US 20080204693 A1
The present invention includes a method for supporting a substrate that features a chuck body having a body surface with a pin extending therefrom having a contact surface lying in a plane, with the pin being movably coupled to the chuck body to move with respect to the plane. To that end, the method includes disposing the substrate upon two spaced-apart bodies; and moving one of the two spaced-apart bodies away from the substrate.
6. A substrate support system comprising:
a chuck body having a body surface with a pin extending therefrom having a contact surface lying in a plane, said pin being movably coupled to said chuck body to move with respect to said plane, wherein said pin includes a cross-member having three spaced-apart contact lands extending from said cross-member and wherein said pin is formed by a pin cell that further comprises a flexure system coupled between said cross-member and said chuck body.
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The present application is a Continuation of U.S. patent application Ser. No. 11/136,886 filed May 25, 2005, entitled “Substrate Support Method,” and listing Pawan K. Nimmakayala and Sidlgata V. Sreenivasan as inventors. U.S. patent application Ser. No. 11/136,886 claims priority to U.S. Provisional Patent Application No. 60/575,442 filed May 28, 2004, entitled “A Chucking System and Method,” listing Pawan K. Nimmakayala and Sidlgata V. Sreenivasan as inventors, and is a Divisional of U.S. Pat. No. 7,245,358 (originally U.S. application Ser. No. 11/136,885) filed May 25, 2005 entitled “Substrate Support System” listing Pawan K. Nimmakayala and Sidlgata V. Sreenivasan as inventors. These applications are incorporated herein by reference.
The field of invention relates generally to support for substrates. More particularly, the present invention is directed to a chuck suited for use in imprint lithography.
Micro-fabrication involves the fabrication of very small structures, e.g., having features on the order of micro-meters or smaller. One area in which micro-fabrication has had a sizeable impact is in the processing of integrated circuits. As the semiconductor processing industry continues to strive for larger production yields while increasing the circuits per unit area formed on a substrate, micro-fabrication becomes increasingly important. Micro-fabrication provides greater process control while allowing increased reduction of the minimum feature dimension of the structures formed. Other areas of development in which micro-fabrication has been employed include biotechnology, optical technology, mechanical systems and the like. Many of the micro-fabrication techniques involve various processes, including deposition, such as chemical vapor deposition, physical vapor deposition, atomic layer deposition and the like, as well as wet and/or dry etching techniques to pattern substrates.
In addition to the standard micro-fabrication techniques, there exists a relatively new and efficient patterning technique referred to as imprint lithography. An exemplary imprint lithography is described in detail in numerous publications, such as U.S. Pat. No. 6,873,087 entitled HIGH PRECISION ORIENTATION ALIGNMENT AND GAP CONTROL STAGES FOR IMPRINT LITHOGRAPHY PROCESSES; U.S. Pat. No. 6,842,226, entitled IMPRINT LITHOGRAPHY TEMPLATE COMPRISING ALIGNMENT MARKS; U.S. Pat. No. 6,696,220 entitled TEMPLATE FOR ROOM TEMPERATURE, LOW PRESSURE MICRO-AND NANO-IMPRINT LITHOGRAPHY; and U.S. Pat. No. 6,719,915 entitled STEP AND FLASH IMPRINT LITHOGRAPHY, all of which are assigned to the assignee of the present invention. The fundamental imprint lithography technique as shown in each of the aforementioned published patent applications includes formatting a relief pattern in a polymerizable layer and transferring the relief pattern into an underlying substrate to form a relief image in the substrate. To that end, a template is employed spaced-apart from the substrate with a formable liquid present between the template and the substrate. The liquid is solidified forming a solidified layer that has a pattern recorded therein that is conforming to a shape of the surface of the template in contact with the liquid. The substrate and the solidified layer are then subjected to processes to transfer into the substrate a relief image that corresponds to the pattern in the solidified layer.
As a result of the aforementioned micro-fabrication techniques, the demand to ensure the flatness/planarity of substrates being processed/patterned has increased, because of the decreasing size of the features being formed. There are a number of factors affecting substrate planarity, many of which can be corrected by conventional substrate chucks. However, the presence of backside particles, particles that contact a surface of a substrate opposite to the surface being patterned, are problematic. For example, particles may become lodged between the substrate and the chuck, referred to as backside particles, which may cause out-of-plane distortion of the substrate resulting in distortions in the pattern generated on the substrate. Out-of-plane distortions may be characterized as possessing two parameters: 1) distortion height; and 2) gap radius. The distortion height is defined as the maximum out-of-plane deviation produced in the substrate by the backside particle. Gap radius is defined as a measure of the length of a region of the substrate spaced-apart from the chuck, measured between the particle and a point of the substrate closest to the particle at which the substrate contacts the chuck. It can be realized that the area of a substrate that undergoes distortion due to the presence of particulate contaminants is much greater than the size of the particulates.
