A thermal conduction sheet holder include, in the following order, an elongated carrier film, a plurality of thermal conduction sheets, and an elongated cover film covering the plurality of thermal conduction sheets, the shortest distance between adjacent thermal conduction sheets is 2 mm or more, the plurality of thermal conduction sheets are disposed at intervals in a longitudinal direction of the carrier film and the cover film, and the plurality of thermal conduction sheets are peelable from the cover film and the carrier film.

Methods for die attachment of multichip and single components may involve printing a sintering paste on a substrate or on the back side of a die. Printing may involve stencil printing, screen printing, or a dispensing process. Paste may be printed on the back side of an entire wafer prior to dicing, or on the back side of an individual die. Sintering films may also be fabricated and transferred to a wafer, die or substrate. A post-sintering step may increase throughput.

The purpose of this invention is to provide a semiconductor device that prevents defects in semiconductor elements caused by differences in thermal expansion and maintains low electrical resistance by directly or indirectly laminating an FeNi alloy metal layer onto the front-surface or back-surface electrodes of the semiconductor element. In this invention, an FeNi alloy metal layer is directly or indirectly applied on the surface electrodes of the semiconductor element, and the semiconductor element is connected to a conductor through the FeNi alloy metal layer. Depending on the application, the Ni content of the FeNi alloy metal layer is set within the range of 36% to 45% by weight, and the thickness of the FeNi alloy metal layer is set within the range of 2 m to 20 m.

The present disclosure describes a bonded semiconductor structure and a method of forming the bonded semiconductor structure. The bonded semiconductor structure includes first and second substrates bonded with a bonding structure. The bonding structure provides high thermal conductivity and high bonding strength between the first and second substrates. The bonding structure includes bonding layers and adhesion layers, with the bonding layers including titanium oxide and the adhesion layers including titanium nitride. The method includes forming a first adhesion layer on the first substrate and a second adhesion layer on the second substrate. The method also includes forming a first bonding layer on the first adhesion layer and a second bonding layer on the second adhesion layer. The method further includes bonding the first and second substrates by bonding the first and second bonding layers together.