MULTI-EXPOSURE LITHOGRAPHY EMPLOYING DIFFERENTIALLY SENSITIVE PHOTORESIST LAYERS
A stack of a second photoresist having a second photosensitivity and a first photoresist having a first photosensitivity, which is greater than second photosensitivity, is formed on a substrate. A first pattern is formed in the first photoresist by a first exposure and a first development, while the second photoresist underneath remains intact. A second pattern comprising an array of lines is formed in the second photoresist. An exposed portion of the second photoresist underneath a remaining portion of the first photoresist forms a narrow portion of a line pattern, while an exposed portion of the second photoresist outside the area of the remaining portions of the photoresist forms a wide portion of the line pattern. Each wide portion of the line pattern forms a bulge in the second pattern, which increases overlay tolerance between the second pattern and the pattern of conductive vias.
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This application is a divisional of U.S. patent application Ser. No. 12/139,722, filed Jun. 16, 2008 the entire content and disclosure of which is incorporated herein by reference.
FIELD OF THE INVENTIONThe present invention relates to semiconductor processing methods, and particularly to methods for multi-exposure lithography employing a vertical stack of differentially sensitive photosensitive layers, and structures for effecting the same.
BACKGROUND OF THE INVENTIONLithography is employed in semiconductor manufacturing to pattern features in a photoresist. A layer of photoresist is exposed to incident light, which may be deep-ultraviolet (DUV) radiation, mid-ultraviolet (MUV) radiation, or X-ray radiation. Alternately, the layer of photoresist may be exposed to energetic electron in e-beam lithography. The energy of the photons or electrons causes changes in chemical composition of exposed portions of the photoresist, for example, by cross-linkage, scission, side chain removal, etc. Pre-baking or post-baking of the photoresist may be employed to maximize the changes in the chemical properties of the exposed portion of the photoresist relative to unexposed portions of the photoresist.
The exposed photoresist is developed to remove one of the set of exposed portions of the photoresist and the set of unexposed portions of the photoresist relative to the other. The photoresist is classified as a positive photoresist or a negative photoresist depending on the nature of the chemical changes upon exposure. If the photoresist becomes chemically less stable upon exposure, the photoresist is a positive photoresist. If the photoresist becomes chemically more stable upon exposure, the photoresist is a negative photoresist. In case a positive photoresist is employed, the exposed portions of the positive photoresist are removed upon development. In case a negative photoresist is employed, the unexposed portions of the negative photoresist are removed upon development.
A developed photoresist comprises a lithographic pattern. The features of the lithographic pattern have dimensions that are the same as, or greater than, a “minimum feature size,” which is also called a “critical dimension.” The minimum feature size is a function of a lithography tool employed to form the lithographic pattern. The minimum feature size F that a projection system can print is given approximately by:
F=k×λ/NA,
where k is a coefficient that reflects tool specific proportionality constant reflecting the efficiency of the lithography system and other process related factors, λ is the wavelength of the light employed for radiation, and NA is the numerical aperture of the lens. Typically, the value of the coefficient k is in the range of about 0.5.
While the minimum feature size is defined only in relation to a lithography tool and normally changes from generation to generation of semiconductor technology, it is understood that the minimum feature size, i.e., the critical dimension, is to be defined in relation to the best performance of lithography tools available at the time of semiconductor manufacturing. The minimum feature sizes include a minimum line width and a minimum line spacing for a nested line pattern, and a minimum via hole diameter for a nested via hole pattern. In general, the minimum feature sizes vary depending on the geometry of the features to be printed on a photoresist. Given geometry and given a specific lithography tool, however, minimum feature sizes are defined as a quantifiable number. Further, since the minimum achievable wavelength is determined by the type of the light source in commercially available lithography tools, for given geometry, the minimum feature sizes may be defined based on the technological capabilities at any given time. As of 2008, the minimum feature sizes are about 50 nm and are expected to shrink in the future. Any dimension less than the lithographic minimum dimension is called a “sublithographic dimension.”
