Improving CMOS Speed and Switching Energy with Vacuum-Gap ...
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2-10-2010 -1- Improving CMOS Speed and Switching Energy with Vacuum-Gap Structures Chenming Hu and Je Min Park Univ. of California, Berkeley
Transcript of Improving CMOS Speed and Switching Energy with Vacuum-Gap ...
2-10-2010-1-
Improving CMOS Speed and Switching Energy with Vacuum-Gap Structures
Chenming Hu and Je Min Park
Univ. of California, Berkeley
2-10-2010-2-
Outline
• Introduction ▪
Background and Motivation
• MOSFETs with Vacuum-Spacer
• Vacuum-Corridor Interconnects
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Reducing Capacitance is Important for Speed
0.01 0.1 1Gate Length, Lgate (um)
0.1
1
10
100
1000
c lass ic sca lin g
T ox (C )
V d d (V )
V t (V )
TOX (Å)
VDD (V)
VTH (V)
B. Meyerson, IBM, Semico Conf., January 2004
CVI
Delay ∝ ∝Q
I
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Reducing Capacitance is Good for Swiching Energy and Noise
Cm
CV2Energy ∝ Crosstalk Noise
Cm∝
10.10.011
10
100
1000
Gate Length (μm)
Po
wer
(W/
cm2)
B. Meyerson, IBM, Semico Conf., January 2004
Metal Lines
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Outline
• Introduction
• MOSFETs with Vacuum-Spacer ▪
Structure, benefits, process ▪
Self-Aligned Contact (SAC) MOSFET
• Vacuum-Corridor Interconnects
• Future Works
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1996 Air-Gap Structure
There is only 6% inverter speed improvement
▪
The fringing capacitance is much smaller than other gate capacitances
▪
Relatively small portion of air-gap (15nm)
P
Air-gap
M. Togo, VLSI 1996
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Gate Capacitances
Gate-channel capacitance
Gate overlap capacitance
Junction/Diffusion capacitance
Fringing capacitance
Gate-to-Contact capacitance
Gate
Source Drain
Contact
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Vertical Scale Down is Difficult
Gate shape
Ideal Scaling
Real Scale Down
Gate Height
Gate Length
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CGC becomes the Dominant Capacitance in Transistor
CGCCGOX
Gate
Contact
» CGC<
CGOX : Gate Oxide Capacitance
CGC : Gate-to-Contact Capacitance
Scale Down
CGOX
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IDS -VGS Characteristics are Same
1.0E-09
1.0E-08
1.0E-07
1.0E-06
1.0E-05
1.0E-04
1.0E-03
1.0E-02
0 0.2 0.4 0.6 0.8 1VGS(V)
IDS(A
/um
)
Conventional Oxide SpacerAir Spacer
VDS=1.0V
Oxide Spacer
Vacuum SpacerGate
Contact
A vacuum spacer transistor is compared with an oxide spacer transistor at 20nm gate length
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Gate Capacitances and switching Charges are Reduced
Oxide Spacer
Vacuum Spacer
QGATE fC/um2
26 19.2
0
5
10
15
20
25
30
35
40
0 0.2 0.4 0.6 0.8 1
VGS(V)
CG
ATE(f
F/
um
2)
Air Spacer
Oxide Spacer
VDS
= 1V
CV2 Energy ∝= QV
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3D Mixed-Mode Device Simulation
dtIV DDDD Extract Propagation Delay
Inverter Switching Energy :
IDD
VIN VOUT
CL
VDD
Miller Capacitances
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Vacuum Spacer CMOS is faster than Oxide Spacer CMOS
-0.25
0
0.25
0.5
0.75
1
1.25
0 1E-11 2E-11 3E-11 4E-11 5E-1Time (s)
Vo
ltag
e (
V)
Oxide SpacerVacuum Spacer
6.1ps
4.7ps
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Gate Spacer Comparison
Air spacer is compared with nitride spacer and oxide spacer
Nitride Spacer
Oxide Spacer
