In a semiconductor device, it is preferable to suppress a variation in characteristics of a temperature sensor. The semiconductor device is provided that includes a semiconductor substrate having a first conductivity type drift region, a transistor section provided in the semiconductor substrate, a diode section provided in the semiconductor substrate, a second conductivity type well region exposed at an upper surface of the semiconductor substrate, a temperature sensing unit that is adjacent to the diode section in top view and is provided above the well region, and an upper lifetime control region that is provided in the diode section, at the upper surface side of the semiconductor substrate, and in a region not overlapping with the temperature sensing unit in top view.

In one embodiment, an IGBT is formed to include a region of semiconductor material. Insulated gate structures are disposed in region of semiconductor material extending from a first major surface. An n-type field stop region extends from a second major surface into the region of semiconductor material. A p+ type polycrystalline semiconductor layer is disposed adjacent to the field stop region and provides an emitter region for the IGBT. An embodiment may include a portion of the p+ type polycrystalline semiconductor being doped n-type.

A semiconductor structure includes a semiconductor substrate having a gate electrode in a gate trench, a buried bus in the semiconductor substrate, the buried bus having a bus conductive filler in a bus trench, where the bus conductive filler is electrically coupled to the gate electrode. The bus conductive filler is surrounded by the gate electrode. The gate trench intersects the bus trench in the semiconductor substrate. The gate electrode includes polysilicon. The bus conductive filler includes tungsten. The semiconductor structure also includes an adhesion promotion layer interposed between the bus conductive filler and the gate electrode, where the adhesion promotion layer includes titanium and titanium nitride. The semiconductor structure also includes a dielectric layer covering the gate electrode over the semiconductor substrate, where the buried bus has a coplanar top surface with the dielectric layer.

A method for manufacturing a substrate wafer 100 includes providing a device wafer (110) having a first side (111) and a second side (112); subjecting the device wafer (110) to a first high temperature process for reducing the oxygen content of the device wafer (110) at least in a region (112a) at the second side (112); bonding the second side (112) of the device wafer (110) to a first side (121) of a carrier wafer (120) to form a substrate wafer (100); processing the first side (101) of the substrate wafer (100) to reduce the thickness of the device wafer (110); subjecting the substrate wafer (100) to a second high temperature process for reducing the oxygen content at least of the device wafer (110); and at least partially integrating at least one semiconductor component (140) into the device wafer (110) after the second high temperature process.

A semiconductor device according to an embodiment includes a first semiconductor layer of a first conductivity type, a second semiconductor layer of a second conductivity type, a third semiconductor layer of the first conductivity type, a fourth semiconductor layer of the second conductivity type, a first electrode connected to the second semiconductor layer and the fourth semiconductor layer, a second electrode facing the second semiconductor layer with an insulating film interposed, a fifth semiconductor layer of the second conductivity type, a sixth semiconductor layer of the first conductivity type, a seventh semiconductor layer of the second conductivity type, a third electrode connected to the fifth semiconductor layer and the seventh semiconductor layer, and a fourth electrode facing the fifth semiconductor layer with an insulating film interposed.

Various improvements in vertical transistors, such as IGBTs, are disclosed. The improvements include forming periodic highly-doped p-type emitter dots in the top surface region of a growth substrate, followed by growing the various transistor layers, followed by grounding down the bottom surface of the substrate, followed by a wet etch of the bottom surface to expose the heavily doped p+ layer. A metal contact is then formed over the p+ layer. In another improvement, edge termination structures utilize p-dopants implanted in trenches to create deep p-regions for shaping the electric field, and shallow p-regions between the trenches for rapidly removing holes after turn-off. In another improvement, a dual buffer layer using an n-layer and distributed n+ regions improves breakdown voltage and saturation voltage. In another improvement, p-zones of different concentrations in a termination structure are formed by varying pitches of trenches. In another improvement, beveled saw streets increase breakdown voltage.

An insulated gate silicon carbide semiconductor device includes: a drift layer of a first conductivity type on a silicon carbide substrate of 4H type with a {0001} plane having an off-angle of more than 0 as a main surface; a first base region; a source region; a trench; a gate insulating film; a protective diffusion layer; and a second base region. The trench sidewall surface in contact with the second base region is a surface having a trench off-angle of more than 0 in a <0001> direction with respect to a plane parallel to the <0001> direction. The insulated gate silicon carbide semiconductor device can relieve an electric field of a gate insulating film and suppress an increase in on-resistance and provide a method for manufacturing the same.

A semiconductor device includes at least one wiring layer disposed on a semiconductor body, a field effect transistor integrated in the semiconductor body, the field effect transistor having a plurality of gate electrodes residing in corresponding gate trenches formed in the semiconductor body, a first circuit integrated in the semiconductor body adjacent to the field effect transistor, and a second circuit integrated in the semiconductor body and remote from the first circuit. The semiconductor device further includes a first additional trench formed in the semiconductor body and at least one conductive pad formed in the at least one wiring layer. The first additional trench includes at least one connecting line which electrically connects the first circuit and the second circuit. The at least one conductive pad is arranged to at least partially cover the first additional trench to form a shielding of the at least one connecting line.

A semiconductor device and manufacturing method achieve miniaturization, prevent rise in threshold voltage and on-state voltage, and prevent decrease in breakdown resistance. N.sup.+-type emitter region and p.sup.++-type contact region are repeatedly alternately disposed in a first direction in which a trench extends in stripe form in a mesa portion sandwiched between trench gates. P.sup.+-type region covers an end portion on lower side of junction interface between n.sup.+-type emitter region and p.sup.++-type contact region. Formation of trench gate structure is such that n.sup.+-type emitter region is selectively formed at predetermined intervals in the first direction in the mesa portion by first ion implantation. P.sup.+-type region is formed less deeply than n.sup.+-type emitter region in the entire mesa portion by second ion implantation. The p.sup.++-type contact region is selectively formed inside the p+-type region by third ion implantation. N.sup.+-type emitter region and p.sup.++-type contact region are diffused and brought into contact.

A method of manufacturing a semiconductor device includes: forming field electrode structures extending in a direction vertical to a first surface in a semiconductor body; forming cell mesas from portions of the semiconductor body between the field electrode structures, including body zones forming first pn junctions with a drift zone; forming gate structures between the field electrode structures and configured to control a current flow through the body zones; and forming auxiliary diode structures with a forward voltage lower than the first pn junctions and electrically connected in parallel with the first pn junctions, wherein semiconducting portions of the auxiliary diode structures are formed in the cell mesas.