EE130/230A Discussion 13
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Transcript of EE130/230A Discussion 13
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EE130/230A Discussion 13
Peng Zheng
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Why New Transistor Structures?• Off-state leakage (IOFF) must be suppressed as Lg is scaled down
– allows for reductions in VT and hence VDD
• Leakage occurs in the region away from the channel surface
Let’s get rid of it!
DrainSource
Gate
Lg
Thin-BodyMOSFET:
Buried Oxide
Source Drain
Gate
Substrate
“Silicon-on-Insulator” (SOI)
Wafer
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Thin-Body MOSFETs• IOFF is suppressed by using an adequately thin body region.
– Body doping can be eliminated higher drive current due to higher carrier mobility
Ultra-Thin Body (UTB)
Buried Oxide
Substrate
Source Drain
Gate
TSi
Lg
TSi < (1/4) Lg
Double-Gate (DG)
Gate
Source Drain
Gate
TSi
TSi < (2/3) Lg
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Effect of TSi on OFF-state Leakage
IOFF = 19 A/mIOFF = 2.1 nA/mLeakage CurrentDensity [A/cm2]
@ VDS = 0.7 V
106
10-1
3x102
0.0
4.0
8.0
12.0
16.0
20.0
G
G
S D
G
G
S D
Si Thickness [nm]
Lg = 25 nm; tox,eq = 12Å
TSi = 10 nm TSi = 20 nm
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Electrostatics:Under normal operating conditions, the BJT may be viewed electrostatically as two independent pn junctions
BJT Types and Definitions• The BJT is a 3-terminal device, with two types: PNP and NPN
VEB = VE – VB
VCB = VC – VB
VEC = VE – VC
= VEB - VCB
VBE = VB – VE
VBC = VB – VC
VCE = VC – VE
= VCB - VEB
EE130/230A Fall 2013 Lecture 25, Slide 5 R. F. Pierret, Semiconductor Device Fundamentals, p. 372
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BJT Circuit Configurations
Output Characteristics for Common-Emitter Configuration
EE130/230A Fall 2013 Lecture 25, Slide 6R. F. Pierret, Semiconductor Device Fundamentals, Fig. 10.4
R. F. Pierret, Semiconductor Device Fundamentals, Fig. 10.3
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BJT Modes of OperationCommon-emitter output characteristics (IC vs. VCE)
Mode Emitter Junction Collector Junction
CUTOFF reverse bias reverse bias
Forward ACTIVE forward bias reverse bias*
Reverse ACTIVE reverse bias* forward bias
SATURATION forward bias forward bias
*more precisely: not strongly forward biasedEE130/230A Fall 2013 Lecture 25, Slide 7
R. F. Pierret, Semiconductor Device Fundamentals, Fig. 10.5
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Sample Problem(a) The energy-band diagrams for a Si PNP BJT in forward-active and saturation modes of
operation are shown below.
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Sample Problem
(a) A family of common-emitter output characteristics (IC vs. VEC curves for different values of VEB) are drawn below.
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Questions regarding the MOSFET design project?
Happy Holidays!