Vacuum Spacer
ION mA/um 1.16 1.06 1.06
IOFF nA/um 4.16 5.55 5.64
Inverter Delay, ps
6.9(1.12)
6.15(1)
4.7(0.76)
Inverter switching energy, fJ
29.5(1.22)
24.2(1)
18.1(0.75)
Nitride Spacer
Contact
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The Benefits of Vacuum Spacer in Future Linear Contact are Greater
Future contact may be linear, not circular
Nitride Spacer
Oxide Spacer
Air Spacer
Inverter Delay, ps
Circular 6.9(1)
6.15(0.89)
4.7(0.68)
Linear 5.96(1)
4.64(0.78)
3.28(0.55)
Inverter switching energy,
fJ
Circular 29.5(1)
24.2(0.82)
18.1(0.61)
Linear 37.2(1)
29.8(0.80)
20.1(0.54)
Linear Contact
Circular Contact
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Process Flow
(a) After S/D formation
(c) Chemical Mechanical Polishing
(b) ILD deposition
(d) Sacrificial spacer removal
(e) ILD2 deposition
Substrate
Source/Drain
Gate
Oxide
Sacrificial spacer
Jemin Park et. al., “Air Spacer MOSFET Technology for 20nm Node and Beyond”, IEEE ICSICT, Oct. 2008, p53-56
Mask Oxide
ILD1
Sacrificial Spacer
Air Spacer
ILD2
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SOI Thinning
Fabrication in Progress
Alignment Mark
400
500
600
700
800
900
1000
1100
#1 #2 #3 #4 #5 #6 #7 avg
Wafer number
Th
ick
ne
ss (
A)
TCBLRTLTRBLBRAVGTafterCafterBafterLafterRafterTlafterTrafterBlafterBrafterAVGafter
Before SOI Thinning
After SOI Thinning
Oxidation condition (Tystar2): 900℃, O2 4000sccm, oxidation 600min, post anneal 20min
Active Patterning
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Another Style of Contact Design, Self-Aligned Contact
Self-Aligned ContactConventional Contact
Gate
Contact
Perfect Alignment
Misaligned
Gate
Contact
WSi2
Poly-Si
Silicon Nitride
Contact
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SRAM size can be reduced with SAC
Intel 45nm SRAM Cell Imaginary Design using SAC
Design Rule : F Cell Width : 10F Cell Height : 5F Cell Area : 50F2
Design Rule : F Cell Width : 10F Cell Height : 3.5F Cell Area : 35F2
Intel Tech. Journal, Vol. 12, 2008
Contact Contact
Gate
Active
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Proposed Process Procedure of SAC with Vacuum Spacer
Substrate
Source/Drain
Gate
Oxide
Nitride
Contact
(a) Gate stack deposition
(b) Gate etch and sidewall oxidation
(c) S/D and spacer formation
(d) ILD deposition and CMP
(e) SAC etch and contact plug deposition
(f) CMP and remove nitride material (g) ILD2 deposition
Air Spacer
Jemin Park et. al., “Air-Spacer Self-Aligned Contact MOSFET for Future Dense Memories”, IEEE SISPAD, Japan, Sep. 2008, p53-56
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(a) After CMP Process
Substrate
Source/Drain Gate
ILD
Sacrificial Spacer
GOX
Sacrificial Gate
Contact
(b) Remove sacrificial gate and form gate stack
(c) Top sacrificial spacer formation
(d) ILD deposition and SAC formation
(e) Remove sacrificial spacers
(f) ILD2 Deposition
Jemin Park et. al., “Gate Last MOSFET with Air Spacer and Self-Aligned Contacts for Dense Memories”, IEEE VLSI-TSA, Taiwan, Apr. 2009, p105-106
Gate Last Process with SAC and Vacuum Spacer
Air Spacer
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Oxide Spacer
Nitride SAC
Air SAC
ION mA/um 1.06 1.13 1.08
IOFF nA/um 5.55 2.56 6.14
Inverter Delay, ps
6.15(1)
11.85(1.93)
5.05(0.82)
Inverter switching energy, fJ
24.2(1)
44.8(1.85)
18.8(0.78)
Relative Area 1 0.7 0.7
SAC MOSFET with vacuum spacer is denser, faster, lower energy than a conventional MOSFET, 20nm.
