Abstract: Various devices, systems, and methods are capable of killing tumor cells by delivering cell-disrupting agents into a tumor in an inward direction from a peripheral border about the tumor. In some examples, a covering that includes one or more emissive elements encompasses at least a portion of a tumor such that the emissive element is directed inwardly toward the tumor so as to be able to introduce a cell-disrupting agent into the tumor. In further examples, the covering is incorporated into a glove.

Abstract: Methods for detecting the physical layout of an integrated circuit are provided. The methods of the present disclosure allow large area imaging of the circuit layout without requiring tedious sample preparation techniques. The imaging can be performed utilizing low-energy beam techniques such as scanning electron microscopy; however, more sophisticated imaging techniques can also be employed. In the methods of the present disclosure, spalling is used to remove a portion of a semiconductor layer including at least one semiconductor device formed thereon or therein from a base substrate. In some cases, a buried insulator layer that is located beneath a semiconductor layer including the at least one semiconductor device can be completely or partially removed. In some cases, the semiconductor layer including the at least one semiconductor device can be thinned. The methods improve the detection quality that the buried insulator layer and a thick semiconductor layer can reduce.

Abstract: Interconnect structures including a graphene cap located on exposed surfaces of a copper structure are provided. In some embodiments, the graphene cap is located only atop the uppermost surface of the copper structure, while in other embodiments the graphene cap is located along vertical sidewalls and atop the uppermost surface of the copper structure. The copper structure is located within a dielectric material.

Abstract: Interconnect structures including a graphene cap located on exposed surfaces of a copper structure are provided. In some embodiments, the graphene cap is located only atop the uppermost surface of the copper structure, while in other embodiments the graphene cap is located along vertical sidewalls and atop the uppermost surface of the copper structure. The copper structure is located within a dielectric material.

Abstract: Semiconductor devices having integrated nanochannels confined by nanometer spaced electrodes, and VLSI (very large scale integration) planar fabrication methods for making the devices. A semiconductor device includes a bulk substrate and a first metal layer formed on the bulk substrate, wherein the first metal layer comprises a first electrode. A nanochannel is formed over the first metal layer, and extends in a longitudinal direction in parallel with a plane of the bulk substrate. A second metal layer is formed over the nanochannel, wherein the second metal layer comprises a second electrode. A top wall of the nanochannel is defined at least in part by a surface of the second electrode and a bottom wall of the nanochannel is defined by a surface of the first electrode.

Abstract: Semiconductor devices having integrated nanochannels confined by nanometer spaced electrodes, and VLSI (very large scale integration) planar fabrication methods for making the devices. A semiconductor device includes a bulk substrate and a first metal layer formed on the bulk substrate, wherein the first metal layer comprises a first electrode. A nanochannel is formed over the first metal layer, and extends in a longitudinal direction in parallel with a plane of the bulk substrate. A second metal layer is formed over the nanochannel, wherein the second metal layer comprises a second electrode. A top wall of the nanochannel is defined at least in part by a surface of the second electrode and a bottom wall of the nanochannel is defined by a surface of the first electrode.

Abstract: Methods for detecting the physical layout of an integrated circuit are provided. The methods of the present disclosure allow large area imaging of the circuit layout without requiring tedious sample preparation techniques. The imaging can be performed utilizing low-energy beam techniques such as scanning electron microscopy; however, more sophisticated imaging techniques can also be employed. In the methods of the present disclosure, spalling is used to remove a portion of a semiconductor layer including at least one semiconductor device formed thereon or therein from a base substrate. In some cases, a buried insulator layer that is located beneath a semiconductor layer including the at least one semiconductor device can be completely or partially removed. In some cases, the semiconductor layer including the at least one semiconductor device can be thinned. The methods improve the detection quality that the buried insulator layer and a thick semiconductor layer can reduce.

Abstract: A semiconductor structure having a high Hall mobility is provided that includes a SiC substrate having a miscut angle of 0.1° or less and a graphene layer located on an upper surface of the SiC substrate. Also, provided are semiconductor devices that include a SiC substrate having a miscut angle of 0.1° or less and at least one graphene-containing semiconductor device located atop the SiC substrate. The at least one graphene-containing semiconductor device includes a graphene layer overlying and in contact with an upper surface of the SiC substrate.

Abstract: Semiconductor devices having integrated nanochannels confined by nanometer spaced electrodes, and VLSI (very large scale integration) planar fabrication methods for making the devices. A semiconductor device includes a bulk substrate and a first metal layer formed on the bulk substrate, wherein the first metal layer comprises a first electrode. A nanochannel is formed over the first metal layer, and extends in a longitudinal direction in parallel with a plane of the bulk substrate. A second metal layer is formed over the nanochannel, wherein the second metal layer comprises a second electrode. A top wall of the nanochannel is defined at least in part by a surface of the second electrode and a bottom wall of the nanochannel is defined by a surface of the first electrode.

Abstract: A semiconductor structure having a high Hall mobility is provided that includes a SiC substrate having a miscut angle of 0.1° or less and a graphene layer located on an upper surface of the SiC substrate. Also, provided are semiconductor devices that include a SiC substrate having a miscut angle of 0.1° or less and at least one graphene-containing semiconductor device located atop the SiC substrate. The at least one graphene-containing semiconductor device includes a graphene layer overlying and in contact with an upper surface of the SiC substrate.

