CA2273387A1 - Compositions and methods involving direct write optical lithography - Google Patents
Compositions and methods involving direct write optical lithography Download PDFInfo
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- CA2273387A1 CA2273387A1 CA002273387A CA2273387A CA2273387A1 CA 2273387 A1 CA2273387 A1 CA 2273387A1 CA 002273387 A CA002273387 A CA 002273387A CA 2273387 A CA2273387 A CA 2273387A CA 2273387 A1 CA2273387 A1 CA 2273387A1
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/70—Microphotolithographic exposure; Apparatus therefor
- G03F7/70216—Mask projection systems
- G03F7/70283—Mask effects on the imaging process
- G03F7/70291—Addressable masks, e.g. spatial light modulators [SLMs], digital micro-mirror devices [DMDs] or liquid crystal display [LCD] patterning devices
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- B01J19/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
- B01J19/0046—Sequential or parallel reactions, e.g. for the synthesis of polypeptides or polynucleotides; Apparatus and devices for combinatorial chemistry or for making molecular arrays
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- B82—NANOTECHNOLOGY
- B82Y—SPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
- B82Y30/00—Nanotechnology for materials or surface science, e.g. nanocomposites
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- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
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- G03F7/70216—Mask projection systems
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03F—PHOTOMECHANICAL PRODUCTION OF TEXTURED OR PATTERNED SURFACES, e.g. FOR PRINTING, FOR PROCESSING OF SEMICONDUCTOR DEVICES; MATERIALS THEREFOR; ORIGINALS THEREFOR; APPARATUS SPECIALLY ADAPTED THEREFOR
- G03F7/00—Photomechanical, e.g. photolithographic, production of textured or patterned surfaces, e.g. printing surfaces; Materials therefor, e.g. comprising photoresists; Apparatus specially adapted therefor
- G03F7/70—Microphotolithographic exposure; Apparatus therefor
- G03F7/70383—Direct write, i.e. pattern is written directly without the use of a mask by one or multiple beams
- G03F7/704—Scanned exposure beam, e.g. raster-, rotary- and vector scanning
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Abstract
An improved optical photolithography system and method provides predetermined light patterns generated by a direct write system without the use of photomasks. The Direct Write System provides predetermined light patterns projected on the surface of a substrate (e.g., a wafer) by using a computer controlled means for dynamically generating the predetermined light pattern, e.g., a spatial light modulator. Image patterns are stored in a computer and through electronic control of the spatial light modulator directly illuminate the wafer to define a portion of the polymer array, rather than being defined by a pattern on a photomask. Thus, in the Direct Write System each pixel is illuminated with an optical beam of suitable intensity and the imaging (printing) of an individual feature is determined by computer control of the spatial light modulator at each photolithographic step without the use of a photomask. The Direct Write System including a spatial light modulator is particularly useful in the synthesis of DNA arrays and provides an efficient means for polymer array synthesis by using spatial light modulators to generate a predetermined light pattern that defines the image patterns of a polymer array to be deprotected.
Description
PATENT APPLICATION
Attorney Docket No. 3848.80505 OPTICAL LITHOGRAPHY
12 This application relates to provisional application Ser. No. 60/087,333 filed 13 May 29, 1998 which is hereby incorporated by reference in its entirety.
Technical Field of the Invention 16 This invention relates to optical lithography and more particularly to direct 17 write optical lithography.
18 Description of the Related Art 19 Polymer arrays, such as the GeneChip~ probe array (Affymetlzx, Inc., Santa Clara, CA), can be synthesized using light-directed methods described, for example, in U.S. Patent 21 Nos. 5,143,854; 5,424,186; 5,510,270; 5, 800,992; 5,445,934; 5,744,305;
Attorney Docket No. 3848.80505 OPTICAL LITHOGRAPHY
12 This application relates to provisional application Ser. No. 60/087,333 filed 13 May 29, 1998 which is hereby incorporated by reference in its entirety.
Technical Field of the Invention 16 This invention relates to optical lithography and more particularly to direct 17 write optical lithography.
18 Description of the Related Art 19 Polymer arrays, such as the GeneChip~ probe array (Affymetlzx, Inc., Santa Clara, CA), can be synthesized using light-directed methods described, for example, in U.S. Patent 21 Nos. 5,143,854; 5,424,186; 5,510,270; 5, 800,992; 5,445,934; 5,744,305;
5,384,261 and 22 5,677,195 and PCT published application no. WO 95/11995, which are hereby incorporated 23 by reference in their entireties. As an example, light-directed synthesis of oligonucleotides 24 employs S'-protected nucleosidephosphoramidite "building blocks." The 5'-protecting groups may be either photolabile or acid-labile. A plurality of polymer sequences in predefined 26 regions are synthesized by repeated cycles of deprotection (selective removal of the protective 27 group) and coupling. Coupling (i.e., nucleotide or monomer addition) occurs only at sites 28 that have been deprotected. Three methods of light-directed synthesis are:
use of photolabile PATENT APPLICATION
Attorney Docket No. 3848.80505 1 protecting groups and direct photodeprotection (DPD); use of acid-labile 4,4'-dimethoxytrityl 2 (DMT) protecting groups and a photoresist; use of DMT protecting groups and a polymer 3 film that contains a photoacid generator (PAG).
4 These methods have many process steps similar to those used in semiconductor integrated circuit manufacturing. These methods also often involve 6 the use of photomasks (masks) that have a predefined image pattern which permits the 7 light used for synthesis of the polymer arrays to reach certain regions of a substrate 8 but not others. The substrate can be non-porous, rigid, semi-rigid,etc. It can be 9 formed into a well, a trench, a flat surface, etc. The substrate can include solids, such as siliceous substances such as silicon, glass, fused silica, quartz, and other solids such 11 as plastics and polymers, such as polyacrylamide, polystyrene, polycarbonate, etc.
12 Typically, the solid substrate is called a wafer from which individual chips are made 13 (See the U.S. patents above which are incorporated herein by reference). As such, the 14 pattern formed on the mask is projected onto the wafer to define which portions of the wafer are to be deprotected and which regions remain protected. See, for example, 16 U.S. Patent Nos. 5,593,839 and 5,571,639 which are hereby incorporated by reference 17 in their entireties.
18 The lithographic or photochemical steps in the synthesis of nucleic acid arrays 19 may be performed by contact printing or proximity printing using photomasks. For example, an emulsion or chrome-on-glass mask is placed in contact with the wafer, or 21 nearly in contact with the wafer, and the wafer is illuminated through the mask by 22 light having an appropriate wavelength. However, masks can be costly to make and 23 use and are capable of being damaged or lost.
PATENT APPLICATION
Attorney Docket No. 3848.80505 1 In many cases a different mask having a particular predetermined image 2 pattern is used for each separate photomasking step, and synthesis of a wafer 3 containing many chips requires a plurality of photomasking steps with different image 4 patterns. For example, synthesis of an array of 20mers typically requires approximately seventy photolithographic steps and related unique photomasks.
So, 6 using present photolithographic systems and methods, a plurality of different image 7 pattern masks must be pre-generated and changed in the photolithographic system at 8 each photomasking step. This plurality of different pattern masks adds lead time to 9 the process and complexity and inefficiency to the photolithographic system and method. Further, contact printing using a mask can cause defects on the wafer so that 11 some of the reaction sites are rendered defective. Thus, a photolithographic system 12 and method that does not require such masks and obviates such difficulties would be 13 generally useful in providing a more efficient and simplified lithographic process.
SUMMARY OF THE INVENTION
16 In view of the abQVe, one advantage of the invention is providing an improved 17 and simplified system and method for optical lithography.
18 Another advantage of the present invention is providing an optical lithography 19 system and method that dynamically generates an image using a computer and reconfigurable light modulator.
21 A further advantage of the present invention is providing an optical 22 lithography system and method that does not use photomasks.
