Abstract: A solar module includes a protective shell with at least two sealed sections formed by moisture barrier sealants. Each sealed section is separated from the adjacent sections and includes at least a portion of a solar cell. In this sectioned configuration, any local defect through the protective shell will only affect the performance of the portions of the solar cells within a particular section that contains this defect and will not affect the portions of the solar cells that are in other sections.

Abstract: A multilayer structure to form absorber layers for solar cells. The multilayer structure includes a base comprising a contact layer on a substrate layer, a first layer on the contact layer, and a metallic layer on the first layer. The first layer includes an indium-gallium-selenide film and the gallium to indium molar ratio of the indium-gallium-selenide film is in the range of 0 to 0.8. The metallic layer includes gallium and indium without selenium. Additional selenium is deposited onto the metallic layer before annealing the structure for forming an absorber.

Abstract: A method of forming a Group IBIIIAVIA solar cell absorber, which includes a top surface region of less than or equal to 300 nm depth. The Ga/(Ga+In) molar ratio within the top surface region is in the range of 0.1-0.3. The Group IBIIIAVIA solar cell absorber is formed by reacting the layers of a multilayer material structure which includes a metallic film including at least Cu and In formed on a base, a separator layer including Se is formed on the metallic film, a metallic source layer substantially including Ga formed on the separator layer, and a cap layer substantially including Se formed on the source layer.

Abstract: An electrochemical co-deposition method and solution to plate uniform, defect free and smooth (In,Ga)—Se films with repeatability and controllable molar ratios of (In,Ga) to Se are provided. Such layers are used in fabrication of semiconductor and electronic devices such as thin film solar cells. In one embodiment, the present invention provides an alkaline electrodeposition solution that includes an In salt, a Se acid or oxide, a tartrate salt as complexing agent for the In species, and a solvent to electrodeposit an In—Se film possessing sub-micron thickness on a conductive surface.

Abstract: The present invention relates to methods and apparatus for plating a conductive material on a workpiece surface in a highly desirable manner. Using a workpiece-surface-influencing device, such as a mask or sweeper, that preferentially contacts the top surface of the workpiece, relative movement between the workpiece and the workpiece-surface-influencing device is established so that an additive in the electrolyte solution disposed on the workpiece and which is adsorbed onto the top surface is removed or otherwise its amount or concentration changed with respect to the additive on the cavity surface of the workpiece. Plating of the conductive material can place prior to, during and after usage of the workpiece-surface-influencing device, particularly after the workpiece surface influencing device no longer contacts any portion of the top surface of the workpiece, to achieve desirable semiconductor structures.

Abstract: A method of forming an ohmic contact and electron reflector on a surface of a CdTe containing compound film as may be found, for example in a photovoltaic cell. The method comprises forming a Cd-deficient, Te-rich surface region at a surface of the CdTe containing compound film; exposing the Cd-deficient surface region to an electron reflector forming material; forming the electron reflector; and laying down a contact layer over the electron reflector layer. The solar cell so produced has a Cd-deficient region which is converted to an electron reflector layer on the surface of a CdTe absorber layer, and an ohmic contact. A Cd/Te molar ratio within the Cd-deficient region decreases from 1 at an interface with the CdTe absorber layer to a value less than 1 towards the ohmic contact.

Abstract: An integrated structure for solar modules may be formed by deposition of a transparent conductive material layer on a transparent support, forming scribe lines through the transparent conductive material layer, depositing a semiconductor window layer, depositing a solar cell absorber layer, depositing a first conductive layer, making cuts through the layers to expose a top surface of the transparent conductive material layer, depositing a second conductive layer and making isolation scribes that separate back contacts of adjacent solar cells from each other. Alternatively, two conductive films may be used with high resistance plugs, thereby permitting optimization of functions. The first film may be selected to optimize good ohmic contact with the absorber layer and/or to present a high diffusion barrier, whereas the second conductive film may be selected to optimize good ohmic contact with the transparent conductive material layer.

Abstract: A deposition method which deposits a CdS buffer layer on a surface of a solar cell from a process solution including all chemical components of the CdS buffer layer material. CdS is deposited in a deposition chamber by heating the surface of the solar cell absorber to cause the transfer of heat from the solar cell absorber layer to at least a portion of the process solution that is in contact with the surface. Used solution is cooled, and replenished in a solution container and redirected into the deposition chamber.

Abstract: Methods and apparatus are described for electrodeposition of Group IIB-VIA materials out of electrolytes comprising Group IIB and Group VIA species onto surfaces of workpieces. In one embodiment a method of electrodeposition is described wherein the control of the process is achieved by measuring an initial value of the electrodeposition current at the beginning of the process and adding Group VIA species into the electrolyte to keep the electrodeposition current substantially constant, such a within +/?10% of the initial value throughout the deposition period. In another embodiment an apparatus comprising multiple deposition chambers are described, each deposition chamber containing an anode and a workpiece, and wherein two thirds of the deposition chambers within the apparatus contain anodes comprising a substantially pure Group VIA element in their composition, and the rest of the deposition chambers contain anodes free from any Group VIA element in their composition.

