive region is limited by the control plate 2. As a result, reference numeral 38 in FIG. 6H is an exposed portion of the photosensitive material 7 by the fourth exposure. Reference numeral 39 drawn in an overlapping manner is a portion exposed by the first exposure, the second exposure, and the third exposure.
[0055]
When the first exposure, the second exposure, the third exposure, and the fourth exposure are performed as described above, the photosensitive material 7 is exposed a plurality of times in a place where the exposure regions overlap.
[0056]
When performing exposure, the liquid crystal panel 1 or the substrate 6 to be exposed is moved by a predetermined distance, although not shown, the stage on which each is mounted may be moved.
[0057]
By the way, when the pattern is projected and exposed, the optical image of the pattern formed on the exposed substrate 6 by the projection optical system 5 is formed with a spread of intensity distribution with respect to the original pattern on the liquid crystal panel 1. .
[0058]
The spread of the intensity distribution of the pattern light image is mainly determined by the optical characteristics such as the numerical aperture and aberration of the projection optical system 5 and the illumination conditions such as the coherence coefficient of the illumination light 4 that illuminates the liquid crystal panel 1.
[0059]
As a result, the pattern size of the photosensitive material 7 obtained when developing after exposure is not always constant, and depends on the spread of the intensity distribution of the pattern light image formed on the exposed substrate 6 and the exposure amount. fluctuate.
[0060]
Accordingly, the shape and size of the pattern of the photosensitive material 7 exposed in the form of dots by each of the four exposures from the first exposure to the fourth exposure vary depending on the total exposure received at each location. The portions exposed by two or more exposures and their surroundings are affected by the exposure farther from the place where the exposure amount is exposed only once.
[0061]
For this reason, a part of the spot-like photosensitive portions are overlapped, and four exposures from the first exposure to the fourth exposure are performed as shown in FIG. 6, and the exposure corresponding to the size of the opening of the opening control plate 2 is performed. If the amount is selected, the overlapping portions of the patterns that form the valleys of the exposure area are overlapped with each other. Therefore, the light intensity distribution by each exposure is overlapped so that the light intensity at the place where the exposure is performed only once is set to the same level. Can do. That is, by connecting a part of the spot-like exposure portions in a superimposed manner, as shown in FIG. 7, it is possible to form a substantially smoothly continuous transfer pattern 40 similar to the envelope.
[0062]
At this time, there is a problem of how many times the circular fine exposure regions are overlapped and the exposure is repeated so that the pattern 40 is formed smoothly and continuously. However, the radius is generally circular or at intervals shorter than 1.2 times the radius. When exposed, the pattern is almost smooth. Accordingly, the exposure distance interval in the four exposures from the first exposure to the fourth exposure is the minimum appropriate interval. Even if exposure is performed at shorter intervals, the smoothness of the connection state is not improved so much, but the number of exposures increases, so the total required time becomes longer. On the other hand, when exposure is performed at longer distance intervals, pattern connection traces are likely to appear.
[0063]
In the portion where the first exposure and the fourth exposure overlap, the distance between the circular fine exposure regions is larger than when the exposure is overlapped in the x direction and the y direction. Although the unevenness remains, the oblique pattern is formed almost smoothly. As in the past, when the transmissive part is specified in the oblique direction on the liquid crystal panel 1, the corners of the rectangular exposed part are connected to each other, and a gap is not formed between the patterns, or a bill-like pattern is formed. However, the improvement is remarkable compared with it.
[0064]
Note that the exposure order of the four exposures from the first exposure to the fourth exposure is arbitrary, and the order shown in FIG. 5 is not necessarily required.
[0065]
Further, although the liquid crystal panel 1 or the exposed substrate 6 is moved in the + x or + y direction in FIG. 5, it may be moved in the −x or −y direction.
