Abstract: The invention is directed to a photovoltaic multilayer laminate, to a method for preparing a photovoltaic multilayer laminate, to a method for preparing a photovoltaic roadway, and to a photovoltaic roadway. The photovoltaic multilayer laminate of the invention comprises multiple flexible photovoltaic foil elements laminated at least to a carrier layer comprising electrical interconnections for said flexible photovoltaic foil elements, wherein said multiple flexible photovoltaic elements are arranged transversely to the longitudinal direction of the laminate, wherein a stretchable or compressible space is provided between each pair of multiple flexible photovoltaic foil elements.

Abstract: A photovoltaic module (1) with a plurality of photovoltaic units (3) each having a positive contact terminal (8) and a negative contact terminal (7), and a single layer back contact substrate (4). The back contact substrate (4) has a positive surface part (6) electrically connected to the positive contact terminal (8) of each of the plurality of photovoltaic units (3), and a negative surface part (5) electrically connected to the negative contact terminal (7) of each of the plurality of photovoltaic units (3). The photovoltaic module (1) further has at least one contact bridge (9a, 9b) in a layer of the photovoltaic module (1) outside of the single layer back contact substrate (4), which provides an electrical connection in the negative surface part (5) and/or in the positive surface part (6).

Abstract: A method for manufacturing a two terminal or three terminal tandem solar cell comprising a silicon-based bottom solar cell and a thin-film top solar cell; the method comprising: providing a silicon substrate with a front surface and a rear surface, carrying out a sequence of steps comprising: creating on the front surface a carrier extracting layer stack comprising at least a carrier extracting layer formed on or in the front surface of the substrate, creating on the rear surface a passivating coating layer comprising deposition of a first AlOx layer, creating sacrificial layer stack comprising a second AlOx layer on the carrier extracting layer stack on the front surface; creating metal-based electrical contacts on the rear surface, including an annealing step; removing the sacrificial layer stack from the carrier extracting layer stack, and creating the thin film top solar cell on the carrier extracting layer stack.

Abstract: A hybrid organic-inorganic solar cell is provided that includes a substrate, a transparent conductive oxide (TCO) layer deposited on the substrate, an n-type electron transport material (ETM) layer, a p-type hole transport material (HTM) layer, an i-type perovskite layer, and an electrode layer, where the substrate layers are arranged in an n-i-p stack, or a p-i-n stack, where the passivating barrier layer is disposed between the layers of the (i) perovskite and HTM, (ii) perovskite and ETM, (iii) perovskite and HTM, and perovskite and ETM, or (iv) TCO and ETM, and ETM and perovskite, and perovskite and HTM, or (v) substrate and TCO, and TCO and ETM, and ETM and perovskite, and perovskite layer and HTM, or (vi) a pair of ETM layers, or (vii) a pair of HTM layers.

Abstract: A gateway device between a first and second communication network outside the gateway device handles communication between a first device in the first network and a second device in the second network. When the gateway receives a communication request from the first device, directed to the second device, for performing a first cryptographic data communication protocol, the gateway determines whether the first cryptographic data communication protocol is registered as unsafe in the gateway device, and/or registered as safe, in particular whether it is safe against key reconstruction by a quantum computer. When the first cryptographic data communication protocol is not registered as unsafe in the gateway device, and/or registered as safe, the gateway device forwards messages exchanged as part of execution of the first cryptographic data communication protocol between the first and second device.

Abstract: A method of forming a photovoltaic product with a plurality of photovoltaic cells is disclosed. The method comprises depositing a stack with first and second electrode layers (12, 16) and a photovoltaic layer (14) arranged in between. The method comprises partitioning the stack. The partitioning includes forming a trench (20) extending through the second electrode layer and the photovoltaic layer to expose the first electrode layer. The stack is first irradiated with a laser beam with a first spotsize and with a first wavelength for which the photovoltaic layer has a relatively high absorption coefficient as compared to that of the second electrode layer. The stack is then irradiated with a second laser beam with a second spotsize, greater than the first spotsize, and with a second wavelength for which the photovoltaic layer has a relatively low absorption coefficient as compared to that of the second electrode layer.

