Engineering, 2010, 2, 673-682
doi:10.4236/eng.2010.29087 Published Online September 2010 (http://www.SciRP.org/journal/eng)
Copyright © 2010 SciRes. ENG
Static and Dynamic Characterization of High-Speed Silicon
Carbide (SiC) Power Transistors
Johnson A. Asumadu1, James D. Scofield2
1Electrical and Computer Engineering Department, Western Michigan University, Kalamazoo, USA
2Air Force Research Laboratory/Propulsion Directorate, Power Division, Wright-Patterson Air Force Base,
Dayton, USA
E-mail: johnson.asumadu@wmich.edu, james.scofield.1@us.af.mil
Received September 14, 2009; revised July 23, 2010; accepted July 24, 2010
Abstract
This paper describes the operating characteristics of NPN 4H-SiC (a polytype of silicon carbide) bipolar
junction transistor (BJT) and 4H-SiC Darlington Pairs. A large amount of experimental data was collected.
The wafer BJTs were able to block over the rated 600 V in the common-emitter configuration and the
TO-220 BJTs were able to block over the 1200 V rated voltage. In the thermal analysis, it is found out that at
higher temperatures the forward and reverse (blocking) characteristics were stable at 100°C and 200°C. The
transistors show positive temperature coefficients of forward voltage (Vf). In general the current gain (
)
characteristics obtained (with VCE = 6 V) were approximately as expected for the BJTs. The
’s were very
low (2 to 5 for wafer BJTs, 5 to 20 for the wafer Darlington Pairs, and 5 to 30 for TO-220 BJTs). The large
amount of experimental data collected confirms some of the superior properties of the Silicon carbide mate-
rial when used to fabricate power semiconductor devices, namely high thermal conductivity and high tem-
perature operability. The data presented here will establish the trends and the performance of silicon carbide
devices. The silicon carbide BJT has fast switching and recovery characteristics. From the analysis, silicon
carbide power devices will be smaller (about 20 times) than a similar silicon power device and with reduced
power losses. Silicon carbide will also be very useful for device integration in high densities, as found in in-
tegrated chips for current handling capabilities, for applications in instrumentation and measurements. Pres-
ently, most of the research is on improving the basic silicon carbide material quality, power device optimiza-
tion, and applications engineering using devices that have been developed to date.
Keywords: Silicon Carbide, Static Characteristics, Dynamic Characteristics
1. Introduction
Today’s efforts to replace conventional mechanical, hy-
draulic, and pneumatic power transfer systems with elec-
tric drives and their power electronics converters have
taken off at an increasingly rapid rate (e.g., automobile
electric brakes, traction control and electronic stabil-
ity-control systems, electronic power-assisted steering
(EPAS), etc.). The high demand for small power devices
for instrumentation and measurements is expected to stay
that way for many years to come, thereby challenging
technology and circuit design in an unprecedented fash-
ion. Biological and biologically-inspired instruments
(e.g., nano-technology probes, MEMS, and so on) as
well as portable equipment (e.g., laptops, palm pilots,
camera recorders, midi players, meters, and more) are a
few examples driving new areas of research in instru-
mentation and measurements. If silicon carbide (SiC)
devices (power transistors, integrated chips (ICs), etc.)
are developed and commercialized, they will replace
silicon (Si) devices, since SiC devices will offer im-
provements to system weight, volume, losses, efficiency,
and temperature capability. These improvements are
needed over the next few years to realize the full poten-
tial of more-electric system paradigms and reduced
power consumption goals. Table 1 illustrates many of
the benefits SiC has to offer. This paper is an expansion
and continuation of our paper [1] on the characteristics of
SiC bipolar transistors.
Silicon carbide material has been widely studied be-
J. A. ASUMADU ET AL.
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674
Table 1. Comparison of the electrical and material proper-
ties of Si and SiC.
