Abstract: A refrigerated merchandiser including a case defining a product display area and including a frame having a mullion. The mullion defining an opening to the product display area. A door is coupled and movable relative to the frame over the opening to provide access to the product display area. A refrigeration system is in communication with the product display area to condition the product display area. A first heater is coupled to and routed along the frame and a second heater is coupled to and routed along the frame. The second heater is separate from the first heater. A controller is operatively coupled to the first heater and the second heater and programmed to dependently control the first heater and the second heater relative to each other to remove or inhibit formation of condensation.

Abstract: A solar cell assembly comprising a plurality of solar cells and a support, the support comprising a conductive layer. The conductive layer is divided into a first conductive portion and a second conductive portion. Each solar cell of the plurality of solar cells comprising a front surface, a rear surface, and a first contact in correspondence with the rear surface. Each one of the plurality of solar cells is placed on the first conductive portion with the first contact electrically connected to the first conductive portion so that the solar cells are connected in parallel through the first conductive portion. A second contact of each solar cell can be connected to the second conductive portion. The two conductive portions serve as bus bars of the solar cell assembly.

Abstract: A solar cell module and method for fabricating the same are provided. The solar cell module comprises: an array of solar cells, each of the solar cells having an area of about 0.01 mm2 to about 9 cm2; interconnection component(s) for electrically connecting at least a part of the solar cells; and a support for supporting the solar cells and the interconnection components thereon.

Abstract: The present application is directed to a multi-terminal semiconductor solar cell. The solar cell may be dual junction solar cells comprising single junctions independently interconnected by a middle lateral conduction layer (MLCL). The solar cells may include a GaAs subcell, a GaInP subcell, and a MLCL disposed therebetween. In addition, the solar cells may include a plurality of terminals. One terminal may be operatively connected to the GaAs subcell, a second terminal may be operatively connected to the GaInP subcell and a third terminal may be operatively connected to the MLCL.

Abstract: A solar cell including a semiconductor body including at least one photoactive junction; and a diamond like carbon layer deposited over the top surface of the semiconductor body.

Abstract: A semiconductor structure that includes a first semiconductor region forming a first surface of the semiconductor structure and having a first polarity and a second semiconductor region forming a second surface of the semiconductor structure and having a second polarity. The structure further includes at least one insulating via formed in the semiconductor structure from said first surface to said second surface, an electrical connection extending through said via and an insulated contact pad on the first surface of the semiconductor structure, said electrical connection extending from said second semiconductor region to said insulated contact pad so as to form a terminal of said second semiconductor region on the first surface.

Abstract: A method and a multijunction solar device having a high band gap heterojunction middle solar cell are disclosed. In one embodiment, a triple-junction solar device includes bottom, middle, and top cells. The bottom cell has a germanium (Ge) substrate and a buffer layer, wherein the buffer layer is disposed over the Ge substrate. The middle cell contains a heterojunction structure, which further includes an emitter layer and a base layer that are disposed over the bottom cell. The top cell contains an emitter layer and a base layer disposed over the middle cell.

Abstract: A solar cell having a multijunction solar cell structure with a bypass diode is disclosed. The bypass diode provides a reverse bias protection for the multijunction solar cell structure. In one embodiment, the multijunction solar cell structure includes a substrate, a bottom cell, a middle cell, a top cell, a bypass diode, a lateral conduction layer, and a shunt. The lateral conduction layer is deposited over the top cell. The bypass diode is deposited over the lateral conduction layer. One side of the shunt is connected to the substrate and another side of the shunt is connected to the lateral conduction layer. In another embodiment, the bypass diode contains an i-layer to enhance the diode performance.

Abstract: A method and a multijunction solar device having a high band gap heterojunction middle solar cell are disclosed. In one embodiment, a triple-junction solar device includes bottom, middle, and top cells. The bottom cell has a germanium (Ge) substrate and a buffer layer, wherein the buffer layer is disposed over the Ge substrate. The middle cell contains a heterojunction structure, which further includes an emitter layer and a base layer that are disposed over the bottom cell. The top cell contains an emitter layer and a base layer disposed over the middle cell.

Abstract: A multi-junction solar cell includes a plurality of monolithic cells joined together by direct wafer bonds. Each monolithic cell has at least one junction. The direct wafer bonds include no intervening material between joined monolithic cells. The direct wafer bonds are achieved by bonding forces between dipoles at the surfaces of adjoining monolithic cells.