According to one embodiment, a semiconductor device is provided. The semiconductor device has a first region formed of semiconductor and a second region formed of semiconductor which borders the first region. An electrode is formed to be in ohmic-connection with the first region. A third region is formed to sandwich the first region. A first potential difference is produced between the first and the second regions in a thermal equilibrium state, according to a second potential difference between the third region and the first region.

A Schottky diode is formed on a silicon support. A non-doped GaN layer overlies the silicon support. An AlGaN layer overlies the non-doped GaN layer. A first metallization forming an ohmic contact and a second metallization forming a Schottky contact are provided in and on the AlGaN layer. First vias extend from the first metallization towards the silicon support. Second vias extend from the second metallization towards an upper surface.

Semiconductor devices including at least one diode over a conductive strap. The semiconductor device may include at least one conductive strap over an insulator material, at least one diode comprising a single crystalline silicon material over a conductive material, and a memory cell on the at least one diode. The at least one diode may be formed from a single crystalline silicon material. Methods of forming such semiconductor devices are also disclosed.

A vertical tunneling FET (TFET) provides low-power, high-speed switching performance for transistors having critical dimensions below 7 nm. The vertical TFET uses a gate-all-around (GAA) device architecture having a cylindrical structure that extends above the surface of a doped well formed in a silicon substrate. The cylindrical structure includes a lower drain region, a channel, and an upper source region, which are grown epitaxially from the doped well. The channel is made of intrinsic silicon, while the source and drain regions are doped in-situ. An annular gate surrounds the channel, capacitively controlling current flow through the channel from all sides. The source is electrically accessible via a front side contact, while the drain is accessed via a backside contact that provides low contact resistance and also serves as a heat sink. Reliability of vertical TFET integrated circuits is enhanced by coupling the vertical TFETs to electrostatic discharge (ESD) diodes.

A semiconductor device includes first and second semiconductor regions, and a third semiconductor region between the first and second semiconductor regions, wherein the dopant concentration of the third semiconductor region is greater than the dopant concentration of the second semiconductor region. The semiconductor device further includes a fourth semiconductor region selectively provided on an upper surface of the second semiconductor region, wherein a portion of the second semiconductor region is interposed between the third semiconductor region and the fourth semiconductor region, an insulating layer disposed on the second semiconductor region and the fourth semiconductor region and having an opening that exposes a portion of a top surface of the fourth semiconductor region, wherein the ratio of an area of opening to an area of the top surface is from 10% to 90%, and a wiring layer on the insulating layer and connected to the fourth semiconductor region via the opening.

An ESD protection device includes a Si substrate and a rewiring layer. The rewiring layer includes Ti/Cu/Ti electrodes are electrically connected through contact holes to an ESD protection circuit with Al electrodes films, which is formed at the surface of the Si substrate. The Al electrode film is electrically connected to the Ti/Cu/Ti electrode, whereas the Al electrode film is electrically connected to the Ti/Cu/Ti electrode. A diode forming region is formed between Al electrode films, whereas a diode forming region is formed between Al electrode films. The Ti/Cu/Ti electrode has no overlap with the diode forming region, whereas the Ti/Cu/Ti electrode has no overlap with the diode forming region. Thus, a semiconductor device is provided which is able to reduce the generation of parasitic capacitance, and able to be applied up to a higher frequency band.

A semiconductor device includes a first conductivity type semiconductor substrate, a second conductivity type first and second buried diffusion layers that are arranged in the semiconductor substrate, a semiconductor layer arranged on the semiconductor substrate, a second conductivity type first impurity diffusion region that is arranged in the semiconductor layer, a second conductivity type second impurity diffusion region that is arranged, in the semiconductor layer, on the second buried diffusion layer, a second conductivity type first well that is arranged in a first region of the semiconductor layer, a first conductivity type second well that is arranged, in the semiconductor layer, in a second region, a first conductivity type third and fourth impurity diffusion regions that are arranged in the first well, and a first conductivity type fifth impurity diffusion region that is arranged in the second well.

A semiconductor device is provided in which a zener diode having a desired breakdown voltage and a capacitor in which voltage dependence of capacitance is reduced are mounted together, and various circuits are realized. The semiconductor device includes: a semiconductor layer; a first conductivity type well that is arranged in a first region of the semiconductor layer; a first conductivity type first impurity diffusion region that is arranged in the well; a first conductivity type second impurity diffusion region that is arranged in a second region of the semiconductor layer; an insulating film that is arranged on the second impurity diffusion region; an electrode that is arranged on the insulating film; and a second conductivity type third impurity diffusion region that is arranged at least on the first impurity diffusion region.

In one aspect, a diode comprises: a semiconductor layer having a first side and a second side opposite the first side, the semiconductor layer having a thickness between the first side and the second side, the thickness of the semiconductor layer being based on a mean free path of a charge carrier emitted into the semiconductor layer; a first metal layer deposited on the first side of the semiconductor layer; and a second metal layer deposited on the second side of the semiconductor layer.

In one embodiment, a Light Emitting Diode (LED) driving device for driving a plurality of LEDs has a switching matrix utilizing a plurality of one of a turn off thyristors or turn off triacs coupled to the plurality of LEDs. A controller is coupled to the switching matrix responsive to a voltage of a rectified AC halfwave, wherein combinations of the plurality of LEDs are altered to ensure a maximum operating voltage of the plurality of LEDs is not exceeded. A current limiting device is coupled to the combinations of the plurality of LED to regulate current. In a second embodiment an offline charge pump utilizes a switching matrix to recombine capacitors in accordance with the voltage on the AC half wave and then in accordance with a desired output voltage to feed a load, such that said recombinations occur at a frequency much higher than the frequency of the AC rectified half wave such that charge is pumped from the input at one voltage to the output at another voltage through the AC halfwave while providing a constant output voltage to the load.