Property Si SiC
Bandgap (eV) 1.11 3.5
Maximum Temperature (°C) 425 > 900
Maximum Voltage (106V/cm) 0.3 4
Thermal Conductivity (W/cm°C) at 300° K 1.5 5
Electron Mobility (cm2/Vs) 1350500
Dielectric Constant 11.8 9.66
Process Maturity HighLow
Intrinsically Hard NO YES
cause it is a promising material for higher power and
high temperature applications. The properties of SiC
include high field electric breakdown (2.2 MV/cm), high
saturated electron drift velocity (2E7 cm/s), and high
thermal conductivity (4.5 W/cm-K) making SiC very att-
ractive for high-voltage, high-frequency, high power se-
miconductor devices and switches, including those for
instrumentation and measurement. The properties of SiC
material and power devices have been documented over
the last twenty years [2-6].
Although 6H- and 4H-SiC polytypes are the most re-
searched crystal structures, the 4H-SiC polytype domi-
nates power device development activity because the
electron mobility in 4H-SiC is two times that of 6H-SiC
perpendicular to the c-axis and about ten times that of
6H-SiC parallel to the c-axis [7,8]. SiC Schottky Barrier
Diodes (SBDs) have been available commercially since
2001 with 300 to 1200 volt, 175oC ratings. Although SiC
power MOSFETs [8,9] have received significant empha-
sis, they continue to suffer from poor MOS channel mo-
bility and reliability, especially in the 4H-SiC polytype.
However, high voltage npn bipolar junction transistors
(BJTs) and gate turn-off bipolar transistors (GTOs) in
4H-SiC have been demonstrated [9,12] with superior
characteristics. SiC BJTs have been reported in the lit-
erature to block 1.8-2.5 kV with peak currents of over 30
A, with DC current gains of 40 when operated in the
common-emitter configuration. The active area of these
devices was in the 1 mm × 1.4 mm to 3.16 mm × 3.16
mm range. Static and dynamic characteristics of 6H-SiC
Diodes, BJTs, and MOSFETs have been presented [10],
but have had drawbacks in performance because of the
poor electron mobility in the vertical direction. Despite
the superior theoretical properties of SiC, material cost,
base material quality, and substrate size are areas all re-
quiring continued development and improvement prior to
widespread technology adoption.
In this paper, the results of forward and reverse V-I
characteristics, current gain characteristics, and dynamic
measurements on 4H-SiC Darlington Pairs and BJTs in
the common-emitter configuration are presented. The
BJTs were characterized in two formats – on wafer pro-
bing and in TO-220 packages. The Darlington Pairs were
in the wafer die format only. The current and voltage
ratings of the wafer power devices are 5 A and 600 V,
respectively, while the ratings of the TO-220 BJTs are 5
A and 1200 V, respectively. The active area of the 4H-
SiC Darlington Pairs and BJTs are in the range of 1 to 3
mm2 with emitter finger widths and spacings from 10 m
× 15 m (pitch = 25 µm) to 10 m × 27 m (pitch = 37
m), respectively. Device data presented in this paper
represent the measured performance characteristics ob-
served from numerous devices of each type, enabling
reasonable statistical inferences.
2. Device Structure, Design, and Fabrication
2.1. Device Structure
The BJTs came in two formats – on wafers and in TO-
220 packages. The Darlington Pairs were available only
on wafers. The current and voltage ratings of the wafer
power devices are 5 A and 600 V, respectively, while the
TO-220 BJTs are 5 A and 1200 V. The Figure 1 shows a
typical BJT cross-sectional diagram of the implanted
device on a wafer. The maximum overall cross-sectional
dimension of a typical transistor is 235 m × 235 m.
The substrate material used for both Darlington Pairs
and BJTs was n-type, 20 m-cm 4H-SiC from Cree, Inc.
on which n-collector, p-base, and n-emitter epitaxy of 10
µm 5E15 cm-3, 1 µm 2E17 cm-3, and 0.5 µm 5E19 cm-3,
respectively, were grown. Devices with active areas in
the range of 1 to 3 mm2 with emitter finger widths and
spacings from 10 m × 15 m (pitch = 25 µm) to 10 m
× 27 m (pitch = 37 m), respectively, were subse-
quently fabricated for testing. Figure 2 shows how a
Darlington Pair and BJT images are laid out on a single
wafer probing Reticle. There are several images on a
N
+
N
+
N
+
N
+, 4H-SiC Substrate
Collector
Thin base
P - Base
Figure 1. Simplified cross-section structure of 4H-SiC BJT.