PATENT APPLICATION
Attorney Docket No. 3848.80505 1 A still further advantage of the present invention is providing an optical 2 lithography system and method that uses computer generated electronic control 3 signals and a spatial light modulator, without any photomask, to project a 4 predetermined light pattern onto a surface of a substrate for the purposes of deprotecting various areas of a polymer array.
6 According to one aspect of the invention, polymer array synthesis is performed using 7 a system without photomasks.
8 According to a second aspect of the invention, polymer array synthesis is performed 9 using a system with a transmissive spatial light modulator and without a lens and photomask.
According to another aspect of the invention, a Direct Write System transmits image 11 patterns to be formed on the surface of a substrate (e.g., a wafer). The image patterns are 12 stored in a computer. The Direct Write System projects light patterns generated from the 13 image patterns onto a surface of the substrate for light-directed polymer synthesis (e.g., 14 oligonucleotide). The light patterns are generated by a spatial light modulator controlled by a computer, rather than being defined by a pattern on a photomask. Thus, in the Direct Write 16 System each pixel is illuminated with an optical beam of suitable intensity and the imaging 17 (printing) of an individual feature on a substrate is determined dynamically by computer 18 control.
19 According to a further aspect of the invention, polymer array synthesis is accomplished using a class of devices known as spatial light modulators to define the image 21 pattern of the polymer array to be deprotected.
PATENT APPLICATION
Attorney Docket No. 3848.80505 1 An even further aspect of the present invention provides methods for synthesizing 2 polymer arrays using spatial light modulators and the polymer arrays synthesized using the 3 methods taught herein.
4 As can be appreciated by one skilled in the art, the invention is relevant to optical lithography in general, and more specifically to optical lithography for polymer array 6 synthesis using photolithograpic processes. However, it is inherent that the invention is 7 generally applicable to eliminating the need for a photomask in optical lithography.
The above objects, features, and advantages of the present invention will become more 11 apparent from the following detailed description taken with the accompanying drawings in 12 which:
13 Figure 1 shows a first embodiment of the invention having a light source, a reflective 14 spatial light modulator, such as a micro-mirror array, and a lens.
~ Figure 2 is a diagrammatic representation of a second embodiment of the invention 16 employing an array of, for example, micro-lenses.
17 Figure 3 illustrates a micro-lens array in the form of Fresnel Zone Plates, which may 18 be used in the invention.
19 Figure 4 shows a third embodiment of the invention having a transmissive spatial light modulator.
PATENT APPLICATION
Attorney Docket No. 3848.80505 2 The present invention refers to articles and patents that contain useful supplementary 3 information. These references are hereby incorporated by reference in their entireties.
4 The presently preferred invention is based on the principle that a Direct Write Optical Lithography System will significantly improve the cost, quality, and efficiency of polymer 6 array synthesis by providing a maskless optical lithography system and method where 7 predetermined image patterns can be dynamically changed during photolithographic 8 processing. As such, an optical lithography system is provided to include a means for 9 dynamically changing an intended image pattern without using a photomask.
One such means includes a spatial light modulator that is electronically controlled by a computer to 11 generate unique predetermined image patterns at each photolithograpic step in polymer array 12 synthesis. The spatial light modulators can be, for example, micromachined mechanical 13 modulators or microelectronic devices (e.g. liquid crystal display (LCD)).
The Direct Write 14 System of the present invention using such spatial light modulators is particularly useful in 1 S the synthesis of polymer arrays, such as polypeptide, carbohydrate, and nucleic acid arrays.
16 Nucleic acid arrays typically include polynucleotides or oligonucleotides attached to glass, 17 for example, Deoxyribonucleic Acid (DNA) arrays.
18 Certain preferred embodiments of the invention involve use of the micromachined 19 mechanical modulators to direct the light to predetermined regions (i.e., known areas on a substrate predefined prior to photolithography processing) of the substrate on which the 21 polymers are being synthesized. The predetermined regions of the substrate associated with, 22 for example, one segment (referred to herein as a pixel) of a micromachined mechanical 23 modulator (e.g., a micro-mirror array) are referred to herein as features.
In each PATENT APPLICATION
Attorney Docket No. 3848.80505 1 predetermined region or feature a particular oligonucleotide sequence, for example, is 2 synthesized. The mechanical modulators come in a variety of types, two of which will be 3 discussed in some detail below.
4 One type of mechanical modulator is a micro-mirror array which uses small metal mirrors to selectively reflect a light beam to particular individual features;
thus causing the 6 individual features to selectively receive light from a light source (i.e., turning light on and 7 off of the individual features). An example is the programmable micro-mirror array Digital 8 Micromirror Device (DMDTM ) manufactured by Texas Instruments, Inc., Dallas, Texas, USA.
9 Texas Instruments markets the arrays primarily for projection display applications (e.g., big-screen video) in which a highly magnified image of the array is projected onto a wall or 11 screen. The present invention shows, however, that with appropriate optics and an 12 appropriate light source, a programmable micro-mirror array can be used for 13 photolithographic synthesis, and in particular for polymer array synthesis.
14 The Texas Instruments' DMDTM array consists of 640 x 480 mirrors (the VGA
version) or 800 x 600 minors (the super VGA (SVGA) version). Devices with more mirrors are under 16 development. Each minor is l6,can x 16 urn and there are 1-,um gaps between mirrors. The 17 array is designed to be illuminated 20 degrees off axis. Each minor can be turned on (tilted 18 10 degrees in one direction) or off (tilted 10 degrees in the other direction). A lens (on axis) 19 images the array onto a target. When a micro-mirror is turned on, light reflected by the micro-mirror passes through the lens and the image of the micro-mirror appears bright. When 21 a micro-mirror is turned off, light reflected by the micro-mirror misses the lens and the image 22 of the micro-mirror appears dark. The array can be reconfigured by software (i.e., every 23 micro-mirror in the array can be turned on or off as desired) in a fraction of a second.
PATENT APPLICATION
Attorney Docket No. 3848.80505 1 An optical lithography system including a micro-mirror array 1 based spatial light 2 modulator according to one embodiment of the invention is shown in FIG. 1.
This 3 embodiment includes a spatial light modulator made of a micro-mirror array 1, and arc lamp 4 3, and a lens 2 to project a predetermined image pattern on a chip or wafer (containing many chips) 4. In operation, collimated, filtered and homogenized light 5 from the arc lamp 3 is 6 selectively reflected as a light beam 6 according to dynamically turned on micro mirrors in 7 the micro-mirror array 1 and transmitted through lens 2 on to chip or wafer 4 as reflected light 8 beam 8. Reflected light from micro-mirrors that are turned off 7 is reflected in a direction 9 away from the lens 2 so that these areas appear dark to the lens 2 and chip or wafer 4. Thus, the spatial light modulator, micro-mirror array 1, modulates the direction of reflected light (6 11 and 7) so as to define a predetermined light image 8 projected onto the chip or wafer 4. The 12 direction of the reflected light alters the light intensity transmitted from each pixel to each 13 feature. In essence, the spatial light modulator operates as a directional and intensity 14 modulator.
The micro-mirror array 1 can be provided by, for example, the micro-mirror array of 16 the Texas Instruments(TI) DMD, in particular, the TI "SVGA DLPTM"
subsystem. The Texas 17 Instruments "SVGA DLP~"" subsystem with optics may be modified for use in the present 18 invention. The Texas Instruments "SVGA DLPT""" subsystem includes a micro-mirror array 19 (shown as micro-mirror array 1 in Fig. 1), a light source, a color filter wheel, a projection lens, and electronics for driving the array and interfacing to a computer. The color filter 21 wheel is replaced with a bandpass filter having, for example, a bandpass wavelength of 365-22 410 nm (wavelength dependent upon the type of photochemicals selected for used in the 23 process). For additional brightness at wavelengths of, for example, 400-410 nm, the light PATENT APPLICATION
Attorney Docket No. 3848.80505 1 source can be replaced with arc lamp 3 and appropriate homogenizing and collimating optics.
