Modeling of threshold voltage of a quadruple gate transistor
Md. Gaffar, Sayed Ashraf Mamuna, and Md. Abdul Matina
Available online 24 February 2011.
Abstract
In this paper, a three dimensional analytical solution of electrostatic potential is presented for undoped (or lightly doped) quadruple gate MOSFET by solving 3-D Poisson's equation. It is shown that the threshold voltage predicted by the analytical solution is in close agreement with TCAD 3-D numerical simulation results. Numerical simulation, self-consistent Schrodinger–Poisson equations, calibrated by 2D non equilibrium green function simulation, are used.
Feb 23, 2011
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SPICE Circuit Simulator Named IEEE Milestone
Simulating a circuit with SPICE is the industry-wide standard way to verify operation at the transistor level before manufacturing an IC. The program has become so ubiquitous that engineers often say they are going to “SPICE a circuit” when they are about to test one. To mark the 40th anniversary of SPICE—the Simulation Program with Integrated Circuit Emphasis—IEEE has designated its creation an IEEE Milestone in Electrical Engineering and Computing.
SPICE was made publicly available in 1971 so that chip designers could modify it—an early example of open-source software. Two years later, SPICE became well known after it was described in a paper by Pederson at the 16th Midwest Symposium on Circuit Theory, in Waterloo, Ont., Canada. During the next few years, developers around the world began using and modifying SPICE, leading it to become the industry standard it is today. “What happened was truly phenomenal,” Nagel wrote in “The Origins of SPICE.” “Within a few years, SPICE had achieved acceptance at almost all electrical engineering schools [for use in teaching] and had [spawned] a cottage industry to supply SPICE derivatives to the rapidly expanding integrated circuit industry.”
[Read more by Anna Bogdanowicz @ IEEE]
Feb 15, 2011
Papers in SSE (vol 57 , issue 1, March 2011)
Analytical threshold voltage model for lightly doped short-channel tri-gate MOSFETs
A. Tsormpatzoglou, D.H. Tassis, C.A. Dimitriadis, G. Ghibaudo, N. Collaert, G. Pananakakis
Generic complex-variable potential equation for the undoped asymmetric independent double-gate MOSFET
Adelmo Ortiz-Conde, Francisco J. García-Sánchez
Compact modeling of CMOS transistors under variable uniaxial stress
Nicoleta Wacker, Harald Richter, Mahadi-Ul Hassan, Horst Rempp, Joachim N. Burghartz
A physical compact DC drain current model for long-channel undoped ultra-thin body (UTB) SOI and asymmetric double-gate (DG) MOSFETs with independent gate operation
F. Lime, R. Ritzenthaler, M. Ricoma, F. Martinez, F. Pascal, E. Miranda, O. Faynot, B. Iñiguez
In-depth physical investigation of GeOI pMOSFET by TCAD calibrated simulation
B. Grandchamp, M.-A. Jaud, P. Scheiblin, K. Romanjek, L. Hutin, C. Le Royer, M. Vinet
Mobility in ultrathin SOI MOSFET and pseudo-MOSFET: Impact of the potential at both interfaces
G. Hamaide, F. Allibert, F. Andrieu, K. Romanjek, S. Cristoloveanu
A. Tsormpatzoglou, D.H. Tassis, C.A. Dimitriadis, G. Ghibaudo, N. Collaert, G. Pananakakis
Generic complex-variable potential equation for the undoped asymmetric independent double-gate MOSFET
Adelmo Ortiz-Conde, Francisco J. García-Sánchez
Research highlights
► Single completely generic equation of channel potential for undoped asymmetric independently driven double-gate MOSFETs. ► Channel potential equation is based on complex variables and is valid for all values of front and back-gate bias. ► The unified nature of the proposed equation provides a better basis for global physical insight. ► Several examples, including the all important fully symmetric case, are analyzed.Compact modeling of CMOS transistors under variable uniaxial stress
Nicoleta Wacker, Harald Richter, Mahadi-Ul Hassan, Horst Rempp, Joachim N. Burghartz
Research highlights
► We propose a method to simulate the effect of uniaxial stress on MOSFETs. ► The method is valid for any drain current and stress directions in (001) Si plane. ► It can perform static and dynamic simulations, in linear and saturation regions. ► It is simulator-independent and does not depend on the source of uniaxial stress. ► It is adaptable to other bulk CMOS nodes and to other technologies such as SOI.A physical compact DC drain current model for long-channel undoped ultra-thin body (UTB) SOI and asymmetric double-gate (DG) MOSFETs with independent gate operation
F. Lime, R. Ritzenthaler, M. Ricoma, F. Martinez, F. Pascal, E. Miranda, O. Faynot, B. Iñiguez
Research highlights
► Valid for long-channel undoped ADGMOSFETS with independent gate operation. ► Fully analytical and explicit derivation with no iterative solutions. ► Accessible front and back gate charges, potentials and currents. ► Unification of symmetric and asymmetric cases. ► Physical solutions similar to classical MOS theory.In-depth physical investigation of GeOI pMOSFET by TCAD calibrated simulation
B. Grandchamp, M.-A. Jaud, P. Scheiblin, K. Romanjek, L. Hutin, C. Le Royer, M. Vinet
Research highlights
► We performed 2D simulations of germanium-on-insulator fully-depleted pMOSFET. ► Interface traps, mobility and leakage were calibrated versus experimental data. ► The prediction of electrical characteristics is accurate for several gate lengths. ► These simulations help in finding guidelines for improving the on-state current.Mobility in ultrathin SOI MOSFET and pseudo-MOSFET: Impact of the potential at both interfaces
G. Hamaide, F. Allibert, F. Andrieu, K. Romanjek, S. Cristoloveanu
Research highlights
► Biasing the back interface in accumulation while extracting carrier mobility in FD-SOI MOSFETs leads to underestimated values. ► Apparent mobility degradation with decreasing film thickness in ultra-thin SOI MOSFET or Pseudo-MOSFET measurement is due to an additional component of the vertical electric field. ► In Pseudo-MOSFET measurements, the additional component of the vertical electric field comes from the traps and charges at the free-surface of the sample. ► We propose a new model to take this additional component of the vertical electric field into account.Feb 14, 2011
Is SPICE good enough for tomorrow's analog?
by Nagel, L.W.; McAndrew, C.C.;
IEEE Bipolar/BiCMOS Circuits and Technology Meeting (BCTM 2010),
Digital Object Identifier: 10.1109/BIPOL.2010.5668096
Publication Year: 2010 , Page(s): 106 - 112
IEEE Bipolar/BiCMOS Circuits and Technology Meeting (BCTM 2010),
Digital Object Identifier: 10.1109/BIPOL.2010.5668096
Publication Year: 2010 , Page(s): 106 - 112
"The answer to the question posed in the title is an emphatic yes! Because SPICE is fairly general purpose and is not tied to any particular technology (not even only semiconductors), SPICE will play a significant role in the design of integrated circuits for a long time. SPICE will not be used to simulate billion transistor circuits, of course, but instead it will play a key role in developing the devices, device models, building blocks, and behavioral models for the building blocks for the billion transistor chips. SPICE will continue to play the role of the foundation of the integrated circuit design infrastructure." [Nagel, L.W.; McAndrew, C.C.]
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