J. A. ASUMADU ET AL.
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675
Image 1
Darli
ngton
Pair
Image 2
BJT
Image 3
BJT
Image 4
BJT
Figure 2. Reticle design layout of BJT and Darlington pair images.
Reticle. Image 1 on all the Reticles is a Darlington Pair
and the remaining images are all BJTs. The characteris-
tics were measured on 4 wafer Reticles with different
orientation, resistivity, and thickness. The images se-
lected on a Reticle are Image 1 – Darlington Pair and
Images 2 to 4 – BJTs as shown in Figure 2.
2.2. Device Design and Fabrication
Table 2 shows the emitter configurations (emitter width
(x), base width (y)) and pitch (x + y) of the selected Im-
ages 2, 3, and 4. The emitter configuration of Darlington
Pair (Image 1) was not available (N/A). A Darlington
Pair was designed to contain 54 emitter fingers and a
BJT has 28 emitter figures. The distance between the
implanted edge termination regions for devices is typi-
cally 2 m. Table 3 shows the off-axis orientation, resis-
tivity, and thickness of the four device wafer Reticles.
Figure 3 shows examples of the top view of a fabricated
4H-SiC Darlington Pair and a BJT.
3. Experimental Setup
The forward and reverse Vce vs. Ic characteristics were
measured using Tektronix 371 curve tracer for both the
wafer and the TO-220 BJTs. The dynamic characteristics
were similarly measured but only on the TO-220 BJTs.
Even though large amount of data was collected for these
studies, results are presented for typical Darlington Pair
and typical BJT devices from the wafer Reticles, and the
TO-220 BJTs.
4. Experimental Results and Discussions
4.1. Experimental Results – Wafer Probing
4H-SiC Darlington Pair and BJT
4.1.1. Forward and Reverse (Blocking)
Characteristics
The Figures 4 and 5 show the forward and reverse
(blocking) Vce vs. Ic characteristics for a typical Dar-
Table 2. Reticle active area.
Images Emitter Width (x) Base Width (y) Pitch (x + y)
1 N/A N/A N/A
2 15 15 30
3 10 15 25
4 15 15 30
J. A. ASUMADU ET AL.
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676
Emitter
Base
Collector at
Backside
of Wafer
(a)
Base
Emitter
Collector at
Backside
of Wafe
r
(b)
Figure 3. (a) Top view of a fabricated 4H-SiC Darlington
Pair; (b) Top view of a fabricated 4H-SiC BJT.
lington Pair (Image 1 on Reticle # 2 ).
Similarly, the Figures 6 and 7 show the forward and
reverse Vce vs. Ic characteristics for a typical BJT (Im-
age 4 on Reticle #4). The sustaining voltage BVCE0
ranges from 200 V to 800 V for the Darlington Pair and
from 200 V to 1200 V for the BJTs. The designed stand-
off voltage of the BJT epitaxy was 600 V.
Reverse voltage characteristics depend on the drift
layer thickness, the base doping used, and the base con-
tact implantation tail, which tends to decrease the base
width. High current gain and high reverse voltage can be
achieved with the proper doping and width of base, and
an optimized carrier lifetime.
4.1.2. Current Gain
The Figure 8 shows the forward current gain character-
istics (base current Ib vs.
) of the above-mentioned de-
vices. The maximum current gains (
max) occur at room
temperature and decrease as temperature and base cur-
rent increase. The low current gains in Darlington Pair
and most of the BJT samples may be due to 1) low emit-
ter injection efficiency because of high base doping and/
or low emitter doping, 2) low minority carrier life-times
in the base layer, and 3) poor ohmic contact resistance of
the p + layer contact [9-12].