Abstract: The invention is directed to a method of preparing NH3, and to a method of regenerating a metal M from MOR1, wherein O is oxygen and R1 is —CH3 and/or —C2H5. The method for preparing NH3 comprises the steps of a) reacting a metal with nitrogen gas to produce a metal nitride, wherein the metal is selected from the group consisting of Li, Be, Mg, Na, Mo, Al, Zn, Ca, Sr, and Ba, b) reacting the metal nitride obtained in step a) with R1OH to produce NH3 and MOR1, wherein R1 represents —CH3 and/or —C2H5, and c) regenerating the metal by electrolysing said MOR1 under formation of HCHO and/or CH3CHO. The method of regenerating a metal M from MOR1, comprises electrolysing of MOR1 under formation of HCHO and/or CH3CHO, wherein R1 represents —CH3 and/or —C2H5.

Abstract: Reactor for processing biomass, e.g. into biochar or bio cokes, with a reactor enclosure (2) having a transport unit (5). In a first reactor section (6) first gas injectors (11) are positioned below the transport unit (5), and first oxidant injectors (12) are positioned above transport unit (5). In a second reactor section (7) second gas injectors (13) are positioned below the transport unit (5), and second oxidant injectors (14) are positioned above the transport unit (5). In a the third reactor section (8) third gas injectors (15) are provided below the transport unit (5). The first, second and third gas injectors (11, 13, 15) are further arranged to output a first, second, and third gas, respectively, each having a low oxygen content, and the first and second oxidant injectors (12, 14) are arranged to output an oxidizing gas only for providing radiation heat energy, using a control unit (20).

Abstract: The invention is directed to a method for amplifying and/or detecting nucleic acid in a sample having a specific pre-treatment step. In particular, the invention provides a pre-treatment for the LAMP method, which can further enhance the sensitivity of LAMP tests. The pre-treatment includes a heat-treatment wherein the sample is heated in the presence of tris(2-carboxyethyl)phosphine (TCEP) and proteinase K.

Abstract: In a method and system for laser induced forward transfer (LIFT), energy (E1,E2) is deposited according to a non-Gaussian intensity profile (Ixy) which is spatially tuned across an interface (11xy) of the donor material (11m) to cause the donor material (11m) to be ejected from the donor substrate as an extended jet (Je) momentarily bridging the transfer distance (Zt) between the donor substrate (11) and the acceptor substrate (12) during a transfer period (Tt). A locally increased intensity spike (Is) at a center of the intensity profile (Ixy) causes a relatively thick jet (J1) of donor material to branch into a relatively thin jet (J2) at a branching position (J12) between the donor substrate (11) and acceptor substrate (12). The thick jet (J1) allows a relatively large transfer (Zt) distance while the thin jet (J2) deposits a relatively small droplet (Jd) of donor material (11m).

Abstract: The invention is directed to an insulation piercing cable connection system, to an insulation piercing cable and an insulation piercing connector for use in said insulation piercing cable connection system, and to a photovoltaic system.

Abstract: A closed-cycle thermal energy storage system includes a thermochemical reactor [400] containing a solid thermochemical material, a heat exchanger [402], a fan [406] for creating forced convection of an air/water mixture circulating around the closed cycle, an evaporator/condenser [408], and a pressure control system that includes a pressure sensor [422], a controller [424], and a pump [404]. The pressure control system actively controls the pressure of the air/water mixture to produce a desired temperature difference across the thermochemical reactor [400]. The adjustable pressure control system controls the pressure of the air/water mixture to a first pressure (e.g., between 10 mbar and 1 bar) during a hydration phase and a second pressure (e.g., between 1 bar and 10 bar) during a dehydration phase.

Abstract: The invention is directed to a process for electrochemically converting a reactant gas, to an electrolyser, to a gas diffusion electrode, to a method for producing a gas diffusion electrode, to a gas diffusion layer, and to the use of said gas diffusion layer and/or gas diffusion electrode. The process comprises reacting a reactant gas at a gas diffusion electrode to form a product gas and/or a liquid product, wherein the gas diffusion electrode comprises a gas diffusion layer comprising a non-porous layer that is permeable to carbon monoxide and/or carbon dioxide gas, and a porous layer, and the reactant gas comprises carbon monoxide and/or carbon dioxide.