2 The lens included with the device is intended for use at very large conjugate ratios and is 3 replaced with lens 2 or set of lenses appropriate for imaging the micro-mirror array 1 onto 4 chip or wafer 4 with the desired magnification. Selection of the appropriate lens and bandpass filter is dependent on, among other things, the requisite image size to be formed on 6 the chip, the type of spatial light modulator, the type of light source, and the type of 7 photoresist and photochemicals being used in the system and process.
8 A symmetric lens system (e.g., lenses arranged by type A-B-C-C-B-A) used at 1:1 9 magnification (object size is the same as the image size) is desirable because certain aberrations (distortion, lateral color, coma) are minimized by symmetry.
Further, a 11 symmetric lens system results in a relatively simple lens design because there are only half as 12 many variables as in an asymmetric system having the same number of surfaces. However, at 13 1:1 magnification the likely maximum possible chip size is 10.88 mm x 8.16 mm with a VGA
14 device, or 10.2 mm x 13.6 mm with an SVGA device. Synthesis of, for example, a standard GeneChipo 12.8 mm x 12.8 mm chip uses an asymmetric optical system (e.g., a 16 magnification of about 1.25:1 with SVGA device) or a larger micro-mirror array (e.g., 17 1028 x 768 minors) if the mirror size is constant. In essence, the lens magnification can be 18 greater than or less than 1 depending on the desired size of the chip.
19 In certain applications of the invention, a relatively simple lens system, such as a back-to-back pair of achromats or camera lens, is adequate. A particularly useful lens for 21 some applications of the invention is the Rodenstock (Rockford, IL) Apo-Rodagon D. This 22 lens is optimized for 1:1 imaging and gives good performance at magnifications up to about 23 1.3:1. Similar lenses may be available from other manufacturers. With such lenses, either PATENT APPLICATION
Attorney Docket No. 3848.80505 1 the Airy disk diameter or the blur circle diameter will be rather large (maybe 10 um or 2 larger). See Modern Optical Engineering, 2d Edition, Smith, W.J., ed., McGraw-Hill, Inc., 3 New York (1990). For higher-quality synthesis, the feature size is several times larger than 4 the Airy disk or blur circle. Therefore, a custom-made lens with resolution of about 1-2 um over a 12.8 mm x 12.8 mm field is particularly desirable.
6 A preferred embodiment of synthesizing polymer arrays with a programmable micro-? mirror array using the DMT process with photoresist takes place as follows.
First, a 8 computer file is generated and specifies, for each photolithography step, which mirrors in the 9 micro-mirror array 1 need to be on and which need to be off to generate a particular predetermined image pattern. Next, the individual chip or the wafer from which it is made 4 11 is coated with photoresist on the synthesis surface and is mounted in a holder or flow cell (not 12 shown) on the photolithography apparatus so that the synthesis surface is in the plane where 13 the image of the micro-mirror array 1 will be formed. The photoresist may be either positive 14 or negative thus allowing deprotection at locations exposed to the light or deprotection at locations not exposed to the light, respectively (example photoresists include: negative tone 16 SU-8 epoxy resin (Shell Chemical) and those shown in the above cited patents and U.S.
17 patent appl. no. 08/634,053). A mechanism for aligning and focusing the chip or wafer is 18 provided, such as a x-y translation stage. Then, the micro-mirror array 1 is programmed for 19 the appropriate configuration according to the desired predetermined image pattern, a shutter in the arc lamp 3 is opened, the chip or wafer 4 is illuminated for the desired amount of time, 21 and the shutter is closed. If a wafer (rather than a chip) is being synthesized; a stepping-22 motor-driven translation stage moves the wafer by a distance equal to the desired center-to-PATENT APPLICATION
Attorney Docket No. 3848.80505 1 center distance between chips and the shutter of the arc lamp 3 is opened and closed again, 2 these two steps being repeated until each chip of the wafer has been exposed.
3 Next, the photoresist is developed and etched. Exposure of the wafer 4 to acid then 4 cleaves the DMT protecting groups from regions of the wafer where the photoresist has been removed. The remaining photoresist is then stripped. Then DMT-protected nucleotides 6 containing the desired base (adenine (A), cytosine (C), guanine (G), or thymine (T)) are 7 coupled to the deprotected oligonucleotides.
8 Subsequently, the chip or wafer 4 is re-coated with photoresist. The steps from 9 mounting the photoresist coated chip or wafer 4 in a holder through re-coating the chip or wafer 4 with photoresist are repeated until the polymer array synthesis is complete.
11 It is worth noting that if a DPD method, using for example 1-(6-nitro-1,3-12 benzodioxol-5-yl)ethyloxycarbonyl (MeNPOC) chemistry, or a PAG method, using a 13 polymer film containing a photoacid generator (PAG), are used for polymer array synthesis 14 then photoresist would not be used and the process is somewhat simplified.
However, the use of a direct write optical lithography system with a spatial light modulator is also applicable to 16 performing a process of deprotection of reaction sites using the DPD and PAG methods 17 without photoresist.
18 As is clear from the above described method for polymer array synthesis, no 19 photomasks are needed. This simplifies the process by eliminating processing time associated with changing masks in the optical lithography system and reduces the 21 manufacturing cost for polymer array synthesis by eliminating the cost of the masks as well 22 as processing defects associated with using masks. In addition, the process has improved 23 flexibility because reprogramming the optical lithography system to produce a different PATENT APPLICATION
Attorney Docket No. 3848.80505 1 generate and verify new photomasks, thus making it possible to transfer an image pattern 2 computer file directly from a CAD or similar system to the optical lithography system or 3 providing electronic signals directly from the CAD system to drive the optical lithography 4 system's means for dynamically producing the desired light pattern (e.g., spatial light modulator). Therefore, the optical lithography system is simplified and more efficient than 6 conventional photomask based optical lithography systems. This is particularly valuable in 7 complex multiple step photolithography processing; for example polymer array synthesis of 8 GeneChipo probe arrays having upwards of seventy or more cycles, especially when many 9 different products are made and revised.
As indicated above, substrates coated with photoresist are employed in preferred 11 embodiments of the invention, e.g., using the DMT process with photoresist.
The use of 12 photoresist with photolithographic methods for fabricating polymer arrays is discussed in 13 McGall et al., Chemtech, pp. 22-32 (February 1997); McGall et al., Proc.
Natl. Acad. Sci., 14 U.S.A., Vol. 93, pp. 13555-13560 (Nov. 1996) and various patents cited above, all of which are incorporated by reference in their entireties. Alternatively, polymer array synthesis 16 processing can be performed using photoacid generators without using a conventional 17 photoresist, e.g., using the PAG process, or using direct photodeprotection without using any 18 photoresist, e.g., using the DPD process. The use of photoacid generators is taught in U.S.
19 Application No. 08/969,227, filed November 13, 1997. However, the present invention is particularly useful when using the DMT and PAG processes for polymer array synthesis.
21 When synthesizing nucleic acid arrays, the photochemical processes used to fabricate 22 the arrays is preferably activated with light having a wavelength greater than 365 nm to avoid 23 photochemical degradation of the polynucleotides used to create the polymer arrays. Other PATENT APPLICATION
Attorney Docket No. 3848.80505 1 wavelengths may be desirable for other probes. Many photoacid generators (PAGs) based on 2 o-nitrobenzyl chemistry are useful at 365 nm. Further, when using the mirror array from 3 Texas Instruments discussed above, the PAG is preferably sensitive above 400 nm to avoid 4 damage to the mirror array. To achieve this, p-nitrobenzyl esters can be used in conjunction with a photosensitizes. For example, p-nitrobenzyltosylate and 2-ethyl-9,10-dimethoxy-6 anthracene can be used to photochemically generate toluenesulfonic acid at 405 nm. See S.C.
