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IMPATT oscillators with enhanced leakage current
Solid-State
Electronics.
1975, Vol. IX. pp. I-I?.
IMPATT
Pergamon
Precs.
Prmted in Great Britain
OSCILLATORS WITH ENHANCED LEAKAGE CURRENT* P. E. COTTRELL
IBM System
Products
Division,
Essex Junction.
Vermont
05452, U.S.A.
and J. M. BORREGO and R. J. GUTMANN Electrophysics
and Electronic
Engineering
Division, Rensselaer
York (Received 7 December Abstract-The behavior of IMPATT experimentally evaluated by irradiating current was induced in diffused junction 1OOnsec pulses of 10 MeV electrons. decreases and the frequency of oscillation is developed which correlates well with 1.
1973; in revisedform
INTRODUCTION
*This work is in part composed from a dissertation submitted by P. E. Cottrell to the Eiectrophysics and Electronic Engineering Division of Rensselaer Polytechnic Institute, Troy, New York in partial fulfillment of the requirements for the Ph.D. degree and was partially supported by the Defense Nuclear Agency through the Air Force Cambridge Research Laboratories, Bedford, Mass., under Contract FI96828-72-C-0112. 18. No. I-A
Troy,
New
20 March
1974)
the elevated junction temperatures of high power IMPATT diodes of up to 50O”K, bulk generation leakage current on the order of 0. I A/cm’ is expected in silicon devices. Also leakage current of 0.1 A/cm’ or more can be expected in a GaAs Schottky diode operating at this temperature from minority carriers going over the potential barrier lowered by the high electric field. This paper is concerned with the experimental characterization and large signal circuit modeling of the effect of leakage current on the RF performance of IMPATT diodes. In the experimental evaluation, operating diodes were irradiated with 1OOnsec pulses of IOMeV electrons produced by a linear accelerator. This radiation creates a photo or leakage current which is proportional to the rate of absorbed energy from the radiation (radiation dose rate) and the sum of the volume of the depletion region and the region from which carriers can reach the depletion region before recombining. A silicon (Diode A) and a GaAs (Diode B) X-band, diffused junction, 0.5 W diode were tested in a waveguide cavity with an the silicon external Q, Q<,,, of 100. In addition, diode was tested in a modified cavity with a Qcxt of 2000. The diode RF output power, frequency and voltage were monitored before, during and after the radiation pulse. An extension of Mouthaan’s[3,4] large signal model was used to predict IMPATT diode performance with leakage current. The model consists of identifiable circuit elements and in simplified form
current
SSE Vol.
Institute,
oscillators with enhanced leakage current has been operating diodes with transient ionizing radiation. Leakage GaAs and silicon X-band IMPATT diodes by irradiation with With increasing leakage current, the oscillator RF power increases. A large signal circuit model of the IMPATT diode experimental measurements.
has been shown to have important effects in IMPATT (impact ionization avalanche transit time) oscillators. Decker, et a/.[11 studied the effect of excess majority carriers in the avalanche region caused by injecting ‘ohmic’ contacts. Minority carriers from the metal-semiconductor contact are injected into the diffused region of an IMPATT diode, move through that region and are swept across the depletion region causing an increase in the leakage current. It was shown that for high bias current densities, effective leakage currents of 6 per cent of the bias current reduced the peak diode output power by ninety per cent. Misawa[2] considered the effect of minority carrier storage in the diffused region of an IMPATT diode. Carriers generated by avalanche multiplication diffuse backwards from the avalanche region into the heavily doped diffused region due to high carrier concentration gradients. These carriers are released later during the IMPATT cycle and act as a large effective leakage current. Leakage current as small as 0.2 per cent of the bias current was shown to reduce the diode efficiency by half. Moreover, at Leakage
Polytechnic
12181, U.S.A.
I
P. E. COTTRELL, J. M. BORREGO and R. J. GUTMANN
2
can be easily evaluated without a digital computer. It can be used to predict diode output power with leakage current without explicit knowledge of the RF circuit if the cw characteristics of the diode with insignificant leakage current are known. If the variation of RF circuit impedance as a function of frequency is also known it can be used to determine the oscillation frequency shift as a function of leakage current. The paper is arranged as follows: section 2 outlines the experimental method used to determine the diode output power and oscillation frequency with enhanced leakage current and section 3 gives the results for the GaAs and silicon X-band IMPATT diodes. In section 4, the device model with enhanced leakage current is derived and the method of evaluation described. The correlation and discussion of theoretical and experimental results is made in section 5. Section 6 summarizes the results of this work. 2.