[0066]
When a large number of the same patterns are transferred onto the substrate 6 to be exposed, the four exposures from the first exposure to the fourth exposure may be sequentially repeated. , The second exposure is performed by changing the pattern on the liquid crystal panel 1, the third exposure is performed by changing the pattern on the liquid crystal panel 1 again, and finally the liquid crystal panel 1 is again performed. Exposure in which the pattern on the liquid crystal panel 1 is the same may be performed continuously, such as changing the upper pattern and performing the fourth exposure. Since the number of times of changing the pattern on the liquid crystal panel 1 is reduced, the time required for transferring the pattern can be shortened.
[0067]
The reason why the pattern can be formed almost smoothly is closely related to the shape of the opening of the opening control plate 2 shown in FIG. 5, and is a square or rectangle having sides in the vertical and horizontal directions as in the prior art. Even if a cell is exposed multiple times and a part is overlapped, it does not work.
[0068]
FIG. 8 shows an example in which a plurality of exposures are performed and a part of the cells is overlapped with a square cell as in the prior art. As shown in FIG. 8A, the first exposure is performed with the shaded portion as the light-shielded liquid crystal cell 41 and 42 as the transmissive liquid crystal cell. As shown in FIG. 8B, the photosensitive material 7 applied on the substrate 6 to be exposed is exposed to such an extent that the exposed portions of the dot-like or adjacent transmissive liquid crystal cells 42 slightly overlap each other. Reference numeral 43 denotes an exposed portion of the photosensitive material 7.
[0069]
In general, the exposure portion 43 of the photosensitive material 7 has a size obtained by multiplying the transmissive liquid crystal cell 42 by the projection exposure magnification. However, since the correspondence becomes difficult to understand, the exposure of the photosensitive material 7 is shown in FIG. The size of the portion 43 is drawn in accordance with the size of the transmissive liquid crystal cell 42.
[0070]
Next, as in the present invention, the liquid crystal panel 1 is moved by a half of the liquid crystal cell pitch p, or the exposed substrate 6 is moved by a distance corresponding to (1/2 of the liquid crystal cell pitch p) × (projection exposure magnification). Then, the second exposure is performed by resetting the transmission and non-transmission of the liquid crystal cell of the liquid crystal panel 1. For example, as shown in FIG. 8C, the liquid crystal panel 1 is moved by ½ of the liquid crystal cell pitch p in the y direction, the shaded portion is used as the light-shielding liquid crystal cell 44, and 45 is the transmissive liquid crystal cell. I do. As a result, 46 in FIG. 8D becomes an exposed portion of the photosensitive material 7 by the second exposure. An overlapped portion 43 is a portion exposed by the first exposure.
[0071]
However, in the state where the aperture control plate 2 is not attached as described above, since the exposure is performed twice over the entire liquid crystal cell width, the light intensity distribution spreads outside the place corresponding to the transmissive liquid crystal cell 45 of the substrate 6 to be exposed. A part is made. Accordingly, when the photosensitive material 6 is a positive type, a dent 48 is formed in the resist pattern 47 after development as shown in FIG. 9A, and when the photosensitive material 6 is a negative type, a protrusion is formed on the resist pattern 49 after development. 50 is made.
[0072]
The size of the aperture of the aperture control plate 2 may be smaller, and when m is an integer greater than 3, it is similar to a circle, oval or any straight line and / or curved circle or oval In the shape, the diameter, the opposite side length, or the diagonal length of the opening in the x and y directions may be set to 2 / m of the liquid crystal cell pitch or a range of −20% to + 20% thereof, respectively.
[0073]
FIG. 10 shows an embodiment where m = 3. The figure shows a situation where the photosensitive material 7 is sequentially exposed by a plurality of exposures. The shape of the opening may be the same as in FIG.
[0074]
In this embodiment, first, the size of the opening, the diameter or the opposite side length or the diagonal length in the x and y directions of the opening of the opening control plate 2 is set to 2/3 of the liquid crystal cell pitch p or -20% to + 20% thereof. By setting the transmission and shading of the liquid crystal cell of the liquid crystal panel 1 to be within the range, and performing the first exposure, dots are exposed at intervals corresponding to the liquid crystal cell pitch p as shown in FIG. .