7 Busman and J.E. Trend, J. Imag. Technol., 1985, 11, 191; A. Nishida, T.
Hamada, and 8 O. Yonemitsu, J. Org. Chem., 1988, 53, 3386. In this system, the sensitizes absorbs the light 9 and then transfers the energy to the p-nitrobenzyltosylate, causing dissociation and the subsequent release of toluensulfonic acid. Alternate sensitizers, such as pyrene, N,N
11 dimethylnapthylamine, perylene, phenothiazine, canthone, thiocanthone, actophenone, and 12 benzophenone that absorb light at other wavelengths are also useful.
13 A variety of photoresists sensitive to 436-nm light are available for use in polymer 14 array synthesis and will avoid photochemical degradation of the polynucleotides.
A second preferred mechanical modulator that may be used in the invention is the 16 Grating Light Valve'M (GLVTM ) available from Silicon LightMachines, Sunnyvale, CA, USA.
17 The GLVtM relies on micromachined pixels that can be programmed to be either reflective or 18 diffractive (Grating Light Valve" technology). Information regarding certain of the 19 mechanical modulators discussed herein is obtained at http://www.ti.com (Texas instruments) and http://siliconlight.com. (Silicon LightMachines).
21 Although preferred spatial light modulators include the mechanical modulators 22 DMD~" available from Texas Instruments and the GLV~" available from Silicon 23 LightMachines, various types of spatial light modulators exist and may be used in the practice PATENT APPLICATION
Attorney Docket No. 3848.80505 1 of the present invention. See Electronic Engineers 'Handbook, 3'd Ed., Fink, D.G. and 2 Christiansen, D. Eds., McGraw-Hill Book Co., New York (1989). Deformable membrane 3 mirror arrays are available from Optron Systems Inc. (Bedford, MA). Liquid-crystal spatial 4 light modulators are available from Hamamatsu (Bridgewater, NJ), Spatialight (Novato, CA), and other companies. However, one skilled in the art must be careful to select the proper 6 light source and processing chemistries to ensure that the liquid-crystal spatial light 7 modulator is not damaged since these devices may be susceptible to damage by various 8 ultraviolet (UV) light. Liquid-crystal displays (LCD; e.g., in calculators and notebook 9 computers) are also spatial light modulators useful for photolithography particularly to synthesize large features. However, reduction optics would be required to synthesize smaller 11 features using LCDs.
12 Some spatial light modulators may be better suited than the Texas Instruments device 13 for use with UV light and would therefore be compatible with a wider range of photoresist 14 chemistries. One skilled in the art will choose the spatial modulator that is compatible with the chosen wavelength of illumination and synthesis chemistries employed. For example, the 16 device from Texas Instruments DMDT"" should not be used with UV
illumination because its 17 micro-mirror array may be damaged by UV light. However, if the passivation layer of the 18 micro-mirror array is modified or removed, the Texas Instruments DMDTM
could be used in 19 the invention with UV light.
One embodiment that is particularly useful when extremely high resolution is required 21 involves imaging the micro-mirror array using a system of the type shown in Fig. 2. In this 22 system, a lens 12 images the micro-mirror array 11 (e.g., DMDTM or GLV'M ) onto an array 10 23 having an array of micro-lenses 15 or non-imaging light concentrators. Each element of the PATENT APPLICATION
Attorney Docket No. 3848.80505 1 array 10 focuses light onto the chip or wafer, e.g., Gene Chip array 14.
Each micro-lens 1 S
2 produces an image of one pixel of the micro-mirror array 11. Optics 16, including a shaping 3 lens 17 may be included to translate light from a light source 13 onto the micro-mirror array 4 11.
For example, if an SVGA DLP'M device is imaged with l:l magnification onto a 6 micro-lens array 10, an appropriate micro-lens array 10 can consist of 800 x 600 lenses 7 (micro-lenses 15) with 17 ,um center-to-center spacing. Alternatively, the micro-lens array 8 can consist of 400 x 300 17 ,um diameter lenses with 34 urn center-to-center spacing, and 9 with opaque material (e.g., chrome) between micro-lenses 15. One advantage of this alternative is that cross-talk between pixels is reduced. The light incident upon each micro-11 lens 15 can be focused to a spot size of 1-2 fan. Because the spot size is much less than the 12 spacing between micro-lenses, a 2-axis translation stage (having, in these examples, a range 13 of travel of at least either 17 ,cnn x 17 ,um or 34 inn x 34 ,um) is necessary if complete 14 coverage of the chip or wafer 14 is desired.
Micro-lenses 15 can be diffractive, refractive, or hybrid (diffractive and refractive).
16 Refractive micro-lenses can be conventional or gradient-index. A portion of a diffractive 17 micro-lens array 10 is shown in Figure 3 and has individual micro-lenses formed as circles 18 commonly known as Fresnel Zone Plates 20. Alternatively an array of non-imaging light 19 concentrators can be employed. An example of such an approach would include a short piece of optical fiber which may be tapered to a small tip.
21 Furthermore, some spatial light modulators are designed to modulate transmitted 22 rather than reflected light. An example of a transmissive spatial light modulator is a liquid PATENT APPLICATION
Attorney Docket No. 3848.80505 1 crystal display (LCD) and is illustrated in another embodiment, shown in Fig. 4. This 2 embodiment includes a light source 33 providing light 35, transmissive spatial light 3 modulator 31 and a computer 39 providing electronic control signals to the transmissive 4 spatial light modulator 31 through cables 40 so as to transmit a desired light image 38 on the chip or wafer 34. The computer 39 may be, for example, a unique programmable controller, 6 a personal computer (PC), or a CAD system used to design the desired image pattern.
7 Using a transmissive spatial light modulator has even additional advantages over the 8 conventional optical lithography system. Reflective spatial light modulators require a large 9 working distance between the modulator and the lens so that the lens does not block the incident light. Designing a high performance lens with a large working distance is more 11 difficult than designing a lens of equivalent performance with no constraints on the working 12 distance. With a transmissive spatial light modulator the working distance does not have to 13 be long and lens design is therefore easier. In fact, as show in Fig. 4, some transmissive 14 spatial light modulators 31 might be useful for proximity or contact printing with no lens at all, by locating the modulator very close to the chip or wafer 34.
16 In fact, the transmissive spatial light modulator in the embodiment of Fig.
4 could be 17 replaced by an LED array or a semiconductor laser arrays emitting light of the appropriate 18 wavelength, each of which not only may be operated to dynamically define a desired image 19 but also act as the light source. Thus, as modified, this embodiment would be simplified so as to not require a separate light source.
21 Although discussed herein in reference to polymer array synthesis, one skilled in the 22 art will appreciate that the present invention has a variety of applications including, among 23 others, silicon micromachining and custom semiconductor chip manufacturing.
However, PATENT APPLICATION
Attorney Docket No. 3848.80505 1 use of some types of spatial light modulators with the invention may result in limiting the 2 types of geometries available in silicon micromachining and custom semiconductor chip 3 manufacturing applications. It is understood that the examples and embodiments described 4 herein are for illustrative purposes only and that various modifications or changes in light thereof will be suggested to persons skilled in the art and are to be included within the spirit 6 and purview of this application and scope of the appended claims.
7 All publications, patents, and patent applications cited herein are hereby incorporated 8 by reference in their entirety for all purposes. Application Serial No.
08/426,202 (filed April 9 21, 1995) relates to the present invention and is hereby incorporated by reference for all purposes.
use of photolabile PATENT APPLICATION
Attorney Docket No. 3848.80505 1 protecting groups and direct photodeprotection (DPD); use of acid-labile 4,4'-dimethoxytrityl 2 (DMT) protecting groups and a photoresist; use of DMT protecting groups and a polymer 3 film that contains a photoacid generator (PAG).