EXPERIMENTAL
METHOD
Leakage current generated In order to experimentally evaluate the response of IMPATT diodes to enhanced leakage current it is necessary to induce a known leakage current in the diode and to measure the diode response. Leakage current was induced by irradiating operating IMPATT diodes with IOOnsec pulses of 10 MeV electrons. The radiation source used was the Air Force Cambridge Research Laboratories linear accelerator. The 10 MeV electrons are able to penetrate the 0.17 in. aiuminium cavity wail and the diode with little energy loss. The 100 nsec pulse length was shorter than the diode’s thermal time constant of about 1 psec. By varying the accelerator peak injector current, radiation dose rates of IO” to 4 x lo9 rads/sec were achieved with little shift in beam energy. The accelerator was operated in the signal pulse mode (one pulse per data point) so that the total accumlated dose received by the diode did not exceed five thousand rads. The absolute level of radiation dose rate was use of thermoiuminsecent determined by dosimetry[S] inside the diode cavity. The diode leakage current due to radiation is given by I, = qKjV
(1)
where q is the electron charge, K is the number of ionized pairs generated per rad per cm), + is the radiation dose rate in radslsec and V is the effective charge generation volume. This effective volume is essentially that volume from which
charge carriers can reach the depletion layer before recombining. This includes all the depletion layer volume and the volume associated with one diffusion length of the appropriate carrier to either side if the minority carrier lifetime is much less than the radiation pulse length. The minority carrier diffusion length for the diffused and the substrate regions of the diodes is difficult to evaluate with an) accuracy. However, in these heavily doped region\ the minority carrier lifetimes are at most I nsec fat both GaAs and silicon. This low lifetime corre\ponds to minority carrier diffusion lengths of le\s than 0.5 pm. If the depletion layer volume (on the order of several microns wide and easier to obtain with precision) only is taken ax the effective volume, the estimate will be no more than 20 peg cent low. Thus the effective volume was taken a\ V=AW,
(2)
where A is the diode cross-sectional area and W, the depletion layer width. The radiation source was calibrated directly in radsisec or absorbed dose rate. It i4 well known [6,7] that on the average, pair creation due to ionzing radiation uses energies of 3.6eV and 4.6eV per pair for silicon and gallium arsenide respectively and thus density of electron-hole pairs generated, K, is 4 x IO” pairs/rad/cm’ in silicon and 7.2 x lOi pairs/rad/cm’ in gallium arsenide. The diode area, A, and total depletion width, Wi, were found by evaluation of the diodes’ current and capacitance variation with reverse bias voltage and are given in Table I. The leakage current for the dose rates used in testing can now be calculated using the depletion volume and equation (1). Although accurate direct measurement of diode leakage current due to the IOMeV electron radiation could not be achieved due to unavoidable noise sources caused by beam current pick up and radiation generated Table.
I. IMPATT
diode parameters Diode A Silicon
Material
77 0.7
v,, (VI N (cm’ X IO’“) A (cm’ x 10~‘)
Diode B &IA\ 64 I .2 ( I ,2’)
I .6
2.2 (2m’)
WT(pm)
4.0
W, (pm) Wdbm) a' (V ') v, (cm/set
7.4 0. 14 0.95
2.7 (I.75 I.95 oz? 0.7
*Data
I .h x IO’)
provided
by the manufacturer.
IMPATT
oscillators
leakage paths in the diode bias circuit, a check was made on the calculated results by measurement of the current due to radiation at bias voltages somewhat below breakdown. After systematic calibration of noise signal, and with a compensating calculation of carrier multiplication, the actual radiation generated diode current was obtained from the measurements. The calculated and measured results are presented in Table 2. While we believe that the calculated values are more correct and certainly form a more consistent set, the error measured data indicates that no excessive exists. RF power and frequency The IMPATT diodes were mounted in a waveguide cavity of the post and disc type@] for characterization and radiation testing. During testing, the entire cavity was in a vacuum chamber which was evacuated to a pressure of less than 3 x 10 5 mm of mercury. Thus, a reduction in circuit Q due to ohmic loading of the RF cavity caused by air ionization was avoided[9] and no significant shunt d.c. current path caused by radiation ionized air was formed. The output signal was carried by X-band waveguide through a glass pressure window to the RF measuring circuit shown in Fig. 1. The IMPATT diode in the RF cavity was tuned by 7 SLIDING SHORT
TO
BIAS
Table. 2. Calculated
and measured
leakage
Calculated Measured Dose rate leakage leakage (rads/sec X IO’) current (mA) current (mA)
Diode A
Diode B
0.2 0.5
0.082 0.21
I4
0.58
4.0
1.7
0.12 0.29 0.74 I.5
0.3 0.95 I.5 3.4
0.2 0.64
0.19 0.68
1.o
I.1
2.3
2.4
means of a calibrated sliding short, slide screw tuner, and if necessary by changing the post and disc diameters. During tuning, the RF power was measured through a directional coupler with the X-band thermistor mount and a power meter. The frequency of oscillation and RF spectrum were monitored with a spectrum analyzer. The diode output power during the radiation pulse was monitored using a crystal detector calibrated with the RF power meter shown in Fig. 1. Also shown is a waveguide frequency discriminator[lO] used to measure the RF output frequency shift during the radiation pulse. The outputs of the RF measurement apparatus provided
CIRCUIT
DIODE -
IN CAVITY
-
SCREW
TO POWER
---_
THERMISTOR
METER
MATCHED LOAD
VARIABLE
1 I
I
ATTENUATOR
I
‘0
I ISOLATOR
I +
&O
CR0
(
PHASE SHIFTER -
MAGIC
-
TEE
current
I
RF DETECTOR
Fig. 1. RF measurement
apparatus.
I MAGIC
-
TEE
-
P.
4
E.
COTTRELL,
.I. M.
BORREG~
and K. .I. GLI~‘MNN
9352
Coax~aicable Fig. 2. IMPATT
the necessary readouts on either d.c. meters or oscilloscopes to completely characterize the IMPATT cw characteristics and response to the 100 nsec radiation pulse. The d.c. bias current was supplied by a variable voltage power supply through the circuit shown in Fig. 2. The circuit provides a method of measuring the diode bias voltage change during the radiation pulse and has a 300 R source impedance up to a frequency of 50 MHz. This is necessary to assure a bias circuit pulse impedance high enough so that the bias current remains constant during the radiation pulse. 3.
