Abstract: A semiconductor device with an insulated-gate field-effect transistor and its manufacturing method. The cell region EFR defined in the first region of one main surface side of semiconductor substrate (SUB), an insulated gate-type field-effect transistor (MFET) is formed, the gate pad region GPR defined in the first region, snubber circuit SNC is formed snubber region SNR is defined. Within the first and second regions, first and second deep trenches spaced apart from each other are formed, and at least one width of the plurality of second deep trenches formed in the second region is smaller than that of the first deep trench formed in the first region.

Abstract: A semiconductor device with an insulated-gate field-effect transistor and its manufacturing method. The cell region EFR defined in the first region of one main surface side of semiconductor substrate (SUB), an insulated gate-type field-effect transistor (MFET) is formed, the gate pad region GPR defined in the first region, snubber circuit SNC is formed snubber region SNR is defined. Within the first and second regions, first and second deep trenches spaced apart from each other are formed, and at least one width of the plurality of second deep trenches formed in the second region is smaller than that of the first deep trench formed in the first region.

Abstract: According to one embodiment, a semiconductor device includes a first electrode, a semiconductor layer, a first conductive part, a second conductive part, and a second electrode. The semiconductor layer includes a first semiconductor region, a second semiconductor region, and a third semiconductor region. The first semiconductor region is electrically connected to the first electrode. The second semiconductor region is provided on the first semiconductor region. The third semiconductor region is provided on the second semiconductor region. The first conductive part includes a buried electrode provided in the first semiconductor region with a first insulator interposed. The second conductive part includes a gate electrode provided on the buried electrode with a second insulator interposed. The first conductive part is electrically connected to the second conductive part. An electrical resistance of the first conductive part is greater than an electrical resistance of the second conductive part.

Abstract: A semiconductor device includes a semiconductor layer, first and second electrodes, one or more gate electrodes, and an array of structures. The semiconductor layer has first and second sides opposite to each other in a first direction. The semiconductor layer is single crystal silicon. The array of structures is in the semiconductor layer and arranged in a second direction perpendicular to the first direction and along a [100] direction of the single crystal silicon and in a third direction that is perpendicular to the first direction and not perpendicular to the second direction. A first distance between first and second ones of the structures adjacent to each other in the third direction is less than a second distance between the first one and a third one of the structures adjacent to the first one in the second direction.

Abstract: According to one embodiment, a semiconductor device includes a first electrode, a first semiconductor region, a second semiconductor region, a third semiconductor region, a metal-including portion being conductive, an insulating portion, a gate electrode, a second electrode, a first interconnect layer, and a second interconnect layer. The first semiconductor region is provided on the first electrode. The second semiconductor region is provided on the first semiconductor region. The third semiconductor region and the metal-including portion are provided on portions of the second semiconductor region. The insulating portion is arranged in a second direction with the third semiconductor region, the second semiconductor region, and a portion of the first semiconductor region. The gate electrode and the second electrode are provided inside the insulating portion. The first interconnect layer is electrically connected to the gate electrode.

Abstract: A semiconductor device with an insulated-gate field-effect transistor and its manufacturing method. The cell region EFR defined in the first region of one main surface side of semiconductor substrate (SUB), an insulated gate-type field-effect transistor (MFET) is formed, the gate pad region GPR defined in the first region, snubber circuit SNC is formed snubber region SNR is defined. Within the first and second regions, first and second deep trenches spaced apart from each other are formed, and at least one width of the plurality of second deep trenches formed in the second region is smaller than that of the first deep trench formed in the first region.

Abstract: In a deep trench DTC reaching a predetermined depth from a first main surface of a semiconductor substrate SUB, a plurality of columnar conductors CCB including plugs PUG and field plates FP are formed. A p type impurity layer PIL is formed along the side wall surface of the deep trench DTC. Between the bottom of the plug PUG and the bottom of the p type impurity layer PIL, the field plate FP and the p type impurity layer PIL are positioned to face each other via an insulating film FIF interposed therebetween. Between the bottom of the p type impurity layer PIL and the bottom of the field plate FP, the field plate FP and an n-type drift layer NDL of the semiconductor substrate SUB are positioned to face each other via the insulating film FIF interposed therebetween.