Abstract: The present disclosure concerns methods for the manufacturing of products with printed conductive tracks. The process comprising scribing a first trench into the surface of the object, wherein on a border of the trench a first ridge is formed to define a first edge of a material receiving track. At a distance from the first trench a second trench is formed, wherein on the borders of the second trench a second ridge is formed facing the first ridge. The first and second ridges define a material receiving track which may be provided with a material suited to form a conductive track.

Abstract: A photovoltaic (PV) module (1) comprising a positive terminal (5), a negative terminal (6), and at least two sub-modules. Each of the at least two sub-modules (10a-c) comprises x parallel-connected sub-strings (13), wherein each of the x parallel-connected sub-strings (13) comprises y series-connected sub-cells (16), wherein the y series-connected sub-cells (16) are arranged in an array. The PV module (1) further comprises a back conductive sheet having a first connection pattern arranged for connecting the x parallel-connected sub-strings (13) of each of the at least two sub-modules (10a-c), wherein each of the at least two sub-modules (10a-c) is provided with a power optimizer circuit (21a-c), and the output of the power optimizer circuits (21a-c) are connected in series between the positive terminal (5) and the negative terminal (6).

Abstract: The invention is directed to a method and a system for regenerating an endothermic salt composition from an aqueous solution thereof, said method comprising a) contacting a switchable-polarity compound with the aqueous solution of the endothermic salt composition to obtain a raffinate phase and an extract phase, wherein the raffinate phase comprises said endothermic salt composition in a higher concentration than said aqueous solution and said extract phase comprises the switchable-polarity compound and water; and b) separating the raffinate phase and the extract phase into a separated raffinate and a separated extract. The endothermic salt can be used in systems for cooling food, milk, medicines and/or air.

Abstract: A device for the detection of analytes comprises a substrate (10) with nano-antennas (11,12). The nano-antennas (11,12) comprise an antenna material (11m, 12m) for forming resonant antenna structures which receive and resonantly interact with source light (L0) to form respective resonance peaks (R1,R2) over a resonant wavelength range (A1,A2) overlapping respective signature wavelength (?1,?2) of a target analyte (A). The resonant interaction causes a locally concentrated field (Ec) of the source light (L0) in the resonant wavelength range (?1,?2). The concentrated intensity (Ic) is localized around a respective target location (T1,T2) which is provided with a sorption material (11s, 12s) that sorbs the target analyte (A). This provides a locally increased analyte concentration (Ac) of the target analyte (A) coinciding with the locally concentrated field (Ec) of the source light (L0). Accordingly, the interaction of the source light (L0) with the target analyte (A) is enhanced.

Abstract: The invention is directed to a salt composition for use in a thermochemical energy storage device, said salt composition comprising a base and a hygroscopic salt that can produce a gas by reacting with an acid. In further aspects the invention is directed to ab energy storage compartment and a thermochemical energy storage device comprising the salt composition.

Abstract: In an aspect of the invention there is provided a plasma thruster device comprising: an electrically insulating substrate, said substrate comprising one or more feed channels for feeding an electrically conductive liquid to a bridge structure; said substrate further provided with electrical terminals; said bridge structure configured to form, when provided with the electrically conductive liquid, an electrical conducting bridge; said bridge structure configured to form contact areas in electrical contact with said electrical terminals, said bridge structure thereby connecting the contact areas, said bridge structure arranged for forming a plasma of said electrically conductive liquid, when the electrically conductive liquid is ionized by a current peak flow circuit that contacts the contact areas via said electrical terminals.

Abstract: The present invention concerns a sorption-enhanced water-gas shift (SEWGS) process for the formation of a CO2 product stream and an H2 product stream, comprising (a) a reaction step, wherein a feed gas comprising COx, wherein x=1-2, and H2O is fed into a SEWGS reactor containing a catalyst and sorbent material capable of adsorbing CO2, thereby forming the H2 product stream and a sorbent material loaded with CO2; (b) a rinse step, wherein steam is fed to the SEWGS reactor, thereby establishing a pressure in the range of 5-50 bar; (c) a pre-blowdown step, wherein the pressure in the SEWGS reactor is reduced to establish a blowdown pressure in the range of 0.5-1.