The pattern in the developed photoresist is subsequently transferred into an underlying layer employing the developed photoresist and an etch mask. Thus, the dimensions of features that may be formed in a semiconductor structure are directly tied to the dimensions of features in the developed photoresist. The minimum pitch of a repetitive lithographic pattern is the twice the minimum feature size since each unit pattern includes a line and a space or a via hole and a surrounding spacer.
Standard lithographic methods form patterns having lithographic dimensions, i.e., dimensions that are greater than the minimum feature size. Each generation of lithography tools thus impose a limitation on the width, spacing, and the pitch of a lithographic pattern. Such limitations are an inherent limit on the size of unit cells of an array of semiconductor devices. For example, static random access memory (SRAM) devices, dynamic random access memory (DRAM) devices, and flash memory devices employ an array of unit cells.
Such a unit cell typically employs features at or near the minimum feature size, which is enabled by the lithography tool employed in the manufacturing process. Frequently, the array of the unit cell employs a two-dimensional array of contact vias and a one dimensional array of conductive lines to maximize the wiring density. For example, the array of the unit cell may comprise a two-dimensional array of substrate contact vias, a one dimensional array of first metal lines, a two-dimensional array of first conductive vias above the first metal lines, a one dimensional array of second metal lines, etc.
An exemplary prior art wiring structure is shown in
The conductive lines 170 are arranged in a one-dimensional array so that the conductive lines 170 have a second lithographic pitch LP2′, which is a pitch that may be formed by lithographic methods, and have a second lithographic spacing LS2′, which is a spacing that may be formed by lithographic methods. The second lithographic spacing LS2′ is the same as the second lithographic pitch LP2′ less the dimension of a conductive line 170 in the direction of the measurement of the second lithographic pitch LP2′. The first lithographic pitch LP1′ and the second lithographic pitch LP2′ are along the same direction and commensurate. Particularly, the first lithographic pitch LP1′ and the second lithographic pitch LP2′ are the same.
Successful fabrication of the exemplary semiconductor structures in
In view of the above, there exists a need for a method of forming wiring structures that provide greater overlay tolerance, and yet provide functional wiring for an array of semiconductor devices.
Further, there exists a need to locally manipulate lithographic images to increase overlay budget so that wiring density may be increased and scaling down of dimensions of semiconductor devices may be facilitated without risking electrical shorts or electrical opens.
SUMMARY OF THE INVENTIONThe present invention provides methods of forming local manipulation of lithographic images in a conductive line so that a local bulge, which has a greater width than the width of the conductive line in neighboring portions, is formed in the portion of the conductive line which a contact via vertically abuts. Such a local bulge increases overlay budget in the lithography process, thereby facilitating scaling of dimensions below lithographic minimum feature dimensions.
In the present invention, a second photoresist having a second photosensitivity is formed on a substrate. A first photoresist having a first photosensitivity, which is greater than second photosensitivity, is formed on the second photoresist. A first pattern is formed in the first photoresist by a first exposure and a first development, while the second photoresist remains intact. A second pattern comprising an array of lines is formed in the second photoresist. An exposed portion of the second photoresist underneath a remaining portion of the first photoresist forms a narrow portion of a line pattern, while an exposed portion of the second photoresist outside the area of the remaining portions of the photoresist forms a wide portion of the line pattern. The overlap of the first pattern and the second pattern may be optimized so that each wide portions of the line pattern forms a bulge in the second pattern, so that the bulges in the second pattern coincide location of conductive vias beneath or above the line to be formed according to the second pattern. The bulges in the second pattern increases overlay tolerance between the second pattern and the pattern of the conductive vias.
According to an aspect of the present invention, a method of forming a patterned structure is provided, which comprises:
forming a stack of, from bottom to top, a second photoresist and a first photoresist on a substrate;
lithographically patterning the first photoresist with a first pattern, wherein a top surface of the second photoresist is exposed in an area of the first pattern; and
lithographically forming a second pattern in the second photoresist, wherein the second pattern includes a plurality of line troughs, wherein each of the plurality of line troughs includes a narrow portion having a first width, and wherein at least one of the plurality of line troughs includes a bulge portion having a second width greater than the first width, wherein the bulge portion is formed underneath the area of the first pattern.
