Abstract: Provided herein are KRAS G12C inhibitors, composition of the same, and methods of using the same. These inhibitors are useful for treating a number of disorders, including pancreatic, colorectal, and lung cancers.

Abstract: The present invention relates to methods, devices and systems for associating consumable data with an assay consumable used in a biological assay. Provided are assay systems and associated consumables, wherein the assay system adjusts one or more steps of an assay protocol based on consumable data specific for that consumable. Various types of consumable data are described, as well as methods of using such data in the conduct of an assay by an assay system. The present invention also relates to consumables (e.g., kits and reagent containers), software, data deployable bundles, computer-readable media, loading carts, instruments, systems, and methods, for performing automated biological assays.

Abstract: In a method of depositing a crystalline germanium layer on a substrate, a substrate is placed in the process zone comprising a pair of process electrodes. In a deposition stage, a crystalline germanium layer is deposited on the substrate by introducing a deposition gas comprising a germanium-containing gas into the process zone, and forming a capacitively coupled plasma of the deposition gas by coupling energy to the process electrodes. In a subsequent treatment stage, the deposited crystalline germanium layer is treated by exposing the crystalline germanium layer to an energized treatment gas or by annealing the layer.

Abstract: Methods for forming boron-containing films are provided. The methods include introducing a boron-containing precursor and a nitrogen or oxygen-containing precursor into a chamber and forming a boron nitride or boron oxide film on a substrate in the chamber. In one aspect, the method includes depositing a boron-containing film and then exposing the boron-containing film to the nitrogen-containing or oxygen-containing precursor to incorporate nitrogen or oxygen into the film. The deposition of the boron-containing film and exposure of the film to the precursor may be performed for multiple cycles to obtain a desired thickness of the film. In another aspect, the method includes reacting the boron-containing precursor and the nitrogen-containing or oxygen-containing precursor to chemically vapor deposit the boron nitride or boron oxide film.

Abstract: A method for forming a compressive stress carbon-doped silicon nitride layer is provided. The method includes forming an initiation layer and a bulk layer thereon, wherein the bulk layer has a compressive stress of between about ?0.1 GPa and about ?10 GPa. The initiation layer is deposited from a gas mixture that includes a silicon and carbon-containing precursor and optionally a nitrogen and/or source but does not include hydrogen gas. The bulk layer is deposited from a gas mixture that includes a silicon and carbon-containing precursor, a nitrogen source, and hydrogen gas. The initiation layer is a thin layer that allows good transfer of the compressive stress of the bulk layer therethrough to an underlying layer, such as a channel of a transistor.

Abstract: Methods for forming boron-containing films are provided. The methods include introducing a boron-containing precursor and a nitrogen or oxygen-containing precursor into a chamber and forming a boron nitride or boron oxide film on a substrate in the chamber. In one aspect, the method includes depositing a boron-containing film and then exposing the boron-containing film to the nitrogen-containing or oxygen-containing precursor to incorporate nitrogen or oxygen into the film. The deposition of the boron-containing film and exposure of the film to the precursor may be performed for multiple cycles to obtain a desired thickness of the film. In another aspect, the method includes reacting the boron-containing precursor and the nitrogen-containing or oxygen-containing precursor to chemically vapor deposit the boron nitride or boron oxide film.

Abstract: A fabrication method and materials produce high quality aperiodic photonic structures. Light emission can be activated by thermal annealing post growth treatments when thin film layers of SiO2 and SiNx or Si-rich oxide are used. From these aperiodic structures, that can be obtained in different vertical and planar device geometries, the presence of aperiodic order in a photonic device provides strong group velocity reduction (slow photons), enhanced light-matter interaction, light emission enhancement, gain enhancement, and/or nonlinear optical properties enhancement.

Abstract: A method for forming a compressive stress carbon-doped silicon nitride layer is provided. The method includes forming an initiation layer and a bulk layer thereon, wherein the bulk layer has a compressive stress of between about ?0.1 GPa and about ?10 GPa. The initiation layer is deposited from a gas mixture that includes a silicon and carbon-containing precursor and optionally a nitrogen and/or source but does not include hydrogen gas. The bulk layer is deposited from a gas mixture that includes a silicon and carbon-containing precursor, a nitrogen source, and hydrogen gas. The initiation layer is a thin layer that allows good transfer of the compressive stress of the bulk layer therethrough to an underlying layer, such as a channel of a transistor.