The present invention provides a conductive material in which, even when the conductive material is left for a certain period of time, solder of conductive particles can be efficiently placed on an electrode, and, in addition, yellowing of the conductive material can be sufficiently suppressed during heating. The conductive material according to the present invention contains a plurality of conductive particles having solder at an outer surface portion of a conductive portion, a curable compound, and a boron trifluoride complex.

A self-heating solder flux material includes a solder flux material and a multi-compartment microcapsule. The solder flux material includes a solvent carrier, and the multi-compartment microcapsule includes a first compartment, a second compartment, and an isolating structure. The first compartment contains a first reactant, and the second compartment contains a second reactant. The isolating structure separates the first compartment from the second compartment. The isolating structure is adapted to rupture in response to a stimulus. Rupture of the isolating structure results in an exothermic reaction between the first reactant and the second reactant. The exothermic reaction generates heat to volatilize the solvent carrier.

A flux includes a rosin resin, an activator, a thixotropic agent, and a solvent. The solvent includes 30% by mass or more and 60% by mass or less monovalent alcohol with respect to a total mass amount of the flux. The monovalent alcohol has 18 or more and 24 or less of carbon atoms in one molecule.

Provided is a solder transfer sheet which is capable of increasing the amount of solder to be transferred without the occurrence of bridging. A solder transfer sheet 1A includes a base material 5, an adhesive layer 4 formed on the surface of the base material 5, a solder powder-containing adhesive layer 3 formed on the surface of the adhesive layer 4, and a solder powder layer 2 formed on the surface of the solder powder-containing adhesive layer 3. In the solder powder layer 2, particles of solder powder 20 are arranged in a one-layer sheet form. In the solder powder-containing adhesive layer 3, solder powder 30 and an adhesive component 31 are mixed so as to have such a thickness that two or more layers of the solder powder 30 are stacked.

A ceramic substrate manufacturing method is provided in which a copper sheet is etched and then bonded to a ceramic substrate, so that the ceramic substrate has reduced to overall processing time and improved reliability and product lifespan. The ceramic substrate manufacturing method includes the steps of: etching a copper sheet so as to prepare a metal substrate; etching a ceramic substrate so as to prepare a unit ceramic substrate; assembling the metal substrate and the unit ceramic substrate; bonding the metal substrate and the unit ceramic substrate so as to form a stack; partially printing a metal paste on the surface of the stack; and sintering the metal paste.

The device intended to be thermoformed comprises a substrate capable of being thermoformed and an electrically conductive member integral with the said substrate. The electrically conductive member comprises: electrically conductive particles, an electrically conductive material, electrically conductive elements of elongated shape. The electrically conductive material has a melting point which is strictly less than the melting point of the electrically conductive particles and than the melting point of the elements of elongated shape.

A pattern-forming method for forming a conductive circuit pattern, the pattern-forming method including the steps of: preparing a pattern-forming composition composed of: Cu powder; solder particles for electrically coupling the Cu powder; a polymer resin; a deforming agent that is selected from among acrylate oligomer, polyglycols, glycerides, polypropylene glycol, dimethyl silicon, simethinecone, tributyl phosphare, and polymethylsiloxane, and that increases bonding force between the Cu powder and the solder particles; a curing agent; and a reductant; forming a circuit pattern by printing the pattern-forming composition on a substrate; heating the circuit pattern at a temperature effective to cure the pattern-forming composition and provide the conductive circuit pattern; and electrolytically plating a metal layer onto the conductive circuit pattern. A circuit pattern having superior conductivity is formed at low cost.

A semiconductor package and methods for producing the same are described. One example of the semiconductor package is described to include a substrate having a first face and an opposing second face. The package is further described to include a plurality of solderable surfaces formed on the first face of the substrate, a first solderable surface in the plurality of solderable surfaces having a pattern plating structure on an outward facing surface of the first solderable surface. There may also be an amount of solder bonded to the outward facing surface of the first solderable surface, where the pattern plating structure on the outward facing surface of the first solderable surface causes the amount of solder to have a first thickness at its ends, a second thickness at its center, and a discrete transition between the first thickness and the second thickness.

A self-heating solder flux material includes a solder flux material and a multi-compartment microcapsule. The solder flux material includes a solvent carrier, and the multi-compartment microcapsule includes a first compartment, a second compartment, and an isolating structure. The first compartment contains a first reactant, and the second compartment contains a second reactant. The isolating structure separates the first compartment from the second compartment. The isolating structure is adapted to rupture in response to a stimulus. Rupture of the isolating structure results in an exothermic reaction between the first reactant and the second reactant. The exothermic reaction generates heat to volatilize the solvent carrier

A method for forming a functional part in a minute space includes the steps of: filling a minute space with a dispersion functional material in which a thermally-meltable functional powder is dispersed in a liquid dispersion medium; evaporating the liquid dispersion medium present in the minute space; and heating the functional powder and hardening it under pressure.