EXPERIMENTAL
RESULTS
The RF power, oscillation frequency and bias voltage were measured for the silicon and GaAs diodes in the nominal Q cavity and for the silicon diode mounted in the high Q cavity for various bias currents and radiation dose rates. Results indicate that the radiation induced leakage current decreases the diode output power and increases the frequency of oscillation. Figure 3 gives typical output of the measurement apparatus for a 100 nsec radiation pulse. The diode output power returns to its original level within 50 nsec following the radiation pulse, indicating the absence of significant carrier trapping. The apparent delay between pulses is merely due to differences in triggering in dual beam oscilloscopes. In fact no measureable delay exists between the radiation pulse and onset of the diode response. Figures 4 and 5 give the diode output power in the nominal Q cavity for the silicon and GaAs diodes during the radiation pulse for various dose rates and bias currents. The fitted curves are used later to facilitate comparison with the theoretical
diode bias circuit.
results. Figure 6 gives similar results for the silicon diode in the high Q cavity which exhibits output power saturation at high bias currents with no radiation. The change in frequency due to the radiation pulse is given in Figs. 7 and 8 for diodes A and B in the nominal Q cavity. The data given is the difference between the measured frequency during the radiation pulse and the cw frequency at the bias current shown. Again. the fitted curves are for later theoretical correlation. The frequency shift of the silicon diode mounted in the high Q cavity was so small that the change in cw frequency with bias current obscured the data for all except the highest bias current. The frequency shift during the radiation pulse is reduced by a factor of about 3 in the high Q cavity compared to the frequency shift for the same diode in the nominal Q cavity. 500 1
Dose
rate
(rads
40
53
/set
Y IO’)
1 30
BIOS
60
current,
70
80
mA
Fig. 4. Output power vs bias current for various radiation dose rates, diode A in the nominal Q cavity.
IMPATToscillators
500 r
Dose Dose
rote
(radslsec
rate
(rods
/set
x IO91
x IO’)
14
ZeK,
0.5
/;j’, o-3
0
//
0
o-95
,J
/o’2
I.5
3.4
40
50
60
70
/
// -.J’
/i
40
50
BIOS
60
current,
70
rote
(rods
Bias
current,
mA
shift during the radiation A in the nominal Q cavity.
pulse,
diode
mA
Fig. 5. Output power vs bias current for various radiation dose rates, diode B in the nominal Q cavity.
Dose
Fig. 7. Frequency
/set
20 Dose
rote
(rads/sec
x10’)
r
x log)
0.95
Zero
/
0 0
/
60
0
o 0.3
0 /
OL’!do BIOS
Fig. 8. Frequency 30 BIOS
40 current.
xl
60
510 6io current,
;o
mA
shift during the radiation in the nominal Q cavity.
pulse, diode B
mA
Fig. 6. Output power vs bias current for various radiation dose rates, diode A in the high Q cavity.
The voltage across the IMPATT diode during the radiation pulse was measured to monitor the change in bias current through the diode. The net change in diode current was found in all cases to be less than 2 mA. In no case could the change in bias current have caused an RF output power reduction of more than five percent of the measured decrease at the highest bias current and of more than 10 per
cent at the lowest bias current at which diodes were tested. The change in frequency of oscillation due to the decrease in bias current was less than 10 per cent of the measured frequency shift at the maximum bias current used for both diodes and at worst 30 per cent for the lowest bias current for which data is presented. 4.
THEORETICAL
Complete model In this section
DIODE
an extension
MODEL
of the large signal,
P. E. COTTRELL, J. M. BORREGOand R. J. GUTMANN
6
IMPATT model proposed by Mouthaan[3,4] will be used to characterize the IMPATT diode with leakage current. The model derived is circuit oriented. that is composed of identifiable circuit elements. With this approach, the large signal effects of leakage current can be easily evaluated and interpreted without obscuring the device physics. A one sided Read [ I I] structure is assumed and the resulting equation which describes the avalanche region particle current and its limitations is well established[l2-141
The component is
of avalanche
current
at frequency
w
L(t)
(8)
= iI sin (wt) - i2 cos (wt)
where i, = 21,M
xk
(3) and where I,, is the avalanche particle current, I, is the leakage current, 6 is the effective ionization rate, W,, is the avalanche width, and u, is the saturated carrier drift velocity. The effective ionization rate, is described by 6 = cu,,+ cu’E,,
(4)
where E,, is the RF electrical field in the avalanche region and LY’is the derivative of the ionization rate with respect to the electric field. If the time dependent voltage across the avalanche region is a single frequency sinusoid. V,,(t) = V,, sin wt
(5)
the steady state, avalanche particle current I,,(t) can be found by solving equation (3) with (4).
(IO)
I.
The total current in the conduction current due to between two parallel plates the displacement current voltage
drift region L(t) is the a space charge moving at constant velocity and due to a time varying
i,,(r) = I,$++e !~,,~“rl~,,l’
MWT<, X cos (kwt) + k2 sin (kwt)
I
M
where
I
is
the
multiplication
l-w \ 1 I~ ” cxcldx , u!,, is the normalized
J
factor
II
(‘3 M=
J,M
Id(r) = - ii sin (wt) - LCOS (wt) + Cd %
avalanche
0 ! t region voltage L’,,= (Y’V,,/WT~~.r,, is the avalanche transit time r,, = W,,/u\,and the 1;s are modified Bessel functions of the first kind. When the bias current i is supplied by a current source it is independent of the RF voltage and can be found by considering the d.c. component of the avalanche current
i =
where Wd is the length of the drift region, Cd is the drift region capacitance and Vd is the voltage across the drift region. Substituting the fundamental component of I,(t) into equation (I 1)
(7)
(12)
where
i, =
_
ii
sin (WTd)
+
iz
SinZ
~
2 OTd i-i 2 t
SinZ 3 sin (07~) i 2 > i4= i, + 120 07d 0 2
J
(13)
(14)
IMPATToscillators
7
and 7d = Wd/ve. With the addition of the displacement current through the avalanche capacitance, C,, a complete steady state, circuit model for operation of an IMPATT diode at angular frequency o has been derived and is shown in Fig. 9(a). Although the model is complicated, it is instrucive to see what effect each current generator has on IMPATT diode operation. Current generator iI increases in value with increasing leakage current and represents an ohmic loss in the avalanche region. Current generator iz represents the avalanche inductance of the IMPATT diode which decreases slightly with increasing leakage current. The negative resistance of the circuit is derived from generator ii. Its value decreases with increasing leakage current and thus reduces the RF voltage and output power. Current generator i4 decreases the capacitive susceptance of the diode with increased leakage current. This has the effect of increasing the frequency of oscillation with increasing leakage current. In the case of the leakage current approaching zero, this circuit model is identical to the circuit model derived by Mouthaan[4]. In the small signal case with leakage current the model reduces to that of Sanderson and Jordan[lS].
