Provided are an underfill material capable of realizing low-pressure mounting and voidless mounting, and a method for manufacturing a semiconductor device using the same. The underfill material includes a main composition containing an acrylic polymer, an acrylic monomer, and a maleimide compound, and the acrylic polymer is contained in a range of 10 parts by mass or more and 60 parts by mass or less in 100 parts by mass of the main composition, and the maleimide compound is contained in a range of 20 parts by mass or more and 70 parts by mass or less in 100 parts by mass of the main composition. Low-pressure mounting and the voidless mounting can be realized.

The objective of the present invention is to provide a technique that ensures conduction between a gate terminal of a semiconductor switching element and a wiring layer in a semiconductor device formed with a wiring layer inside a ceramic layer. This semiconductor device comprises: a wiring layer that is inside a ceramic layer formed above an insulation layer; and a metal layer for connecting terminals from the semiconductor switching element other than the gate terminal. The wiring layer and the gate terminal from the semiconductor switching element are connected electrically via a connection part formed from a conductive material. The connection part protrudes more than the metal layer toward the semiconductor switching element.

A highly reliable bonded structure having excellent thermal fatigue resistance characteristics and thermal stress relaxation characteristics is provided. The bonded structure of the present invention comprises a first member, a second member capable of being bonded to the first member, and a bonding part interposed between a first bond surface at the first member side and a second bond surface at the second member side to bond the first member and the second member. The bonding part has at least a bonding layer, a reinforcing layer, and an intermediate layer. The bonding layer is composed of an intermetallic compound and bonded to the first bond surface.

An electronic-part-reinforcing thermosetting resin composition has: a viscosity of 5 Pa.Math.s or less at 140° C.; a temperature of 150° C. to 170° C. as a temperature corresponding to a maximum peak of an exothermic curve representing a curing reaction; and a difference of 20° C. or less between the temperature corresponding to the maximum peak and a temperature corresponding to one half of the height of the maximum peak in a temperature rising range of the exothermic curve.

Provided are a semiconductor element bonding apparatus and a semiconductor element bonding method that do not cause a bonding material to protrude and also ensure adhesion, even when there are variations in a thickness of a semiconductor element or a workpiece and even when there are projections and depressions on surfaces. A semiconductor element bonding apparatus includes disposing means for disposing a workpiece and a semiconductor element at positions facing each other, moving means for moving the workpiece or the semiconductor element in a vertical direction, displacement measuring means for measuring displacement of the workpiece or the semiconductor element in the vertical direction, load measuring means for measuring a contact load between the workpiece and the semiconductor element with the bonding material interposed therebetween, and elastic modulus calculating means for calculating an elastic modulus from results of the measurement by the displacement measuring means and the load measuring means.

Provided are a semiconductor element bonding apparatus and a semiconductor element bonding method that do not cause a bonding material to protrude and also ensure adhesion, even when there are variations in a thickness of a semiconductor element or a workpiece and even when there are projections and depressions on surfaces. A semiconductor element bonding apparatus includes disposing means for disposing a workpiece and a semiconductor element at positions facing each other, moving means for moving the workpiece or the semiconductor element in a vertical direction, displacement measuring means for measuring displacement of the workpiece or the semiconductor element in the vertical direction, load measuring means for measuring a contact load between the workpiece and the semiconductor element with the bonding material interposed therebetween, and elastic modulus calculating means for calculating an elastic modulus from results of the measurement by the displacement measuring means and the load measuring means.

Electronic assembly methods and structures are described. In an embodiment, an electronic assembly method includes bringing together an electronic component and a routing substrate, and directing a large area photonic soldering light pulse toward the electronic component to bond the electronic component to the routing substrate.

A sintering powder comprising: a first type of metal particles having a mean longest dimension of from 100 nm to 50 μm.

A sintering powder comprising: a first type of metal particles having a mean longest dimension of from 100 nm to 50 μm.

A method for producing a stable sandwich arrangement of two components with solder situated therebetween, comprising the steps:

(1) providing two components, each having at least one contact surface, and a free solder preform,
(2) producing a sandwich arrangement of the components and a solder preform arranged between them and thus not yet connected to them by bringing into contact (i) each one of the contact surfaces, (ii) each of the single contact surface of the components or (iii) one of the contact surfaces of one component and a single contact surface of the other component, with the contact surfaces of the free solder preform, and
(3) hot-pressing the sandwich arrangement produced in step (2) so as to form the stable sandwich arrangement at a temperature being at 10 to 40% below the melting temperature of the solder metal of the solder preform, expressed in ° C.