In one embodiment, the second photoresist has a second photosensitivity and the first photoresist has a first photosensitivity, and wherein the first photosensitivity is greater than the second photosensitivity.
In another embodiment, the second pattern is formed by simultaneously lithographically exposing the first photoresist having the first pattern and the second photoresist with a light exposure pattern generated by a lithographic mask containing a pattern of a set of parallel lines of a constant width.
In yet another embodiment, the method further comprises:
transferring the second pattern into the substrate by etching, wherein the second pattern is replicated in an upper surface of the substrate; and
forming a plurality of conductive lines embedded in the substrate, wherein each of the plurality of conductive lines includes a narrow conductive portion having a third width, and wherein at least one of the plurality of conductive lines includes a conductive bulge portion having a fourth width greater than the third width.
According to another aspect of the present invention, a patterned structure is provided, which comprises:
at least one exposed second photoresist portion located on a substrate and laterally abutted by at least one second photoresist portion, wherein the at least one second photoresist portion comprises a second unexposed photosensitive material and the at least one exposed second photoresist portion comprises a second exposed photosensitive material, wherein the second exposed photoresist material is a material derived from the second unexposed photoresist material by lithographic exposure, i.e., an exposed portion of a second photoresist constitutes the second exposed photoresist material and an unexposed portion of the second photoresist constitutes the second unexposed photoresist material; and
at least one exposed first photoresist portion located directly on the at least one exposed second photoresist portion and the at least one second photoresist portion and comprising a first exposed photosensitive material.
In one embodiment, the first exposed photoresist material is a material derived from a first unexposed photoresist material by lithographic exposure, and the first unexposed photoresist material has a first photosensitivity and the second unexposed photosensitive material has a second photosensitivity, and wherein the first photosensitivity is greater than the second photosensitivity.
According to yet another aspect of the present invention, a patterned structure is provided, which comprises a plurality of conductive lines embedded in a substrate, arranged in a periodic array, and separated by an insulating material therebetween, wherein each of the plurality of conductive lines includes a narrow conductive portion having a first width, and wherein at least one of the plurality of conductive lines includes a conductive bulge portion having a second width greater than the first width, and wherein the conductive bulge portion is separated from a neighboring conductive line by a sublithographic spacing.
In one embodiment, the conductive bulge portion is separated by the sublithographic spacing from a narrow conductive portion in the neighboring conductive line.
In another embodiment, the conductive bulge portion is separated by the sublithographic spacing from another conductive bulge portion in the neighboring conductive line.
In yet another embodiment, the plurality of conductive lines comprises a two-dimensional array of a unit cell structure having a horizontal cross-sectional area of a parallelogram or a rectangle.
In still another embodiment, a first length of a first side of the parallelogram or the rectangle is a distance between a neighboring pair of conductive bulge portions along a lengthwise direction of the plurality of conductive lines, and a second length of the second side of the parallelogram or the rectangle is a distance between another neighboring pair of the conductive bulge portions located in neighboring conductive lines.
In even another embodiment, the patterned structure further comprises an array of conductive vias in another two dimensional array having another unit cell structure having a same horizontal cross-sectional area as the unit cell structure.
In a further embodiment, the unit cell structure comprises a dielectric material portion having a constant width of the sublithographic spacing and laterally abutted by a pair of the plurality of conductive lines.
As stated above, the present invention relates to methods for multi-exposure lithography employing a vertical stack of differentially sensitive photosensitive layers, and structures for effecting the same, which are now described in detail with accompanying figures. As used herein, when introducing elements of the present invention or the preferred embodiments thereof, the articles “a”, “an”, “the” and “said” are intended to mean that there are one or more of the elements. Throughout the drawings, the same reference numerals or letters are used to designate like or equivalent elements. Detailed descriptions of known functions and constructions unnecessarily obscuring the subject matter of the present invention have been omitted for clarity. The drawings are not necessarily drawn to scale.