can be truncated for k > 1 with little loss of accuracy. With some algebraic manipulation equations (7), (9), (lo), (13) and (14) become
Approximate model Simplification of the model can be easily achieved by assuming a leakage current much smaller than the bias current while retaining the large RF voltage level. Since Zk(x) > L+,(x) the summation terms in the expressions for the current generators of the model decrease at least as fast as (kw~,M/2) ~I. For reasonable values of normalized avalanche voltage, avalanche transit time and leakage current the current generator expressions
Further simplification can be achieved for reasonable physical parameters and operating conditions. The displacement current through the junction capacitance is much greater than the reactive currents produced by avalanche dynamics. Elimination of the reactive current generators give the circuit shown in Fig. 9(b). Thus, the simplified model consists of only one active element with the parameters given by equations (IS), (lg), (20), and
z= Z,MZ$2V,)
(15)
i, = 2Z/3 cos 4 sin 4
(16)
iz = 2Z/3 co? 4
(17)
i, = 2Z/3 cos 4
sin C-1 2 sin
(-1 WTd 2
w7L ( 2
(18)
41
i4 = 2Z/3 cos 4
(19)
WTd
(-) 2 where
cot 4 =-
MWT” 2
(20)
and p=- Z1(2U”) Z0(2v, )’
(21)
(21). 0 +
V V
I
Fig. 9(a). Complete
IMPATTdiode
I
0
circuit
model.
Fig. 9(b).
Simplified
IMPATT
4 diode circuit
model.
8
COTTRELL,
P. E. The models
derived
do not account field
by
the
saturation
RF
voltage
approximation calculation
They
and
as
thus.
power
depletion
width
rate precludes
the
of the change in d.c. diode voltage
of the ionization
due
to rectification
of the RF current
variation
of
However,
the principal
ionization
on the performance oscillation
rate
by the nonlinear
with
effects
held. current
of IMPATT
diode
parameters
are well described
electric
of leakage
Fig. IO. Simplified RF circuit model
by these large signal
models. Evaluation
of the simplified
X-band
silicon
the simplified
complete output
model (Fig. 9(b)) and
model (Fig. 9(a)) was carried
the complete show
model power
IMPATT
model
for
out for a
diode.
Results
in agreement
prediction
at leakage
of the
current
At
higher
densities to the
leakage
the difference increasing
truncated
from
equation
influence
of
the complete
quently.
diode
RF
below
bias
I
the predict
large due terms
The
measured diode
the
leakage
current
buildup
of the avalanche
timing
is not
agreement
particle
a
causes
current
maintained.
and thus optimum
These
results
arc
in
with those of Misawa[l6]. (‘OMPARISON
OF
In order calculate diode
with
RF
enhanced
sary to consider connected in
output
leakage
obtained
from
10
inductance.
L.,
where R,
the
to
in the nominal
package
resistance,
is represented
and R, I-
by
correctly with
predicts
The package capacitance
C,, was neglected
expected
inductance
current
almost
series
resonant
with
the diode
L,
is
capacitive
Once the microwave diode performance can he predicted ties
measurement impedance function
for
condition.
at which
circuit impedance
according a given
diodes
or theoretical of
a
diode
Unfortunately
IMPATT typical
of frequency
is known.
to the derived structure
and
at the frcquenare
prediction oscillator
is extremely
model
most
useful,
of the RF circuit
difficult.
as a In this
and for
as no saturation
the
the silicon Compari-
diode
current
and
for the silicon
nominal Q cavity
Q cavities
and
power-
saturation levels fat
This is to be
effects except for leakage agreement
measured
output
of output
for the power
for the model.
quantitative
KF
.A\ can be
between
power- with
the
Icakage
diode
in both the high and
GaAs
diode in the nominal
is quite good.
The fr-equency
shifts measured
during the radia
tion pulse are more than an order of magnitude than can be predicted reactance
are GaAc
show that the theory
variation
except
were considered
predicted
susceptance.
operating
seen.
with
and the
current
shown at the highest hias current
case
package
leakage
the silicon diode in the high Q cavity.
in this
the
current
and measured
the
hias current
effects
previ-
power
respectively.
power with no leakage current
the
of RF
cavity
of Fig. 9(a)
This is shown
1.
I I-13 for the silicon and
diode in the high Q cavity.
jX, (0).
since
with
cry’,WI\
assumptions
model with no leakage model
data1 171.
[ IX]. The value of the
the prediction
diode
bias. The
( W,,. W,,) were
coctlicient.
and
circuit
circuit.
reverse
are listed in Table
in Figs.
diodes
work
W,
of the diode current
width
son of the predicted
parasitic
circuit
model IMPATT
in
data.
width
and Haddad’s
parameters
discussed
complete
depletion
with
region
it is neces-
represents
the total
microwave
diode of the
en-
given
from published
and total
of the ionization
parameters
Using
plotted
with
A. W,,. W,,. CY’ and r, were
Schroeder
The derivative above
to
subse-
described
development
current.
the equivalent
to the microwave
Fig.
the
power
AND
RESLITS
to use the theoretical the
the
variation
ously
THEORETIC-\L
EXPISRIhIENT.41~
A
and drift
Mouthaan’s 5.
by
taken from Goedhloed‘s
premature
performance
by evaluation
avalanche
due to the finite leakage current.
used
and,
This procedure
were determined and capacitance
the peak to peak avalanche
were
impedance
or calculated
area
of
fixed.
current.
characteristics
,4.
of
is reduced
circuit
is justified
either
output current
the diode
leakage
Appendix
power
leakage
RF
Evaluation
current
RF
The diode parameters
current
summation
model.
determine hanced
up to
in results become
insignificant
(6) shows that with the d.c. component
current Also,
or
the diode
with
the
levels
current
work.
with
per cent of the bias current densities of 500 A/cm’or less.
