A tunneling field effect transistor for light detection, including a p-type region connected to a source terminal, a n-type region connected to a drain terminal, an intrinsic region located between the p-type region and the n-type region to form a P-I junction or an N-I junction with the n-type region or the p-type region, respectively, a first insulating layer and a first gate electrode, the first gate electrode covering a portion of the intrinsic region on one side, and a second insulating layer and a second gate electrode, the second insulating layer and the second gate electrode covering an entire other side of the intrinsic region opposite to the one side, wherein an area of the intrinsic region that is not covered by the first gate electrode forms a non-gated intrinsic area configured for light absorption.

A semiconductor device includes a substrate, two gate structures, an interlayer dielectric layer and a material layer. The substrate has at least two device regions separated by at least one isolation structure disposed in the substrate. Each device region includes two doped regions disposed in the substrate. The gate structures are respectively disposed on the device regions. In each device region, the doped regions are respectively disposed at two opposite sides of the gate structure. The interlayer dielectric layer is disposed over the substrate and peripherally surrounds the gate structures. A top of the interlayer dielectric layer has at least one concave. The material layer fills the concave and has a top surface elevated at the same level with top surfaces of the gate structures. A ratio of a thickness of a thickest portion of the material layer to a pitch of the gate structures ranges from 1/30 to 1/80.

A semiconductor device includes a substrate, at least one active semiconductor fin, at least one first dummy semiconductor fin, and at least one second dummy semiconductor fin. The active semiconductor fin is disposed on the substrate. The first dummy semiconductor fin is disposed on the substrate. The second dummy semiconductor fin is disposed on the substrate and between the active semiconductor fin and the first dummy semiconductor fin. A top surface of the first dummy semiconductor fin and a top surface of the second dummy semiconductor fin are curved in different directions.

A dual channel trench LDMOS transistor includes a semiconductor layer of a first conductivity type formed on a substrate; a first trench formed in the semiconductor layer where a trench gate is formed in an upper portion of the first trench; a body region of the second conductivity type formed in the semiconductor layer adjacent the first trench; a source region of the first conductivity type formed in the body region and adjacent the first trench; a planar gate overlying the body region; a drain drift region of the first conductivity type formed in the semiconductor layer and in electrical contact with a drain electrode; and alternating N-type and P-type regions formed in the drain drift region with higher doping concentration than the drain-drift regions to form a super-junction structure in the drain drift region.

Some embodiments relate to a two transistor band gap reference circuit. A first transistor includes a first source, a first drain, a first body region separating the first source from the first drain, and a first gate. The first drain and first gate are coupled to a DC supply terminal. The second transistor includes a second source, a second drain, a second body region separating the second source from the second drain, and a second gate. The second gate is coupled to the DC supply terminal, and the second drain is coupled to the first source. Body bias circuitry is configured to apply a body bias voltage to at least one of the first and second body regions. Other embodiments relate to FinFET devices.

A method comprises forming one or more fins in a first region on an insulated substrate. The method also comprises forming one or more fins formed in a second region on the insulated substrate. The insulated substrate comprising a silicon substrate, and an insulator layer deposited on the silicon substrate. The one or more fins in the first region comprising a first material layer deposited on the insulator layer. The one or more fins in the second region comprising a second material layer deposited on the insulator layer.

A semiconductor device includes: a semiconductor chip having a main surface; an output region formed over the main surface with output elements being arranged in the output region; an inner element region surrounded by the output region and insulated and isolated from the output region with a first element different from the output elements being arranged in the inner element region; a first wiring layer formed over the main surface so as to cover the output region, and including a first output wiring electrically connected to the output elements; and a second wiring layer formed over the first wiring layer, and including second output wirings electrically connected to the first output wiring and a connection wiring insulated and isolated from the second output wirings, the connection wiring extending across the output region from the inner element region to an outer region outside the output region.

The present disclosure provides a bio-field effect transistor (BioFET) and a method of fabricating a BioFET device. The method includes forming a BioFET using one or more process steps compatible with or typical to a complementary metal-oxide-semiconductor (CMOS) process. The BioFET device may include a substrate; a gate structure disposed on a first surface of the substrate and an interface layer formed on the second surface of the substrate. The interface layer may allow for a receptor to be placed on the interface layer to detect the presence of a biomolecule or bio-entity. An amplification factor of the BioFET device may be provided by a difference in capacitances associated with the gate structure on the first surface and with the interface layer formed on the second surface.

Nanowire metal-oxide semiconductor (MOS) Field-Effect Transistors (FETs) (MOSFETs) employing a nanowire channel structure employing recessed conductive structures for conductively coupling nanowire structures are disclosed. Conductive structures are disposed between adjacent nanowire structures to conductively couple nanowire structures. Providing conductive structures in the nanowire channel structure increases the average cross-sectional area of nanowire structures, as compared to a similar nanowire channel structure not employing conductive structures, thus increasing effective channel width and drive strength for a given channel structure height. The precision of a gate material filling process is also eased, because gate material does not have to be disposed in areas between adjacent nanowire structures occupied by conductive structures. The conductive structure width can also be recessed with regard to width of nanowire structures in the nanowire channel structure to allow for a thicker metal gate to lower the gate resistance, while providing excellent electrostatic gate control of the channel.

A double gate trench power transistor and manufacturing method thereof are provided. The double gate trench power transistor gate structure includes an epitaxial layer, a trench structure formed in the epitaxial layer, at least two gate structures, and a shielding electrode structure. The trench structure includes a deep trench portion and two shallow trench portions respectively adjacent to two opposite sides of the deep trench portion. Each of the gate structures formed in each of the shallow trench portions includes a gate insulating layer and a gate electrode. The gate insulating layer has a first dielectric layer, a second dielectric layer and a third dielectric layer. The second dielectric layer is interposed between the first and third dielectric layers. Additionally, a portion of the gate insulating layer is in contact with a shielding dielectric layer of the shielding electrode structure.