Drain-induced barrier lowering

About: Drain-induced barrier lowering is a research topic. Over the lifetime, 6163 publications have been published within this topic receiving 101547 citations.

Method of fabricating a vertical FET device with low gate to drain overlap capacitance

Abstract: This is a vertical MOSFET device with low gate to drain overlap capacitance. It can comprise a semiconductor substrate 22 of the first conductivity type, a source region 24,26 of a second conductivity type formed in the upper surface of the substrate 22; a vertical pillar with a channel region 28 of the first conductivity type, a lightly doped drain region 30 of the second conductivity type and a highly doped drain contact region 32 of the second conductivity type; a gate insulator 34, and a gate electrode 36 surrounding the vertical pillar not substantially extending into the highly doped drain contact region 30. This is also a method of forming a vertical MOSFET device on a single crystal semiconductor substrate, the device having a pillar on the substrate, with the pillar having a channel region in a lower portion and with the channel region having a top and a highly doped first source/drain region in an upper portion of the pillar, with the substrate having a highly doped second source/drain region and with a gate insulator on the substrate and on the pillar. The method comprises: isotropically forming a gate electrode material layer on the pillar and the substrate; anisotropically depositing a gate height determining insulator material on horizontal surfaces to at least the top of the channel region but not substantially overlapping the first highly doped source/drain region; and etching exposed gate electrode material to remove exposed gate electrode material above the gate height determining insulator material.

Method for programming a nonvolatile memory

Abstract: A method for programming a nonvolatile memory cell having a control gate, a floating gate, a drain, a source, and a channel region disposed between the drain and source, the method includes the steps of applying a first voltage to the control gate to form an inversion layer in the channel region, the first voltage being varied to program at least two threshold levels of the memory cell, applying a second voltage to the drain and a third voltage to the source, the second voltage being greater than the third voltage, monitoring a current flowing between the drain and the source during the programming of the at least two threshold levels, and terminating any one of the first voltage, the second voltage, and the third voltage when the monitored current reaches a preset reference current to thereby stop the programming of the at least two threshold levels.

Tunneling Current--Voltage Characteristics of Graphene Field-Effect Transistor

Abstract: We develop an analytical device model for a graphene field-effect transistor. Using this model, we calculate its current–voltage characteristics at sufficiently high gate voltages when a n–p–n (p–n–p) lateral junction is formed in the transistor channel and the source–drain current is associated with the interband tunneling through this junction.

Folded-Accumulation LDMOST: New Power MOS Transistor With Very Low Specific On-Resistance

Abstract: A new lateral power MOSFET structure [folded-accumulation LDMOS (FALDMOS)] is proposed, in which the silicon-substrate surface is trenched to form a folded shape from the channel to the drain electrode and the gate is extended to the drain. The majority-carrier accumulation layer is formed as the device is in on state due to the extended gate in the drift region whose concentration is higher than that in a conventional LDMOS at the same breakdown voltage (BV), resulting from the additional electric-field modulation, and an extra majority carrier is introduced on the sidewall of the trench, which reduced the on-resistance of the drift region further. In addition, the channel density is doubled because of trenching the folded channel, which reduced the channel on-resistance. It indicates by simulation that the specific on-resistance of 4.6 mOmegamiddotmm2 with a BV of 27.4 V in FALDMOS is lower than that of the previously reported lowest one.

Non-volatile memory array using gate breakdown structure in standard sub 0.35 micron CMOS process

Abstract: A non-volatile memory cell is provided that includes a low voltage CMOS storage transistor having a source region and a drain region that are commonly connected to ground. The low voltage storage transistor is programmed by applying a high programming voltage to its gate, thereby rupturing the gate oxide of the storage transistor. The high programming voltage is applied to the low voltage storage transistor through a high voltage p-channel transistor. The high voltage p-channel transistor has a thicker gate oxide than the storage transistor, thereby enabling the p-channel transistor to withstand higher voltages. The high voltage p-channel transistor also has a higher breakdown voltage than a high voltage n-channel transistor of the same size. Both the low voltage storage transistor and the high voltage p-channel transistor are fabricated in accordance with a standard sub 0.35 micron process. The state of the low voltage storage transistor can be read through the p-channel transistor, or through a dedicated high voltage n-channel transistor. In one embodiment, the programming voltage is generated by a charge pump circuit fabricated in accordance with a standard sub 0.35 micron process. In another embodiment, the decoder circuits that access the non-volatile memory cell use high voltage p-channel transistors to transmit the high programming voltage. Another embodiment of the present invention includes a system-on-a-chip structure that implements the non-volatile memory of the present invention.