An integrated circuit having a vertical transistor includes first through fourth gate lines extending in a first direction and sequentially arranged in parallel with each other, a first top active region over the first through third gate lines and insulated from the second gate line, and a second top active region. The first top active region forms first and third transistors with the first and third gate lines respectively. The second top active region is over the second through fourth gate lines and insulated from the third gate line. The second top active region forms second and fourth transistors with the second and fourth gate lines respectively.

A semiconductor structure with current flow path direction controlling is provided, which comprises a substrate and an epitaxial layer having a first conductivity type on the substrate. A first doped region is on the substrate and the first doped region has the first or a second conductivity type. A second doped region is enclosed by the epitaxial layer and has the second conductivity type. A third doped region is located in the epitaxial layer and between the first and second doping regions, and the third doped region has the second conductivity type. A fourth doped region is enclosed by the third doped region and has the first conductivity type. A fifth doped region is enclosed by the first doped region and the conductivity type is opposite to that of the first doped region.

Techniques related to a boosted vertical field effect transistor and method of fabricating the same are provided. A logic device can comprise a vertical field effect transistor comprising a substrate, a first epitaxial layer and a second epitaxial layer. A bottom source/drain contact can be between a top surface and the first epitaxial layer and a top source/drain contact can be between the top surface and the second epitaxial layer at respective first portions of one or more vertical fins. The logic device can also comprise a boosted bipolar junction transistor. A bipolar junction transistor contact can be between the top surface and the second epitaxial layer at respective second portions of the one or more vertical fins. The respective first portions and the respective second portions can be opposite portions of the one or more vertical fins.

Two dual-gate transistors, which are electrically connected in parallel and provided in a compact design, are disclosed.

An integrated circuit is fabricated on a semiconductor substrate. An insulated gate bipolar transistor (IGBT) is formed upon the semiconductor substrate in which the IGBT has an anode terminal, a cathode terminal, and a gate terminal, and a drift region. A diode is also formed on the semiconductor substrate and has an anode terminal and a cathode terminal, in which the anode of the diode is coupled to the anode terminal of the IGBT and the cathode of the diode is coupled to the drift region of the IGBT.

The present disclosure provides a FINFET device integrated with a TFET and its manufacturing method. Two end portions of the fin structure respectively form an N-type doped drain and a source which is consisted by a top P-type doped region and a bottom N-type doped region. As a result, the bottom N-type doped region of the source, the drain, the channel, the high-k dielectric layer and the gate structure on the surface of the sidewall of the fin structure form a MOS FINFET device, and the top P-type doped region of the source, the drain, the channel, the high-k dielectric layer and the gate structure on the top surface of the fin structure form the TFET device. The integration of the TFET and the FINFET is achieved, which decreases the cost.

A ferroelectric field effect transistor includes a semiconductor substrate, with first and second source/drain regions being formed within the semiconductor substrate and being separated by a channel region. An interface layer is disposed on the channel region. A gate insulator layer is disposed on the interface layer. A ferroelectric layer is disposed on the gate insulator layer.

A semiconductor device is provided. The semiconductor device includes a substrate, a gate strip, a source doped region and a body doped region. The substrate has an active region. The gate strip is disposed on the substrate within the active region. The gate strip extends along a first direction. The source doped region is located in the active region and adjacent to a first side of the gate strip along the first direction. The body doped region is located in the active region and adjacent to the first side of the gate strip. The body doped region and the source doped region have opposite conductivity types. The body doped region has a first length along a second direction that is different from the first direction, wherein the first length gradually changes along the first direction.

Different portions of a continuous loop of semiconductor material are electrically isolated from one another. In some embodiments, the end of the loop is electrically isolated from mid-portions of the loop. In some embodiments, loops of semiconductor material, having two legs connected together at their ends, are formed by a pitch multiplication process in which loops of spacers are formed on sidewalls of mandrels. The mandrels are removed and a block of masking material is overlaid on at least one end of the spacer loops. In some embodiments, the blocks of masking material overlay each end of the spacer loops. The pattern defined by the spacers and the blocks are transferred to a layer of semiconductor material. The blocks electrically connect together all the loops. A select gate is formed along each leg of the loops. The blocks serve as sources/drains. The select gates are biased in the off state to prevent current flow from the mid-portion of the loop's legs to the blocks, thereby electrically isolating the mid-portions from the ends of the loops and also electrically isolating different legs of a loop from each other.

A semiconductor device includes a floating buried doped region, a first doped region disposed between the floating buried doped region and a first major surface, and a semiconductor region disposed between the floating buried doped region and a second major surface. A trench isolation structure extends from the first major surface and terminates within the semiconductor region and the floating buried doped region abuts the trench isolation structure. A second doped region is disposed in the first doped region has an opposite conductivity type to the first doped region. A first isolation device is disposed in the first doped region and is configured to divert current injected into the semiconductor device from other regions thereby delaying the triggering of an internal SCR structure. In one embodiment, a second isolation structure is disposed within the first doped region and is configured to disrupt a leakage path along a sidewall surface of the trench isolation structure.