Abstract: The invention relates to a semiconductor device (10) with a substrate (11) and a semiconductor body (12) of silicon which comprises an active region (A) with a transistor (T) and a passive region (P) surrounding the active region (A) and which is provided with a buried conducting region (1) of a metallic material that is connected to a conductive region (2) of a metallic material sunken from the surface of the semiconductor body (12), by which the buried conductive region (1) is made electrically connectable at the surface of the semiconductor body (12). According to the invention, the buried conducting region (1) is made at the location of the active region (A) of the semiconductor body (12). In this way, a very low buried resistance can be locally created in the active region (A) in the semiconductor body (12), using a metallic material that has completely different crystallographic properties from the surrounding silicon. This is made possible by using a method according to the invention.

Abstract: This invention describes implementation of medium/high voltage semiconductor devices with a better voltage-blocking capability versus specific on-resistan?e trade off. This approach can be implemented in baseline and submicron CMOS without any additional process steps. Said devices comprise dielectric regions and semiconductor regions formed between them. Conductive extentions are formed on the dielectric regions, said extentions interacting capacitively with the semiconducter regions.

Abstract: A avalanche mode photodiode array (102) is fabricated using a silicon on insulator wafer and substrate transfer process. The array includes a plurality of photodiodes (100). The photodiodes (100) include an electrically insulative layer (206), a depletion region (204), and first (208) and second (210) doped regions. An interconnection layer (212) includes electrodes (214, 216) which provides electrical connections to the photodiodes. The photodiode array (102) is carried by a handle wafer (217).

Abstract: A semiconductor device is formed with a lower field plate (32) and optional lateral field plates (34) around semiconductor (20) in which devices are formed, for example power FETs or other transistor or diode types. The semiconductor device is manufactured by forming trenches with insulated sidewalls, etching cavities (26) at the base of the trenches which join up and then filling the trenches with conductor (30).

Abstract: An impact ionisation MOSFET is formed with the offset from the gate to one of the source/drain regions disposed vertically within the device structure rather than horizontally. The semiconductor device comprises a first source/drain region having a first doping level; a second source/drain region having a second doping level and of opposite dopant type to the first source/drain region, the first and second source/drain regions being laterally separated by an intermediate region having a doping level less than either of the first and second doping levels; a gate electrode electrically insulated from, and disposed over, the intermediate region, the first and second source/drain regions being laterally aligned with the gate electrode; where the entire portion of the first source/drain region that forms a boundary with the intermediate region is separated vertically from the top of the intermediate region.

Abstract: It is described an integrated circuit design and a method to fabricate the same for a high-efficiency, low-noise, position sensitive X-ray detection in particular for medical applications. The device (350) is based on deep recesses (354) filled with an X-ray sensitive scintillator material. A shallow first electrode (360) is formed on the surface of the substrate (352) sidewalls separating two neighboring recesses (354). This sidewall electrode (360) in combination with particular frontside wafer electrode (363) structure results in a full depletion of the entire device (350) and a removal of signal charge towards the low capacitance readout electrode (363). The described integrated circuit element (350) ensures high and not depth dependent light collection efficiency.

Abstract: A method of manufacturing a semiconductor device includes forming trenches (22), and then selectively etching a buried layer (14) to form a cavity. An insulator is then deposited on the sidewalls of the trenches (22), not covering the cavity, and the cavity is then used to form a conductive region (28) in the cavity. The trench (22) can then be filled with insulator (40), in which case the conductive region (28) may form a precisely located doped region, or with conductor to form a contact to the conductive region (28).

Abstract: A double gate transistor on a semiconductor substrate (2) includes a first diffusion region (S2), a second diffusion region (S3), and a double gate (FG, CG). The first and second diffusion regions (S2, S3) are arranged in the substrate spaced by a channel region (CR). The double gate includes a first gate electrode (FG) and a second gate electrode (CG). The first gate electrode is separated from the second gate electrode by an interpoly dielectric layer (IPD). The first gate electrode is arranged above the channel region and is separated from the channel region by a gate oxide layer (G). The second gate electrode is shaped as a central body. The interpoly dielectric layer is arranged as a conduit-shaped layer surrounding an external surface (A1) of the body of the second gate electrode. The interpoly dielectric layer is surrounded by the first gate electrode.

Abstract: A method of manufacturing a semiconductor device wherein a laminate structure comprising a sacrificial layer is sandwiched between two etch stop layers (8,11) and which separates a semiconductor membrane (9) from a bulk substrate (1) is used to provide an underetched structure. Access trenches (4) and support trenches (5) are formed in the layered structure through the thickness of the semiconductor layer (9) and through the upper etch stop layer (8). The support trenches extend deeper through the sacrificial layer (12) and the lower etch stop layer and are filled. The sacrificial layer is exposed and etched away selectively to the etch stop layers to form a cavity (30) and realise a semiconductor membrane which is attached to the bulk substrate via a vertical support structure comprising the filled support trenches.