[0075]
Reference numeral 51 denotes an exposed portion of the photosensitive material 7 on the exposed substrate 6. The exposure unit 51 has a size obtained by multiplying the size of the aperture of the aperture control plate 2 by the projection exposure magnification.
[0076]
Next, the liquid crystal panel 1 is moved in the x or y direction by 1/3 of the liquid crystal cell pitch p, or the exposed substrate 6 is moved by a distance corresponding to (1/3 of the liquid crystal cell pitch p) × (projection exposure magnification). The second exposure is performed as shown in FIG. 10B by moving and resetting the transmission and light shielding of the liquid crystal cell of the liquid crystal panel 1. Reference numeral 52 denotes an exposure portion by the second exposure. Here, the case where the liquid crystal panel 1 is moved in the y direction is shown as an example.
[0077]
Further, the liquid crystal panel 1 is moved 2/3 of the liquid crystal cell pitch in the y direction with respect to the position where the first exposure is performed, or the substrate 6 to be exposed is moved in the y direction (2/3 of the liquid crystal cell pitch) × (projection exposure magnification). ), The third exposure is performed by setting the transmission and shading of the cells of the liquid crystal panel 1 again. In FIG. 10C, reference numeral 53 denotes an exposure unit by the third exposure, and 54 denotes an exposure unit by the first exposure and the second exposure.
[0078]
Next, the liquid crystal panel 1 is moved 1/3 of the liquid crystal cell pitch in the x direction with respect to the position where the first exposure is performed, or the substrate 6 to be exposed is moved in the x direction (1/3 of the liquid crystal cell pitch) × (projection exposure). The fourth exposure is performed by moving a distance corresponding to (magnification) and resetting the transmission and shading of the cells of the liquid crystal panel 1. In FIG. 10D, reference numeral 55 denotes an exposure unit by the fourth exposure, and reference numeral 56 denotes an exposure unit by any one of the exposure from the first exposure to the third exposure.
[0079]
Further, the liquid crystal panel 1 is moved 2/3 of the liquid crystal cell pitch in the x direction with respect to the position where the first exposure is performed, or the substrate 6 to be exposed is moved in the x direction (2/3 of the liquid crystal cell pitch) × (projection exposure magnification). ), The fifth exposure is performed by resetting the transmission and shading of the cells of the liquid crystal panel 1. In FIG. 10 (e), 57 is an exposure unit by the fifth exposure, and 58 is an exposure unit by any one of the exposure from the first exposure to the fourth exposure.
[0080]
Next, the liquid crystal panel 1 is moved 1/3 of the liquid crystal cell pitch in the x direction and 2/3 of the liquid crystal cell pitch in the y direction with respect to the position where the first exposure has been performed, or the exposed substrate 6 is moved in the x direction (liquid crystal Move the cell by a distance corresponding to (1/3 of the cell pitch) x (projection exposure magnification) and (2/3 of the liquid crystal cell pitch) x (projection exposure magnification) in the y direction, and reset the transmission and shading of the cells on the liquid crystal panel 1 Then, a sixth exposure is performed. In FIG. 10 (f), 59 is an exposure unit by the sixth exposure, and 60 is an exposure unit by any one of the exposure from the first exposure to the fifth exposure.
[0081]
Further, the liquid crystal panel 1 is moved 2/3 of the liquid crystal cell pitch in the x direction and 1/3 of the liquid crystal cell pitch in the y direction with respect to the position where the first exposure is performed, or the exposed substrate 6 is moved in the x direction (liquid crystal cell pitch). 2/3) × (projection exposure magnification), move in the y direction by a distance corresponding to (1/3 of the liquid crystal cell pitch) × (projection exposure magnification), and reset the transmission and shading of the liquid crystal panel 1 cells. A seventh exposure is performed. In FIG. 10G, reference numeral 61 denotes an exposure part by the seventh exposure, and 62 denotes an exposure part by any one of the exposure from the first exposure to the sixth exposure.