Abstract: A solar module includes a protective shell with at least two sealed sections formed by moisture barrier sealants. Each sealed section is separated from the adjacent sections and includes at least a portion of a solar cell. In this sectioned configuration, any local defect through the protective shell will only affect the performance of the portions of the solar cells within a particular section that contains this defect and will not affect the portions of the solar cells that are in other sections.

Abstract: A system and method of forming a thin film solar cell with a metallic foil substrate are provided. After forming a semiconductor absorber film over the front surface of the metallic foil substrate a back surface of the metallic foil substrate is treated using a material removal process to form a treated back surface in a process chamber. In one embodiment, the material removal process is performed while depositing a transparent conductive layer over the semiconductor absorber film in the process chamber.

Abstract: A method and system to modify a surface composition of thin film Group IBIIIA VIA solar cell absorbers having non-uniformly distributed Group IIIA materials or graded materials, such as Indium (In), gallium (Ga) and aluminum (Al). The graded materials distribution varies between the surface and the bottom of the absorber layer such that a molar ratio of (Ga+Al)/(Ga+Al+In) is the highest at the bottom of the absorber layer and the lowest at the surface of the absorber. Within the bulk of the absorber, the molar ratio gradually changes between the bottom and the surface of the absorber. In one embodiment, the surface composition of a graded absorber layer may be modified by removing a top portion or slice of the absorber layer, where the molar ratio is low so as to expose the inner portions of the absorber layer having a higher molar ratio of graded materials.

Abstract: The present invention advantageously provides for, in different embodiments, low-cost deposition techniques to form high-quality, dense, well-adhering Group IBIIIAVIA compound thin films with macro-scale as well as micro-scale compositional uniformities. In one embodiment, there is provided a method of growing a Group IBIIIAVIA semiconductor layer on a base, and includes the steps of depositing on the base a film of Group IB material and at least one layer of Group IIIA material, intermixing the film of Group IB material and the at least one layer of Group IIIA material to form an intermixed layer, and forming over the intermixed layer a metallic film comprising at least one of a Group IIIA material sub-layer and a Group IB material sub-layer. Other embodiments are also described.

Abstract: A thin film solar cell includes a buffer layer disposed between a transparent conductive layer and a junction partner layer. The solar cell has an absorber layer made from a Group II-VI compound which is in contact with the junction partner layer. The buffer layer is made from at least one of cadmium doped tin oxide, indium sulfide, tin doped indium sulfide, gallium sulfide and tin doped gallium sulfide.

Abstract: A method of forming a doped Group IBIIIAVIA absorber layer for solar cells by reacting a partially reacted precursor layer with a dopant structure. The precursor layer including Group IB, Group IIIA and Group VIA materials such as Cu, Ga, In and Se are deposited on a base and partially reacted. After the dopant structure is formed on the partially reacted precursor layer, the dopant structure and partially reacted precursor layer is fully reacted. The dopant structure includes a dopant material such as Na.

Abstract: A method of forming an ohmic contact to a surface of a Cd and Te containing compound film as may be found, for example in a photovoltaic cell. The method comprises forming a Te-rich layer on the surface of the Cd and Te containing compound film; depositing an interface layer on the Te-rich layer; and laying down a contact layer on the interface layer. The interface layer is composed of a metallic form of Zn and Cu.

Abstract: A method and a system are provide for forming planar precursor structures which are subsequently converted into thin film solar cell absorber layers. A precursor structure is first formed on the front surface of the foil substrate and then planarized through application of force or pressure by a smooth surface to obtain a planar precursor structure. The precursor structure includes at least one of a Group IB material, Group IIIA material and Group VIA material. The planar precursor structures are reacted to form planar and compositionally uniform thin film absorber layers for solar cells.

Abstract: A process and apparatus which form a solar cell absorber on a surface of a workpiece as the workpiece and a carrier are advanced through a rapid thermal processing (RTP) chamber. In one embodiment, the surface of the workpiece includes a precursor layer and an absorber constituent is disposed on the carrier. Initially an absorber constituent vapor can be formed in the RTP chamber by advancing the carrier into the RTP chamber to vaporize the absorber constituent from the carrier. The workpiece with the precursor layer is then moved into the RTP chamber to react the absorber constituent vapor and the precursor layer to form an absorber layer on the workpiece.

Abstract: A system is described to deposit a buffer layer onto exposed surfaces of two different solar cell absorber layers of two different flexible workpieces from a process solution including all chemical components of the buffer layer material. The buffer layer is deposited from the process or deposition solution while the flexible workpieces are simultaneously heated and processed within a chamber in a face to face manner as the process solution is flown through a process gap formed between the exposed surfaces of the two solar cell absorber layers.

Abstract: A photovoltaic module which has at least two solar cells, and a method and system to manufacture such photovoltaic modules. The solar cells are disposed on a surface of an insulating carrier film and an isolation structure is formed between the solar cells to electrically isolate them. A conductor structure such as conductive fingers and busbars is formed on the module. The fingers are formed substantially on the top transparent conductive layer of the cells and the busbar is formed substantially over the insulation structure. The busbar electrically connects the top transparent conductive layer of one of the cells to the conductive base of the other cell.