4 These methods have many process steps similar to those used in semiconductor integrated circuit manufacturing. These methods also often involve 6 the use of photomasks (masks) that have a predefined image pattern which permits the 7 light used for synthesis of the polymer arrays to reach certain regions of a substrate 8 but not others. The substrate can be non-porous, rigid, semi-rigid,etc. It can be 9 formed into a well, a trench, a flat surface, etc. The substrate can include solids, such as siliceous substances such as silicon, glass, fused silica, quartz, and other solids such 11 as plastics and polymers, such as polyacrylamide, polystyrene, polycarbonate, etc.
12 Typically, the solid substrate is called a wafer from which individual chips are made 13 (See the U.S. patents above which are incorporated herein by reference). As such, the 14 pattern formed on the mask is projected onto the wafer to define which portions of the wafer are to be deprotected and which regions remain protected. See, for example, 16 U.S. Patent Nos. 5,593,839 and 5,571,639 which are hereby incorporated by reference 17 in their entireties.
18 The lithographic or photochemical steps in the synthesis of nucleic acid arrays 19 may be performed by contact printing or proximity printing using photomasks. For example, an emulsion or chrome-on-glass mask is placed in contact with the wafer, or 21 nearly in contact with the wafer, and the wafer is illuminated through the mask by 22 light having an appropriate wavelength. However, masks can be costly to make and 23 use and are capable of being damaged or lost.
PATENT APPLICATION
Attorney Docket No. 3848.80505 1 In many cases a different mask having a particular predetermined image 2 pattern is used for each separate photomasking step, and synthesis of a wafer 3 containing many chips requires a plurality of photomasking steps with different image 4 patterns. For example, synthesis of an array of 20mers typically requires approximately seventy photolithographic steps and related unique photomasks.
So, 6 using present photolithographic systems and methods, a plurality of different image 7 pattern masks must be pre-generated and changed in the photolithographic system at 8 each photomasking step. This plurality of different pattern masks adds lead time to 9 the process and complexity and inefficiency to the photolithographic system and method. Further, contact printing using a mask can cause defects on the wafer so that 11 some of the reaction sites are rendered defective. Thus, a photolithographic system 12 and method that does not require such masks and obviates such difficulties would be 13 generally useful in providing a more efficient and simplified lithographic process.
SUMMARY OF THE INVENTION
16 In view of the abQVe, one advantage of the invention is providing an improved 17 and simplified system and method for optical lithography.
18 Another advantage of the present invention is providing an optical lithography 19 system and method that dynamically generates an image using a computer and reconfigurable light modulator.
21 A further advantage of the present invention is providing an optical 22 lithography system and method that does not use photomasks.
PATENT APPLICATION
Attorney Docket No. 3848.80505 1 A still further advantage of the present invention is providing an optical 2 lithography system and method that uses computer generated electronic control 3 signals and a spatial light modulator, without any photomask, to project a 4 predetermined light pattern onto a surface of a substrate for the purposes of deprotecting various areas of a polymer array.
6 According to one aspect of the invention, polymer array synthesis is performed using 7 a system without photomasks.
8 According to a second aspect of the invention, polymer array synthesis is performed 9 using a system with a transmissive spatial light modulator and without a lens and photomask.
According to another aspect of the invention, a Direct Write System transmits image 11 patterns to be formed on the surface of a substrate (e.g., a wafer). The image patterns are 12 stored in a computer. The Direct Write System projects light patterns generated from the 13 image patterns onto a surface of the substrate for light-directed polymer synthesis (e.g., 14 oligonucleotide). The light patterns are generated by a spatial light modulator controlled by a computer, rather than being defined by a pattern on a photomask. Thus, in the Direct Write 16 System each pixel is illuminated with an optical beam of suitable intensity and the imaging 17 (printing) of an individual feature on a substrate is determined dynamically by computer 18 control.
19 According to a further aspect of the invention, polymer array synthesis is accomplished using a class of devices known as spatial light modulators to define the image 21 pattern of the polymer array to be deprotected.
PATENT APPLICATION
Attorney Docket No. 3848.80505 1 An even further aspect of the present invention provides methods for synthesizing 2 polymer arrays using spatial light modulators and the polymer arrays synthesized using the 3 methods taught herein.
4 As can be appreciated by one skilled in the art, the invention is relevant to optical lithography in general, and more specifically to optical lithography for polymer array 6 synthesis using photolithograpic processes. However, it is inherent that the invention is 7 generally applicable to eliminating the need for a photomask in optical lithography.
The above objects, features, and advantages of the present invention will become more 11 apparent from the following detailed description taken with the accompanying drawings in 12 which:
13 Figure 1 shows a first embodiment of the invention having a light source, a reflective 14 spatial light modulator, such as a micro-mirror array, and a lens.
~ Figure 2 is a diagrammatic representation of a second embodiment of the invention 16 employing an array of, for example, micro-lenses.
17 Figure 3 illustrates a micro-lens array in the form of Fresnel Zone Plates, which may 18 be used in the invention.
19 Figure 4 shows a third embodiment of the invention having a transmissive spatial light modulator.
PATENT APPLICATION
Attorney Docket No. 3848.80505 2 The present invention refers to articles and patents that contain useful supplementary 3 information. These references are hereby incorporated by reference in their entireties.
4 The presently preferred invention is based on the principle that a Direct Write Optical Lithography System will significantly improve the cost, quality, and efficiency of polymer 6 array synthesis by providing a maskless optical lithography system and method where 7 predetermined image patterns can be dynamically changed during photolithographic 8 processing. As such, an optical lithography system is provided to include a means for 9 dynamically changing an intended image pattern without using a photomask.
One such means includes a spatial light modulator that is electronically controlled by a computer to 11 generate unique predetermined image patterns at each photolithograpic step in polymer array 12 synthesis. The spatial light modulators can be, for example, micromachined mechanical 13 modulators or microelectronic devices (e.g. liquid crystal display (LCD)).
The Direct Write 14 System of the present invention using such spatial light modulators is particularly useful in 1 S the synthesis of polymer arrays, such as polypeptide, carbohydrate, and nucleic acid arrays.
16 Nucleic acid arrays typically include polynucleotides or oligonucleotides attached to glass, 17 for example, Deoxyribonucleic Acid (DNA) arrays.
18 Certain preferred embodiments of the invention involve use of the micromachined 19 mechanical modulators to direct the light to predetermined regions (i.e., known areas on a substrate predefined prior to photolithography processing) of the substrate on which the 21 polymers are being synthesized. The predetermined regions of the substrate associated with, 22 for example, one segment (referred to herein as a pixel) of a micromachined mechanical 23 modulator (e.g., a micro-mirror array) are referred to herein as features.
In each PATENT APPLICATION
Attorney Docket No. 3848.80505 1 predetermined region or feature a particular oligonucleotide sequence, for example, is 2 synthesized. The mechanical modulators come in a variety of types, two of which will be 3 discussed in some detail below.
4 One type of mechanical modulator is a micro-mirror array which uses small metal mirrors to selectively reflect a light beam to particular individual features;
thus causing the 6 individual features to selectively receive light from a light source (i.e., turning light on and 7 off of the individual features). An example is the programmable micro-mirror array Digital 8 Micromirror Device (DMDTM ) manufactured by Texas Instruments, Inc., Dallas, Texas, USA.
9 Texas Instruments markets the arrays primarily for projection display applications (e.g., big-screen video) in which a highly magnified image of the array is projected onto a wall or 11 screen. The present invention shows, however, that with appropriate optics and an 12 appropriate light source, a programmable micro-mirror array can be used for 13 photolithographic synthesis, and in particular for polymer array synthesis.