Abstract: Provided are a semiconductor device including a desired snubber part in accordance with use of the semiconductor device and a method of manufacturing the semiconductor device. A snubber region having a snubber part is defined in a gate pad region defined on a side close to a first main surface of a semiconductor substrate. A p-type diffusion layer and an n-type column layer contacted to each other are formed in the snubber region. The p-type diffusion layer and the n-type column layer are formed as a parasitic capacitance of the snubber part while the n-type column layer is electrically coupled to a drain. The p-type diffusion layer, which extends in a Y-axis direction, is a resistance of the snubber part and electrically coupled to a source.

Abstract: Provided are a semiconductor device and a manufacturing method therefor that can prevent the breakage of an element and in which the control of impurity amounts is less susceptible to variations in manufacturing processes. A semiconductor substrate has a front surface and includes hole portions extending from the front surface to an inside of the substrate. N-type regions are formed in the semiconductor substrate. At wall surfaces of the hole portions, p-type regions are formed to configure p-n junction with the n-type regions. Each of the p-type regions includes a low-concentration region and a high-concentration region formed at the wall surface of each hole portion. A width of the high-concentration region along the wall surface of the hole portion becomes smaller from the front surface toward a deeper position.

Abstract: A semiconductor substrate is easily warped by the shrink of the insulating film formed within the deep trench according to the thermal processing in the super junction structure. In order to solve the above problem, in a semiconductor device, an element region and a terminal region are defined on one main surface of the semiconductor substrate. The terminal region is arranged to surround the element region. In the terminal region, a plurality of buried insulators are formed from the main surface of the semiconductor substrate in a way of penetrating an n-type diffusion layer and an n-type column layer and arriving at an n-type epitaxial layer. The buried insulator is formed within a deep trench. The plural buried insulators are arranged in island shapes mutually at a distance from each other.

Abstract: A semiconductor substrate is easily warped by the shrink of the insulating film formed within the deep trench according to the thermal processing in the super junction structure. In order to solve the above problem, in a semiconductor device, an element region and a terminal region are defined on one main surface of the semiconductor substrate. The terminal region is arranged to surround the element region. In the terminal region, a plurality of buried insulators are formed from the main surface of the semiconductor substrate in a way of penetrating an n-type diffusion layer and an n-type column layer and arriving at an n-type epitaxial layer. The buried insulator is formed within a deep trench. The plural buried insulators are arranged in island shapes mutually at a distance from each other.

Abstract: A deep trench which reaches a predetermined depth from one principal surface is formed in an element region of a semiconductor substrate. A TEOS oxide film and a polycrystalline silicon film are formed so as to fill the deep trench. In formation of a MOSFET and in formation of a protective insulating film on/over a surface of an element region by thermal oxidation, a silicon thermal oxide film grows, the TEOS oxide film contracts and the polycrystalline silicon film expands when oxidized and turning into a silicon oxide film, and thereby an embedded insulator is formed in the deep trench.

Abstract: There is provided a semiconductor device and its manufacturing method capable of avoiding generation of a through-current flowing between the drain and source and suppressing the potential fluctuation with time in the field plate electrode. A drain region is arranged on a first surface of a semiconductor substrate, a source region is arranged on a second surface thereof, and a drift region is arranged between the drain region and the source region. The semiconductor substrate has a trench extending from the second surface into the drift region. The field plate electrode is arranged within the trench to be electrically insulated from the drain region and insulated from the drift region oppositely. The Zener diode is electrically coupled between the source region and the field plate electrode. The Zener diode is coupled in a forward direction from the source region to the field plate electrode.

