Junction field effect transistors (JFETs) and related manufacturing methods are disclosed herein. A disclosed four terminal JFET includes an integrated high voltage capacitor (HVC). The JFET includes a first terminal coupled to a drain region, a second terminal coupled to the source region, a third terminal coupled to the base region, and an integrated HVC terminal coupled to an integrated HVC electrode which forms an HVC with the drain region. The JFET also includes a channel formed by a channel region. A bias on the base region fully depletes the channel of majority carriers. The channel has an unbiased concentration of majority carriers. The integrated HVC electrode is positioned relative to the channel region such that applying the bias to the integrated HVC terminal depletes the channel by at most ten percent of the unbiased concentration of majority carriers.

A capacitive element of an integrated circuit includes first and second electrodes. The first electrode is formed by a first electrically conductive layer located above a semiconductor well doped with a first conductivity type. The second electrode is formed by a second electrically conductive layer located above the first electrically conductive layer of the semiconductor well. The second electrode is further formed by a doped surface region within the semiconductor well that is heavily doped with a second conductivity type opposite the first conductivity type, wherein the doped surface region is located under the first electrically conductive layer. An inter-electrode dielectric area electrically separates the first electrode and the second electrode.

The present disclosure relates to a switching device including a RC snubber network. The present disclosure further relates to a RC snubber network for a switching device. A switching device is provided that includes a trench transistor and an RC snubber network connected in between a first terminal and a second terminal of the trench transistor. The RC snubber network includes at least one current concentrating segment that is configured to locally force a major part of the snubber current passing through the trench capacitors to flow through a reduced number of trench capacitors to thereby increase the Ohmic losses associated with the snubber current.

The present invention provides an epitaxial structure of N-face group III nitride, its active device, and the method for fabricating the same. By using a fluorine-ion structure in device design, a 2DEG in the epitaxial structure of N-face group III nitride below the fluorine-ion structure will be depleted. Then the 2DEG is located at a junction between a i-GaN channel layer and a i-Al.sub.yGaN layer, and thus fabricating GaN enhancement-mode AlGaN/GaN high electron mobility transistors (HEMTs), hybrid Schottky barrier diodes (SBDs), or hybrid devices. After the fabrication step for polarity inversion, namely, generating stress in a passivation dielectric layer, the 2DEG will be raised from the junction between the i-GaN channel layer and the i-Al.sub.yGaN layer to the junction between the i-GaN channel layer and the i-Al.sub.xGaN layer.

Examples of an integrated circuit with a capacitor structure and a method for forming the integrated circuit are provided herein. In some examples, an integrated circuit device includes a substrate and a trench isolation material disposed on the substrate. An isolation structure is disposed on the trench isolation material. A first electrode disposed on the isolation structure, and a second electrode disposed on the isolation structure. A capacitor dielectric is disposed on the isolation structure between the first electrode and the second electrode. In some such examples, the isolation structure includes a first hard mask disposed on the trench isolation material, a dielectric disposed on the first hard mask, and a second hard mask disposed on the dielectric.

Provided is a negative capacitance FinFET device including a FinFET device including a gate stack, a drain electrode and a source electrode formed on a substrate and a ferroelectric negative capacitor connected to the gate stack of the FinFET device and having a negative capacitance. The FinFET device has an extension length (L.sub.ext) from a side-wall of the gate stack to the drain electrode or the source electrode and the extension length is set such that a size of a hysteresis window in the negative capacitance FinFET device is 1 V or less.

A stacked capacitor structure includes a MOS varactor and a stacked capacitor. The stacked capacitor is electrically connected to the MOS varactor. The MOS varactor includes a substrate, a gate, a first source/drain and a second source/drain. The substrate has a well, and the gate is positioned over the well. The first source/drain and the second source/drain are formed in the well and positioned at opposing sides of the gate. The stacked capacitor includes a plurality of metal layers. The metal layers are spaced from each other, stacked above the gate, and positioned below an inductive element.

The present invention provides an epitaxial structure of Ga-face group III nitride, its active device, and the method for fabricating the same. The epitaxial structure of Ga-face AlGaN/GaN comprises a substrate, an i-GaN (C-doped) layer on the substrate, an i-Al(y)GaN buffer layer on the i-GaN (C-doped) layer, an i-GaN channel layer on the i-Al(y)GaN buffer layer, and an i-Al(x)GaN layer on the i-GaN channel layer, where x=0.1˜0.3 and y=0.05˜0.75. By using the p-GaN inverted trapezoidal gate or anode structure in device design, the 2DEG in the epitaxial structure of Ga-face group III nitride below the p-GaN inverted trapezoidal structure will be depleted, and thus fabricating p-GaN gate enhancement-mode (E-mode) AlGaN/GaN high electron mobility transistors (HEMTs), p-GaN anode AlGaN/GaN Schottky barrier diodes (SBDs), or hybrid devices.

A low noise device includes an isolation feature in a substrate. The low noise device further includes a gate stack over a channel in the substrate. The gate stack includes a gate dielectric layer extending over a portion of the isolation feature, and a gate electrode over the gate dielectric layer. The low noise device further includes a charge trapping reducing structure adjacent to the isolation feature. The charge trapping reducing structure is configured to reduce a number of charge carriers adjacent an interface between the isolation feature and the channel.

Provided is a negative capacitance FinFET device including a FinFET device including a gate stack, a drain electrode and a source electrode formed on a substrate and a ferroelectric negative capacitor connected to the gate stack of the FinFET device and having a negative capacitance. The FinFET device has an extension length (L.sub.ext) from a side-wall of the gate stack to the drain electrode or the source electrode and the extension length is set such that a size of a hysteresis window in the negative capacitance FinFET device is 1 V or less.