Static induction transistor

About: Static induction transistor is a research topic. Over the lifetime, 8155 publications have been published within this topic receiving 107058 citations. The topic is also known as: SIT.

MoS2 Tribotronic Transistor for Smart Tactile Switch

Abstract: A novel tribotronic transistor has been developed by vertically coupling a single-electrode mode triboelectric nanogenerator and a MoS2 field effect transistor. Once an external material contacts with or separates from the device, negative charges are induced by triboelectrification on the surface of the polymer frictional layer, which act as a “gate” voltage to modulate the carrier transport in the MoS2 channel instead of the conventional applied gate voltage; the drain-source current can be tuned in the range of 1.56–15.74 μA, for nearly ten times. The application of this MoS2 tribotronic transistor for the active smart tactile switch is also demonstrated, in which the on/off ratio can reach as high as ≈16 when a finger touches the device and the increased drain-source current is sufficient to light two light-emitting diodes. This work may provide a technique route to utilize the 2D materials based tribotronic transistors in MEMS, nanorobotics, and human–machine interfacing.

Element substrate and light-emitting device

Abstract: A light emitting device and an element substrate which are capable of suppressing variations in the luminance intensity of a light emitting element among pixels due to characteristic variations of a driving transistor without suppressing off-current of a switching transistor low and increasing storage capacity of a capacitor. According to the invention, a depletion mode transistor is used as a driving transistor. The gate of the driving transistor is fixed in its potential or connected to the source or drain thereof to operate in a saturation region with a constant current flow. A current controlling transistor which operates in a linear region is connected in series to the driving transistor, and a video signal for transmitting a light emission or non-emission of a pixel is inputted to the gate of the current controlling transistor through a switching transistor.

SOI FET design to reduce transient bipolar current

Abstract: Producing a gap between a source and/or drain region of a silicon-on-insulator (SOI) field effect transistor which is less than the thickness of a depletion region normally surrounding the source and/or drain region, preferably at zero volts bias, permits gain of a parasitic bipolar transistor formed therewith to be transiently reduced and the effective base-emitter junction capacitance to be transiently increased during only modes of operation in which the parasitic bipolar conduction dominates normal operation of the field effect transistor. Such transient reduction of gain coupled with a transient reduction of high frequency response reduces the parasitic bipolar current spike to a degree greater than previously achievable and is fully compatible with other techniques of reducing such current spike. As applied to an SOICMOS SRAM, the transistor structure including such a gap is effective in suppressing half-select write disturb effects while maintaining the benefits of excess charge storage and floating body effects in the transistor.

Radio-frequency single-electron transistor: Toward the shot-noise limit

Abstract: We have fabricated an aluminum single-electron transistor and characterized it at frequencies up to 10 MHz by measuring the reflected signal from a resonant tank in which the transistor is embedded. We measured the charge sensitivity of this radio-frequency single-electron transistor to be 3.2×10−6 e/Hz, which corresponds to the uncoupled energy sensitivity of 4.8 ℏ. Our measurements indicate that with further improvements, the radio-frequency single-electron transistor could reach the shot-noise limit estimated to be about 1 ℏ.

Electronic circuit, method of driving the same, electronic device, electro-optical device, electronic apparatus, and method of driving the electronic device

Abstract: A gate of a driving transistor is set to a offset level corresponding to the threshold of the driving transistor by an initializing current flowing between a source and a drain of the driving transistor or a compensating transistor for the driving transistor. A conduction state of the driving transistor is set according to a gate voltage of the gate of the driving transistor that corresponds to a data signal and the threshold of the driving transistor. A current of which a level corresponds to the conduction state and of which the direction is opposite to the direction of the initializing current flows through driving transistor.