Referring to
Each of the first, second, and third exemplary wiring structures comprises a substrate 10 in which a plurality of conductive lines 70 is embedded. Each of the conductive lines 70 comprises a conductive material such as a metal or a doped semiconductor material. The plurality of conductive lines 70 may be arranged in a periodic array. Each of the conductive lines 70 is separated by an insulating material portion 72. Each of the plurality of conductive lines includes a narrow conductive portion NCP having a first width W1. At least one of the plurality of conductive lines 70 includes a conductive bulge portion CBP having a second width W2, which greater than the first width W1.
A plurality of conductive vias 60 is also embedded in the substrate 10. Each of the conductive vias 60 comprises a conductive material such as a metal or a doped semiconductor material. The plurality of conductive vias 60 may be arranged in a periodic array. The plurality of conductive vias 60 may be located directly on top surfaces of the conductive lines 70 as shown in
The substrate 10 may include a semiconductor-device-containing substrate 9 including at least one semiconductor device. The plurality of conductive vias 60 may be formed within the semiconductor-device-containing substrate 9, or may be formed in a via-level dielectric layer 62 as embedded structures.
In one embodiment, the plurality of conductive lines 70 comprises a two-dimensional array of a unit cell structure UC having a horizontal cross-sectional area of a parallelogram or a rectangle. Specifically, the unit cell structure in the first and third exemplary wiring structures is a parallelogram which is not a rectangle as shown in
The plurality of conductive vias 60 may also comprise a two-dimensional array. A unit cell structure of the array of the plurality of conductive vias 60 may have the same horizontal cross-sectional area the unit cell structure. Particularly, the location of each conductive via 60 may substantially coincide with a geometric center of one of the conductive bulge portions CBP in the array of the conductive lines 70 so that the entirety of the conductive vias 60 abutting the plurality of conductive lines 70 is confined within the boundaries of the conductive lines in a see-through top-down view.
According to the present invention, each of the conductive bulge portion CBP is separated from a neighboring conductive line 70 by a sublithographic spacing SLS. Particularly, the unit cell structure UC comprises a dielectric material portion DMP having a constant width of the sublithographic spacing SLS and laterally abutted by a pair of the plurality of conductive lines 70.
In the case of the first exemplary wiring structures shown in
In the case of the second exemplary wiring structure shown in
As will be subsequently described, the width of each narrow conductive portion NCP, i.e., the first width W1, is a lithographic line width, which is at least a minimum lithographic width of a nested line pattern generated by a lithography tool employed to pattern the narrow conductive portions NCP. The spacing between a neighboring pair of narrow conductive portions NCP, which is herein referred to as a second lithographic spacing LS2, is a lithographic spacing, which is at least a minimum lithographic spacing of the nested line pattern generated by the lithography tool employed to pattern the narrow conductive portions NCP. The sum of the first width W1 and the second lithographic spacing LS2, which is the sum of the lithographic line width and the lithographic spacing of the nested line pattern generated by the lithography tool employed to pattern the narrow conductive portions NCP, is the lithographic pitch of the nested line pattern generated by the lithography tool, and is herein referred to as a second lithographic pitch LP2. The first width W1 may be the lithographic minimum width, which is the minimum width that may be obtained with the lithography tool for nested line patterns. Likewise, the second lithographic spacing LS2 may be the lithographic minimum spacing, which is the minimum spacing that may be obtained with the lithography tool for nested line patterns.
The sublithographic spacing SLS may be the second lithographic pitch LP2 less the second width W2, i.e., the width of a conductive bulge portion CBP. Since the second lithographic pitch LP2 is equal to the sum of the width of each narrow conductive portion NCP and the spacing between a neighboring pair of narrow conductive portions NCP, the sublithographic spacing SLS may be equal to the sum of the first width W1 and the second lithographic spacing LS2 less the second width W2. The width of the conductive bulge portion CBP, i.e., the second width W2, is not determined by lithographic limitations of a single exposure, but is determined by a combination of two exposures employing a stack of two photoresists. Consequently, the sublithographic spacing SLS is not limited by any single lithographic process, thereby being a “sublithographic” spacing having a dimension less than the minimum lithographic spacing imposed by the limitations of geometry and the lithography tool employed to form the nested line pattern of the narrow conductive portions NCP.
