A microfabricated laminated conductor, comprising at least two flat metallic conductors held together parallel by their edges by a first dielectric material anchor, such that there exists a gap of between several nanometers and several micrometers between most of the at least two flat metallic conductors.

A method of manufacturing a lead wire for a solar cell includes heating a wire material by a direct resistance heating or by an induction heating to reduce a 0.2% proof stress of the wire material while conveying the wire material and plating the wire material that is in a heated condition obtained by the direct resistance heating or by the induction heating while further conveying the wire material. An apparatus is configured to implement the method, and includes a plating bath, a conveyor mechanism configured to convey the wire material, a heater configured to heat the wire material, and a controller configured to control the conveyor mechanism and the heater.

A rotatable connector device includes a stationary member, a rotatable member rotatably attached thereto, and a flat cable housed in an annular space between the stationary and rotatable members. One end of the flat cable is connected to a stationary-side connector fixed to the stationary member, and another end of the flat cable is connected to a rotating-side connector fixed to the rotatable member. The flat cable includes a folded-back portion bent and folded back at a middle section in a longitudinal direction thereof. The flat cable includes a predetermined number of conductor/conductors each comprising a copper alloy and wound up or rewound with bending kept at the folded-back portion. Each conductor satisfies Y14.175X.sup.2249.35X+1406.9 for a bending radius of 4 to 8 mm, where X denotes bending radius, and Y denotes 0.2% yield stress, and has an electrical conductivity of 50% IACS or greater.

According to embodiments of the present invention, a conductive paste is provided. The conductive paste has a composition including a plurality of conductive nanoparticles and a plurality of conductive nanowires, wherein a weight ratio of the plurality of conductive nanoparticles to the plurality of conductive nanowires is between about 10:1 and about 50:1. According to further embodiments of the present invention, a method for forming an interconnection and an electrical device are also provided.

A multi-strand composite electrical conductor assembly includes a strand formed of carbon nanotubes and an elongated metallic strand having substantially the same length as the carbon nanotube strand. The assembly may further include a plurality of metallic strands that have substantially the same length as the carbon nanotube strand. The carbon nanotube strand may be located as a central strand and the plurality of metallic strands surround the carbon nanotube strand. The metallic strand may be formed of a material such as copper, silver, gold, or aluminum and may be plated with a material such as nickel, tin, copper, silver, and/or gold. Alternatively or additionally, the metallic strand may be clad with a material such as nickel, tin, copper, silver, and/or gold.

Disclosed is a copper-cobalt-silicon (CuCoSi) alloy for electronic material with an improved balance among electro-conductivity, strength and bend formability, which includes 0.5 to 3.0% by mass of Co, 0.1 to 1.0% by mass of Si, and the balance of Cu and inevitable impurities, having a ratio of mass percentages of Co and Si (Co/Si) given as 3.5Co/Si5.0, having an average particle size of second phase particles, within the range of the particle size of 1 to 50 m seen in a cross-section taken in parallel with the direction of rolling, of 2 to 10 nm, and having an average distance between the adjacent second phase particles of 10 to 50 nm.

A composition comprising a plurality of coated metal particles with a metal core surrounded by nested shells formed by an electrically conductive layer and by a barrier layer, at least one of the shells being formed by electroless plating. The invention also comprises a method of producing such compositions as well as the use of the composition in, for example, crystalline-silicon solar cell devices having contact structures formed on one or more surfaces of a solar cell device, such as those used in back contact solar cell devices or emitter wrap through (EWT) solar cell devices.

An electrically conductive wire for deep water transmission includes a first wire portion and a second wire portion. The first wire portion makes up one end of the wire, and is formed from a first metal. The second wire portion is formed from a second metal. The first metal has a higher ultimate tensile strength than the second metal. The first wire portion is used to support the weight of the second wire portion, thereby allowing the electrically conductive wire to be used in underwater or subsea power cables which may be freely suspended from their origin for providing electricity to electrical devices located in deep water or ultra-deep water.

Electrical cable for supplying aircraft and similar devices with alternating current having at least partially higher frequencies of preferably 400 Hz. The cable is provided with a central neutral and/or return conductor and at least six phase conductors arranged in a concentrically distributed manner about the neutral and/or return conductor, wherein every phase is distributed on two symmetrically opposing phase conductors. The neutral and/or return conductor is formed, in a very space-saving manner and with low inductivity, by six individually insulated compact neutral wires, the total cross-section of which approximately corresponds to the cross-section of an individual solid neutral wire.

In various embodiments, superconducting wires feature assemblies of clad composite filaments and/or stabilized composite filaments embedded within a wire matrix. The wires may include one or more stabilizing elements for improved mechanical properties.