Disclosed is an electromagnetic wave absorbing heat conductive sheet having superior heat conductivity and electromagnetic wave absorbency. The electromagnetic wave absorbing heat conductive sheet comprises a polymer matrix component; a magnetic metal power; and a fibrous heat conductive filler oriented in one direction.

Disclosed is an electromagnetic wave absorbing heat conductive sheet having superior heat conductivity and electromagnetic wave absorbency. The electromagnetic wave absorbing heat conductive sheet comprises a polymer matrix component; a magnetic metal power; and a fibrous heat conductive filler oriented in one direction.

An object of the present invention is to provide an anisotropic conductive bonding member capable of achieving excellent conduction reliability and insulation reliability, a semiconductor device using the same, a semiconductor package, and a semiconductor device production method. An anisotropic conductive bonding member of the present invention includes an insulating base which is made of an inorganic material, a plurality of conductive paths which are made of a conductive member, penetrate the insulating base in a thickness direction thereof, and are provided in a mutually insulated state, and a pressure sensitive adhesive layer which is provided on a surface of the insulating base, in which each of the conductive paths has a protrusion protruding from the surface of the insulating base, the protrusion of each of the conductive paths is buried in the pressure sensitive adhesive layer, and the pressure sensitive adhesive layer contains a polymer material and an antioxidant material.

A method of deposition of a thermal interface material onto a circuit assembly and an integrated circuit formed therefrom is provided. The method includes depositing a thermal interface material at a first layer thickness between a first layer of a circuit assembly and a second layer of the circuit assembly. The thermal interface material includes an emulsion of liquid metal droplets and polymer. The first layer thickness is at least 1.1 times a D.sub.90 of the liquid metal droplets prior to compressing the circuit assembly. The method includes compressing the circuit assembly to decrease the first layer thickness to a second layer thickness, thereby deforming the liquid metal droplets. The second layer thickness is no greater than a D.sub.90 of the liquid metal droplets in thermal interface material prior to compressing the circuit assembly.

Disclosed is an electromagnetic wave absorbing heat conductive sheet having superior heat conductivity and electromagnetic wave absorbency. The electromagnetic wave absorbing heat conductive sheet comprises a polymer matrix component; a magnetic metal power; and a fibrous heat conductive filler oriented in one direction.

Disclosed is an electromagnetic wave absorbing heat conductive sheet having superior heat conductivity and electromagnetic wave absorbency. The electromagnetic wave absorbing heat conductive sheet comprises a polymer matrix component; a magnetic metal power; and a fibrous heat conductive filler oriented in one direction.

An object of the present invention is to provide an anisotropic conductive bonding member capable of achieving excellent conduction reliability and insulation reliability, a semiconductor device using the same, a semiconductor package, and a semiconductor device production method. An anisotropic conductive bonding member of the present invention includes an insulating base which is made of an inorganic material, a plurality of conductive paths which are made of a conductive member, penetrate the insulating base in a thickness direction thereof, and are provided in a mutually insulated state, and a pressure sensitive adhesive layer which is provided on a surface of the insulating base, in which each of the conductive paths has a protrusion protruding from the surface of the insulating base, the protrusion of each of the conductive paths is buried in the pressure sensitive adhesive layer, and the pressure sensitive adhesive layer contains a polymer material and an antioxidant material.

An integrated circuit die with two material layers having metal nano-particles and the method of forming the same are provided. The integrated circuit die includes a device layer comprising a first transistor, a first interconnect structure on a first side of the device layer, a first material layer on the first interconnect structure, wherein the first material layer comprises first metal nano-particles, and a second material layer bonded to the first material layer, wherein the second material layer comprises second metal nano-particles, and wherein the first material layer and the second material layer share an interface.