In case the plurality of conductive vias 60 comprises a two-dimensional array, the pitch of the two-dimensional array is herein referred to as a first lithographic pitch LP1. The direction of the first lithographic pitch LP1 may be different from the direction of the second lithographic pitch LP2. The conductive vias 60 belonging to a neighboring row are offset from the conductive vias 60 in a row by half of the first length L1, i.e., half the periodicity of the unit cell structure UC in the lengthwise direction of the conductive lines 70. Such offset enables dense packing of conductive vias 60 and conductive lines 70.
Preferably, lateral dimensions of each of the conductive bulge portions CBP in the conductive lines 70 are selected such that edges of the conductive vias 60 are located within the conductive bulge portions CBP even with overlay variation. In other words, the cross-sectional areas of the conductive vias 60, which are designed to be placed on or under the conductive lines 70, are confined within the cross-sectional areas of the conductive lines even after lateral displacement of the conductive vias 60 within the limits of the overlay budget necessarily involved in fabrication of the conductive lines 70 and the conductive vias 60. Thus, the conductive bulge portions CBP enable scaling of dimensions in the direction of the second width W2, i.e., in the direction perpendicular to the lengthwise direction of the conductive lines 70.
Referring to
The second photoresist 20 has a second photosensitivity and the first photoresist 30 has a first photosensitivity at least over a wavelength range for lithographic exposure. The first photosensitivity is greater than the second photosensitivity, i.e., the first photoresist 30 may be developed with less lithographic exposure to light than the second photoresist 20. The vertical stack of the second photoresist 20 and the first photoresist 30 comprises differentially sensitive photoresist layers, i.e., photoresist layers having different photosensitivity.
The second photoresist 20 may be a typical deep ultra-violet (DUV) photoresist, a typical mid-ultraviolet (MUV) photoresist, a typical extreme ultraviolet (EUV), or a typical electron beam resist.
The first photoresist 30 comprises a material that absorbs light at the imaging wavelength of the second photoresist 20, and thus blocks light associated with side lobe printing during from reaching the second photoresist 20. It is preferred that the first photoresist 30 has an absorption parameter k greater than the absorption parameter of the second photoresist 20 at the imaging wavelength of the second photoresist 20. The absorption parameter k indicates the amount of absorption loss when an electromagnetic wave propagates through a material, such as a photoresist. The absorption parameter of the first photoresist 30 is preferably in the range from about 0.05 to about 0.8, more preferably in the range from about 0.08 to about 0.5 at the imaging wavelength of the second photoresist 20.
The differential photosensitivity across the first photoresist 30 and the second photoresist 20 may be effected by employing different photosensitive chemicals across the first photoresist 30 and the second photoresist 20. In this case, the first photoresist 20 comprises a first photosensitive chemical and the second photoresist 20 comprises a second photosensitive chemical. The first photosensitive chemical has greater photosensitivity than the second photosensitive chemical.
The material of the first photoresist 30 that is employed in the present invention includes, but is not limited to, a composition referred to as a “grey resist.” A grey resist includes a resist polymer with an absorbing moiety. The absorbing moiety of the resist polymer of the grey resist may be any chemical moieties that absorb radiation at the exposure wavelength. Preferably, the absorbing moiety includes, but is not limited to, unsubstituted and substituted aromatic moieties such as benzene, naphthalene, hydroxy-substituted benzene, and hydroxy-substituted naphthalene. Examples of resist polymers for the grey resist include polymers containing polycyclic moieties commonly used in 193 nm photoresists and phenol groups commonly used in 248 nm photoresists. The grey resist is selected to be photoimageable at the same wavelength of light as the second photoresist 20, and is also developable with an aqueous base developing solution typically used to develop the second photoresist 20. In addition to the resist polymer, the grey resist further comprises a photoacid generator and a solvent. Preferably, the grey resist also contains a quencher.