The Figure 8 also shows the effect of temperature on
the common-emitter current gains (
) from room tem-
perature to 200°C. As temperature increases, background
carrier concentrations in the base region increase. This is
due to an increase in the ionization fraction of the alu-
minum (EA ~200 meV) acceptors, as a result, emitter
T = 200°C
0
200
400
600
800
1000
1200
1400
1600
1800
10 20
Vce (V)
Ic
(
mA
)
T = 100°C
0
500
1000
1500
2000
2500
510 15
Vce (V)
Ic
(
mA
)
T = 25°C
0
100
200
300
400
500
600
700
800
10 2
0
Vce
V
Ic
(
mA
)
Figure 4. Darlington pair forward Vce-Ic characteristics at
25°C, 100°C, & 200°C.
J. A. ASUMADU ET AL.
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677
Figure 5. Darlington Pair reverse Vce-Ic characteristics at
25°C, 100°C, & 200°C.
injection efficiency decreases. As a consequence of this,
increases with temperature to the minority carrier life-
times are offset. The result is that the common-emitter
current gain,
decreases with temperature (a negative
temperature coefficient not observed in silicon (Si) de-
vices). This prevents thermal runaway and makes the SiC
power device very attractive for paralleling. Also, the
on-resistance will increase because of a decrease in col-
lector layer electron mobility. In general, all the com-
mon-emitter current gain characteristics were in the
range shown in Figure 8.
Figure 6. BJT Pair forward Vce-Ic characteristics at 25°C,
100°C, & 200°C.
4.1.3. Early Voltage
Table 4 shows representative values of device Early
Voltages (VA) at room temperature from three different
Reticles. The devices showed VA ranging from 115 V to
2000 V. The VA of a typical Darlington Pair ranges from
115 to 165 V. The VA of Darlington Pairs on some of the
Reticles was much higher; ranging from 118 V to 1900
V. The VA of a typical BJT ranges from 325 V to 347 V.
The VA of BJTs on some of the Reticles was much
higher; ranging from 267 V to 2000 V.
T = 200°C
-
50
0
1
00
Ice(mA)
2
00
300
400
0 510 15 20
Vce
V
T = 100°C
0
100
200
300
400
500
600
510 1
5
20
Vce
V
Ice(mA)
T = 25°C
Ice(mA)
-100
0
100
200
300
400
500
600
700
800
900
0510 15 20
Vce
V
T = 200°C
-50
0
50
100
150
200
250
300
0 500 1000
Vce (V)
Ic(mA)
T = 100°C
-50
0
100
200
300
400
500
0
500 1000
Vce (V)
Ic(mA)
T = 25°C
-2
0
2
4
6
8
10
12
14
16
18
2
0
0
500 1000
Vce (V)
Ic(mA)
J. A. ASUMADU ET AL.
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Figure 7. BJT Pair reverse Vce-Ic characteristics at 25°C,
100°C and 200°C.
Table 4. Early voltage.
Images VA1 VA2 VA3
Image 1 Darling
Pair 165.912 156.711 155.189
Image 3 BJT 325.383 347.990 330.968
The VA values are very high, which could imply that
the effective base width is large, possibly due to carrier
trapping at deep level defects and compensated base
doping. This would be consistent with the low current
gains (low base carrier lifetimes) and high Early Volt-
ages observed.
4.2. Experimental Results – TO-220 BJTs
4.2.1. Forward and Reverse (Block) Characteristics,
and Current Gain
The Figures 9 and 10 show typical forward (Ib = 20 mA
in steps) and reverse characteristics representative of the
4H-SiC BJTs in the TO-220 casing. Figure 11 shows the
Ib vs.
characteristics for the same devices. Typical
values of
vary from 5 to 29, with maximum current
gain (
max) of about 30 at room temperature and 200
mA base current. The decrease in the current gain at
room temperature and at 200°C is relatively small. The
maximum collector current at room temperature was
about 6 A but reduces to about 5 A at 200°C. These im-
proved characteristics, compared to the wafer devices,
reflect an improved base layer epitaxy process yielding
enhanced transport characteristics.
At high temperatures the emitter injection efficiency is
reduced, due to the increase in majority carrier concen-
tration in the base from an increased deep acceptor ioni-
zation fraction. The expected variation in the forward
characteristics between room temperature and at 200°C
is due to the positive temperature coefficient of RDS,ON.
