Patent application number | Description | Published |
20110129954 | METHOD FOR MANUFACTURING A PHOTOVOLTAIC CELL STRUCTURE - In the frame of photovoltaic cell manufacturing a silicon compound layer is deposited upon a carrier structure. Manufacturing flexibility is increased on one hand by incorporating ambient air exposure of such silicon compound layer and on the other preventing deterioration of reproducibility by such ambient air exposure by enriching the surface of the addressed silicon compound layer which is to be exposed to ambient air to an oxygen enrichment. | 06-02-2011 |
20110180124 | PHOTOVOLTAIC CELL AND METHOD OF MANUFACTURING A PHOTOVOLTAIC CELL - A photovoltaic cell comprises an electrode layer ( | 07-28-2011 |
20110180142 | ELECTRICAL AND OPTICAL PROPERTIES OF SILICON SOLAR CELLS - The method for manufacturing a photovoltaic cell or a photovoltaic converter panel comprises depositing a layer of p-doped amorphous silicon using a gas mixture comprising silane, methane, hydrogen and trimethylboron in a ratio of 1:2:2:1.25. In particular, plasma-enhanced chemical vapor deposition is used for the deposition. The corresponding photovoltaic cells and photovoltaic converter panels are also described. | 07-28-2011 |
20110186127 | METHOD FOR DEPOSITING AN AMORPHOUS SILICON FILM FOR PHOTOVOLTAIC DEVICES WITH REDUCED LIGHT-INDUCED DEGRADATION FOR IMPROVED STABILIZED PERFORMANCE - A thin film photovoltaic device on a substrate is being realized by a method for manufacturing a p-i-n junction semiconductor layer stack with a p-type microcrystalline silicon layer, a p-type amorphous silicon layer, a buffer silicon layer comprising preferably intrinsic amorphous silicon, an intrinsic type amorphous silicon layer, and an n-type silicon layer over the intrinsic type amorphous silicon layer. | 08-04-2011 |
20110240107 | LARGE-AREA THIN-FILM-SILICON PHOTOVOLTAIC MODULES - Micromorph tandem cells with stabilized efficiencies of 11.0% have been achieved on as-grown LPCVD ZnO front TCO at bottom cell thickness of just 1.3 μm in combination with an antireflection concept. Applying an advanced LPCVD ZnO front TCO stabilized tandem cells of 10.6% have been realized at a bottom cell thickness of only 0.8 μm. Implementing intermediate reflectors in Micromorph tandem cell devices allow for, compared to commercial SnO | 10-06-2011 |
20120227799 | HIGH EFFICIENCY MICROMORPH TANDEM CELLS - A method for manufacturing a micromorph tandem cell is disclosed. The micromorph tandem cell comprises a μc-Si:H bottom cell and an a-Si:H top cell, an LPCVD ZnO front contact layer and a ZnO back contact in combination with a white reflector. The method comprises the steps of
| 09-13-2012 |
20120270362 | NEW INTRINSIC ABSORBER LAYER FOR PHOTOVOLTAIC CELLS - So as to manufacture an intrinsic absorber layer of amorphous hydrogenated silicon within a p-i-n configuration a solar cell by PeCvD deposition upon a base structure, thereby improving throughput an simultaneously maintaining quality of the absorber layer, a specific processing regime is proposed, wherein in the reactor for depositing the addressed absorber layer a pressure of between 1 mbar and 1.8 mbar is established and a flow of silane and of hydrogen with a dilution of silane to hydrogen of 1:4 up to 1:10 and generating an RF plasma with a generator power of between 600W and 1200W per 1.4 m | 10-25-2012 |
20150136210 | SILICON-BASED SOLAR CELLS WITH IMPROVED RESISTANCE TO LIGHT-INDUCED DEGRADATION - Solar devices with high resistance to light-induced degradation are described. A wide optical bandgap interface layer positioned between a p-doped semiconductor layer and an intrinsic semiconductor layer is made resistant to light-induced degradation through treatment with a hydrogen-containing plasma. In one embodiment, a p-i-n structure is formed with the interface layer at the p/i interface. Optionally, an additional interface layer treated with a hydrogen-containing plasma is formed between the intrinsic layer and the n-doped layer. Alternatively, a hydrogen-containing plasma is used to treat an upper portion of the intrinsic layer prior to deposition of the n-doped semiconductor layer. The interface layer is also applicable to-multi-junction solar cells with plural p-i-n structures. The p-doped and n-doped layers can optionally include sublayers of different compositions and different morphologies (e.g., microcrystalline or amorphous). The overall structure shows both an increased stability with respect to light-induced degradation and an improved performance level. | 05-21-2015 |