GUTMlNh
R. .t.
[ 141 are not modeled. The use of a linear
modulation
typical
and
of the d.c. electric
swing
such
BORREGO
M.
here have limitations.
for perturbation
effects
J.
during the radiation
I,C tuned circuit
less
from the change in the diode pulse using
:I
simple
model. This simply means that the
IMPATT
9
oscillators
500 r
Leakage 400
current
(mA)
/
-
Zero
Data Theory
---
300% i al
i
a,
zoo-
z a
5 a
:
::
60
40-
IOOzo-
BIOS
current,
mA
Leakage
400
current
(mA)
/
”
/,
40
30
Fig. 1 I. Comparison of theoretical and experimental variation of output power with bias current, diode A in the nominal Q cavity.
Doto ---Theory
alas
Fig. 13. Comparison of theoretical variation of output with bias current, Q cavity.
alas
current,
mA
nominal
Q
cavity.
waveguide cavity tends to stabilize the frequency of the diode with a rapidly varying reactance with frequency. For small frequency deviations, Ao, from the angular frequency oo, the RF circuit reactance can be expressed as X(o)
= X(w) + X’(w,,)Aw
50
60
mA
and experimental diode A in the high
where X,,(w,J is the cavity reactance at the cw oscillation frequency and X’(w) is the rate of change of cavity reactance with frequency. Since the diode susceptance is largely due to junction capacitance it can, to first order, be considered linear with frequency. Using the fact that the diode reactance is approximately equal in magnitude to the lead reactance, wL,, the fractional oscillation frequency shift can be found from the circuit
AW -= WI,
Fig. 12. Comparison of theoretical and experimental variation of output power with bias current, diode B in the
current.
AXz, X‘l 3 + X’(& T
(22)
where AXd is the change in diode reactance due to the enhanced leakage current and XI is the diode reactance with no leakage current. The theoretical curves shown in Figs. 14 and IS have been calculated using equation (22) developed from the RF circuit model shown in Fig. IO and a value of X’/L calculated from one frequency shift data point taken at one radiation dose rate and RF output power level for each diode. The resulting values ranged from 10-30. It can be seen that indeed the diode frequency shift due to enhanced leakage current is proportional to the change in diode reactance and that the proportionality constant is on the order of 10. Although the equivalent
P. E. COTTRELL, J. M. B~RREGO and
I0
lated
40
current
Leakoge
(mA)
R. J.
GUTM.~NN
by irradiation
energy irradiation
-
Data ---Theory
hole-electron The
high
current
during
current,
mA
Fig. 14. Comparison of theoretical and experimental frequency shift with leakage current, diode A in the nominal Q cavity.
diode
Comparison
power
as a function
show
good
for the GaAs
current
(ma)
diode
agreement 0.64 /
/
/
/
/
/
/
/
/
/
02
/’ /
BlQS
mA
current,
Fig. 15. Comparison of theoretical and experimental frequency shift with leakage current, diode B in the nominal Q cavity. of the disc and post waveguide
circuit
not been derived
from
analysis indicates
that the proportionality
obtained within
are
the
first principles,
reasonable[l9].
limits
of experimental
The
cavity
has
a simplified constants
agreement
is
error.
6. SUMMARY
The major an IMPATT in
RF
effect of enhanced
leakage
current
in
diode has been shown to be a decrease
power
oscillation.
and
Enhanced
an
increase leakage
in
frequency
current
of
the
and predicted
testing
RF
between
current and
experiment
and silicon diodes mounted The
high
results
cavity
are
effects
The
in
qualitative
dominate
measured
is proportional change
to the constant analysis
at the
oscillation predicted
due to enhanced
;I qualitative
in
for the silicon
leakage that is in
of
the RF
REFERENCES
,/’
/
parameter%
and leakage
a proportionality
with
current.
D. Decker. C. Nunn and H. Frost. IEEE ‘Trc~r~,\. Electron Deuices ED-l& 141 (1971). 3 ‘1‘. Misawa, Solid-Sr. Electrorl. 13, 1369 (1970). -. 3. K. Mouthaan. Phil. Rcs. Rrp. 25. 31 (1970). IEEE Trctns. MicrowcIw Theorq cutd 4. K. Mouthnan, Techniques. MTT-IX, 853 (1970). 5. T. Cameron. N. Suntharalingam and C;. Kcnncy. ThermolL~minescrnt Dosimetry. University of Wi\consin Press (1968). E#ect.s ;,I Srmic.orltllrc.to,- Drricuc. 6. Larin, Radiution Wiley, New York (1968). 7. C. Klein, J. uppl. Phvs. 39. 3029 (1968). 8. T. Misawa and N. D. Kenyon, IEEE Trtrns. Microwctoe Theory urtd Techniques MTT-18. 969 (1970). 9. R. Chaffin. IEEE 7’run.s. Nucleur Science NS-1X. 436 (1971). fEEE Tmm. Microwc~w Theory md IO. R. Mohn. Techniques MTT-11. 263 (1963). I I. W. T. Read, Bell Spst. Tech. J. 37. 401 (IY%). Lee,J. uppl. Phys.41, 1743 (1970). 12. R. KuvasandC. 13. J. Nigrin. Proc. IEEE 60, 916 (1972). and G. Haddad. IEEE Proc. 61. 153 14. W. Schroeder (1973). and A. Jordan, Solid-St. Electron. IS. 15 A. Sanderson 140 (1972). Electron. 13. 1363 (1970). 16. T. Misawa, So/id-St. and G. Haddad, IEEE Prw. 59, 1245 17. W. Schroeder (1971). Solid-Sf. Eleclron. 15. 635 (1972). 18. J. Goedhloed, Ph.D. di\s. Rensselaer Polytehnic lnstiI9 P. Cottrell, tute. Troy. New York (1973). I
/’
with
diodes were
circuit.