The epitaxial growth process was optimized to increase
the minority carrier lifetime in the emitter and base lay-
ers, which in turn leads to higher dc current gain. This
was accomplished by performing the growth at lower
0
5
10
15
20
25
30
00.20.4 0.6
Ib (A)
(A/A)
25oC
100oC
200oC
(a)
0
1
2
3
4
5
6
7
00.2 0.4 0.6
Ib (A)
(A/A)
25oC
100oC
200oC
(b)
Figure 8. (a) Darlington Pair Current (Ib) vs. Gain (
); (b)
BJT Current (Ib) vs. Gain (
).
T = 200°C
-50
0
50
150
250
350
450
0
500 1000 1500
Vce (V)
Ice(mA)
T = 100°C
-50
0
50
150
250
350
450
0 500 1000
Vce
V
Ice(mA)
T = 25°C
0
10
20
30
40
50
200 400 600
800
1000
Vce (V)
Ic(mA)
J. A. ASUMADU ET AL.
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679
Ic(A)
1
2
3
4
5
6
0 5 10 15
Vce (V)
T = 200°C
T = 25°C
Ic(A)
1
2
3
4
5
6
7
0 510
Vce
V
T = 100°C
Ic(A)
1
2
3
4
5
6
0 5 10 15
Vce (V)
Figure 9. TO-220 BJT forward Vce-Ic characteristics at
25°C, 100°C and 200°C.
temperatures, reducing point defects and impurities, and
maintaining stoichiometry of the highly doped emitter
layer.
Due to SiC’s higher on-state conductivity and lower
off-state leakage current at high operating temperatures
compared to Si, superior performance at high operating
junction temperatures, including lower power dissipation
in the active area of the device is realized.
4.2.2. Dynamic Characteristics
Figure 12 shows the experimental setup used to study
the dynamic characteristics of the 4H-SiC BJTs (TO-220
casing) and the sustaining voltage between the collector
terminal and the emitter terminal (VCE0(sus)). The dy-
namic characteristics are performed at room temperature.
Figure 10. TO-220 BJT reverse VceIc characteristics at
25°C, 100°C, and 200°C.
Ic(A)
100
200
300
400
050 10 15
00
Vce (V)
T = 200°C
Ic(A)
0
100
300
500
700
900
05001000 1500
Vce (V)
T = 100°C
T = 25oC
-
50
Ic(A)
100
200
300
400
0
1000 2000
Vce (V)
-50 0
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5
10
15
20
25
30
35
0 0.05 0.1 0.15
0.2 0.25
Ib (mA)
(A/A)
200oC
25oC
100oC
Figure 11. TO-220 BJT Current (Ib) – Gain (
).
The dynamic characteristics analysis was performed at
low voltage due to restrictions of the test equipment. The
circuit was constructed using a power supply of 15 V,
low-power resistors, current probes, and operated from a
pulse generator at two switching frequencies (100 kHz
and 1 MHz with a duty-cycle ratio of 50%). The load
resistance was approximately 20 ohm (rated 20 W) con-
nected in the common-emitter configuration mode.
The SiC power BJT was turned on and off by applying
the pulses of the generator to the base of the transistor.
The turn-on and turn-off measurements were taken at
room temperature.
Figure 13(a) shows typical turn-on characteristics of a
4H-SiC BJT with the pulse generator operated at 100
kHz. The turn-on rise time is much faster than a typical
Si BJT. A typical turn-on rise time of 312 ns was ob-
served at room temperature. Figure 13(b) shows the
turn-off characteristics of the 4H-SiC BJT at room tem-
perature. The turn-off fall time is observed to be nomi-
nally 92.5 ns at room temperature. Turn-on rise time can
be improved by decreasing the base contact resistance
and by increasing carrier extraction in the base-emitter
junction.