[0082]
FIG. 8 shows only the seventh exposure described above, but if necessary, the liquid crystal panel 1 is 1/3 of the liquid crystal cell pitch in the x direction with respect to the position where the first exposure is performed, y Move the liquid crystal cell pitch in the direction by 1/3 or move the exposed substrate 6 in the x direction (1/3 of the liquid crystal cell pitch) × (projection exposure magnification) and in the y direction (1/3 of the liquid crystal cell pitch) × (projection exposure magnification) ) Is moved by a distance corresponding to (8), and transmission and shading of the cells of the liquid crystal panel 1 are reset and the eighth exposure is performed.
[0083]
If necessary, the liquid crystal panel 1 is moved 2/3 of the liquid crystal cell pitch in the x direction and 2/3 of the liquid crystal cell pitch in the y direction with respect to the position where the first exposure is performed, or the exposed substrate 6 is moved x Move by a distance corresponding to (2/3 of the liquid crystal cell pitch) × (projection exposure magnification) in the direction and (2/3 of the liquid crystal cell pitch) × (projection exposure magnification) in the y direction, and transmit and block the cells of the liquid crystal panel 1 Is reset and the ninth exposure is performed.
[0084]
In addition to the eighth exposure and the ninth exposure, each exposure may be omitted according to the desired pattern shape.
[0085]
In addition, the exposure order of the exposure performed a plurality of times is arbitrary, and the order shown in FIG. 10 is not necessarily required.
[0086]
Further, although the liquid crystal panel 1 or the substrate 6 to be exposed is moved in the + x or + y direction in FIG. 8, it may be moved in the −x or −y direction.
[0087]
If an exposure amount corresponding to the size of the aperture of the aperture control plate 2 is selected by these multiple exposures, as in the case of FIG. 5, the overlapping portions of the patterns that form the valleys of the exposure region overlap. By superimposing the spread of the light intensity distribution due to each exposure, it is possible to make the light intensity the same as the place where the light is exposed only once. That is, by connecting a part of the spot-like exposure portions in a superimposed manner, as shown in FIG. 11, a substantially smooth and continuous pattern 63 similar to the envelope can be formed.
[0088]
When m ≧ 4, when n is 0 or a positive integer smaller than m, move n / m of the liquid crystal cell pitch p in the x and / or y direction with respect to the first exposure position, or The substrate 6 to be exposed is moved by a distance corresponding to (cell pitch n / m) × (projection exposure magnification) to reset the transmission and shading of the cells of the liquid crystal panel 1 and perform exposure one after another.
[0089]
The plurality of exposures may be performed in any order.
[0090]
When exposed in this manner, the photosensitive material 7 on the substrate 6 to be exposed has a shape that envelops all of the portions exposed in a dot-like manner by a plurality of exposures, as shown in FIGS. To be exposed.
[0091]
Therefore, the pattern of the photosensitive material 6 formed after development has a smooth outer shape in which the unevenness corresponding to the joints of the exposed portions is smoothed.
[0092]
The smoothness of the pattern side wall including the cases of FIGS. 6 and 10 is not limited to the shape and size of the opening of the opening control plate 2, the type and thickness of the photosensitive material 7, and the numerical aperture of the projection optical system 5. Depending on the exposure wavelength of the illumination light 4, the degree of coherence, and the like, if the exposure amount is selected, the circle and the polygon are connected and smoothness that cannot be considered as being exposed.
[0093]
Further, even when the exposure amount is not optimal, there is only a deterioration in the pattern due to the liquid crystal cell boundary and the portion corresponding to the TFT as compared with the case where the transfer pattern is connected in units of the entire liquid crystal cell in the conventional projection exposure apparatus and method. Therefore, a pattern having a remarkably smooth outer shape can be obtained.
[0094]
The aperture diameter of the aperture control plate 2 or the opposite side length or diagonal length in the x and y directions is 2 / m of the liquid crystal cell pitch or a range of −20% to + 20% when m is an integer of 3 or more. If it is set within the range, a conventional fine pattern of about 2 / m can be formed as (approximately 2 / m of the liquid crystal cell pitch p) × (projection exposure magnification).
