A device that is capable of eliminating a power trace that can be analyzed in a power analysis attack and serves as a highly effective countermeasure against power analysis attacks. The device comprising an optical source providing optical energy to an integrated circuit. An optical detector optically linked to the optical source and converts the optical energy from the optical source into electrical energy to power a secure circuit.

A device that is capable of eliminating a power trace that can be analyzed in a power analysis attack and serves as a highly effective countermeasure against power analysis attacks. The device comprising an optical source providing optical energy to an integrated circuit. An optical detector optically linked to the optical source and converts the optical energy from the optical source into electrical energy to power a secure circuit.

The invention provides a dual-initiated and fast cross-linked EVA (ethylene/vinyl acetate copolymer) film for the encapsulation of solar modules, which greatly enhances the speed of the encapsulation. The EVA film is mainly prepared from the following raw materials: 100 parts by mass of ethylene/vinyl acetate copolymer, 0.01 to 1.5 parts by mass of a free-radical photoinitiator, 0.01 to 1.5 parts by mass of a free-radical thermal initiator, 0.5 to 10 parts by mass of an auxiliary cross-linking agent, 0.1 to 5 parts by mass of a tackifier and 0.01 to 5 parts by mass of a light stabilizer. The present invention adds photothermal dual-initiated free-radical initiators and the auxiliary cross-linking agent of multi-functional acrylates or methacrylates to the EVA and use a thermal-UV dual curing process to prepare the solar module. The curing time is shorten to 5 to 10 min and the yield is high; meanwhile, the EVA film has advantages of uniform curing, high crosslink density, high bonding strength between the film and glass, and good anti-aging property.

There is provided a solar battery control apparatus comprising: a solar battery in a vehicle; a vehicle speed detecting unit; a load circuit capable of be controlled to vary a generated current; and a control unit configured to perform MPPT control while controlling the load circuit to vary the generated current, wherein the control unit varies the generated current within a range having a certain upper limit value upon the speed of the vehicle being detected to be greater than a predetermined speed. The predetermined speed is set to be less than a speed at which the generated current becomes unable to be varied to correspond to a change in an i-V output characteristic of the solar battery, and the certain upper limit value is set to be less than a value of short-circuiting current having been reduced according to the change.

There is provided a solar battery control apparatus comprising: a solar battery in a vehicle; a vehicle speed detecting unit; a load circuit capable of be controlled to vary a generated current; and a control unit configured to perform MPPT control while controlling the load circuit to vary the generated current, wherein the control unit varies the generated current within a range having a certain upper limit value upon the speed of the vehicle being detected to be greater than a predetermined speed. The predetermined speed is set to be less than a speed at which the generated current becomes unable to be varied to correspond to a change in an i-V output characteristic of the solar battery, and the certain upper limit value is set to be less than a value of short-circuiting current having been reduced according to the change.

A photovoltaic collector includes a photovoltaic cell including a first conduction layer, a second conduction layer, and a photovoltaic layer absorbing incident light and generating electric current. The photovoltaic layer is electrically connected to the first conduction layer on a first side of the photovoltaic layer and to the second conduction layer on a second side opposite to the first side. The first conduction layer is an ultrastatic conducting layer being made using ultrasonic spray technology. The photovoltaic collector further includes a plurality of connection units disposed along on an outer peripheral edge of the photovoltaic collector. Each connection unit is adapted to connect with an adjacent connection unit of an adjacent photovoltaic collector to tessellate and electrically interconnect and interlock the photovoltaic collector with a plurality of adjacent photovoltaic collectors without requiring additional cable wires.

A semiconductor device includes: a conductive layer; a plurality of nanopillars spaced apart from each other overlying the conductive layer, each nanopillar comprising a first semiconductor layer and a second semiconductor layer on the first semiconductor layer, the first semiconductor layer being different in conductivity type from the second semiconductor layer; and a graphene layer overlying the plurality of nanopillars, the graphene layer being connected to each of the plurality of nanopillars.

A semiconductor device includes: a conductive layer; a plurality of nanopillars spaced apart from each other overlying the conductive layer, each nanopillar comprising a first semiconductor layer and a second semiconductor layer on the first semiconductor layer, the first semiconductor layer being different in conductivity type from the second semiconductor layer; and a graphene layer overlying the plurality of nanopillars, the graphene layer being connected to each of the plurality of nanopillars.

The present invention generally relates to artificial photosystems and methods of their use, for example in artificial photosynthesis, wherein the artificial photosystems comprise one or more light-harvesting antenna (LHA) comprising a conjugated polyelectrolyte (CPE) complex (CPEC) comprising a donor CPE and an acceptor CPE, wherein the donor CPE and acceptor CPE are an electronic energy transfer (EET) donor/acceptor pair.

The present invention generally relates to artificial photosystems and methods of their use, for example in artificial photosynthesis, wherein the artificial photosystems comprise one or more light-harvesting antenna (LHA) comprising a conjugated polyelectrolyte (CPE) complex (CPEC) comprising a donor CPE and an acceptor CPE, wherein the donor CPE and acceptor CPE are an electronic energy transfer (EET) donor/acceptor pair.