Abstract: A method for forming a photovoltaic device comprising the steps of: providing a first conductive material on a substrate; depositing a continuous layer of a dielectric material less than 10 nm thick on the first conductive material; annealing the first conductive material and the layer of dielectric material; forming a chalcogenide light-absorbing material on the layer of dielectric material; and depositing a second material on the light-absorbing material such that the second material is electrically coupled to the light-absorbing material; wherein the first conductive material and the dielectric material are selected such that, during the step of annealing, a portion of the first conductive material undergoes a chemical reaction to form: a layer of a metal chalcogenide material at the interface between first conductive material and the dielectric material; and a plurality of openings in the layer of dielectric material; the openings being such to allow electrical coupling between the light-absorbing materia

Abstract: The present disclosure relates to reversal agents, which specifically bind to anti-Factor XI and/or anti-Factor XIa antibodies (e.g., NOV1401), and reverse one or more anticoagulant effects of the anti-Factor XI and/or anti-Factor XIa antibodies (e.g., NOV1401), as well as to methods of use thereof, such as methods for reversing anticoagulant effects of such anti-Factor XI and/or anti-Factor XIa antibodies (e.g., NOV1401), and to related methods for managing bleeding or bleeding risks.

Abstract: There is provided a quantum circuit based system configured to model infinite-size systems, in which one or more quantum circuits are configured as an infinite tensor network representation of quantum states of effectively infinite physical or chemical systems.

Abstract: Self-cleaning electrochemical cells, systems including self-cleaning electrochemical cells, and methods of operating self-cleaning electrochemical cells are disclosed. The self-cleaning electrochemical cell can include a plurality of concentric electrodes disposed in a housing, for example, a cathode and an anode, a fluid channel defined between the concentric electrodes, a separator residing between the concentric electrodes, first and second end caps coupled to respective ends of the housing, and an inlet cone. The separators may be configured to localize the electrodes and dimensioned to minimize a zone of reduced velocity occurring downstream from the separator. The end caps and inlet cone may be dimensioned to maintain fully developed flow and minimize pressure drop across the electrochemical cell.

Abstract: Disclosed is an adamantine semiconductor. The semiconductor comprises a first element being from one of the following groups: VIII, VII, VI, V, IV, III, II, ? or 0. The semiconductor also comprises at least two other elements, the at least two other elements being from group I, II, III, IV, V, VI and/or VII. The first element being from group VIII, VII, VI, V, IV, III, II, ? or 0 includes an element not formally being from group VIII, VII, VI,V, IV, III,II, ? or 0 but is known to assume the same oxidation state as the elements that do lie in these groups. The at least two other elements from group I, II, III, IV, V, VI and/or VII includes elements not formally being from group I, II, III, IV, V, VI and/or VII but are known to assume the same oxidation state as the elements that do lie in these groups.

Abstract: An inlet flow structure can comprise: a plurality of bellmouth elements, each of the plurality of bellmouth elements including a bellmouth and a diffuser; a plurality of supply plenums, each of the plurality of supply plenums surrounding a respective one of the plurality of bellmouth elements, wherein the plurality of supply plenums are divided by a wall which provides equivalent air flow to each bellmouth element. The inlet flow structure comprises an inlet plenum disposed on the plurality of supply plenums and an outlet plenum disposed on the plurality of bellmouth elements.

Abstract: Self-cleaning electrochemical cells, systems including self-cleaning electrochemical cells, and methods of operating self-cleaning electrochemical cells are disclosed. The self-cleaning electrochemical cell can include a plurality of concentric electrodes disposed in a housing, a fluid channel defined between the concentric electrodes, and an electrical connector positioned at a distal end of a concentric electrode and electrically connected to the electrode. The electrical connectors may be configured to provide a substantially even current distribution to the concentric electrode and minimize a zone of reduced velocity occurring downstream from the electrical connector. The electrical connector may be configured to cause a temperature of an electrolyte solution to increase by less than about 0.5° C. while transmitting at least 100 W of power.

Abstract: A muon detector system capable of determining muon direction and flight trajectory or path is disclosed. The muon detector system includes scintillators for determining muon direction, and an array of muon detectors arranged in orthogonal layers for determining flight trajectory. The system can be used for tomographic and telescopic mode imaging, and may be used for imaging concealed and/or subterranean objects.

Abstract: The present disclosure provides a photovoltaic module, which comprises a photon absorbing material comprising a solar cell; The photovoltaic module also comprises a glass material positioned within a plane and being positioned over the photon absorbing material such that in use light is incident on the glass material and the glass material transmits light towards the photon absorbing material, the glass material having a front surface facing away from the photon absorbing material. The front surface of the glass material has a shape which is profiled such that the emittance of infrared light from the front surface of the glass material is increased compared to that of a flat front surface, the emittance of the infrared light being associated with absorbance of infrared light that is incident upon the front surface. A rear backing sheet of the photovoltaic module may have a shape that is profiled in a corresponding manner.

