Abstract: The present invention relates to a developable bottom antireflective coating (BARC) composition and a pattern forming method using the BARC composition. The BARC composition includes a first polymer having a first carboxylic acid moiety, a hydroxy-containing alicyclic moiety, and a first chromophore moiety; a second polymer having a second carboxylic acid moiety, a hydroxy-containing acyclic moiety, and a second chromophore moiety; a crosslinking agent; and a radiation sensitive acid generator. The first and second chromophore moieties each absorb light at a wavelength from 100 nm to 400 nm. In the patterning forming method, a photoresist layer is formed over a BARC layer of the BARC composition. After exposure, unexposed regions of the photoresist layer and the BARC layer are selectively removed by a developer to form a patterned structure in the photoresist layer. The BARC composition and the pattern forming method are especially useful for implanting levels.

Abstract: The profile of a via can be controlled by forming a profile control liner within each via opening that is formed into a dielectric material prior to forming a line opening within the dielectric material. The presence of the profile control liner within each via opening during the formation of the line opening prevents rounding of the corners of a dielectric material portion that is present beneath the line opening and adjacent the via opening.

Abstract: After formation of line openings in a hard mask layer, hard mask level spacers are formed on sidewalls of the hard mask layer. A photoresist is applied and patterned to form a via pattern including a via opening. The overlay tolerance for printing the via pattern is increased by the lateral thickness of the hard mask level spacers. A portion of a dielectric material layer is patterned to form a via cavity pattern by an etch that employs the hard mask layer and the hard mask level spacers as etch masks. The hard mask level spacers are subsequently removed , and the pattern of the line is subsequently transferred into an upper portion of the dielectric material layer, while the via cavity pattern is transferred to a lower portion of the dielectric material layer.

Abstract: An article including a microelectronic substrate is provided as an article usable during the processing of the microelectronic substrate. Such article includes a microelectronic substrate having a front surface, a rear surface opposite the front surface and a peripheral edge at boundaries of the front and rear surfaces. The front surface is a major surface of the article. A removable annular edge extension element having a front surface, a rear surface and an inner edge extending between the front and rear surfaces has the inner edge joined to the peripheral edge of the microelectronic substrate. In such way, a continuous surface is formed which includes the front surface of the edge extension element extending laterally from the peripheral edge of the microelectronic substrate and the front surface of the microelectronic substrate, the continuous surface being substantially co-planar and flat where the peripheral edge is joined to the inner edge.

Abstract: Disclosed is a semiconductor structure which includes a semiconductor substrate and a wiring layer on the semiconductor substrate. The wiring layer includes a plurality of fin-like structures comprising a first metal; a first layer of a second metal on each of the plurality of fin-like structures wherein the first metal is different from the second metal, the first layer of the second metal having a height less than each of the plurality of fin-like structures; and an interlayer dielectric (ILD) covering the plurality of fin-like structures and the first layer of the second metal except for exposed edges of the plurality of fin-like structures at predetermined locations, and at locations other than the predetermined locations, the height of the plurality of fin-like structures has been reduced so as to be covered by the ILD.

Abstract: The present invention relates to a hybrid photoresist composition for improved resolution and a pattern forming method using the photoresist composition. The photoresist composition includes a radiation sensitive acid generator, a crosslinking agent and a polymer having a hydrophobic monomer unit and a hydrophilic monomer unit containing a hydroxyl group. At least some of the hydroxyl groups are protected with an acid labile moiety having a low activation energy. The photoresist is capable of producing a hybrid response to a single exposure. The patterning forming method utilizes the hybrid response to form a patterned structure in the photoresist layer. The photoresist composition and the pattern forming method of the present invention are useful for printing small features with precise image control, particularly spaces of small dimensions.

Abstract: Disclosed are embodiments of an improved semiconductor wafer structure having protected clusters of carbon nanotubes (CNTs) on the back surface and a method of forming the improved semiconductor wafer structure. Also disclosed are embodiments of a semiconductor module with exposed CNTs on the back surface for providing enhanced thermal dissipation in conjunction with a heat sink and a method of forming the semiconductor module using the disclosed semiconductor wafer structure.