Abstract: A FinFET and methods for its manufacture are provided. The method of the invention provides an elegant process for manufacturing FinFETs with separated gates. It is compatible with a wide range of dielectric materials and gate electrode materials, providing that the gate electrode material(s) can be deposited conformally. Provision of at least one upstanding structure (or “dummy fin”) (40) on each side of the fin (4) serves to locally increase the thickness of the gate electrode material layer (70). In particular, as the shortest distance between each upstanding structure (40) and the respective side of the fin (4) is arranged in accordance with the invention to be less than twice the thickness of the conformal layer, the thickness of the gate electrode material layer (70) all the way across this distance between each upstanding structure (40) and the fin (4) is increased relative to that over planar regions of the substrate (2).

Abstract: A semiconductor device is formed by forming a second trench 120 at the base of a first trench 18, depositing insulator 124 at the base of the second trench 120, and then etching cavities 26 laterally from the sidewalls of the second trench, but not the base which is protected by insulator 124. The invention may in particular be used to form semiconductor devices with cavities under the active components, or by filling the cavities to form silicon on insulator or silicon on conductor devices.

Abstract: A semiconductor device includes at least one active component (18) having a p-n junction (26) on the semiconductor substrate in an active region (19) of the semiconductor substrate (4). A shallow trench isolation pattern is used to form a plurality of longitudinally extending shallow trenches (12) containing insulator (14). These trenches define a plurality of longitudinal active stripes (10) between the shallow trenches (12). The shallow trench isolation depth (ds?) is greater than the junction depth (dsO of the longitudinal active stripes and the width (wsO of the active stripes (10) is less than the depletion length (ldepi) of the p-n junction.

Abstract: The invention relates to a method of manufacturing a semiconductor device (10) comprising a substrate (11) and a semiconductor body (12) in which at least one semiconductor element (1) is formed, wherein on the substrate (11) a semiconductor layer (2) is formed comprising a mixed crystal of silicon and germanium, further called the silicon-germanium layer (2) and having a lower surface close to the substrate (11) and an upper surface more remote from the substrate (11), and wherein the silicon-germanium layer (2) is subjected to an oxidizing treatment at a surface of the silicon-germanium layer (2) while the other surface of the silicon-germanium layer (2) is protected against the oxidizing treatment by a blocking layer (3).

Abstract: The invention relates to a method of manufacturing a bipolar transistor on a semiconductor substrate (11) which is provided with a first, a second and a third layer (1,2,3) of a first, second and third semiconductor material respectively, all of a first conductivity type. A first portion of the second layer (2) is transformed into a buried isolation region (15) comprising a first electrically insulating material. A first semiconductor region (6) of the first conductivity type, comprising, for example, a collector region, is formed from a second portion of the second layer (2) adjoining the buried isolation region (15) and a portion of the first layer (1) adjoining the second portion of the second layer (2). Then a base region (7) is formed on the buried isolation region (15) and on the first semiconductor region (6) by transforming the third layer (3) into a second conductivity type, which is opposite to the first conductivity type.

Abstract: A avalanche mode photodiode array (102) is fabricated using a silicon on insulator wafer and substrate transfer process. The array includes a plurality of photodiodes (100). The photodiodes (100) include an electrically insulative layer (206), a depletion region (204), and first (208) and second (210) doped regions. An interconnection layer (212) includes electrodes (214, 216) which provides electrical connections to the photodiodes. The photodiode array (102) is carried by a handle wafer (217).

Abstract: A method of making a semiconductor device includes forming shallow trench isolation structures (14) in a semiconductor device layer. The shallow trench isolation structures are U- or O-shaped enclosing field regions (28) formed of the semiconductor device layer which is doped and/or suicided to be conducting. The semiconductor device may include an extended drain region (50) or drift region and a drain region (42). An insulated gate (26) may be provided over the body region. A source region (34, 40) may be shaped to have a deep source region (40) and a shallow source region (34). A contact region (60) of the same conductivity type as the body may be provided adjacent to the deep source region (40). The body extends under the shallow source region (34) to contact the contact region (60).

Abstract: A method of manufacturing a lateral semiconductor device comprising a semiconductor body (2) having top and bottom major surfaces (2a, 2b), the body including a drain drift region (6a) of a first conductivity type. The method includes the steps of forming a vertical access trench (20) in the semiconductor body which extends from its top major surface (2a) and has a bottom and sidewalls; forming at least one horizontal trench (16) extending within the drain drift region (6a) which extends from a sidewall of the vertical trench (20) in the finished device; and forming a RESURF inducing structure (22) extending within the at least one horizontal trench. In this way, vertically separated lateral RESURF inducing structures are formed without encountering problems associated with known techniques for forming RESURF structures.

Abstract: A method of manufacturing a semiconductor device includes forming trench isolation structures, exposing some of the trench isolation structures 28 to leave others 30 masked, and then selectively etching a buried layer to form a cavity 32 under an active device region 34. The active device region 34 is supported by support regions in the exposed trenches 28. The buried layer may be a SiGe layer on a Si substrate.

Abstract: A semiconductor device is formed with a lower field plate (32) and optional lateral field plates (34) around semiconductor (20) in which devices are formed, for example power FETs or other transistor or diode types. The semiconductor device is manufactured by forming trenches with insulated sidewalls, etching cavities (26) at the base of the trenches which join up and then filling the trenches with conductor (30).