Abstract: The present disclosure provides a photovoltaic module comprising a photon absorbing material for absorbing electromagnetic radiation. The photon absorbing material comprises solar cells and a glass material. The photovoltaic module also comprises an anti-reflective coating that has anti-reflective properties in a first wavelength range and reflective properties in a second wavelength range. The anti-reflective coating is positioned over the glass material. The anti-reflective coating comprises a layered structure that has layers that together have an out-of-sequence or non-graded refractive index profile.

Abstract: Disclosed is an assembly for mounting to a photovoltaic module. The photovoltaic module has a radiation receiving surface and a second surface opposite the radiation receiving surface. At least one of the radiation receiving surface and the second surfaces are also arranged to transmit radiation. A photon absorbing material is positioned between the first and second surfaces. The assembly comprises a cooling element configured to mount to the at least one of the radiation receiving surface and the second surface. The cooling element has a plurality of protrusions that are configured to increase a heat transfer coefficient of the photovoltaic module compared to a heat transfer coefficient that the photovoltaic module would have without the plurality of protrusions.

Abstract: An electrochemical cell includes a cathode and an anode disposed in a housing. Each of the cathode and anode portions extending radially outward from a region proximate a central axis of the housing. A surface area of an active surface of the anode is greater than a surface area of an internal surface of the housing. A surface area of an active surface of the cathode is greater than a surface area of an internal surface of the housing.

Abstract: An electrochemical cell includes a housing having an inlet, an outlet, and a central axis and an anode-cathode pair disposed concentrically within the housing about the central axis and defining an active area between an anode and a cathode of the anode-cathode pair. An active surface area of at least one of the anode and the cathode has a surface area greater than a surface area of an internal surface of the housing. The anode-cathode pair is configured and arranged to direct all fluid passing through the electrochemical cell axially through the active area.

Abstract: An inlet flow structure can comprise: a plurality of bellmouth elements, each of the plurality of bellmouth elements including a bellmouth and a diffuser; a plurality of supply plenums, each of the plurality of supply plenums surrounding a respective one of the plurality of bellmouth elements, wherein the plurality of supply plenums are divided by a wall which provides equivalent air flow to each bellmouth element. The inlet flow structure comprises an inlet plenum disposed on the plurality of supply plenums and an outlet plenum disposed on the plurality of bellmouth elements.

Abstract: The present invention provides an implantable medical product in a pouch structure, comprising an extracellular matrix (ECM) structure in sheet form. The pouch structure has an internal region and is configured to receive an electrical medical device therein. In particular, a larger pouch structure is designed to accommodate a medical device having a larger size, such as a subcutaneous implantable cardioverter-defibrillators (S-ICDs). In particular, lock-stitched seamed ECM sheets form a larger pouch structure. It is preferable that the stitches can securely hold the ECM sheets together by providing mechanical strength and durability to withstand the weight of the electronic medical device. The stitches securely hold the pouch structure together and does not fall apart during trimming or cutting of the pouch structure.

Abstract: Autonomous selling, vending, and/or distributing of alcoholic beverages upon autonomous verification that the prospective purchaser or consumer satisfies any applicable age restrictions and/or is not intoxicated beyond the acceptable limit.

Abstract: A muon detector system capable of determining muon direction and flight trajectory or path is disclosed. The muon detector system includes scintillators for determining muon direction, and an array of muon detectors arranged in orthogonal layers for determining flight trajectory. The system can be used for tomographic and telescopic mode imaging, and may be used for imaging concealed and/or subterranean objects.

Abstract: An electrochemical cell includes a housing having an inlet, an outlet, and a central axis and an anode-cathode pair disposed concentrically within the housing about the central axis and defining an active area between an anode and a cathode of the anode-cathode pair. An active surface area of at least one of the anode and the cathode has a surface area greater than a surface area of an internal surface of the housing. The anode-cathode pair is configured and arranged to direct all fluid passing through the electrochemical cell axially through the active area.

Abstract: A muon detector system capable of determining muon direction and flight trajectory or path is disclosed. The muon detector system includes scintillators for determining muon direction, and an array of muon detectors arranged in orthogonal layers for determining flight trajectory. The system can be used for tomographic and telescopic mode imaging, and may be used for imaging concealed and/or subterranean objects.

Abstract: The invention provides a material with perovskite-type structure having a formula selected from Formula I and Formula II. in which A? represents one or more monovalent cations that can be selected from alkali metal ions, (organo)ammonium and (organo)phosphonium ions; A? represents one or more divalent cations that can be selected from alkaline earth metal cations; A?? represents one or more trivalent cations that can be selected from lanthanide ions; a, b and c are each in the range of from 0 to 1, a+b+c=1; x=a+2b+3c; d is in the range of from 1 to 5, each of e, f and g are in the range of from 0 to 1. with the proviso that g is less than 1 in Formula I; e+f+g?1; y=2(e+f)+3g; each X in “X” and “X2” is independently selected from the halogens; and h is in the range of from 0.0001 to 0.2. X2 is a dihalogen moiety, and can be the source of a valence band “hole” in the photovoltaic semiconducting material. The invention also relates to photovoltaic devices or a surface coating that comprises the material.