Abstract: A stack of an organic planarization layer (OPL) and a template layer is provided over a substrate. The template layer is patterned to induce self-assembly of a copolymer layer to be subsequently deposited. A copolymer layer is deposited and annealed to form phase-separated copolymer blocks. An original self-assembly pattern is formed by removal of a second phase separated polymer relative to a first phase separated polymer. The original pattern is transferred into the OPL by an anisotropic etch, and the first phase separated polymer and the template layer are removed. A spin-on dielectric (SOD) material layer is deposited over the patterned OPL that includes the original pattern to form SOD portions that fill trenches within the patterned OPL. The patterned OPL is removed selective to the SOD portions, which include a complementary pattern. The complementary pattern of the SOD portions is transferred into underlying layers by an anisotropic etch.

Abstract: A first metallic hard mask layer over an interconnect-level dielectric layer is patterned with a line pattern. At least one dielectric material layer, a second metallic hard mask layer, a first organic planarization layer (OPL), and a first photoresist are applied above the first metallic hard mask layer. A first via pattern is transferred from the first photoresist layer into the second metallic hard mask layer. A second OPL and a second photoresist are applied and patterned with a second via pattern, which is transferred into the second metallic hard mask layer. A first composite pattern of the first and second via patterns is transferred into the at least one dielectric material layer. A second composite pattern that limits the first composite pattern with the areas of the openings in the first metallic hard mask layer is transferred into the interconnect-level dielectric layer.

Abstract: A dielectric disposable gate structure can be formed across a semiconductor material portion, and active semiconductor regions are formed within the semiconductor material portion. Raised active semiconductor regions are grown over the active semiconductor regions while the dielectric disposable gate structure limits the extent of the raised active semiconductor regions. A planarization dielectric layer is formed over the raised active semiconductor regions. In one embodiment, the dielectric disposable gate structure is removed, and a dielectric gate spacer can be formed by conversion of surface portions of the raised active semiconductor regions around a gate cavity. Alternately, an etch mask layer overlying peripheral portions of the disposable gate structure can be formed, and a gate cavity and a dielectric spacer can be formed by anisotropically etching an unmasked portion of the dielectric disposable gate structure. A replacement gate structure can be formed in the gate cavity.

Abstract: A stack of an organic planarization layer (OPL) and a template layer is provided over a substrate. The template layer is patterned to induce self-assembly of a copolymer layer to be subsequently deposited. A copolymer layer is deposited and annealed to form phase-separated copolymer blocks. An original self-assembly pattern is formed by removal of a second phase separated polymer relative to a first phase separated polymer. The original pattern is transferred into the OPL by an anisotropic etch, and the first phase separated polymer and the template layer are removed. A spin-on dielectric (SOD) material layer is deposited over the patterned OPL that includes the original pattern to form SOD portions that fill trenches within the patterned OPL. The patterned OPL is removed selective to the SOD portions, which include a complementary pattern. The complementary pattern of the SOD portions is transferred into underlying layers by an anisotropic etch.

Abstract: A method of selectively forming a germanium structure within semiconductor manufacturing processes removes the native oxide from a nitride surface in a chemical oxide removal (COR) process and then exposes the heated nitride and oxide surface to a heated germanium containing gas to selectively form germanium only on the nitride surface but not the oxide surface.

Abstract: A stack of a first metal line and a first dielectric cap material portion is formed within a line trench of first dielectric material layer. A second dielectric material layer is formed thereafter. A line trench extending between the top surface and the bottom surface of the second dielectric material layer is patterned. A photoresist layer is applied over the second dielectric material layer and patterned with a via pattern. An underlying portion of the first dielectric cap material is removed by an etch selective to the dielectric materials of the first and second dielectric material layer to form a via cavity that is laterally confined along the widthwise direction of the line trench and along the widthwise direction of the first metal line. A dual damascene line and via structure is formed, which includes a via structure that is laterally confined along two independent horizontal directions.

