accelerating industrialization and remaining challenges for sic...
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Accelerating Industrialization and remaining challenges for SiC power devices
Thomas NEYER, tech. fellow, SiC Technology
- Substrate needs
- critical substrate supply
ON’s status chart for SiC
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2015 2016 2017 2018 2019 2020
- Product releasesDiodes:4A – 50A for 650V available as discretes6A – 50A for 1200V an in modules
MosFET:Q1/2018: 80mΩ 1200V in TO247 released – safe launchfrom Q2/2019:20mΩ, 40mΩ, 160mΩ in TO247-3LQ2 same products in D2PAK-7L, TO247-4L
alt. sources under evaluation
Sources secured
SiC 6” Volume ramp-up
Huge Fab capacity available: >10.000 WSPWGlobal Development - 24hrs: Asia/EU/US
12/12/20183
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SIC WEEKLY WAFER STARTSSBD MosFET Modules
Customer projects SiC MosFET - OBC
40kW on-board rapid charger for E-Bus fleet (36 SiC MosFETs/system)
Performance traits:- Excellent current sharing- Good dvdt control (>25V/ns)- Active rectification- zero field fails
Customer projects SiC MosFET – FormulaE
High performance traction system:50A Diodes1200V 160A MosFET (16 in parallel)Overdrive boost (increased VDC, VGS_op)
12/12/20185
SiC performance beats Silicon in volume applications
Traction system level evaluation:
12/12/20186
UpperIGBT
LowerIGBT
UpperDiode
LowerDiode
UpperMOSFET
LowerMOSFET
UpperMOSFET
LowerMOSFET
UpperMOSFET
LowerMOSFET
SW Loss, W 312.29 314.02 54.16 53.80 7.35 7.35 13.68 13.67 8.14 8.13Cond Loss, W 190.45 191.01 38.25 37.74 501.99 501.69 140.42 140.50 178.22 177.93Max Temp, °C 116.52 116.52 81.11 81.11 141.80 141.80 83.73 83.73 87.62 87.62
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Motoring Operation Die Losses (per switch) and Temperature
Cond Loss, W SW Loss, W Max Temp, °C
IGBT/Diode 2X5.6mm2 2X8mm2 4X5.6mm2
2X15mm2 + 2X10mm2
Other system evaluations in ON: 3-phase 10kW OBC/PFC stage
70-140kHz Peak efficiency: ~99% (limited by inductor)
Full-bridge DCDC converter (hard switching)
Vin=400V, Vout=220V, Tj=110 C, 13ARMS
4xNTHL040N65S3F (650V, SuperFETIII): Peak efficiency: 90.6%
4x60mΩ (900V, SiC MosFET): Peak efficiency: 94.0%
SiC MosFET competitive in Si Super Junction applications
Example 900V SiCFET vs 650V SuperJunction FET for LLC
due to low QOSS, QG and Qrr – SiCFET excellent in LLC
12/12/20187
SiC performance beats Silicon IGBTs in the lab
12/12/20188
FS4-1200V 20A vs. ON Semi SiC MOSFET under identical drive conditions
no current tail
faster Turn-on current
fast SiC turn-off600V 500A turn on
VGE= - 5 / +20V
Eon at 25°C
Paralleling of 20mΩ ON Semi SiC MosFETs vs IGBTs
Eoff at 25°C
fast SiC turn-on
Challenges – limiting factor for scaling
Limiting factor for SiC MosFET: Rsp [mΩ.cm2] – channel resistance
Approaches:- Vertical channel (ie Trench) – E shielding challenge- Deposited GOX – intrinsic quality- Low temperature GOX formation - research
12/12/20189
Resistancecomponent
Resistancepercentage
N+ source 0.6 %
Channel 59.0 %
JFET 20.5 %
N Epi 14.3 %
Sub 5.6 %
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Challenges – cooling for small die sizes
Real estate for a 60kW 800V DC inverter switch
in scaleGen 1: 20%
die area
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Power dissipation capability [W]
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Si-IGBT SiC FET 1 SiC FET2 SiC FET 3
Power density [W/mm2]
Perfect cooling
singleside
direct cooling
doublesidedirect cooling
Increase SiC Tjmax to 200 C
Ag sinteringGen 2
Gen 3
Challenges - SiC chip in discrete package
Large SiC chips in discrete packages
Temperature cycling (-55C – 150C)
12/12/201811
FEA modeling discovers:
Dependent on chip design, certain locations experience >20 times stress and strain during cycling than Silicon chip
Material Si SiC
Elastic Modulus (Gpa) 130 410
Tensile strength (Mpa) 7000 3440
Hardness (mohs) 6.5 9
CTE (1E-6/C) 2.6 4.5
Overcame problem with patented design and optimized assembly BOM
Typical failure cases for GOX (HTGB – burn-in):
SiC MosFET in its infancy of volume production (compared to Si), Oxide is thinner and intrinsically less clean
Challenges - SiC MosFET in its infancy
Gate oxide integrity for SiC MosFETs and TDDB
0.01%
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99.99%
EPI defects
Bias voltage [V]Fa
ilure
pro
babi
lity
In (early) mass production SiC MosFETs need - optimized cleaning, oxidation and anneal- Very low electric field (<3 MV/cm)- tight inline contamination control- highest substrate and Epi quality
Implemented at ON-Semi:
- 100% Epitaxy defect screening- 100% metallic cleaning efficiency- 100% electrical test screening (incl. burn-in)- 100% in-process defect control
Challenges - SiC Epitaxy and defectivity control
Tracing back burn-in failures to substrate defects
Made visible by post Epi scans
12/12/201814
Challenges - unconstrained supply chain
Cost: 30% 30% 15% 12% 13%
12/12/201815
external
within ON Semi
SiC Wafering
Roznov, Czech Republic
ON SiC Vertical Integration
External boule supply
several sources
SiC FE Process
Bucheon, Korea
Thinning, backmetal
Bucheon, Korea
WAT/Sort test
Bucheon, Korea
Assembly, test
Suzhou, China and Seremban, Malaysia
Applications
SiC Epi, Metrology
South Portland, MA, USAand Bucheon, Korea