/
/
shift
reactance
current
-Data ---Theory
of bia\
currents.
the
leakage
or
of this model were derived
but saturation
bias
frequency
the
region
from
of a model proposed
electrical
Q cavity.
of
pulse.
leakage
agreement
in
pairs
photo
of measured
theory
mounted
depletion
and structural
non-destructive
higher Leokaqe
to include electrical
diode\.
the nominal
distribution
effects in IMPATT
for evaluation
agreement
the a
the radiation
diode\ The high
the semiconductor.
ionized
by an extension
by Mouthaan necessary
in
the
creating
current
characterized
from
field
sweep
volume
Leakage
The
ionizes a uniform
electric
depletion
IMPATT electrons.
pairs throughout
continuously
BIOS
of operating
with 100 nsec pulses of 10 MeV
was
of
simu-
11
IMPATToscillators APPENDIX
Relationship between RF circuit output characterizution
A
impedance
ment of the oscillation starting current, oscillation frequency and RF output power at a known bias current can be used to determine the RF circuit impedance at frequency w. This has been done for the diodes used in this study and the results are given in Table 3. In general, the characteristics with enhanced leakage current can be predicted by a solution of the tuning conditions, [equation (Al)], the circuit model (Fig. 9(a)), and the constant current condition [equation (7)], for a given diode and operating point. This involves, however, the simultaneous solution of three coupled, transcendental equations with three unknowns. However, certain simplifications can be made. Since the diode reactance is largely passive junction capacitance, to first order the diode oscillation frequency can be considered constant as leakage current is varied. Thus, the terms WT,, and ~7~ in the active elements of the model can be replaced by constant transit angles 0, = OG-,, and &, = ti17~. This eliminates one variable (w) and one transcendental equation (X, = - X,) when calculating the diode operating characteristics with leakage current. Furthermore for small frequency deviations the real part of the RF circuit impedance can be considered constant and the value derived from the cw measurement previously described can be used to find the diode operating characteristics with leakage current. Solving the tuning condition for a fixed frequency and RF circuit resistance for the simple model with leakage current in Fig. 9(b) gives the following result for a diode with enhanced leakage current
and diode RF
The IMPATT model can be related to the RF circuit by solution of the tuning condition equationl4J Z,, = - Z,
= ~ (R,%+ R, + jX, ).
(Al)
When this expression is evaluated for the diode with no leakage current, the results relate the normalized avalanche voltage to the physically measurable oscillation starting current I,,.,,, and the bias current 1141
of RF where I..,,,,, is a function electrical and structural parameters, RF circuit impedance
frequency, the diode and the real part of the
(A3
where Q = [WC, (Rs + R, )J-‘.
(A4)
The reactive part of the circuit impedance determines the frequency of oscillation which in this case is independent of the RF voltage and bias currentf41
c,, - = cos $J P
This equation with equation (20) can be solved simultaneously with equation (15) for D, and M. The diode output power, P, with enhanced leakage current can now be calculated as it is proportional to the square of the normalized voltage. The RF output power P at a bias current I is
Measurement of the oscillation starting current and the frequency of oscillation for a diode with known electrical and physical parameters, therefore, determines the total load RF resistance, R, + R ,, and the load reactance X,,. The RF output power is given by[4]
P P,=
If the RF output power is also measured for a given bias current, the RF load resistance, R,. can be determined from equations (A?). (A3) and (A6). Thus, the measure3. Derived
and measured
((3%~) (2x1 Diode A Nominal Q Diode B Nominal Q Diode A High Q
tj”> (G 1
where P,, is a measured reference power at reference current I,, v,,
(A6)
Table.
(A7)
diode operating
parameters
I,,
P,,
R,_ + Rs
R,.
X0
(mA)
(mW)
(a)
(fl)
(fi)
IO.6
33.5
63
324
1.98
I.17
- 40.0
8.9
32.0
64
316
I.91
1.88
~ 25.8
9.8
22.5
44
68
I ,57
0.285
- 42.4
12
P. E. COITRELL, J. M.
BORREGO and R. J. GUTMANN
above calculation can be easily done by hand as only a few iterations are necessary to solve equations (A7) and (15). The calculated value of normalized avalanche voltage can now be used to find the values of the current generators, actual avalanche voltage. and the diode impedance. If the change in transit angle is small, the increase in oscillation frequency due to enhanced leakage current can now be calculated from the change in diode impedance if the variation of RF circuit impedance with frequency i\ known a\; the tuning condition must be still met. The model described by Fig. 9(a) and equations (7). (9). (10). (13) and (14) can be evaluated by iterative ~imultaneoux solution or by systematic evaluation. If again the frequency shift is considered small. the real part
of the RF circuit impedance is considered constant and the use of the transit angles 0,. and (Id simplify the calculation of diode impedance. Assuming the RF circuit resistance constant with frequency the value of the real part of the diode impedance with no leakage current can be matched to the calculated diode impedance with leakage current. The diode output power is then P = &I<,
*R,
(A%
where I,, is the total diode current. Again the oscillation frequency shift can be calculated from the tuning condition and the evaluated circuit model if the RF circuit impedance as a function of frequency is known. The above procedure is used in calculating the theoretical results presented in this paper.