Abstract: A method for defining a template for directed self-assembly (DSA) materials includes patterning a resist on a stack including an ARC and a mask formed over a hydrophilic layer. A pattern is formed by etching the ARC and the mask to form template lines which are trimmed to less than a minimum feature size (L). Hydrophobic spacers are formed on the template lines and include a fractional width of L. A neutral brush layer is grafted to the hydrophilic layer. A DSA material is deposited between the spacers and annealed to form material domains in a form of alternating lines of a first and a second material wherein the first material in contact with the spacers includes a width less than a width of the lines. A metal is added to the domains forming an etch resistant second material. The first material and the spacers are removed to form a DSA template pattern.

Abstract: A method of forming different structures of a semiconductor device using a single mask and a hybrid photoresist. The method includes: applying a first photoresist layer on a semiconductor substrate; patterning the first photoresist layer using a photomask to form a first patterned photoresist layer; using the first patterned photoresist layer to form a first structure of a semiconductor device; removing the first patterned photoresist layer; applying a second photoresist layer on the semiconductor substrate; patterning the second photoresist layer using the photomask to form a second patterned photoresist layer; using the second patterned photoresist layer to form a second structure of a semiconductor device; removing the second patterned photoresist layer; and wherein either the first or the second photoresist layer is a hybrid photoresist layer comprising a hybrid photoresist.

Abstract: A method for defining a template for directed self-assembly (DSA) materials includes forming an etch stop layer on a neutral material, forming a mask layer on the etch stop layer and forming an anti-reflection coating (ARC) on the mask layer. A resist layer is patterned on the ARC using optical lithography to form a template pattern. The ARC and the mask layer are reactive ion etched down to the etch stop layer in accordance with the template pattern to form a template structure. The ARC is removed from the mask layer and the template structure is trimmed to reduce a width of the template structure. A wet etch is performed to remove the etch stop layer to permit the neutral material to form an undamaged DSA template for DSA materials.

Abstract: A method for defining a template for directed self-assembly (DSA) materials includes patterning a resist on a stack including an ARC and a mask formed over a hydrophilic layer. A pattern is formed by etching the ARC and the mask to form template lines which are trimmed to less than a minimum feature size (L). Hydrophobic spacers are formed on the template lines and include a fractional width of L. A neutral brush layer is grafted to the hydrophilic layer. A DSA material is deposited between the spacers and annealed to form material domains in a form of alternating lines of a first and a second material wherein the first material in contact with the spacers includes a width less than a width of the lines. A metal is added to the domains forming an etch resistant second material. The first material and the spacers are removed to form a DSA template pattern.

Abstract: A dielectric disposable gate structure can be formed across a semiconductor material portion, and active semiconductor regions are formed within the semiconductor material portion. Raised active semiconductor regions are grown over the active semiconductor regions while the dielectric disposable gate structure limits the extent of the raised active semiconductor regions. A planarization dielectric layer is formed over the raised active semiconductor regions. In one embodiment, the dielectric disposable gate structure is removed, and a dielectric gate spacer can be formed by conversion of surface portions of the raised active semiconductor regions around a gate cavity. Alternately, an etch mask layer overlying peripheral portions of the disposable gate structure can be formed, and a gate cavity and a dielectric spacer can be formed by anisotropically etching an unmasked portion of the dielectric disposable gate structure. A replacement gate structure can be formed in the gate cavity.

Abstract: The profile of a via can be controlled by forming a profile control liner within each via opening that is formed into a dielectric material prior to forming a line opening within the dielectric material. The presence of the profile control liner within each via opening during the formation of the line opening prevents rounding of the corners of a dielectric material portion that is present beneath the line opening and adjacent the via opening.

Abstract: A method for defining a template for directed self-assembly (DSA) materials includes forming an etch stop layer on a neutral material, forming a mask layer on the etch stop layer and forming an anti-reflection coating (ARC) on the mask layer. A resist layer is patterned on the ARC using optical lithography to form a template pattern. The ARC and the mask layer are reactive ion etched down to the etch stop layer in accordance with the template pattern to form a template structure. The ARC is removed from the mask layer and the template structure is trimmed to reduce a width of the template structure. A wet etch is performed to remove the etch stop layer to permit the neutral material to form an undamaged DSA template for DSA materials.