Switching speeds in this range are indicative of well
controlled minority carrier lifetimes in the base. Very
short turn-off times are obtained even though the junc-
tion breakdown voltage VBE is less than 10 V. The dy-
namic characteristics shows that the switching features of
the SiC power devices can be very fast but at high fre-
quencies the controlling external circuit must have high
switching speed (rise time). The very fast switching
characteristics show that a SiC-based BJT device has low
effective stored charge even when operated at high tem-
peratures. Therefore, the switching losses in SiC devices
caused by the stored charges are negligible in these de-
vices; whereas about 30% of losses in Si power devices
and ICs occur during switching [9]. The switching cir-
cuits required can be totally integrated into the switching
scheme, and can be dynamically adaptive, fast, ultra low
losses, and very small size. The SiC-devices have excel-
lent high short circuit capability, especially suitable for
commuting applications in power electronics and swit-
ching circuits.
Maximum sustaining voltage characteristics, between
the collector terminal and the emitter terminal, at a col-
lector current of 100 mA is shown in Figure 14. A 392
H inductance was placed in the collector leg of the cir-
cuit shown in Figure 12.
The transistor was subjected to a transient voltage
forcing the transistor to go into avalanche breakdown for
a short time. The sustaining collector-emitter voltage
VCE0(sus) was observed to be 40 V (at collector current
of 100 mA) at room temperature.
Figure 15(a) shows typical turn-on and turn-off char-
acteristics of a 4H-SiC BJT, with the pulse generator
operated at 1 MHz. It was observed that the voltage at
the collector collapsed. Even though the BJT turn-on rise
time has been shown to be 312 ns (3.205 MHz), the
power supply failed because the switching speed (the rise
time) of the power supply is lower than 1 MHz (restric-
tions of the test equipment).
Figure 15(b) shows the characteristics of the maxi-
mum sustaining collector-emitter voltage at a switching
frequency of 1 MHz. The sustaining voltage VCE0(sus)
was observed to be 25 V (at collector current of 100 mA)
at room temperature. The sustaining voltage should have
remained relatively constant at collector current of 100
mA for all the switching frequencies. However, the
switching speed (the rise time) of the power supply is
less than 1 MHz and contributed to this anomaly.
5. Conclusions
The experimental data collected confirms some of the
SiC BJT
(TO-220)
Figure 12. Experimental setup for dynamic characteristics.
J. A. ASUMADU ET AL.
Copyright © 2010 SciRes. ENG
681
(a)
(b)
Figure 13. (a) Turn-on characteristics at 100 kHz; (b) Turn-
off characteristics at 100 kHz.
Figure 14. Maximum sustaining voltage (at collector cur-
rent of 100 mA) at 100 kHz.
(a)
(b)
Figure 15. (a) Dynamic characteristics at 1 MHz; (b) Maxi-
mum sustaining voltage (at collector current of 100 mA) at
1 MHz.
superior properties of the SiC material when used to fab-
ricate electrical and electronics devices for applications
in power electronics, instrumentation and measurements.
The forward characteristic exhibited stability at high
temperatures because of the higher percentage of deep
level acceptor ionization in the base region. The gain
also decreases as the temperature increases. This nega-
tive temperature coefficient property prevents thermal
runaway and makes SiC power BJT devices very attrac-
tive for paralleling. The BJTs also show high reverse
(blocking) voltages considering the fact that the effective
on-resistances (6 m-cm2 at 25oC) of these devices are
very small. The current gain, however, was observed to
decrease for BJTs with smaller pitches, possibly caused
by limited recombination in the base region and low
emitter injection efficiency due to emitter crowding ef-
I
B
I
C
I
B
I
C
I
C
VC
VCEO(sus)
I
B
I
C
VCEO(sus)
I
C
VCE
J. A. ASUMADU ET AL.
Copyright © 2010 SciRes. ENG
682
fects. Base layer ohmic contacts need improvement to
reduce the ~5E-3 -cm2 specific base contact resistivity
measured. The Early Voltage values were very high
which likely is due to large effective base widths. This is
consistent with low current gain and high Early Voltage
effect. The other very prominent features of the SiC BJT
include the fast turn-on switching speed, very fast turn-
off time, and the robust behavior under critical thermal
conditions.
Two key observations can be made from the data col-
lected. First, for example, a 1000-volt SiC power device
will be 5X smaller or 5X more efficient than comparable
Si device operating at twice the environmental tempera-
ture. Secondary, SiC power devices will reduce switch-
ing power losses in many applications.
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