14 The Texas Instruments' DMDTM array consists of 640 x 480 mirrors (the VGA
version) or 800 x 600 minors (the super VGA (SVGA) version). Devices with more mirrors are under 16 development. Each minor is l6,can x 16 urn and there are 1-,um gaps between mirrors. The 17 array is designed to be illuminated 20 degrees off axis. Each minor can be turned on (tilted 18 10 degrees in one direction) or off (tilted 10 degrees in the other direction). A lens (on axis) 19 images the array onto a target. When a micro-mirror is turned on, light reflected by the micro-mirror passes through the lens and the image of the micro-mirror appears bright. When 21 a micro-mirror is turned off, light reflected by the micro-mirror misses the lens and the image 22 of the micro-mirror appears dark. The array can be reconfigured by software (i.e., every 23 micro-mirror in the array can be turned on or off as desired) in a fraction of a second.
PATENT APPLICATION
Attorney Docket No. 3848.80505 1 An optical lithography system including a micro-mirror array 1 based spatial light 2 modulator according to one embodiment of the invention is shown in FIG. 1.
This 3 embodiment includes a spatial light modulator made of a micro-mirror array 1, and arc lamp 4 3, and a lens 2 to project a predetermined image pattern on a chip or wafer (containing many chips) 4. In operation, collimated, filtered and homogenized light 5 from the arc lamp 3 is 6 selectively reflected as a light beam 6 according to dynamically turned on micro mirrors in 7 the micro-mirror array 1 and transmitted through lens 2 on to chip or wafer 4 as reflected light 8 beam 8. Reflected light from micro-mirrors that are turned off 7 is reflected in a direction 9 away from the lens 2 so that these areas appear dark to the lens 2 and chip or wafer 4. Thus, the spatial light modulator, micro-mirror array 1, modulates the direction of reflected light (6 11 and 7) so as to define a predetermined light image 8 projected onto the chip or wafer 4. The 12 direction of the reflected light alters the light intensity transmitted from each pixel to each 13 feature. In essence, the spatial light modulator operates as a directional and intensity 14 modulator.
The micro-mirror array 1 can be provided by, for example, the micro-mirror array of 16 the Texas Instruments(TI) DMD, in particular, the TI "SVGA DLPTM"
subsystem. The Texas 17 Instruments "SVGA DLP~"" subsystem with optics may be modified for use in the present 18 invention. The Texas Instruments "SVGA DLPT""" subsystem includes a micro-mirror array 19 (shown as micro-mirror array 1 in Fig. 1), a light source, a color filter wheel, a projection lens, and electronics for driving the array and interfacing to a computer. The color filter 21 wheel is replaced with a bandpass filter having, for example, a bandpass wavelength of 365-22 410 nm (wavelength dependent upon the type of photochemicals selected for used in the 23 process). For additional brightness at wavelengths of, for example, 400-410 nm, the light PATENT APPLICATION
Attorney Docket No. 3848.80505 1 source can be replaced with arc lamp 3 and appropriate homogenizing and collimating optics.
2 The lens included with the device is intended for use at very large conjugate ratios and is 3 replaced with lens 2 or set of lenses appropriate for imaging the micro-mirror array 1 onto 4 chip or wafer 4 with the desired magnification. Selection of the appropriate lens and bandpass filter is dependent on, among other things, the requisite image size to be formed on 6 the chip, the type of spatial light modulator, the type of light source, and the type of 7 photoresist and photochemicals being used in the system and process.
8 A symmetric lens system (e.g., lenses arranged by type A-B-C-C-B-A) used at 1:1 9 magnification (object size is the same as the image size) is desirable because certain aberrations (distortion, lateral color, coma) are minimized by symmetry.
Further, a 11 symmetric lens system results in a relatively simple lens design because there are only half as 12 many variables as in an asymmetric system having the same number of surfaces. However, at 13 1:1 magnification the likely maximum possible chip size is 10.88 mm x 8.16 mm with a VGA
14 device, or 10.2 mm x 13.6 mm with an SVGA device. Synthesis of, for example, a standard GeneChipo 12.8 mm x 12.8 mm chip uses an asymmetric optical system (e.g., a 16 magnification of about 1.25:1 with SVGA device) or a larger micro-mirror array (e.g., 17 1028 x 768 minors) if the mirror size is constant. In essence, the lens magnification can be 18 greater than or less than 1 depending on the desired size of the chip.
19 In certain applications of the invention, a relatively simple lens system, such as a back-to-back pair of achromats or camera lens, is adequate. A particularly useful lens for 21 some applications of the invention is the Rodenstock (Rockford, IL) Apo-Rodagon D. This 22 lens is optimized for 1:1 imaging and gives good performance at magnifications up to about 23 1.3:1. Similar lenses may be available from other manufacturers. With such lenses, either PATENT APPLICATION
Attorney Docket No. 3848.80505 1 the Airy disk diameter or the blur circle diameter will be rather large (maybe 10 um or 2 larger). See Modern Optical Engineering, 2d Edition, Smith, W.J., ed., McGraw-Hill, Inc., 3 New York (1990). For higher-quality synthesis, the feature size is several times larger than 4 the Airy disk or blur circle. Therefore, a custom-made lens with resolution of about 1-2 um over a 12.8 mm x 12.8 mm field is particularly desirable.
6 A preferred embodiment of synthesizing polymer arrays with a programmable micro-? mirror array using the DMT process with photoresist takes place as follows.
First, a 8 computer file is generated and specifies, for each photolithography step, which mirrors in the 9 micro-mirror array 1 need to be on and which need to be off to generate a particular predetermined image pattern. Next, the individual chip or the wafer from which it is made 4 11 is coated with photoresist on the synthesis surface and is mounted in a holder or flow cell (not 12 shown) on the photolithography apparatus so that the synthesis surface is in the plane where 13 the image of the micro-mirror array 1 will be formed. The photoresist may be either positive 14 or negative thus allowing deprotection at locations exposed to the light or deprotection at locations not exposed to the light, respectively (example photoresists include: negative tone 16 SU-8 epoxy resin (Shell Chemical) and those shown in the above cited patents and U.S.
17 patent appl. no. 08/634,053). A mechanism for aligning and focusing the chip or wafer is 18 provided, such as a x-y translation stage. Then, the micro-mirror array 1 is programmed for 19 the appropriate configuration according to the desired predetermined image pattern, a shutter in the arc lamp 3 is opened, the chip or wafer 4 is illuminated for the desired amount of time, 21 and the shutter is closed. If a wafer (rather than a chip) is being synthesized; a stepping-22 motor-driven translation stage moves the wafer by a distance equal to the desired center-to-PATENT APPLICATION
Attorney Docket No. 3848.80505 1 center distance between chips and the shutter of the arc lamp 3 is opened and closed again, 2 these two steps being repeated until each chip of the wafer has been exposed.
3 Next, the photoresist is developed and etched. Exposure of the wafer 4 to acid then 4 cleaves the DMT protecting groups from regions of the wafer where the photoresist has been removed. The remaining photoresist is then stripped. Then DMT-protected nucleotides 6 containing the desired base (adenine (A), cytosine (C), guanine (G), or thymine (T)) are 7 coupled to the deprotected oligonucleotides.
8 Subsequently, the chip or wafer 4 is re-coated with photoresist. The steps from 9 mounting the photoresist coated chip or wafer 4 in a holder through re-coating the chip or wafer 4 with photoresist are repeated until the polymer array synthesis is complete.
11 It is worth noting that if a DPD method, using for example 1-(6-nitro-1,3-12 benzodioxol-5-yl)ethyloxycarbonyl (MeNPOC) chemistry, or a PAG method, using a 13 polymer film containing a photoacid generator (PAG), are used for polymer array synthesis 14 then photoresist would not be used and the process is somewhat simplified.
However, the use of a direct write optical lithography system with a spatial light modulator is also applicable to 16 performing a process of deprotection of reaction sites using the DPD and PAG methods 17 without photoresist.
