Patent application number | Description | Published |
20090047784 | RESIST STRIPPING METHODS USING BACKFILLING MATERIAL LAYER - A method for fabricating a microelectronic structure provides for forming a backfilling material layer at least laterally adjacent, and preferably laterally adjoining, a resist layer located over a substrate. Preferably, the resist layer comprises a surface treated resist layer. Optionally, the backfilling material layer may be surface treated similarly to the surface treated resist layer. Under such circumstances: (1) surface portions of the backfilling material layer and resist layer; and (2) remaining portions of the backfilling material layer and resist layer, may be sequentially stripped using a two step etch method, such as a two step plasma etch method. Alternatively, a surface portion of the surface treated resist layer only may be stripped while using a first etch method, and the remaining portions of the resist layer and backfilling material layer may be planarized prior to being simultaneously stripped while using a second etch method. | 02-19-2009 |
20110006367 | GATE PATTERNING OF NANO-CHANNEL DEVICES - Methodologies and gate etching processes are presented to enable the fabrication of gate conductors of semiconductor devices, such as NFETs and/or PFETs, which are equipped with nano-channels. In one embodiment, a sacrificial spacer of equivalent thickness to the diameter of the gate nano-channel is employed and is deposited after patterning the gate conductor down to the gate dielectric. The residue gate material that is beneath the nano-channel is removed utilizing a medium to high density, bias-free, fluorine-containing or fluorine- and chlorine-containing isotropic etch process without compromising the integrity of the gate. In another embodiment, an encapsulation/passivation layer is utilized. In yet further embodiment, no sacrificial spacer or encapsulation/passivation layer is used and gate etching is performed in an oxygen and nitrogen-free ambient. | 01-13-2011 |
20120193680 | STRUCTURE WITH ISOTROPIC SILICON RECESS PROFILE IN NANOSCALE DIMENSIONS - A trench is formed by an anisotropic etch in a semiconductor material layer employing a masking layer, which can be gate spacers. In one embodiment, an adsorbed fluorine layer is provided at a cryogenic temperature only on vertical sidewalls of the semiconductor structure including the sidewalls of the trench. The adsorbed fluorine layer removes a controlled amount of the underlying semiconductor material once the temperature is raised above the cryogenic temperature. The trench can be filled with another semiconductor material to generate stress in the semiconductor material layer. In another embodiment, the semiconductor material is laterally etched by a plasma-based etch at a controlled rate while a horizontal portion of a contiguous oxide liner prevents etch of the semiconductor material from the bottom surface of the trench. | 08-02-2012 |
20120193715 | STRUCTURE WITH ISOTROPIC SILICON RECESS PROFILE IN NANOSCALE DIMENSIONS - A trench is formed by an anisotropic etch in a semiconductor material layer employing a masking layer, which can be gate spacers. In one embodiment, an adsorbed fluorine layer is provided at a cryogenic temperature only on vertical sidewalls of the semiconductor structure including the sidewalls of the trench. The adsorbed fluorine layer removes a controlled amount of the underlying semiconductor material once the temperature is raised above the cryogenic temperature. The trench can be filled with another semiconductor material to generate stress in the semiconductor material layer. In another embodiment, the semiconductor material is laterally etched by a plasma-based etch at a controlled rate while a horizontal portion of a contiguous oxide liner prevents etch of the semiconductor material from the bottom surface of the trench. | 08-02-2012 |
20130087860 | BORDERLESS SELF-ALIGNED METAL CONTACT PATTERNING USING PRINTABLE DIELECTRIC MATERIALS - Borderless self-aligned metal contacts to high density complementary metal oxide semiconductor (CMOS) circuits and methods for constructing the same. An example method includes creating an enclosed region for metal deposition defined by the gates of the adjacent transistors and an opposing pair of dielectric walls adjacent to source regions and drain regions of the adjacent transistors. The method further includes depositing a metal layer within the enclosed region. The metal contacts thus formed are self-aligned to the enclosed regions. | 04-11-2013 |