In a preferred embodiment, the first photoresist 30 is a positive photoresist that becomes chemically less stable upon lithographic exposure to light. The second photoresist 20 is another positive photoresist that becomes chemically less stable upon exposure.
The thickness of the second photoresist 20 may be from about 50 nm to about 600 nm, and typically from about 100 nm to about 300 nm, although lesser and greater thicknesses are also contemplated herein. The thickness of the first photoresist 30 may be from about 5 nm to about 200 nm, and typically from about 10 nm to about 100 nm, although lesser and greater thicknesses are also contemplated herein.
Referring to
The first pattern may include line troughs in the horizontal direction. In this case, a first lithographic mask 100, shown in
After the first exposure and the first development, the first photoresist 30 is patterned so that top surfaces of the second photoresist 20 are exposed underneath the line troughs. The second photoresist 20, which is less sensitive than the first photoresist 30, remains substantially intact, i.e., the entirety of the second photoresist 20 remains throughout the first exposure and the first development.
Referring to
Specifically, the remaining portion of the first photoresist 30, which has the first pattern, and the second photoresist 20 are simultaneously lithographically exposed with a light exposure pattern generated by a second lithographic mask 200, which is shown in
The light exposure pattern generated by the second lithographic mask 200 has a modulation of light intensity in a direction perpendicular to the set of parallel lines, i.e., in the horizontal direction corresponding to the pattern of vertical lines in the second lithographic mask 200. Due to the wave properties of light and imperfections in the optical properties of the material employed in the transparent portions 202 and the opaque portions 220, however, light intensity is non-zero throughout an exposure filed, which includes the entirety of the first exemplary lithographic structure. In other words, the intensity of light impinging on the remaining portions of the first photoresist 30 does not have a square waveform having zero intensity regions between non-zero intensity regions, but have a continuously modulating waveform which is non-zero throughout the field of the exposure. Since the first photosensitivity, i.e., the sensitivity of the first photoresist 30, is greater than the second photosensitivity, i.e., the sensitivity of the second photoresist 20, the entirety of the first photoresist 30 having the first pattern is exposed during the second exposure to be converted to the exposed first photoresist portions 30X.
Unlike the first photoresist 30, the second photoresist is exposed only in regions illuminated with sufficient light intensity since the second photosensitivity is lower than the first photosensitivity. The since the first photoresist 30 absorbs and blocks light to an underlying portion of the second photoresist 20, the regions of the second photoresist 20 underlying the line troughs between the remaining portions of the first photoresist 30 (See
Referring to
The second pattern includes a plurality of line troughs running in the vertical direction, i.e., in the direction perpendicular to the direction of the line troughs in the first pattern in the remaining portion of the first photoresist 20 prior to removal thereof. Each of the plurality of line troughs includes a narrow portion having a first width W1, which corresponds to the first width W1 of the first and second exemplary wiring structures of
Further, at least one of the plurality of line troughs includes a bulge portion having a second width W2, which corresponds to the second width W2 of the first and second exemplary wiring structures of
The width of the narrow portions of the vertical line troughs in the second photoresist 20, i.e., the first width W1, is a lithographic width, of which the dimension is limited by lithography and is at least a minimum lithographic spacing of the lithography tool employed to generate the second pattern. The spacing between a neighboring pair of wide portions of the vertical line troughs in the second photoresist, i.e., the distance between two neighboring line trough portions having the second width W2, may be a sublithographic width, which is less than the minimum line width for nested line structures. The portions of the second photoresist 20 between neighboring pairs of line trough portions having the second width W2 are supported by portions of the second photoresist 20 having a greater width and located between line trough portions having the first width W1. Due to such lateral structural support, the distance between a neighboring pair of line trough portions having the second width W2 may be a sublithographic dimension, which may not be achieved in nested line and space structures due to lack of lateral support, i.e., a straight line photoresist portion having such a sublithographic distance as a line width would fall for lack of lateral support. The width of the portions of the second photoresist 20 between a pair of neighboring narrow line trough portions having the first width W1 is a first lithographic width LW1, which may be substantially the same as the second lithographic spacing LS2 in
The first exemplary lithographic structure and/or variations of the first exemplary lithographic structure may be employed to form the first, second, or third exemplary wiring structure of
A conductive material is filled in the line troughs formed in the upper portion of the substrate 10, and is subsequently planarized to form a plurality of conductive lines 70 (See
Referring to
A third lithographic mask 300 shown in
After the first exposure and the first development, the first photoresist 30 is patterned so that top surfaces of the second photoresist 20 are exposed underneath the cavities. The second photoresist 20, which is less sensitive than the first photoresist 30, remains substantially intact, i.e., the entirety of the second photoresist 20 remains throughout the first exposure and the first development.