Abstract: Provided are a semiconductor device including a desired snubber part in accordance with use of the semiconductor device and a method of manufacturing the semiconductor device. A snubber region having a snubber part is defined in a gate pad region defined on a side close to a first main surface of a semiconductor substrate. A p-type diffusion layer and an n-type column layer contacted to each other are formed in the snubber region. The p-type diffusion layer and the n-type column layer are formed as a parasitic capacitance of the snubber part while the n-type column layer is electrically coupled to a drain. The p-type diffusion layer, which extends in a Y-axis direction, is a resistance of the snubber part and electrically coupled to a source.

Abstract: A semiconductor substrate is easily warped by the shrink of the insulating film formed within the deep trench according to the thermal processing in the super junction structure. In order to solve the above problem, in a semiconductor device, an element region and a terminal region are defined on one main surface of the semiconductor substrate. The terminal region is arranged to surround the element region. In the terminal region, a plurality of buried insulators are formed from the main surface of the semiconductor substrate in a way of penetrating an n-type diffusion layer and an n-type column layer and arriving at an n-type epitaxial layer. The buried insulator is formed within a deep trench. The plural buried insulators are arranged in island shapes mutually at a distance from each other.

Abstract: To provide a semiconductor device equipped with a snubber portion having an improved withstand voltage and capable of reducing a surge voltage at turn-off of an insulated gate field effect transistor portion. The concentration of a first conductivity type impurity in a snubber semiconductor region is greater than that in a drift layer. The thickness of a snubber insulating film between the snubber semiconductor region and a snubber electrode is greater than that of a gate insulating film between a gate electrode and a body region.

Abstract: A deep trench which reaches a predetermined depth from one principal surface is formed in an element region of a semiconductor substrate. A TEOS oxide film and a polycrystalline silicon film are formed so as to fill the deep trench. In formation of a MOSFET and in formation of a protective insulating film on/over a surface of an element region by thermal oxidation, a silicon thermal oxide film grows, the TEOS oxide film contracts and the polycrystalline silicon film expands when oxidized and turning into a silicon oxide film, and thereby an embedded insulator is formed in the deep trench.

Abstract: Provided are a semiconductor device and a manufacturing method therefor that can prevent the breakage of an element and in which the control of impurity amounts is less susceptible to variations in manufacturing processes. A semiconductor substrate has a front surface and includes hole portions extending from the front surface to an inside of the substrate. N-type regions are formed in the semiconductor substrate. At wall surfaces of the hole portions, p-type regions are formed to configure p-n junction with the n-type regions. Each of the p-type regions includes a low-concentration region and a high-concentration region formed at the wall surface of each hole portion. A width of the high-concentration region along the wall surface of the hole portion becomes smaller from the front surface toward a deeper position.

Abstract: An improvement is achieved in the performance of a semiconductor device. Over the main surface of a semiconductor substrate for the n-type base of an IGBT, an insulating layer is formed. In a trench of the insulating layer, an n-type semiconductor layer is formed over the semiconductor substrate and, on both sides of the semiconductor layer, gate electrodes are formed via gate insulating films. In an upper portion of the semiconductor layer, a p-type semiconductor region for a p-type base and an n+-type semiconductor region for an n-type emitter are formed. Under the gate electrodes, parts of the insulating layer are present. The side surfaces of the gate electrodes opposite to the side surfaces thereof facing the semiconductor layer via the gate insulating films are adjacent to the insulating layer.

Abstract: To provide a semiconductor device equipped with a snubber portion having an improved withstand voltage and capable of reducing a surge voltage at turn-off of an insulated gate field effect transistor portion. The concentration of a first conductivity type impurity in a snubber semiconductor region is greater than that in a drift layer. The thickness of a snubber insulating film between the snubber semiconductor region and a snubber electrode is greater than that of a gate insulating film between a gate electrode and a body region.