20130123159 | AQUEOUS CERIUM-CONTAINING SOLUTION HAVING AN EXTENDED BATH LIFETIME FOR REMOVING MASK MATERIAL - An aqueous solution of a cerium (IV) complex or salt having an extended lifetime is provided. In one embodiment, the extended lifetime is achieved by adding at least one booster additive to an aqueous solution of the cerium (IV) complex or salt. In another embodiment, the extended lifetime is achieved by providing an aqueous solution of a cerium (IV) complex or salt and a cerium (III) complex or salt. The cerium (III) complex or salt can be added or it can be generated in-situ by introducing a reducing agent into the aqueous solution of the cerium (IV) complex or salt. The aqueous solution can be used to remove a mask material, especially an ion implanted and patterned photoresist, from a surface of a semiconductor substrate. | 05-16-2013 |
20130143397 | USE OF AN ORGANIC PLANARIZING MASK FOR CUTTING A PLURALITY OF GATE LINES - An organic planarizing layer (OPL) is formed atop a semiconductor substrate which includes a plurality of gate lines thereon. Each gate line includes at least a high k gate dielectric and a metal gate. A patterned photoresist having at least one pattern formed therein is then positioned atop the OPL. The at least one pattern in the photoresist is perpendicular to each of the gate lines. The pattern is then transferred by etching into the OPL and portions of each of the underlying gate lines to provide a plurality of gate stacks each including at least a high k gate dielectric portion and a metal gate portion. The patterned photoresist and the remaining OPL layer are then removed utilizing a sequence of steps including first contacting with a first acid, second contacting with an aqueous cerium-containing solution, and third contacting with a second acid. | 06-06-2013 |
20140124870 | SPUTTER AND SURFACE MODIFICATION ETCH PROCESSING FOR METAL PATTERNING IN INTEGRATED CIRCUITS - One embodiment of an integrated circuit includes a plurality of semiconductor devices and a plurality of conductive lines connecting the plurality of semiconductor devices, wherein at least some of the plurality of conductive lines have pitches of less than one hundred nanometers and sidewall tapers of between approximately eighty and ninety degrees. Another embodiment of an integrated circuit includes a plurality of semiconductor devices and a plurality of conductive lines connecting the plurality of semiconductor devices, wherein at least some of the plurality of conductive lines are fabricated by providing a layer of conductive metal in a multi-layer structure fabricated upon a wafer and sputter etching the layer of conductive metal using a methanol plasma, wherein a portion of the layer of conductive metal that remains after the sputter etching forms the one or more conductive lines. | 05-08-2014 |
20140124935 | SPUTTER AND SURFACE MODIFICATION ETCH PROCESSING FOR METAL PATTERNING IN INTEGRATED CIRCUITS - One embodiment of an integrated circuit includes a plurality of semiconductor devices and a plurality of conductive lines connecting the plurality of semiconductor devices, wherein at least some of the plurality of conductive lines have line widths of less than forty nanometers. Another embodiment of an integrated circuit includes a plurality of semiconductor devices and a plurality of conductive lines connecting the plurality of semiconductor devices, wherein at least some of the plurality of conductive lines are fabricated by providing a layer of conductive metal in a multi-layer structure fabricated upon a wafer, performing a first sputter etch of the layer of conductive metal using a methanol plasma, and performing a second sputter etch of the layer of conductive metal using a second plasma, wherein a portion of the layer of conductive metal that remains after the second sputter etch forms the one or more conductive lines. | 05-08-2014 |
20140127906 | SPUTTER AND SURFACE MODIFICATION ETCH PROCESSING FOR METAL PATTERNING IN INTEGRATED CIRCUITS - Fabricating conductive lines in an integrated circuit includes providing a conductive metal in a multi-layer structure, performing a first sputter etch of the conductive metal using methanol plasma, and performing a second sputter etch of the conductive metal using a second plasma, wherein a portion of the conductive metal that remains after the second sputter etch forms the conductive lines. Alternatively, fabricating conductive lines includes providing a conductive metal as an intermediate layer in a multi-layer structure, etching the multi-layer structure to expose the conductive metal, performing a first etch of the conductive metal using methanol plasma, performing a second sputter etch of the conductive metal using a second plasma, wherein a portion of the conductive metal that remains after the second sputter etch forms the conductive lines, forming a liner that surrounds the conductive lines, and depositing a dielectric layer on the multi-layer structure. | 05-08-2014 |