Prior art attempts to overcome particulate contaminants include pin type and groove type chucks. These chucking systems attempt to avoid the drawbacks associated with backside particles by minimizing the contact area between the substrate and the chuck. However, these chucking systems only reduce the probability of particles being lodged between the chuck and the substrate, but do not avoid or attenuate the non-planarity should a particle get lodged between a chuck and a substrate.
There is a need, therefore, to provide improved support systems for substrates.
The present invention includes a method for supporting a substrate that features a chuck body having a body surface with a pin extending therefrom having a contact surface lying in a plane, with the pin being movably coupled to the chuck body to move with respect to the plane. To that end, the method includes disposing the substrate upon two spaced-apart bodies; and moving one of the two spaced-apart bodies away from the substrate. These and other embodiments are discussed more fully below.
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In the present embodiment, sub-portions 48 of imprinting layer 34 in superimposition with projections 30 remain after the desired, usually minimum distance “d”, has been reached, leaving sub-portions 46 with a thickness t1 and sub-portions 48 with a thickness t2. Thickness t2 is referred to as a residual thickness. Thicknesses “t1” and “t2” may be any thickness desired, dependent upon the application. The total volume contained in droplets 38 may be such so as to minimize, or to avoid, a quantity of material 40 from extending beyond the region of surface 36 in superimposition with patterned mold 26, while obtaining desired thicknesses t1 and t2.
Pin cells 60 are configured so that contact lands 72 are equally loaded with force to which the same is subjected by substrate 32 resting on one of pins 61. In this manner, the load to which a given pin cell 60 is subjected is transferred to ground, i.e., foundation region 88. As a result each of pin cells 60 operates much like an ordinary pin-type chuck when supporting a “uniform normal load”. However, unlike typical pin-type chucking mechanisms, in the presence of a non-uniform load, e.g., in the presence of a particulate contaminant 92 disposed between substrate 32 and one or more of contact lands 72, one or more of pins 61 becomes compliant. Specifically, flexure stem 80 and side flexures 84 flex, allowing pins 61 to be compliant. This minimizes, if not abrogates, non-planarity in substrate 32 due to the presence of particulate contaminant 92. To that end, it is desired that the height of each of contact lands 72, measured between nadir surface 76 and contact surface 66, has a magnitude no less than the maximum dimension of anticipated particulate contaminants. As a result, in the presence of particulate contaminant 92, shown more clearly in
This is accomplished, in part, by establishing the relative bending stiffness of the various elements of each of pin cells 60 to obtain a desired movement of pin 61. For example, the bending stiffness of flexure stem 80 is less than the bending stiffness of either cross-member 70 or side flexures 84. The bending stiffness of cross-member 70 is substantially greater than side flexures 84. As a result, cross-member 70 is considered a rigid body. By establishing the relative bending stiffness among the components as mentioned above, rotation of cross-member 70 occurs about a remote axis, i.e., an axis spaced-apart from cross-member 70. As shown, various axes 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106 and 107 may function as the remote axis and, for a given pin 61, the axis among axes 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106 and 107 is dependent upon the size of particulate contaminant 92 and current configuration, i.e., designed bending stiffness ratio of flexure stem 80 to side flexures 84.
Referring to both
Base layer 112 includes a centrally disposed through hole 121 adapted to be in superimposition with throughway 120 when base layer 112 and foundation layer 110 are placed in a final seating position. In the present example the diameter of through hole 121 is approximately 2 millimeters. Typically, the entire surface of base layer 112 that faces pin layer 114 is covered with base cells 122, excepting the region in which through hole 121 is present and region 119 which is located at a periphery of base layer 112 in superimposition with rim 115 of pin layer 114. However, eight base cells 122 are shown for simplicity. The detailed arrangement of an array of nine base cells 122 is discussed with respect to region 123, shown more clearly in
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Stem 80 is fabricated to facilitate flexing along direction 132. To that end, disposed on opposed sides of flexure stem 80 are recessed regions 126, with each of recessed regions being flanked by a pair of vacuum channels 128, extending along direction 132. Specifically, regions 126 are disposed on opposing sides of flexure stem 80 with each region 126 extending from void 125 away from flexure stem 80. Recess regions 124 are arranged in two pairs, with each of the two pairs of regions 124 being disposed on opposing side of flexure stem 80. Each of recessed regions 124 associated with each pair extends from one of the vacuum channels 128, extending adjacent to one of recessed regions 126, away from the remaining recessed regions 124 associated with the pair.
