A method of manufacturing a semiconductor device, the method including: preparing an insulated circuit substrate including a conductive plate; partially fixing a plate-like bonding member onto the conductive plate so as to make a positioning of the bonding member in a horizontal direction; mounting a semiconductor chip on the bonding member; and heating and melting the bonding member so as to form a bonding layer for bonding the insulated circuit substrate and the semiconductor chip each other.

A method of manufacturing a semiconductor device, the method including: preparing an insulated circuit substrate including a conductive plate; partially fixing a plate-like bonding member onto the conductive plate so as to make a positioning of the bonding member in a horizontal direction; mounting a semiconductor chip on the bonding member; and heating and melting the bonding member so as to form a bonding layer for bonding the insulated circuit substrate and the semiconductor chip each other.

A solder material may include nickel and tin. The nickel may include first and second amounts of particles. A sum of the particle amounts is a total amount of nickel or less. The first amount is between 5 at % and 60 at % of the total amount of nickel. The second amount is between 10 at % and 95 at % of the total amount of nickel. The particles of the first amount have a first size distribution, the particles of the second amount have a second size distribution, 30% to 70% of the first amount have a particle size in a range of about 5 μm around a particle size the highest number of particles have according to the first size distribution, and 30% to 70% of the second amount have a particle size in a range of about 5 μm around a particle size the highest number of particles have according to the second size distribution.

An electronic component includes a lead frame; a semiconductor chip arranged above the lead frame; and a connection layer sequence arranged between the lead frame and the semiconductor chip, wherein the connection layer sequence includes a first intermetallic layer including gold and indium or gold, indium and tin, a second intermetallic layer including indium and a titanium compound, indium and nickel, indium and platinum or indium and titanium, and a third intermetallic layer including indium and gold.

An electronic component includes a lead frame; a semiconductor chip arranged above the lead frame; and a connection layer sequence arranged between the lead frame and the semiconductor chip, wherein the connection layer sequence includes a first intermetallic layer including gold and indium or gold, indium and tin, a second intermetallic layer including indium and a titanium compound, indium and nickel, indium and platinum or indium and titanium, and a third intermetallic layer including indium and gold.

A semiconductor package includes: a first package substrate; a first semiconductor device mounted on the first package substrate; a second package substrate arranged on an upper part of the first semiconductor device; and a heat-dissipating material layer arranged between the first semiconductor device and the second package substrate and having a thermal conductivity of approximately 0.5 W/m.Math.K to approximately 20 W/m.Math.K, wherein the heat-dissipating material layer is in direct contact with an upper surface of the first semiconductor device and a conductor of the second package substrate.

A semiconductor package includes: a first package substrate; a first semiconductor device mounted on the first package substrate; a second package substrate arranged on an upper part of the first semiconductor device; and a heat-dissipating material layer arranged between the first semiconductor device and the second package substrate and having a thermal conductivity of approximately 0.5 W/m.Math.K to approximately 20 W/m.Math.K, wherein the heat-dissipating material layer is in direct contact with an upper surface of the first semiconductor device and a conductor of the second package substrate.

A layer structure includes a first layer including at least one material selected from a first group consisting of nickel, copper, gold, silver, palladium, tin, zinc, platinum, and an alloy of any of these materials; a third layer including at least one material selected from a second group consisting of nickel, copper, gold, palladium, tin, silver, zinc, platinum, and an alloy of any of these materials; and a second layer between the first layer and the third layer. The second layer consists of or essentially consists of nickel and tin. The second layer includes an intermetallic phase of nickel and tin.

A temperature-sensor assembly comprising at least one temperature sensor and at least one supply line, wherein the temperature sensor has at least one electrically insulating substrate with an upper side and an underside, wherein a temperature-sensor structure with at least one sensor-contact surface is formed at least on parts of the upper side, wherein the supply line has at least one supply-line contact surface, wherein the supply-line contact surface is connected to the sensor-contact surface at least in part by means of a first sinter layer.

A temperature-sensor assembly comprising at least one temperature sensor and at least one supply line, wherein the temperature sensor has at least one electrically insulating substrate with an upper side and an underside, wherein a temperature-sensor structure with at least one sensor-contact surface is formed at least on parts of the upper side, wherein the supply line has at least one supply-line contact surface, wherein the supply-line contact surface is connected to the sensor-contact surface at least in part by means of a first sinter layer.