Abstract: The present invention provides an improved amorphization/templated recrystallization (ATR) method for forming hybrid orientation substrates and semiconductor device structures. A direct-silicon-bonded (DSB) silicon layer having a (011) surface crystal orientation is bonded to a base silicon substrate having a (001) surface crystal orientation to form a DSB wafer in which the in-plane <110> direction of the (011) DSB layer is aligned with an in-plane <110> direction of the (001) base substrate. Selected regions of the DSB layer are amorphized down to the base substrate to form amorphized regions aligned with the mutually orthogonal in-plane <100> directions of the (001) base substrate, followed by recrystallization using the base substrate as a template.

Abstract: A FET structure with a nanowire forming the FET channel, and doped source and drain regions formed by radial epitaxy from the nanowire body is disclosed. A top gated and a bottom gated nanowire FET structures are discussed. The source and drain fabrication can use either selective or non-selective epitaxy.

Abstract: Methods for removing or reducing the thickness of a material layer remaining at Si-Si interfaces after silicon wafer bonding. The methods include an anneal which is performed at a temperature sufficient to dissolve oxide, yet not melt silicon.

Abstract: A positron emission scanner is disclosed having a timing compensation element which uses position information originating from a spatial locator element to compensate for travel time of timing signals. A method of constructing a PET image is also discussed in which a timing error function is convolved with an envelope function evaluated along a line of response to derive an emission event weight for use in image construction.

Abstract: A FET structure with a nanowire forming the FET channel, and doped source and drain regions formed by radial epitaxy from the nanowire body is disclosed. A top gated and a bottom gated nanowire FET structures are discussed. The source and drain fabrication can use either selective or non-selective epitaxy.

Abstract: The present invention provides a method for removing or reducing the thickness of ultrathin interfacial oxides remaining at Si—Si interfaces after silicon wafer bonding. In particular, the invention provides a method for removing ultrathin interfacial oxides remaining after hydrophilic Si—Si wafer bonding to create bonded Si—Si interfaces having properties comparable to those achieved with hydrophobic bonding. Interfacial oxide layers of order of about 2 to about 3 nm are dissolved away by high temperature annealing, for example, an anneal at 1300°-1330° C. for 1-5 hours. The inventive method is used to best advantage when the Si surfaces at the bonded interface have different surface orientations, for example, when a Si surface having a (100) orientation is bonded to a Si surface having a (110) orientation. In a more general aspect of the invention, the similar annealing processes may be used to remove undesired material disposed at a bonded interface of two silicon-containing semiconductor materials.

Abstract: The present invention provides a method for removing or reducing the thickness of ultrathin interfacial oxides remaining at Si—Si interfaces after silicon wafer bonding. In particular, the invention provides a method for removing ultrathin interfacial oxides remaining after hydrophilic Si—Si wafer bonding to create bonded Si—Si interfaces having properties comparable to those achieved with hydrophobic bonding. Interfacial oxide layers of order of about 2 to about 3 nm are dissolved away by high temperature annealing, for example, an anneal at 1300°-1330° C. for 1-5 hours. The inventive method is used to best advantage when the Si surfaces at the bonded interface have different surface orientations, for example, when a Si surface having a (100) orientation is bonded to a Si surface having a (110) orientation. In a more general aspect of the invention, the similar annealing processes may be used to remove undesired material disposed at a bonded interface of two silicon-containing semiconductor materials.

Abstract: A FET structure with a nanowire forming the FET channel, and doped source and drain regions formed by radial epitaxy from the nanowire body is disclosed. A top gated and a bottom gated nanowire FET structures are discussed. The source and drain fabrication can use either selective or non-selective epitaxy.

Abstract: The present invention provides an improved amorphization/templated recrystallization (ATR) method for forming hybrid orientation substrates and semiconductor device structures. A direct-silicon-bonded (DSB) silicon layer having a (011) surface crystal orientation is bonded to a base silicon substrate having a (001) surface crystal orientation to form a DSB wafer in which the in-plane <110> direction of the (011) DSB layer is aligned with an in-plane <110> direction of the (001) base substrate. Selected regions of the DSB layer are amorphized down to the base substrate to form amorphized regions aligned with the mutually orthogonal in-plane <100> directions of the (001) base substrate, followed by recrystallization using the base substrate as a template.

Abstract: The present invention provides an improved amorphization/templated recrystallization (ATR) method for forming hybrid orientation substrates and semiconductor device structures. A direct-silicon-bonded (DSB) silicon layer having a (011) surface crystal orientation is bonded to a base silicon substrate having a (001) surface crystal orientation to form a DSB wafer in which the in-plane <110> direction of the (011) DSB layer is aligned with an in-plane <110> direction of the (001) base substrate. Selected regions of the DSB layer are amorphized down to the base substrate to form amorphized regions aligned with the mutually orthogonal in-plane <100> directions of the (001) base substrate, followed by recrystallization using the base substrate as a template.