In an exemplary embodiment, a width 140 of flexure stem 80 measured along direction 132 is approximately 0.05 millimeter. A length 141 of flexure stem 80, measured along direction 134 is approximately 0.3 millimeter, with flexure stem 80 extending from foundation support 88, along direction 136 a distance 142 of approximately 0.35 millimeter. A width 143 of each vacuum channel, measured transversely to a height thereof that is determined along direction 136, is approximately 0.1 millimeter. Regions 124 and 126 are recessed a distance sufficient to allow pin 61 to flex in response to a particle contaminant no greater than the largest sized particulate contaminant anticipated and to ensure that the structural integrity of pin 61 is not compromised when subjected to forces produced by the presence of a larger particulate contaminant. In the present example, regions 124 and 126 are recessed a distance of approximately 0.01 millimeter with respect to an apex 153 of flexure stem 80, along direction 136. A width 145 of pin cell 60 measured along direction 132 is approximately two millimeters, and a length 146 of pin cell 60 measured along direction 134 is approximately two millimeters. A distance 147 between adjacent vacuum channels 128 of a given pair extending parallel to one another is approximately 0.3 millimeter. A width 148 of regions 126 extending from void 125 along direction 132 is approximately 0.35 millimeter, with regions 126 extending to be coextensive with length 141 of flexure stem 80. A length 149 of regions 124 extending from an adjacent vacuum channel 128, along direction 134, is approximately 0.3 millimeter, with a width 150 measured along direction 132 being approximately 0.5 millimeter. Each of regions 124 are spaced apart from an adjacent vacuum channel 128 extending along direction 134 a distance 151 of approximately 0.1 millimeter. Thickness 152 of base layer 112 is approximately 0.5 millimeter.
Referring to both
A second pair of U-shaped throughways 160 includes a base portion 161 positioned proximate to cross-member 70 and extending between both contact lands 72. Specifically, base portion 161 extends along direction 132, transversely to direction 134, with each end thereof having a first serif portion 162 extending therefrom, away from cross-member 70 parallel to direction 134 and terminating in a second serif portion 163, defining a pair of second serif portions. Each of second serif portions 163 extends spaced-apart from and parallel to serif 159. In this manner, defined between each U-shaped throughway 157 and U-shaped throughway 160 is flexure member 84 configured with an L-shaped body. One end of flexure member 84 is connected to a corner of cross-member 70 proximate to a contact land 72, defining a primary joint 164. The remaining portion of flexure member 84 extends from primary flexure 164, terminating in a second end. Disposed proximate to, and spaced-apart from the second end of each flexure member 84 is a rectangular throughway 165, defining pair of spaced-apart secondary joints 166 proximate to the second end. The portion of flexure member 84 extending between primary joint 164 and secondary joints 166 defines a rigid body 167.
Chuck body 58 may be fabricated using any known method. In the present example, chuck body 58 is fabricated from silicon wafers using standard micro-fabrication techniques. As a result, exemplary materials from which chuck body 58 may be fabricated include silicon and/or fused silica. Furthermore, to improve wear resistance, selective surfaces, e.g. contact lands 72, may be coated with hardened materials, such as silicon nitride, silicon carbide and the like. Typically, base layer 112 is fabricated separately from pin layer 114 and subsequently made integral employing standard techniques, such as, silicon welding, forming device layer 200. As a result, vacuum channels 128 and void 125 are in fluid communication with throughways 160, 157 and 166 and throughway 120. In an exemplary technique, assembly of device layer 200 with foundation layer 110 was undertaken with surface 155 facing an optical flat and a vacuum/electrostatic force being applied to chuck device layer 200. In this fashion, non-planarity in device layer 200 may be attenuated, if not abrogated. An adhesive is then applied to either surface of base layer 112 facing foundation layer 110 or surface 116 or both. Device layer 200 is then adhered to foundation layer 110. It is desired to provide a sufficient volume of adhesive so that non-planarity induced in device layer 200 due to non-planarity in surface 116 is attenuated.
To provide desired lateral stiffness to substrate 32, adjacent pin cells 60 of chuck body 58 are arranged so that longitudinal axes 71 of cross members 70 of adjacent pin cells 60 extend along orthogonal directions, i.e., neighboring pin cells 60 are oriented at 90 degrees with respect to each other.
The embodiments of the present invention described above are exemplary. Many changes and modifications may be made to the disclosure recited above while remaining within the scope of the invention. For example, foundation layer 110 may be abrogated and device layer may be employed with standard electrostatic and/or vacuum chucking devices. In this fashion, existing chucking systems may be retrofitted with device layer 200 substantially improving the operational characteristics of existing chucking systems. The scope of the invention should, therefore, be determined not with reference to the above description, but instead should be determined with reference to the appended claims along with their full scope of equivalents.