18 As is clear from the above described method for polymer array synthesis, no 19 photomasks are needed. This simplifies the process by eliminating processing time associated with changing masks in the optical lithography system and reduces the 21 manufacturing cost for polymer array synthesis by eliminating the cost of the masks as well 22 as processing defects associated with using masks. In addition, the process has improved 23 flexibility because reprogramming the optical lithography system to produce a different PATENT APPLICATION
Attorney Docket No. 3848.80505 1 generate and verify new photomasks, thus making it possible to transfer an image pattern 2 computer file directly from a CAD or similar system to the optical lithography system or 3 providing electronic signals directly from the CAD system to drive the optical lithography 4 system's means for dynamically producing the desired light pattern (e.g., spatial light modulator). Therefore, the optical lithography system is simplified and more efficient than 6 conventional photomask based optical lithography systems. This is particularly valuable in 7 complex multiple step photolithography processing; for example polymer array synthesis of 8 GeneChipo probe arrays having upwards of seventy or more cycles, especially when many 9 different products are made and revised.
As indicated above, substrates coated with photoresist are employed in preferred 11 embodiments of the invention, e.g., using the DMT process with photoresist.
The use of 12 photoresist with photolithographic methods for fabricating polymer arrays is discussed in 13 McGall et al., Chemtech, pp. 22-32 (February 1997); McGall et al., Proc.
Natl. Acad. Sci., 14 U.S.A., Vol. 93, pp. 13555-13560 (Nov. 1996) and various patents cited above, all of which are incorporated by reference in their entireties. Alternatively, polymer array synthesis 16 processing can be performed using photoacid generators without using a conventional 17 photoresist, e.g., using the PAG process, or using direct photodeprotection without using any 18 photoresist, e.g., using the DPD process. The use of photoacid generators is taught in U.S.
19 Application No. 08/969,227, filed November 13, 1997. However, the present invention is particularly useful when using the DMT and PAG processes for polymer array synthesis.
21 When synthesizing nucleic acid arrays, the photochemical processes used to fabricate 22 the arrays is preferably activated with light having a wavelength greater than 365 nm to avoid 23 photochemical degradation of the polynucleotides used to create the polymer arrays. Other PATENT APPLICATION
Attorney Docket No. 3848.80505 1 wavelengths may be desirable for other probes. Many photoacid generators (PAGs) based on 2 o-nitrobenzyl chemistry are useful at 365 nm. Further, when using the mirror array from 3 Texas Instruments discussed above, the PAG is preferably sensitive above 400 nm to avoid 4 damage to the mirror array. To achieve this, p-nitrobenzyl esters can be used in conjunction with a photosensitizes. For example, p-nitrobenzyltosylate and 2-ethyl-9,10-dimethoxy-6 anthracene can be used to photochemically generate toluenesulfonic acid at 405 nm. See S.C.
7 Busman and J.E. Trend, J. Imag. Technol., 1985, 11, 191; A. Nishida, T.
Hamada, and 8 O. Yonemitsu, J. Org. Chem., 1988, 53, 3386. In this system, the sensitizes absorbs the light 9 and then transfers the energy to the p-nitrobenzyltosylate, causing dissociation and the subsequent release of toluensulfonic acid. Alternate sensitizers, such as pyrene, N,N
11 dimethylnapthylamine, perylene, phenothiazine, canthone, thiocanthone, actophenone, and 12 benzophenone that absorb light at other wavelengths are also useful.
13 A variety of photoresists sensitive to 436-nm light are available for use in polymer 14 array synthesis and will avoid photochemical degradation of the polynucleotides.
A second preferred mechanical modulator that may be used in the invention is the 16 Grating Light Valve'M (GLVTM ) available from Silicon LightMachines, Sunnyvale, CA, USA.
17 The GLVtM relies on micromachined pixels that can be programmed to be either reflective or 18 diffractive (Grating Light Valve" technology). Information regarding certain of the 19 mechanical modulators discussed herein is obtained at http://www.ti.com (Texas instruments) and http://siliconlight.com. (Silicon LightMachines).
21 Although preferred spatial light modulators include the mechanical modulators 22 DMD~" available from Texas Instruments and the GLV~" available from Silicon 23 LightMachines, various types of spatial light modulators exist and may be used in the practice PATENT APPLICATION
Attorney Docket No. 3848.80505 1 of the present invention. See Electronic Engineers 'Handbook, 3'd Ed., Fink, D.G. and 2 Christiansen, D. Eds., McGraw-Hill Book Co., New York (1989). Deformable membrane 3 mirror arrays are available from Optron Systems Inc. (Bedford, MA). Liquid-crystal spatial 4 light modulators are available from Hamamatsu (Bridgewater, NJ), Spatialight (Novato, CA), and other companies. However, one skilled in the art must be careful to select the proper 6 light source and processing chemistries to ensure that the liquid-crystal spatial light 7 modulator is not damaged since these devices may be susceptible to damage by various 8 ultraviolet (UV) light. Liquid-crystal displays (LCD; e.g., in calculators and notebook 9 computers) are also spatial light modulators useful for photolithography particularly to synthesize large features. However, reduction optics would be required to synthesize smaller 11 features using LCDs.
12 Some spatial light modulators may be better suited than the Texas Instruments device 13 for use with UV light and would therefore be compatible with a wider range of photoresist 14 chemistries. One skilled in the art will choose the spatial modulator that is compatible with the chosen wavelength of illumination and synthesis chemistries employed. For example, the 16 device from Texas Instruments DMDT"" should not be used with UV
illumination because its 17 micro-mirror array may be damaged by UV light. However, if the passivation layer of the 18 micro-mirror array is modified or removed, the Texas Instruments DMDTM
could be used in 19 the invention with UV light.
One embodiment that is particularly useful when extremely high resolution is required 21 involves imaging the micro-mirror array using a system of the type shown in Fig. 2. In this 22 system, a lens 12 images the micro-mirror array 11 (e.g., DMDTM or GLV'M ) onto an array 10 23 having an array of micro-lenses 15 or non-imaging light concentrators. Each element of the PATENT APPLICATION
Attorney Docket No. 3848.80505 1 array 10 focuses light onto the chip or wafer, e.g., Gene Chip array 14.
Each micro-lens 1 S
2 produces an image of one pixel of the micro-mirror array 11. Optics 16, including a shaping 3 lens 17 may be included to translate light from a light source 13 onto the micro-mirror array 4 11.
For example, if an SVGA DLP'M device is imaged with l:l magnification onto a 6 micro-lens array 10, an appropriate micro-lens array 10 can consist of 800 x 600 lenses 7 (micro-lenses 15) with 17 ,um center-to-center spacing. Alternatively, the micro-lens array 8 can consist of 400 x 300 17 ,um diameter lenses with 34 urn center-to-center spacing, and 9 with opaque material (e.g., chrome) between micro-lenses 15. One advantage of this alternative is that cross-talk between pixels is reduced. The light incident upon each micro-11 lens 15 can be focused to a spot size of 1-2 fan. Because the spot size is much less than the 12 spacing between micro-lenses, a 2-axis translation stage (having, in these examples, a range 13 of travel of at least either 17 ,cnn x 17 ,um or 34 inn x 34 ,um) is necessary if complete 14 coverage of the chip or wafer 14 is desired.
Micro-lenses 15 can be diffractive, refractive, or hybrid (diffractive and refractive).
16 Refractive micro-lenses can be conventional or gradient-index. A portion of a diffractive 17 micro-lens array 10 is shown in Figure 3 and has individual micro-lenses formed as circles 18 commonly known as Fresnel Zone Plates 20. Alternatively an array of non-imaging light 19 concentrators can be employed. An example of such an approach would include a short piece of optical fiber which may be tapered to a small tip.