[0095]
Further, exposure is performed by moving the liquid crystal panel 1 by a pattern of (approximately 1 / m of the liquid crystal cell pitch p) (approximately 1 / m of the liquid crystal cell pitch p) (approximately 1 / m of the liquid crystal cell pitch p) x (projection exposure magnification). / M) × (projection exposure magnification) by moving the exposed substrate 6 and performing exposure, it is possible to form a pattern having a fine pitch of 2 / m of the pattern that has been conventionally transferred.
[0096]
FIG. 12 shows, as an example, an example in which a pattern having a 2/3 line width and a 2/3 pitch can be formed by the method shown in FIG. 10 when m = 3. FIG. 12A shows the overlap of exposure locations, and 64 is an exposure location corresponding to one opening of the aperture control plate 2. FIG. 12B shows the pattern shape of the photosensitive material 7 obtained after development. The figure shows the case where a positive resist is used as the photosensitive material 7, wherein 65 is a resist and 66 is a pattern formed by removing the resist after development.
[0097]
In the above description, the liquid crystal cell pitch is assumed to be equal in the x direction and the y direction. However, it is clear that the present invention is effective even if the liquid crystal cell pitch is not necessarily equal in the x direction and the y direction.
[0098]
For example, when the liquid crystal cell has a vertically long liquid crystal and the liquid crystal cell pitch in the y direction is longer than the liquid crystal cell pitch in the x direction, the shape of the opening of the opening control plate 2 may be a shape as illustrated in FIG.
13A is an oval opening 67 made of an arbitrary curve, FIGS. 13B and 13C are polygonal openings 68 and 69, FIG. 13D, FIG. 13E and FIG. (F) is a shape 70, 71, 72 with rounded corners of the polygon. The size of the opening and the distance to move the liquid crystal panel 1 and the substrate 6 to be exposed at the time of exposure may be determined based on the liquid crystal cell pitch in each direction separately for the x direction and the y direction.
[0099]
By the way, when a pattern is formed by superposing a plurality of exposures as described above according to the present invention, the time required for pattern formation becomes longer depending on the number of exposures. Therefore, it is more convenient to configure so that the opening control plate 2 having an appropriately sized opening can be attached as necessary.
[0100]
FIG. 14 shows a liquid crystal matrix projection exposure apparatus of the present invention provided with a retracting / entry mechanism for attaching / detaching the aperture control plate 2. The carriage 74 on which the aperture control plate 2 is mounted moves on the guide mechanism 73, and the aperture control plate 2 in the retracted position indicated by the solid line in the figure is carried into the use position 75 indicated by the two-dot chain line.
[0101]
When the transferred pattern may have some dents or protrusions, the opening control plate 2 is retracted, and the opening control plate 2 is mounted when a smooth pattern is required.
[0102]
A retracting / entering mechanism for attaching and detaching the opening control plate 2 may be arbitrary, and a retracting / entering mechanism using a rotating arm may be provided as shown in FIG. .
[0103]
FIG. 15 shows a liquid crystal matrix projection exposure apparatus in which a plurality of aperture control plates can be replaced. A plurality of opening control plates are prepared in the opening control plate stocker 76. In the figure, three aperture control plates indicated by 77, 78, and 79 are drawn, but the number of stocks is arbitrary.
[0104]
A rotary arm 81 that rotates and moves up and down while holding the aperture control plate on the rotary column 80 is attached, and a required aperture control plate is selected and mounted on the liquid crystal panel 1.
[0105]
Also in this case, the retracting / entry mechanism for attaching and detaching the opening control plate may be arbitrary, and as shown in FIG. 14, the carriage on which the opening control plates 77, 78, and 79 are moved on the guide mechanism, or the telescopic mechanism You may use an arm to do. In addition, 82 shown with the dashed-two dotted line has shown the use position of the opening control board.
[0106]
【The invention's effect】
As described above, according to the liquid crystal matrix projection exposure apparatus and the liquid crystal matrix projection exposure method of the present invention, even if there is a boundary between the liquid crystal cells where the exposure light beam is not transmitted, Even if a TFT that does not transmit exposure light is provided, it is possible to transfer and form a pattern having a smooth outer shape that is not conspicuously connected.
