摘要:
Described are embodiments including an apparatus that provides a thin film solar cell base structure for a photovoltaic device, a method of manufacturing a photovoltaic device, a roll to roll method of manufacturing a thin film solar cell base structure, and a ruthenium alloy sheet material.
摘要:
Aspects of the present inventions include an electrodeposition solution for deposition of a thin film that includes a Group VA material, a method of electroplating to deposit a thin film that includes a Group VA material, among others.
摘要:
The present invention provides methods for forming a buffer layer for Group IBIIIAVIA solar cells. The buffer layer is formed using chemical bath deposition and the layer is formed in steps. A first buffer layer is formed on the absorber and the first buffer layer is then treated using etching, oxidizing, annealing or some combination thereof. Subsequently a second buffer layer is then positioned on the treated surface. Additional buffer layers can be added following treatment of the previously deposited layer.
摘要:
The present invention provides a method to form Group IBIIIAVIA solar cell absorber layers on continuous flexible substrates. In a preferred aspect, the method forms a Group IBIIIAVIA absorber layer for manufacturing photovoltaic cells by providing a workpiece having a precursor layer formed over a substrate, the precursor layer including copper, indium, gallium and selenium; heating the precursor layer to a first temperature; reacting the precursor layer at the first temperature for a first predetermined time to transform the precursor layer to a partially formed absorber structure; cooling down the partially formed absorber structure to a second temperature, wherein both the first temperature and the second temperature are above 400° C.; and reacting the partially formed absorber structure at the second temperature for a second predetermined time, which is longer than the first predetermined time, to form a Group IBIIIAVIA absorber layer.
摘要:
The present invention provides a method and precursor structure to form a solar cell absorber layer. The method includes electrodepositing a first layer including a film stack including at least a first film comprising copper, a second film comprising indium and a third film comprising gallium, wherein the first layer includes a first amount of copper, electrodepositing a second layer onto the first layer, the second layer including at least one of a second copper-indium-gallium-ternary alloy film, a copper-indium binary alloy film, a copper-gallium binary alloy film and a copper-selenium binary alloy film, wherein the second layer includes a second amount of copper, which is higher than the first amount of copper, and electrodepositing a third layer onto the second layer, the third layer including selenium; and reacting the precursor stack to form an absorber layer on the base.
摘要:
A thin film solar cell including a Group IBIIIAVIA absorber layer on a defect free base including a stainless steel substrate is provided. The stainless steel substrate of the base is surface treated to remove the surface roughness such as protrusions that cause shunts. Before removing the protrusions, a thin protective ruthenium film is first deposited on the recessed surface portions of the substrate to protect these portions during the following protrusion removal. The protrusions on the surface receives very little or no ruthenium during the deposition. After the ruthenium film is formed, the protrusions are etched and removed by an etchant which only attacks the stainless steel but neutral to the ruthenium film. A contact layer is formed over the ruthenium layer and the exposed portions of the substrate to complete the base.
摘要:
The present invention provides a method to form Group IBIIIAVIA solar cell absorber layers on continuous flexible substrates. In a preferred aspect, the method forms a Group IBIIIAVIA absorber layer for manufacturing photovoltaic cells by providing a workpiece having a precursor layer formed over a substrate, the precursor layer including copper, indium, gallium and selenium; heating the precursor layer to a first temperature; reacting the precursor layer at the first temperature for a first predetermined time to transform the precursor layer to a partially formed absorber structure; cooling down the partially formed absorber structure to a second temperature, wherein both the first temperature and the second temperature are above 400° C.; and reacting the partially formed absorber structure at the second temperature for a second predetermined time, which is longer than the first predetermined time, to form a Group IBIIIAVIA absorber layer.
摘要:
The present invention provides a method and precursor structure to form a Group IBIIIAIVA solar cell absorber layer. The method includes forming a Group IBIIIAVIA compound layer on a base by forming a precursor layer on the base through electrodepositing three different films, and then reacting the precursor layer with selenium to form the Group IBIIIAVIA compound layer on the base. The three films, described by the precursor layer, include in one embodiment a first alloy film comprising copper, indium and gallium, a second alloy film comprising copper and selenium formed on the first alloy film; and a selenium film formed on the second alloy film.
摘要:
The present invention provides methods for forming a doped Group IBIIIAVIA absorber layer for a solar cell. The method includes forming precursor layers that include a dopant rich layer and then annealing the precursor layers. The annealing process results in dopants diffusing through the layers to an exterior surface. The annealing process is periodically halted to remove dopants from the exposed surface.
摘要:
The present invention provides a method and precursor structure to form a solar cell absorber layer. The method includes forming a CIGS solar cell absorber on a base by depositing a first layer on the base, where in the first layer includes non-crystalline copper-selenide that is electrically nonconductive, and then heat treating the first layer at a first temperature range to transform the non-crystalline copper-selenide into a crystalline copper-selenide that is electrically conductive, thereby ensuring that the first layer becomes a first conductive layer. Thereafter, other steps follow to complete formation of the CIGS solar cell absorber.