The Case for Vacuum Spacer SAC
Oxide Nitride
Air
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10
25
40
55
70
20 32 45 65Gate Length (nm)
Sw
itch
ing E
ner
gy
(fJ)
25
35
45
55
65
Imp
rovem
en
t (%
)
6
8
10
12
14
20 32 45 65Gate Length (nm)
Del
ay T
ime
(ps)
15
20
25
30
35
Imp
rovem
en
t (%
)
Vaccum spacer – scaling effect
Benefits increase with scaling
SAC with Nitride Spacer
SAC with Air Spacer
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Outline
• Introduction
• MOSFETs with Vacuum-Spacer
• Vacuum-Corridor Interconnects ▪
The Proposed Process of Air-Corridor ▪
The Characteristics of Air-Corridor
• Future Works
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Previous Air-Gap Structures
An air gap is located only between metals
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Proposed Vacuum-Corridor structures
Etch Stop layer
Metal
Dielectric Beam
Mutual Capacitance : CM
Total Capacitance : CTOTAL
Overlap Capacitance : CO
CM
CO
CO
CM
CTOTAL ∝
Delay, CM ∝
Crosstalk Noise
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Process Flow I
Sacrificial Material MetalIMDStopper
(a) Via Etch (b) Line Etch (c) Metal depo & CMP
(d) Etch Stopper & IMD (e) Dielectric beam Spacer Formation
(f) Sacrificial material depo & CMP
Jemin Park et. al., VMIC, Fremont CA, Oct. 2008, p229-234
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Jemin Park et. al., VMIC, Fremont CA, Oct. 2008, p229-234
Process Procedure II
(g) Metal 2 Process (h) Metal 3 process (i) Removal all Sacrificial Material
Sacrificial Material MetalIMDStopper
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Metal Width 59nm 40nm 28nm 20nm
Metal Space 59nm 40nm 28nm 20nm
Metal A/R 1.8 1.8 1.9 2.0
Metal Thick 1062Å 720Å 532Å 400Å
Required Bulk Dielectric Constant 2.9 2.7 2.5 2.3
Stopper Layer Thick 10nm 10nm 5nm 5nm
IMD Thick (Metal + Via Height) 2124Å 1440Å 1064Å 800Å
Beam Dielectric Constant for Air-Corridor 2.9 2.9 2.9 2.9
Assumption for simulation2007 ITRS spec
ITRS Key Parameters of Each Generation
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0
200
400
600
800
1000
20 30 40 50 60 70 80Air percentage (%)
Cap
acitan
ce (
aF/u
m)
20% of vacuum percentage
80% of vacuum percentageThicker Beam Dielectric
Total Capacitance
Mutual Capacitance
CTOTAL,con
CMutual,con
Dielectric Beam
Metal Line
Capacitances vs. Vacuum Percentage
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Insensitive to via height
0
200
400
600
800
1000
1200
1400
360 576 792 1008 1224 1440
Via Height (A)
Tot
al C
apac
itan
ce (
aF/u
m)
0
100
200
300
400
500
360 576 792 1008 1224 1440Via Height (A)
Mutu
al C
apac
itan
ce (
aF/u
m)
Conventional Structure
Air-Corridor Structure
Conventional Structure
Air-Corridor Structure
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0
1
2
3
4
5
360 576 792 1008 1224 1440Metal Height (A)
Rel
ativ
e RC d
elay
48
51
54
57
60
Impro
vem
ent
(%)
Vacuum-Corridor has less RC delay and higher CMP margin
Relative Delay vs. Metal Height
Conventional Structure
Air-Corridor Structure
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The Effective k of Vacuum-Corridor Interconnects
No Solution
Bea
m D
iele
ctric
Const
ant
20 30 40 50 60 70 80
Air Percentage (%)
2.25
2.9
3.3
3.6
3.9
1.31.4
1.51.6
1.71.8
1.92.0
2.12.22.3
2.42.5
2.6No Solution
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Papers and Patents
PAPERS:
1. “An Vacuum-Sheath Interconnect Structure for Dense Memory” Je Min Park and Chenming HuElectronics Letters, accepted and will be published on December, 20092. “Air-Spacer MOSFET with Self-Aligned Contact for Future Dense Memories”Je Min Park and Chenming HuElectron Device Letters, accepted and will be published on December, 20093. “Gate Last MOSFET with Air Spacer and Self-Aligned Contacts for Dense Memories”Je Min Park and Chenming HuVLSI-TSA, pp105-106, Taiwan, Apr. 20094. “Air-Spacer MOSFET Technology for 20nm Node and Beyond” Je Min Park and Chenming HuICSICT, pp53-56, China, Oct. 20085. “Air-Spacer Self-Aligned Contact MOSFET for Future Dense Memories” Je Min Park and Chenming HuSISPAD, pp313-316, Japan, Sep. 20086. “An-Air-Corridor Interconnect Structure”Je Min Park and Chenming HuVMIC, pp229-234, Fremont, CA., Oct. 2008
PATENTS: (UC Patents Pending)
1. “Transistor Speed And Power Improvements” Je Min Park and Chenming HuUC Case 2008-107-02. "Air Corridor Interconnect Structure" Je Min Park and Chenming HuUC Case 2009-044-0
