標題: 深次微米n通道金氧半場效電晶體之參數萃取及元件模式的新技術
New Parameter Extraction and Device Modeling Techniques for Deep-Submicrometer n-MOSFET's
作者: 簡育生
Jian, Yu-Sheng
吳慶源
Wu, Qing-Yuan
電子研究所
關鍵字: 金氧半場效電晶體;通道長度;臨界電壓;逆短通道效應;參數萃取;元件模擬;電子工程;MOSFET;channel length;threshold voltage;Reverse Short-Channel Length Effect;parameter extraction;device simulation;ELECTRONIC-ENGINEERING
公開日期: 1996
摘要: This thesis focuses on the parameter extraction and device
modeling techniques for submicrometer and deep submicrometer n-
MOSFET's. The extraction method of each paramaters is based on
its domination in the device characteristics. All the structure
and mobility parameters are considered in sequence. Besides, the
Reverse Short-Channel Effect(RSCE) on the threshold voltage of
short-channel devices are investigated. An accurate model is
proposed to simulate this effect, and a simplified analytic
model can be derived. Furthermore, an analytic threshold-voltage
model on the damaged MOSFET devices is derived from the 3-zones
Poisson's equation with considering the 2-Deffects. This thesis
focuses on the most important issues of very-short-channel
MOSFET's. In this thesis, the parameter extraction, device
simulation and modeling are comprehensively studied. In Chapter
1, motivation and general introduction of this thesis are given.
In Chapetr 2, a new extraction algorithm for the metallurgical
channel length of conventional and Lightly Doped Drain(LDD)
MOSFET's is presented, which is based on the well-known
resistance method with performing a special technique to
eliminate the uncertainty of the channel length as well as to
reduce the influence of the parasitic source/drain resistance on
threshold-voltage determination. In particular, the
metallurgicall channel length is determined from a wide range of
gate-voltage-dependent effective channel length at an adequate
gate-voltage-dependent effective channel length at an adequate
gate overdrive. The 2-D numerical analysis clearly shows that
the adequate gate overdrive is strongly dependent on the dopant
concentration in the source/drain region. Therefore, an analytic
equation is derived to determine the adequate gate overdrive for
various source/drain and channel dopings. It shows that higher
and lower gate overdrives are needed to accurately determine the
metallurgical channel length of conventional and LDD MOSFET
devices, respectively. It is the first time that we can give a
correct gate overdrive to accurately extract the metallurgical
channel length not oly for conventional devices but also for LDD
MOS devices. Besides, the parasitic source/drain resistance can
also be extracted using our new extraction algorithm. In Chapter
3, a new physical model for doping redistribution induced by the
RSCE for n-MOSFET devices is proposed. It is deduced from the
well-known physical and electrical characteristics of the RSCE.
This model accounts for not only the lateral but also the
vertical doping redistribution. The most importance is the
doping depletion effect in the bulk is also included by a
depletion coefficient. Simulation results show good agreements
as compared with the experimrntal data. In addition, simplifying
this model by double integrations, an analytic threshold-voltage
model for n-MOSFET devices with the RSCE is derived. The derived
analytic threshold-voltage model introduces four parameters to
describe the RSCE, each of them has its physical meaning and
therefore can help us to get more insight into the RSCE. This
simple and accurate model can be easily implemented into circuit
simulator without major modification. In Chapter 4, a new
analytic threshold-voltage model for a MOSFET device with
localized interface charges is presented. Dividing the damaged
MOSFET device into three zones, the surface potential is
obtained by solving the 2-D Poisson's equation. Calculating the
minimum surface potential,the analytic threshold-voltage model
is derived. It is verified that the model accurately predicts
the threshold voltage for not only the fresh devices but also
the damaged devices. Moreover, the DIBL and substrate bias
effects are also included in this model. It is shown that the
screening effects due to built-in potential and drain bias
dominate the impactof the localized interface charges on the
threshold voltage. Calculation results show that the extension,
position and density of localized interface charges are the main
issues to influence the threshold voltageof a damaged MOSFET
device. Simulation results using a 2-D device simulator are used
to verify the validity of this model, and quite good agreements
are obtained for various cases. In Chapter 5, the descriptions
for the extraction techniques of the device parameters are
illustrated. The extraction technique of each parameter is
obtained according to its most important influences on the
device characteristics for different devices operated under
different bias conditions. All the parameters including device
structure and mobility model model for a set of test devices are
extracted in sequence. The whole extracted parameters are
putting into a device simulator-SUMMOS and the simulation
results show excellent agreements as compared with the
experimental data, and the validity of the extraction techniques
is verified. Device characteristics for the existing devices are
examined, some comments and suggestions on improving the
performance are declared. In addition, a design example for a
very short-channel device is demonstrated by considering the
threshold-voltage roll-off and Drain-Induced Barrier Lowering(
DIBL) effects, lateral electric field, leakage current,
transconductance and saturation current of the device. Finally,
conclusions are given in Chapter 6, where the major
contributions of this thesis and some possible future researches
are proposed.
URI: http://140.113.39.130/cdrfb3/record/nctu/#NT854428007
http://hdl.handle.net/11536/62493
顯示於類別:畢業論文