Abstract: Described herein are methods and computer systems for classification of CD8 T-cell topology using a patient response-based linear cutoff model. A plurality of histology images of tissue samples in a plurality of patients are received by a computer system. An image analysis of the plurality of histology images is performed to obtain a CD8+ T-cell abundance in the tumor parenchyma and stroma in each of the plurality of histology images. Real inflammation scores and tumor infiltration scores are determined based on a polar coordinate transformation of the CD8+ T-cell abundance in the tumor parenchyma and stroma. Based on the real inflammation scores and tumor infiltration scores, a feature space is generated, and linear boundaries or linear cutoffs between a plurality of classifications in the feature space are identified based on the real inflammation scores, the tumor infiltration scores, and patient response data.

Abstract: A gas delivery substrate for mounting gas supply components of a gas delivery system for a semiconductor processing apparatus is provided. The substrate may include a plurality of layers having major surfaces thereof bonded together forming a laminate with openings for receiving and mounting first, second, third and fourth gas supply components on an outer major surface. The substrate may include a first gas channel extending across an interior major surface that at least partially overlaps a second gas channel extending across a different interior major surface. The substrate may include a first gas conduit including the first gas channel connecting the first gas supply component to the second gas supply component, and a second gas conduit including the second channel connecting the third gas supply component to the fourth gas supply component. Also disclosed are various techniques for manufacturing gas delivery substrates.

Abstract: Methods and apparatuses for additively manufactured tubular passages, additively manufactured manifolds, and additively manufactured heaters are provided.

Abstract: A gas delivery substrate for mounting gas supply components of a gas delivery system for a semiconductor processing apparatus is provided. The substrate may include a plurality of layers having major surfaces thereof bonded together forming a laminate with openings for receiving and mounting first, second, third and fourth gas supply components on an outer major surface. The substrate may include a first gas channel extending across an interior major surface that at least partially overlaps a second gas channel extending across a different interior major surface. The substrate may include a first gas conduit including the first gas channel connecting the first gas supply component to the second gas supply component, and a second gas conduit including the second channel connecting the third gas supply component to the fourth gas supply component. Also disclosed are various techniques for manufacturing gas delivery substrates.

Abstract: A gas delivery substrate for mounting gas supply components of a gas delivery system for a semiconductor processing apparatus is provided. The substrate may include a plurality of layers having major surfaces thereof bonded together forming a laminate with openings for receiving and mounting first, second, third and fourth gas supply components on an outer major surface. The substrate may include a first gas channel extending across an interior major surface that at least partially overlaps a second gas channel extending across a different interior major surface. The substrate may include a first gas conduit including the first gas channel connecting the first gas supply component to the second gas supply component, and a second gas conduit including the second channel connecting the third gas supply component to the fourth gas supply component. Also disclosed are various techniques for manufacturing gas delivery substrates.

Abstract: Methods and apparatuses for additively manufactured tubular passages, additively manufactured manifolds, and additively manufactured heaters are provided.

Abstract: Methods and apparatuses for additively manufactured tubular passages, additively manufactured manifolds, and additively manufactured heaters are provided.

Abstract: Component-locating templates or masks for use with positioning fluid-flow components on monolithic ceramic substrates are provided, as well as techniques for the manufacture of such templates.

Abstract: A manifold constructed by additive manufacturing for use in semiconductor processing tools is provided. The manifold may include a mixing chamber and portions of a plurality of flow paths with each flow path including a first fluid flow component interface, a second fluid flow component interface, a first tubular passage fluidically connecting the first mixing chamber with a first fluid flow component interface outlet of that flow path, and a second tubular passage fluidically connecting a first fluid flow component interface inlet of that flow path with a second fluid flow component interface outlet of that flow path. Each fluid flow component interface is configured to interface with a corresponding fluid flow component such that the corresponding fluid flow component, when installed, is able to interact with fluid flow between the fluid flow component interface inlet and the fluid flow component interface outlet.

Abstract: Methods and apparatuses for additively manufactured tubular passages, additively manufactured manifolds, and additively manufactured heaters are provided.

Abstract: A manifold constructed by additive manufacturing for use in semiconductor processing tools is provided. The manifold may include a mixing chamber and portions of a plurality of flow paths with each flow path including a first fluid flow component interface, a second fluid flow component interface, a first tubular passage fluidically connecting the first mixing chamber with a first fluid flow component interface outlet of that flow path, and a second tubular passage fluidically connecting a first fluid flow component interface inlet of that flow path with a second fluid flow component interface outlet of that flow path. Each fluid flow component interface is configured to interface with a corresponding fluid flow component such that the corresponding fluid flow component, when installed, is able to interact with fluid flow between the fluid flow component interface inlet and the fluid flow component interface outlet.

Abstract: Component-locating templates or masks for use with positioning fluid-flow components on monolithic ceramic substrates are provided, as well as techniques for the manufacture of such templates.

Abstract: A gas delivery substrate for mounting gas supply components of a gas delivery system for a semiconductor processing apparatus is provided. The substrate may include a plurality of layers having major surfaces thereof bonded together forming a laminate with openings for receiving and mounting first, second, third and fourth gas supply components on an outer major surface. The substrate may include a first gas channel extending across an interior major surface that at least partially overlaps a second gas channel extending across a different interior major surface. The substrate may include a first gas conduit including the first gas channel connecting the first gas supply component to the second gas supply component, and a second gas conduit including the second channel connecting the third gas supply component to the fourth gas supply component. Also disclosed are various techniques for manufacturing gas delivery substrates.

Abstract: An integrated dry gas fuel cell (IDG-FC) is provided. The IDG-FC includes at least one solid oxide fuel cell having an anode, a cathode and an electrolyte membrane disposed between the anode and the cathode. The IDG-FC further includes a conversion bed, where carbon dioxide gas is provided to the conversion bed to convert carbon monoxide gas from the carbon dioxide gas. Solid carbonaceous fuel is provided to the conversion bed to promote the gas conversion. The carbon monoxide is provided as fuel to the anode, and air is supplied to the cathode to provide oxygen for oxidation of the carbon monoxide at the anode to generate electric power. This new process does not require water, and supplies the oxygen required for the oxidation reaction through an ionically selective solid oxide electrolyte membrane.

Abstract: A screen protector assembly for use with a flat panel display having a display panel located on a front surface thereof. The screen protector assembly comprises a transparent screen panel having a pair of slots formed therein adjacent a top edge of the screen panel and a pair of c-shaped hanger clamps for detachably securing the screen panel to the flat panel display. Each clamp hanger comprises a top portion for engaging a top surface of the flat panel display, an arm extending downwardly from the top portion, and a tail portion end for providing a clamping force between the screen panel and the back surface of the front panel display. The arm has a tab protruding rearwardly from the arm with an upwardly extending hook forming a neck for supporting a top surface of the slot. The tab is shaped to fit within the slot of the screen panel such that a top surface of the slot rests on the neck and hangs thereform.

Abstract: An integrated dry gas fuel cell (IDG-FC) is provided. The IDG-FC includes at least one solid oxide fuel cell having an anode, a cathode and an electrolyte membrane disposed between the anode and the cathode. The IDG-FC further includes a conversion bed, where carbon dioxide gas is provided to the conversion bed to convert carbon monoxide gas from the carbon dioxide gas. Solid carbonaceous fuel is provided to the conversion bed to promote the gas conversion. The carbon monoxide is provided as fuel to the anode, and air is supplied to the cathode to provide oxygen for oxidation of the carbon monoxide at the anode to generate electric power. This new process does not require water, and supplies the oxygen required for the oxidation reaction through an ionically selective solid oxide electrolyte membrane.