Referring to
The second pattern includes a plurality of line troughs running in the vertical direction, i.e., in the direction perpendicular to the direction of the line troughs in the first pattern in the remaining portion of the first photoresist 20 prior to removal thereof. Each of the plurality of line troughs includes a narrow portion having a first width W1, which corresponds to the first width W1 of the first and second exemplary wiring structures of
The remaining portion of the first photoresist 30, which has the first pattern, and the second photoresist 20 are simultaneously lithographically exposed with a light exposure pattern generated by a fourth lithographic mask 400, which is shown in
The light exposure pattern generated by the second lithographic mask 200 has a modulation of light intensity in a direction perpendicular to the set of parallel lines, i.e., in the horizontal direction corresponding to the pattern of vertical lines in the fourth lithographic mask 400 in the same manner as in the steps of the second exposure and the second development of the first exemplary lithographic structure described above. During the second development, all of the remaining portions of the first photoresist having the first pattern are developed and removed.
The second exemplary lithographic structure may be employed to form a wiring structure in the same manner as described above.
Embodiments in which an anti-reflective coating layer is employed are explicitly contemplated herein. Referring to
Since the ARC layer 12 is not photosensitive, continuation of processing employing the methods for forming the first exemplary lithographic structure provides the third exemplary lithographic structure shown in
While the invention has been described in terms of specific embodiments, it is evident in view of the foregoing description that numerous alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the invention is intended to encompass all such alternatives, modifications and variations which fall within the scope and spirit of the invention and the following claims.
Claims
1. A patterned structure comprising:
- at least one exposed second photoresist portion located on a substrate and laterally abutted by at least one second photoresist portion, wherein said at least one second photoresist portion comprises a second unexposed photosensitive material and said at least one exposed second photoresist portion comprises a second exposed photosensitive material, wherein said second exposed photoresist material is a material derived from said second unexposed photoresist material by lithographic exposure; and
- at least one exposed first photoresist portion located directly on said at least one exposed second photoresist portion and said at least one second photoresist portion and comprising a first exposed photosensitive material.
2. The patterned structure of claim 1, wherein said first exposed photoresist material is a material derived from a first unexposed photoresist material by lithographic exposure.
3. The patterned structure of claim 2, wherein said first unexposed photoresist material has a first photosensitivity and said second unexposed photosensitive material has a second photosensitivity, and wherein said first photosensitivity is greater than said second photosensitivity.
4. The patterned structure of claim 3, wherein said first unexposed photoresist material is a positive photoresist that becomes chemically less stable upon exposure.
5. The patterned structure of claim 4, wherein said second unexposed photoresist material is another positive photoresist that becomes chemically less stable upon exposure.
6. The patterned structure of claim 1, wherein a portion of said at least one exposed second photoresist portion does not underlie said at least one exposed first photoresist portion.
7. The patterned structure of claim 6, wherein a portion of said at least one second photoresist portion does not underlie said at least one exposed first photoresist portion.
8. The patterned structure of claim 1, wherein said at least one exposed second photoresist portion comprises a plurality of exposed second photoresist lines in a first one-dimensional array, and wherein said at least one second photoresist portion comprises a plurality of unexposed second photoresist lines in a second one-dimensional array.