Electronics.
1975, Vol. IX. pp. I-I?.
IMPATT
Pergamon
Precs.
Prmted in Great Britain
OSCILLATORS WITH ENHANCED LEAKAGE CURRENT* P. E. COTTRELL
IBM System
Products
Division,
Essex Junction.
Vermont
05452, U.S.A.
and J. M. BORREGO and R. J. GUTMANN Electrophysics
and Electronic
Engineering
Division, Rensselaer
York (Received 7 December Abstract-The behavior of IMPATT experimentally evaluated by irradiating current was induced in diffused junction 1OOnsec pulses of 10 MeV electrons. decreases and the frequency of oscillation is developed which correlates well with 1.
1973; in revisedform
INTRODUCTION
*This work is in part composed from a dissertation submitted by P. E. Cottrell to the Eiectrophysics and Electronic Engineering Division of Rensselaer Polytechnic Institute, Troy, New York in partial fulfillment of the requirements for the Ph.D. degree and was partially supported by the Defense Nuclear Agency through the Air Force Cambridge Research Laboratories, Bedford, Mass., under Contract FI96828-72-C-0112. 18. No. I-A
Troy,
New
20 March
1974)
the elevated junction temperatures of high power IMPATT diodes of up to 50O”K, bulk generation leakage current on the order of 0. I A/cm’ is expected in silicon devices. Also leakage current of 0.1 A/cm’ or more can be expected in a GaAs Schottky diode operating at this temperature from minority carriers going over the potential barrier lowered by the high electric field. This paper is concerned with the experimental characterization and large signal circuit modeling of the effect of leakage current on the RF performance of IMPATT diodes. In the experimental evaluation, operating diodes were irradiated with 1OOnsec pulses of IOMeV electrons produced by a linear accelerator. This radiation creates a photo or leakage current which is proportional to the rate of absorbed energy from the radiation (radiation dose rate) and the sum of the volume of the depletion region and the region from which carriers can reach the depletion region before recombining. A silicon (Diode A) and a GaAs (Diode B) X-band, diffused junction, 0.5 W diode were tested in a waveguide cavity with an the silicon external Q, Q<,,, of 100. In addition, diode was tested in a modified cavity with a Qcxt of 2000. The diode RF output power, frequency and voltage were monitored before, during and after the radiation pulse. An extension of Mouthaan’s[3,4] large signal model was used to predict IMPATT diode performance with leakage current. The model consists of identifiable circuit elements and in simplified form
current
SSE Vol.
Institute,
oscillators with enhanced leakage current has been operating diodes with transient ionizing radiation. Leakage GaAs and silicon X-band IMPATT diodes by irradiation with With increasing leakage current, the oscillator RF power increases. A large signal circuit model of the IMPATT diode experimental measurements.
has been shown to have important effects in IMPATT (impact ionization avalanche transit time) oscillators. Decker, et a/.[11 studied the effect of excess majority carriers in the avalanche region caused by injecting ‘ohmic’ contacts. Minority carriers from the metal-semiconductor contact are injected into the diffused region of an IMPATT diode, move through that region and are swept across the depletion region causing an increase in the leakage current. It was shown that for high bias current densities, effective leakage currents of 6 per cent of the bias current reduced the peak diode output power by ninety per cent. Misawa[2] considered the effect of minority carrier storage in the diffused region of an IMPATT diode. Carriers generated by avalanche multiplication diffuse backwards from the avalanche region into the heavily doped diffused region due to high carrier concentration gradients. These carriers are released later during the IMPATT cycle and act as a large effective leakage current. Leakage current as small as 0.2 per cent of the bias current was shown to reduce the diode efficiency by half. Moreover, at Leakage
Polytechnic
12181, U.S.A.
I
P. E. COTTRELL, J. M. BORREGO and R. J. GUTMANN
2
can be easily evaluated without a digital computer. It can be used to predict diode output power with leakage current without explicit knowledge of the RF circuit if the cw characteristics of the diode with insignificant leakage current are known. If the variation of RF circuit impedance as a function of frequency is also known it can be used to determine the oscillation frequency shift as a function of leakage current. The paper is arranged as follows: section 2 outlines the experimental method used to determine the diode output power and oscillation frequency with enhanced leakage current and section 3 gives the results for the GaAs and silicon X-band IMPATT diodes. In section 4, the device model with enhanced leakage current is derived and the method of evaluation described. The correlation and discussion of theoretical and experimental results is made in section 5. Section 6 summarizes the results of this work. 2.