[0107]
Also, the oblique line pattern can be transferred and formed much more smoothly than before.
[0108]
Furthermore, by reducing the size of the aperture of the aperture control plate, even if the liquid crystal cell size and the liquid crystal cell pitch of the liquid crystal panel to be specified are the same, it is possible to transfer a finer pattern and a pattern with a smaller pattern pitch than the conventional one. it can.
A pattern having a smaller pattern pitch than the conventional one can be transferred.
[0109]
Note that by reducing the size of the aperture of the aperture control plate, a plurality of exposures are required. However, since exposure is performed at a distance interval of an integral number of the liquid crystal cell pitch, an increase in the number of exposures is the minimum necessary. Number of times.
[Brief description of the drawings]
FIG. 1 is a block diagram of a liquid crystal matrix projection exposure apparatus of the present invention.
FIG. 2 is another block diagram of the liquid crystal matrix projection exposure apparatus of the present invention.
FIG. 3 is a relationship between a cell arrangement of a liquid crystal panel and an opening of an opening control plate.
FIG. 4 is a detailed view of the positional relationship between the liquid crystal cell and the opening of the opening control plate.
FIG. 5 is an example of an opening shape of an opening control plate for a square liquid crystal cell.
FIG. 6 is an explanatory diagram of a liquid crystal matrix projection exposure method of the present invention.
7 is a pattern shape transferred by the method of the present invention shown in FIG.
FIG. 8 shows an exposure state when connection exposure is performed without using an aperture control plate.
FIG. 9 shows a transfer pattern shape when connection exposure is performed without using an aperture control plate.
FIG. 10 is an explanatory diagram of another liquid crystal matrix projection exposure method of the present invention.
11 is a pattern shape transferred by the method of the present invention shown in FIG.
FIG. 12 is an explanatory diagram of an example in which a pattern with a fine width and a fine pitch can be formed.
FIG. 13 is an example of an opening shape of an opening control plate for liquid crystal cells having different liquid crystal cell pitches in the x and y directions.
FIG. 14 is a block diagram of a liquid crystal matrix projection exposure apparatus of the present invention provided with a retracting / entry mechanism for attaching and detaching an aperture control plate.
FIG. 15 is a block diagram of a liquid crystal matrix projection exposure apparatus of the present invention in which a plurality of aperture control plates can be replaced.
FIG. 16 is a block diagram of a projection exposure apparatus using a conventional original drawing substrate.
FIG. 17 is a block diagram of a conventional liquid crystal matrix projection exposure apparatus.
18 is a schematic diagram of the liquid crystal panel 1. FIG.
FIG. 19 is an explanatory diagram of a pattern shape formed by a conventional liquid crystal matrix projection exposure apparatus.
[Explanation of symbols]
1 LCD panel
2 Opening control plate
3 Lighting equipment
4 Illumination light
5 Projection optical system
6 Substrate to be exposed
7 Photosensitive material
8 Pattern specification part
10 Liquid crystal cell
20, 21, 22, 23, 24, 25 Opening shape examples
26 29, 32, 36 Light-shielding liquid crystal cell
27, 30, 33, 37 Transmission liquid crystal cell
28, 31, 34, 35, 38, 39 Exposure part
40 Transcription pattern
73 Guide mechanism
74 Carriage
76 Opening control plate stocker
80 Rotating prop
81 Rotating arm

Claims (7)

Liquid crystal matrix projection having a liquid crystal panel designating a pattern shape as a transmission part or non-transmission part, an illuminating device for illuminating the liquid crystal panel, and a projection optical system for projecting the pattern designated by the liquid crystal panel onto a substrate to be exposed In the exposure apparatus,
Similar to a circle, oval, or a circle or oval with a circular shape, an oval shape, or an arbitrary straight line and / or a curved line, which is close to or in close contact with the liquid crystal panel and restricts the transmission region of the liquid crystal cell of the liquid crystal panel to only a part. An aperture control plate having an aperture of the shape corresponding to all the liquid crystal cells is provided ,
The substrate to be exposed is projected and exposed as the first exposure to the extent that the exposed portions of the dotted or adjacent liquid crystal cells that are the transmission portions on the liquid crystal panel slightly overlap with each other through the aperture control plate. ,
