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.

Method of fabricating an high-performance insulated-gate field-effect transistor

Abstract: An improved device fabrication method and transistor structure 36 provide shallow, heavily doped, source/drain junction regions 64 and a uniformly doped lower gate region 50 having a high concentration of dopants efficiently distributed near the gate electrode/gate interface 51. The gate, source, and drain terminals of transistor 36 may be interconnected to other neighboring or remote devices through the use of reacted refractory metal interconnect segments 98 and 100. Transistor structure 36 of the present invention may be constructed in an elevated source/drain format to include elevated source/drain junction regions 87 which may be fabricated simultaneous with a primary upper gate electrode region 88. This elevated source/drain junction feature is provided without added device processing complexity.

Pass gate circuit with body bias control

Abstract: A pass gate circuit includes a pass transistor and a body bias control circuit for biasing the body of the pass transistor to reduce body effect. The body bias control circuit includes one or more control transistors arranged to selectively connect the substrate (body) of the pass transistor to the drain or gate of the pass transistor when predetermined voltages are applied to the drain and gate of the pass transistor. As a result, the pass transistor exhibits a reduced body effect in the on-state. In one embodiment, the body bias control circuit includes a first control transistor having a drain and gate connected to the gate of the pass transistor, a gate connected to the drain of the pass transistor, and a source. The body bias control circuit also includes a second control transistor having a drain connected to the source of the first control transistor, a source connected to a body of the pass transistor, and a gate connected to the drain of the pass transistor. The bodies of the pass transistor, first control transistor and second control transistor are electrically interconnected. With this arrangement, the body of the pass transistor is biased "high" by the gate of the pass transistor only when both the gate and drain of the pass transistor are at a high voltage level.

Influence of impact-ionization-induced instabilities on the maximum usable output voltage of Si-bipolar transistors

Abstract: The onset of impact-ionization-induced instabilities limits the operating range of Si-bipolar transistors, especially in power stages. Therefore, analytical relations which characterize the onset of instabilities are derived for different driving conditions (mainly V/sub BE/=const. and I/sub E/=const.) and arbitrary transistor geometries. They allow the designer and technologist to calculate the maximum usable dc output voltage in dependence on transistor dimensions and technological parameters. As a consequence, the voltage range above BV/sub CE0/ can now be more intensively and reliably used and thus the performance potential of a given technology can be better exploited. However, the reduction of the maximum tolerable output voltage with increasing emitter (or collector) current must be carefully considered. The presented theory and analytical results are verified by three-dimensional (3-D) transistor simulations and by measurements.

Static Random Access Memory (SRAM) Cell and Method for Forming Same

Abstract: An embodiment is a method for forming a static random access memory (SRAM) cell. The method comprises forming transistors on a semiconductor substrate and forming a first linear intra-cell connection and a second linear intra-cell connection. Longitudinal axes of the active areas of the transistors are parallel. A first pull-down transistor and a first pull-up transistor share a first common gate structure, and a second pull-down transistor and a second pull-up transistor share a second common gate structure. The first linear intra-cell connection electrically couples active areas of the first pull-down transistor and the first pull-up transistor to the second common gate structure. The second linear intra-cell connection electrically couples active areas of the second pull-down transistor and the second pull-up transistor to the first common gate structure.

Semiconductor memory device and method of formation

Abstract: A semiconductor memory device is formed having a substrate (12). A diffusion (14) is formed within the substrate (12). A first vertical transistor stack (122) is formed. A second vertical transistor stack (124) is formed. The first vertical transistor stack (122) has a transistor (100) underlying a transistor (104). The second vertical transistor stack (124) has a transistor (102) underlying a transistor (106). The transistors (100 and 104) are connected in series, and the transistors (102 and 106) are connected in series. In a preferred form, transistors (100 and 102) are electrically connected as latch transistors for a semiconductor memory device and transistors (106 and 104) are connected as pass transistors. Two vertical stacks (126 and 128) form electrical interconnections (118 and 120) and resistive devices (134 and 138) for the semiconductor memory device.