21 Furthermore, some spatial light modulators are designed to modulate transmitted 22 rather than reflected light. An example of a transmissive spatial light modulator is a liquid PATENT APPLICATION
Attorney Docket No. 3848.80505 1 crystal display (LCD) and is illustrated in another embodiment, shown in Fig. 4. This 2 embodiment includes a light source 33 providing light 35, transmissive spatial light 3 modulator 31 and a computer 39 providing electronic control signals to the transmissive 4 spatial light modulator 31 through cables 40 so as to transmit a desired light image 38 on the chip or wafer 34. The computer 39 may be, for example, a unique programmable controller, 6 a personal computer (PC), or a CAD system used to design the desired image pattern.
7 Using a transmissive spatial light modulator has even additional advantages over the 8 conventional optical lithography system. Reflective spatial light modulators require a large 9 working distance between the modulator and the lens so that the lens does not block the incident light. Designing a high performance lens with a large working distance is more 11 difficult than designing a lens of equivalent performance with no constraints on the working 12 distance. With a transmissive spatial light modulator the working distance does not have to 13 be long and lens design is therefore easier. In fact, as show in Fig. 4, some transmissive 14 spatial light modulators 31 might be useful for proximity or contact printing with no lens at all, by locating the modulator very close to the chip or wafer 34.
16 In fact, the transmissive spatial light modulator in the embodiment of Fig.
4 could be 17 replaced by an LED array or a semiconductor laser arrays emitting light of the appropriate 18 wavelength, each of which not only may be operated to dynamically define a desired image 19 but also act as the light source. Thus, as modified, this embodiment would be simplified so as to not require a separate light source.
21 Although discussed herein in reference to polymer array synthesis, one skilled in the 22 art will appreciate that the present invention has a variety of applications including, among 23 others, silicon micromachining and custom semiconductor chip manufacturing.
However, PATENT APPLICATION
Attorney Docket No. 3848.80505 1 use of some types of spatial light modulators with the invention may result in limiting the 2 types of geometries available in silicon micromachining and custom semiconductor chip 3 manufacturing applications. It is understood that the examples and embodiments described 4 herein are for illustrative purposes only and that various modifications or changes in light thereof will be suggested to persons skilled in the art and are to be included within the spirit 6 and purview of this application and scope of the appended claims.
7 All publications, patents, and patent applications cited herein are hereby incorporated 8 by reference in their entirety for all purposes. Application Serial No.
08/426,202 (filed April 9 21, 1995) relates to the present invention and is hereby incorporated by reference for all purposes.
Claims (36)
1. A method for deprotecting reaction sites on a substrate comprising the steps of:
providing a substrate having protected reaction sites;
modulating light direction with a spatial light modulator so as to generate a predetermined light pattern used for deprotecting selected portions of said protected reaction sites.
providing a substrate having protected reaction sites;
modulating light direction with a spatial light modulator so as to generate a predetermined light pattern used for deprotecting selected portions of said protected reaction sites.
2. The method of claim 1, further comprising the step of directing light from a light source to said spatial light modulator.
3. The method of claim 2, further comprising the step of projecting said predetermined light pattern onto a surface of said substrate with a lens.
4. The method of claim 3, further comprising the step of transmitting said predetermined light pattern from said lens through a micro-lens array.
5. The method of claim 2, further comprising the step of transmitting said predetermined light pattern through an array of non-imaging light concentrators.
6. The method of claim 4, further comprising the step of moving said substrate with a translation stage.
7. The method of claim 2, wherein said spatial light modulator is a micro-mirror array.
8. The method of claim 7, wherein said spatial light modulator is a DMD TM.
9. The method of claim 2, wherein said spatial light modulator is a GLV TM.
10. The method of claim 4, wherein said spatial light modulator is a SVGA DLP
TM.
TM.
11. The method of claim 1, further comprising the step of generating a computer file that specifies, for each photolithography step, which portions of said spatial light modulator will operatively illuminate which portions of said protected reaction sites.
12. The method of claim 11, further comprising the step of programming said spatial light modulator to a desired configuration with information contained in said computer file.
13. A method of deprotecting reaction sites on a substrate comprising:
providing a substrate having protected reaction sites;
providing a light source;
providing a spatial light modulator;
orienting said substrate, said light source, and said spatial light modulator such that when said light source illuminates, intensity of illumination from said light source is modulated by said spatial light modulator and generates a predetermined light image pattern;
and illuminating said substrate with said predetermined light image pattern at said substrate so as to deprotect at least one of said protected reaction sites.
providing a substrate having protected reaction sites;
providing a light source;
providing a spatial light modulator;
orienting said substrate, said light source, and said spatial light modulator such that when said light source illuminates, intensity of illumination from said light source is modulated by said spatial light modulator and generates a predetermined light image pattern;
and illuminating said substrate with said predetermined light image pattern at said substrate so as to deprotect at least one of said protected reaction sites.
14. The method of claim 13, further comprising the step of projecting said predetermined light pattern onto a surface of said substrate with a lens.
15. The method of claim 14, further comprising the step of transmitting said predetermined light pattern from said lens through a micro-lens array.
16. The method of claim 13, further comprising the step of transmitting said predetermined light pattern through an array of non-imaging light concentrators.
17. The method of claim 15, further comprising the step of moving said substrate with a translation stage.
18. The method of claim 13, wherein said spatial light modulator is a micro-minor array.
19. The method of claim 18, wherein said spatial light modulator is a DMD TM.
20. The method of claim 13, wherein said spatial light modulator is a GLV TM.
21. The method of claim 15, wherein said spatial light modulator is a SVGA
DLP TM.
DLP TM.
22. The method of claim 13, further comprising the step of generating a computer file that specifies, for each photolithography step, which portions of said spatial light modulator will operatively illuminate which portions of said protected reaction sites.
23. The method of claim 22, further comprising the step of programming said spatial light modulator to a desired configuration with information contained in said computer file.
24. An optical lithography system, consisting essentially of:
a light source;
a substrate mount; and a means for dynamically defining a light pattern using unpatterned light from said light source without using a photomask.
a light source;
a substrate mount; and a means for dynamically defining a light pattern using unpatterned light from said light source without using a photomask.
25. The optical lithography system of claim 24, wherein said means for dynamically defining a light pattern includes a spatial light modulator module modulating light direction or light intensity to generate a predetermined light image.
26. The optical lithography system of claim 24, wherein said means for dynamically defining a light pattern includes a micro-mirror array modulating light by changing angular position of micro-mirrors in said micro-mirror array.
27. The optical lithography system of claim 25, wherein said spatial light modulator is a DMD TM
28. The optical lithography system of claim 25, wherein said spatial light modulator is a GLV TM.
29. The optical lithography system of claim 25, wherein said spatial light modulator is a SVGA DLP TM.
30. The optical lithography system of claim 29, wherein said light source includes an arc lamp.
31. The optical lithography system of claim 26, wherein said micro-mirror array includes a plurality of micro-mirrors, each of said micro-mirrors selectively illuminate a single feature on a substrate using specular reflection of light directed toward said substrate (turn on), and selectively not illuminating of said single feature by specular reflection of light directed away from said substrate (turn off).
32. An optical lithography system, comprising:
a spatial light modulator which provides a predetermined two dimensional light pattern on a substrate without use of a photomask and holographic image.
a spatial light modulator which provides a predetermined two dimensional light pattern on a substrate without use of a photomask and holographic image.
33. The optical lithography system of claim 32, wherein said predetermined two dimensional light image is used for deprotecting reaction sites of a polymer array.
34. The optical lithography system of claim 33, further comprising a light source.
35. The optical lithography system of claim 34, wherein said light source includes an arc lamp.
36. The optical lithography system of claim 35, wherein said spatial light modulator includes a micro-mirror array modulating light by changing angular position of micro-mirrors in said micro-mirror array.
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JP2000040660A (en) | 2000-02-08 |
US20050088722A1 (en) | 2005-04-28 |
US6271957B1 (en) | 2001-08-07 |
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