The liquid crystal panel is moved with respect to the position of the liquid crystal panel at the time of the first exposure, or the position of the substrate to be exposed is moved with respect to the position of the substrate to be exposed at the time of the first exposure, and a pattern shape is formed on the liquid crystal panel. A liquid crystal matrix projection exposure apparatus characterized in that the substrate to be exposed is projected and exposed to the specified pattern shape through the aperture control plate.   2. A liquid crystal matrix projection exposure apparatus according to claim 1, wherein the aperture control plate has a diameter or opposite side length or diagonal length in the x and y directions of 80% or more of the liquid crystal cell pitch and less than or equal to the liquid crystal cell pitch in each of the x and y directions. A liquid crystal matrix projection exposure apparatus comprising:   2. The liquid crystal matrix projection exposure apparatus according to claim 1, wherein when m is an integer of 3 or more, the diameter or opposite side length or diagonal length of the aperture in the x and y directions is 2 of the liquid crystal cell pitch in each of the x and y directions. / M or a liquid crystal matrix projection exposure apparatus having an aperture control plate set in the range of -20% to + 20% Liquid crystal matrix projection having a liquid crystal panel designating a pattern shape as a transmission part or non-transmission part, an illuminating device for illuminating the liquid crystal panel, and a projection optical system for projecting the pattern designated by the liquid crystal panel onto a substrate to be exposed In the exposure apparatus,
Similar to a circle, oval, or a circle or oval with a circular shape, an oval shape, or an arbitrary straight line and / or a curved line, which is close to or in close contact with the liquid crystal panel and restricts the transmission region of the liquid crystal cell of the liquid crystal panel to only a part. An aperture control plate having an aperture of the shape corresponding to all the liquid crystal cells is provided,
The substrate to be exposed is projected and exposed as the first exposure to the extent that the exposed portions of the dotted or adjacent liquid crystal cells that are the transmission portions on the liquid crystal panel slightly overlap with each other through the aperture control plate. ,
The liquid crystal panel is moved with respect to the position of the liquid crystal panel at the time of the first exposure, or the position of the substrate to be exposed is moved with respect to the position of the substrate to be exposed at the time of the first exposure, and a pattern shape is formed on the liquid crystal panel. Is designated as a transmissive part or a light-shielding part, and the substrate to be exposed is projected and exposed to the designated pattern shape through the opening control plate,
A liquid crystal matrix projection exposure apparatus having a retract / entry mechanism for attaching and detaching the aperture control plate Liquid crystal matrix projection having a liquid crystal panel designating a pattern shape as a transmission part or non-transmission part, an illuminating device for illuminating the liquid crystal panel, and a projection optical system for projecting the pattern designated by the liquid crystal panel onto a substrate to be exposed In the exposure apparatus,
Similar to a circle, oval, or a circle or oval with a circular shape, an oval shape, or an arbitrary straight line and / or a curved line, which is close to or in close contact with the liquid crystal panel and restricts the transmission region of the liquid crystal cell of the liquid crystal panel to only a part. A plurality of aperture control plates having apertures in the shape corresponding to all the liquid crystal cells are provided with different shapes and / or dimensions of the apertures,
The substrate to be exposed is projected and exposed as the first exposure to the extent that the exposed portions of the dotted or adjacent liquid crystal cells that are the transmission portions on the liquid crystal panel slightly overlap with each other through the aperture control plate. ,
The liquid crystal panel is moved with respect to the position of the liquid crystal panel at the time of the first exposure, or the position of the substrate to be exposed is moved with respect to the position of the substrate to be exposed at the time of the first exposure, and a pattern shape is formed on the liquid crystal panel. Is designated as a transmissive part or a light-shielding part, and the substrate to be exposed is projected and exposed to the designated pattern shape through the opening control plate,
