Abstract: A method is described for forming a film of amorphous silicon (a-Si:H) on a substrate by deposition from a plasma. The substrate is placed in an enclosure, a film precursor gas is introduced into the enclosure, and unreacted and dissociated gas is extracted from the enclosure so as to provide a low pressure in the enclosure. Microwave energy is introduced into the gas within the enclosure to produce a plasma therein by distributed electron cyclotron resonance (DECR) and cause material to be deposited from the plasma on the substrate. The substrate is held during deposition at a temperature in the range 200-600° C., preferably 225-350° C. and a bias voltage is applied to the substrate at a level to give rise to a sheath potential in the range ?30 to ?105V, preferably using a source of RF power in the range of 50-250 mW/cm2 of the area of the substrate holder.

Abstract: A photovoltaic panel has an absorbent photovoltaic material, particularly based on cadmium, said panel including a front side substrate, particularly a transparent glass substrate with a transparent electrode coating, where the antireflection coating placed above the metal functional layer opposite the substrate has a single antireflection layer, based on mixed zinc tin oxide over its whole thickness, or where the antireflection coating placed above the metal functional layer opposite the substrate has at least two antireflection layers including, on the one hand, an antireflection layer which is closer to the functional layer and is based on mixed zinc tin oxide over its whole thickness and, on the other, an antireflection layer which is further from the functional layer and is not based on mixed zinc tin oxide over its whole thickness.

Abstract: A method is disclosed for forming a film of an amorphous material, for example amorphous silicon, on a substrate (14), by deposition from a plasma. A substrate is placed in an enclosure having a defined volume, and a film precursor gas, for example silane, is introduced into the enclosure through pipes (20). Unreacted and dissociated gas is extracted from the enclosure through exit (22) so as to provide a low pressure in the enclosure. Microwave energy is introduced into the gas within the enclosure to produce a plasma therein by distribution electron cyclotron resonance, and cause material to be deposited from the plasma on the substrate. The normalised precursor gas flow rate, defined as the precursor gas flow rate, divided by the area of the distributed plasma source, is greater than or equal to 700 sccm/m2, and the gas residence time, defined as the volume of the reactor divided by the effective precursor gas pumping rate, is not more than 30 ms.

Abstract: A method is described for forming a film of amorphous silicon (a-Si:H) on a substrate by deposition from a plasma. The substrate is placed in an enclosure, a film precursor gas is introduced into the enclosure, and unreacted and dissociated gas is extracted from the enclosure so as to provide a low pressure in the enclosure. Microwave energy is introduced into the gas within the enclosure to produce a plasma therein by distributed electron cyclotron resonance (DECR) and cause material to be deposited from the plasma on the substrate. The substrate is held during deposition at a temperature in the range 200-600° C., preferably 225-350° C. and a bias voltage is applied to the substrate at a level to give rise to a sheath potential in the range ?30 to ?105V, preferably using a source of RF power in the range of 50-250 mW/cm2 of the area of the substrate holder.

Abstract: Method of fabricating a transparent electrode based on zinc oxide, characterized in that a layer based on zinc oxide is deposited on at least one of the faces of a substrate or on at least one layer in contact with one of the faces of said substrate, and in that this layer is subjected to a heat treatment so as to over-oxidize a portion of the surface of said layer to a fraction of its thickness.