9. The patterned structure of claim 8, wherein each of said plurality of exposed second photoresist lines comprises:
- at least one narrow exposed second photoresist line portion having a first width and underlying said at least one second photoresist portion; and
- at least one wide exposed second photoresist line portion having a second width and not underlying said at least one second photoresist portion.
10. The patterned structure of claim 9, wherein said second width is greater than said first width.
11. The patterned structure of claim 1, wherein said at least one exposed first photoresist portion comprises a plurality of exposed first photoresist lines in a one-dimensional array.
12. The patterned structure of claim 11, wherein each of said plurality of exposed first photoresist lines has a constant width and a constant spacing from a neighboring exposed first photoresist line.
13. The patterned structure of claim 12, wherein one of said at least one exposed second photoresist portion is located underneath said at least one exposed first photoresist portion and is a narrow portion of a line pattern, and another of said at least one exposed second photoresist portion is located outside an area of said at least one exposed first photoresist portion and is a wide portion of said line pattern.
14. The patterned structure of claim 13, wherein a lengthwise direction of said plurality of exposed first photoresist lines is perpendicular to a lengthwise direction of said line pattern including said at least one exposed second photoresist portion.
15. The patterned structure of claim 1, wherein said at least one exposed first photoresist portion comprises an exposed grey resist.
16. A patterned structure comprising:
- at least one exposed second photoresist portion located on a substrate and laterally abutted by at least one second photoresist portion, wherein said at least one second photoresist portion comprises a second unexposed photosensitive material and said at least one exposed second photoresist portion comprises a second exposed photosensitive material, wherein said second exposed photoresist material is a material derived from said second unexposed photoresist material by lithographic exposure; and
- at least one exposed first photoresist portion located directly on said at least one exposed second photoresist portion and said at least one second photoresist portion and comprising a first exposed photosensitive material, wherein one of said at least one exposed second photoresist portion is located underneath said at least one exposed first photoresist portion and is a narrow portion of a line pattern, and another of said at least one exposed second photoresist portion is located outside an area of said at least one exposed first photoresist portion and is a wide portion of said line pattern.
17. The patterned structure of claim 16, wherein said first exposed photoresist material is a material derived from a first unexposed photoresist material by lithographic exposure.
18. The patterned structure of claim 16, wherein a portion of said at least one exposed second photoresist portion does not underlie said at least one exposed first photoresist portion.
19. The patterned structure of claim 16, wherein said at least one exposed first photoresist portion comprises a plurality of exposed first photoresist lines in a one-dimensional array.
20. A patterned structure comprising:
- at least one exposed second photoresist portion located on a substrate and laterally abutted by at least one second photoresist portion, wherein said at least one second photoresist portion comprises a second unexposed photosensitive material and said at least one exposed second photoresist portion comprises a second exposed photosensitive material, wherein said second exposed photoresist material is a material derived from said second unexposed photoresist material by lithographic exposure; and
- at least one exposed first photoresist portion located directly on said at least one exposed second photoresist portion and said at least one second photoresist portion and comprising a first exposed photosensitive material, wherein said first exposed photoresist material is a material derived from a first unexposed photoresist material by lithographic exposure, said at least one exposed first photoresist portion comprises a plurality of exposed first photoresist lines in a one-dimensional array, each of said plurality of exposed first photoresist lines has a constant width and a constant spacing from a neighboring exposed first photoresist line, one of said at least one exposed second photoresist portion is located underneath said at least one exposed first photoresist portion and is a narrow portion of a line pattern, and another of said at least one exposed second photoresist portion is located outside an area of said at least one exposed first photoresist portion and is a wide portion of said line pattern, and a lengthwise direction of said plurality of exposed first photoresist lines is perpendicular to a lengthwise direction of said line pattern including said at least one exposed second photoresist portion.
Type: Application
Filed: Feb 28, 2012
Publication Date: Jun 21, 2012
Applicant: International Business Machines Corporation (Armonk, NY)
Inventors: Wu-Song Huang (Brewster, NY), Wai-kin Li (Beacon, NY), Ping-Chuan Wang (Hopewell Junction, NY)
Application Number: 13/406,965
International Classification: B32B 3/00 (20060101);