A liquid crystal matrix projection exposure apparatus having a mechanism for selecting and attaching / detaching an arbitrary aperture control plate. The transmissive region of the liquid crystal cell in the liquid crystal panel has a circular shape, an oval shape, a circular shape constituted by an arbitrary straight line and / or curved line, a shape similar to an elliptical shape, a diameter in the x and y directions, or an opposite side length or diagonal. The length is limited by an aperture control plate having an opening corresponding to all the liquid crystal cells with a length of 80% or more of the liquid crystal cell pitch and less than or equal to the liquid crystal cell pitch in each of the x and y directions. Leave,
A first step of designating a pattern shape on the liquid crystal panel as a transmissive portion or a light shielding portion, and projecting and exposing the substrate to be exposed to the designated pattern shape while passing through the opening of the opening control plate ;
The position of the liquid crystal panel is moved in the x direction by ½ of the x direction pitch of the liquid crystal cell with respect to the position of the liquid crystal panel or the substrate to be exposed in the first step, or (Liquid crystal cell pitch) x (projection exposure magnification) ½, move in the x direction,
A second step of re-designating the pattern shape on the liquid crystal panel as a transmission part or a light-shielding part, and projecting and exposing the substrate to be exposed to the designated pattern shape while passing through the opening of the opening control plate ;
The position of the liquid crystal panel is moved in the y direction by a half of the y direction pitch of the liquid crystal cell with respect to the position of the liquid crystal panel or the exposed substrate in the first step, or the position of the exposed substrate is changed to the y direction (y direction). (Liquid crystal cell pitch) x (projection exposure magnification) ½ in the y direction,
A third step of re-designating the pattern shape on the liquid crystal panel as a transmissive portion or a light-shielding portion, and projecting and exposing the substrate to be exposed to the designated pattern shape while passing through the opening of the opening control plate ;
With respect to the position of the liquid crystal panel or the substrate to be exposed in the first step, the position of the liquid crystal panel is set to the x direction pitch of the liquid crystal cell with respect to the position of the liquid crystal panel or the substrate to be exposed in the first step. Move the half of the y-direction pitch of the liquid crystal cell in the 1/2 and y directions, or move the position of the substrate to be exposed in the x direction (x direction liquid crystal cell pitch) × 1/2 (projection exposure magnification), y direction (X-direction liquid crystal cell pitch) x (projection exposure magnification) ½,
And a fourth step of re-designating the pattern shape on the liquid crystal panel as a transmissive portion or a light-shielding portion, and projecting and exposing the substrate to be exposed to the designated pattern shape while passing through the opening of the opening control plate. Liquid crystal matrix projection exposure method characterized When the transmission region of the liquid crystal cell in the liquid crystal panel has a circular shape, an oval shape, a circular shape constituted by an arbitrary straight line and / or curved line, or a shape similar to an oval, and m is an integer of 3 or more, x, An aperture control plate having openings corresponding to all liquid crystal cells, with the diameter or opposite side length or diagonal length of the opening in the y direction being set to 2 / m of the liquid crystal cell pitch or a range of -20% to + 20% thereof, respectively. Limit and leave only a part of each liquid crystal cell as a transmission part,
A first step of designating a pattern shape on the liquid crystal panel as a transmissive portion or a light shielding portion, and projecting and exposing the substrate to be exposed to the designated pattern shape while passing through the opening of the opening control plate ;
When n is an arbitrary positive integer smaller than 0 or m with respect to the position of the liquid crystal panel or the substrate to be exposed in the first step, the position of the liquid crystal panel is set to x with respect to the first exposure position. Move the liquid crystal cell pitch n / m in the direction and / or y direction, or move the substrate to be exposed by a distance corresponding to (cell pitch n / m) × (projection exposure magnification),
And a step of re-designating the pattern shape on the liquid crystal panel as a transmissive portion or a light-shielding portion, and projecting and exposing the substrate to be exposed to the designated pattern shape while passing through the opening of the opening control plate. Liquid crystal matrix projection exposure method

Images