EXPERIMENTAL
METHOD
Leakage current generated In order to experimentally evaluate the response of IMPATT diodes to enhanced leakage current it is necessary to induce a known leakage current in the diode and to measure the diode response. Leakage current was induced by irradiating operating IMPATT diodes with IOOnsec pulses of 10 MeV electrons. The radiation source used was the Air Force Cambridge Research Laboratories linear accelerator. The 10 MeV electrons are able to penetrate the 0.17 in. aiuminium cavity wail and the diode with little energy loss. The 100 nsec pulse length was shorter than the diode’s thermal time constant of about 1 psec. By varying the accelerator peak injector current, radiation dose rates of IO” to 4 x lo9 rads/sec were achieved with little shift in beam energy. The accelerator was operated in the signal pulse mode (one pulse per data point) so that the total accumlated dose received by the diode did not exceed five thousand rads. The absolute level of radiation dose rate was use of thermoiuminsecent determined by dosimetry[S] inside the diode cavity. The diode leakage current due to radiation is given by I, = qKjV
(1)
where q is the electron charge, K is the number of ionized pairs generated per rad per cm), + is the radiation dose rate in radslsec and V is the effective charge generation volume. This effective volume is essentially that volume from which
charge carriers can reach the depletion layer before recombining. This includes all the depletion layer volume and the volume associated with one diffusion length of the appropriate carrier to either side if the minority carrier lifetime is much less than the radiation pulse length. The minority carrier diffusion length for the diffused and the substrate regions of the diodes is difficult to evaluate with an) accuracy. However, in these heavily doped region\ the minority carrier lifetimes are at most I nsec fat both GaAs and silicon. This low lifetime corre\ponds to minority carrier diffusion lengths of le\s than 0.5 pm. If the depletion layer volume (on the order of several microns wide and easier to obtain with precision) only is taken ax the effective volume, the estimate will be no more than 20 peg cent low. Thus the effective volume was taken a\ V=AW,
(2)
where A is the diode cross-sectional area and W, the depletion layer width. The radiation source was calibrated directly in radsisec or absorbed dose rate. It i4 well known [6,7] that on the average, pair creation due to ionzing radiation uses energies of 3.6eV and 4.6eV per pair for silicon and gallium arsenide respectively and thus density of electron-hole pairs generated, K, is 4 x IO” pairs/rad/cm’ in silicon and 7.2 x lOi pairs/rad/cm’ in gallium arsenide. The diode area, A, and total depletion width, Wi, were found by evaluation of the diodes’ current and capacitance variation with reverse bias voltage and are given in Table I. The leakage current for the dose rates used in testing can now be calculated using the depletion volume and equation (1). Although accurate direct measurement of diode leakage current due to the IOMeV electron radiation could not be achieved due to unavoidable noise sources caused by beam current pick up and radiation generated Table.
I. IMPATT
diode parameters Diode A Silicon
Material
77 0.7
v,, (VI N (cm’ X IO’“) A (cm’ x 10~‘)
Diode B &IA\ 64 I .2 ( I ,2’)
I .6
2.2 (2m’)
WT(pm)
4.0
W, (pm) Wdbm) a' (V ') v, (cm/set
7.4 0. 14 0.95
2.7 (I.75 I.95 oz? 0.7
*Data
I .h x IO’)
provided
by the manufacturer.
IMPATT
oscillators
leakage paths in the diode bias circuit, a check was made on the calculated results by measurement of the current due to radiation at bias voltages somewhat below breakdown. After systematic calibration of noise signal, and with a compensating calculation of carrier multiplication, the actual radiation generated diode current was obtained from the measurements. The calculated and measured results are presented in Table 2. While we believe that the calculated values are more correct and certainly form a more consistent set, the error measured data indicates that no excessive exists. RF power and frequency The IMPATT diodes were mounted in a waveguide cavity of the post and disc type@] for characterization and radiation testing. During testing, the entire cavity was in a vacuum chamber which was evacuated to a pressure of less than 3 x 10 5 mm of mercury. Thus, a reduction in circuit Q due to ohmic loading of the RF cavity caused by air ionization was avoided[9] and no significant shunt d.c. current path caused by radiation ionized air was formed. The output signal was carried by X-band waveguide through a glass pressure window to the RF measuring circuit shown in Fig. 1. The IMPATT diode in the RF cavity was tuned by 7 SLIDING SHORT
TO
BIAS
Table. 2. Calculated
and measured
leakage
Calculated Measured Dose rate leakage leakage (rads/sec X IO’) current (mA) current (mA)
Diode A
Diode B
0.2 0.5
0.082 0.21
I4
0.58
4.0
1.7
0.12 0.29 0.74 I.5
0.3 0.95 I.5 3.4
0.2 0.64
0.19 0.68
1.o
I.1
2.3
2.4
means of a calibrated sliding short, slide screw tuner, and if necessary by changing the post and disc diameters. During tuning, the RF power was measured through a directional coupler with the X-band thermistor mount and a power meter. The frequency of oscillation and RF spectrum were monitored with a spectrum analyzer. The diode output power during the radiation pulse was monitored using a crystal detector calibrated with the RF power meter shown in Fig. 1. Also shown is a waveguide frequency discriminator[lO] used to measure the RF output frequency shift during the radiation pulse. The outputs of the RF measurement apparatus provided
CIRCUIT
DIODE -
IN CAVITY
-
SCREW
TO POWER
---_
THERMISTOR
METER
MATCHED LOAD
VARIABLE
1 I
I
ATTENUATOR
I
‘0
I ISOLATOR
I +
&O
CR0
(
PHASE SHIFTER -
MAGIC
-
TEE
current
I
RF DETECTOR
Fig. 1. RF measurement
apparatus.
I MAGIC
-
TEE
-
P.
4
E.
COTTRELL,
.I. M.
BORREG~
and K. .I. GLI~‘MNN
9352
Coax~aicable Fig. 2. IMPATT
the necessary readouts on either d.c. meters or oscilloscopes to completely characterize the IMPATT cw characteristics and response to the 100 nsec radiation pulse. The d.c. bias current was supplied by a variable voltage power supply through the circuit shown in Fig. 2. The circuit provides a method of measuring the diode bias voltage change during the radiation pulse and has a 300 R source impedance up to a frequency of 50 MHz. This is necessary to assure a bias circuit pulse impedance high enough so that the bias current remains constant during the radiation pulse. 3.
EXPERIMENTAL
RESULTS
The RF power, oscillation frequency and bias voltage were measured for the silicon and GaAs diodes in the nominal Q cavity and for the silicon diode mounted in the high Q cavity for various bias currents and radiation dose rates. Results indicate that the radiation induced leakage current decreases the diode output power and increases the frequency of oscillation. Figure 3 gives typical output of the measurement apparatus for a 100 nsec radiation pulse. The diode output power returns to its original level within 50 nsec following the radiation pulse, indicating the absence of significant carrier trapping. The apparent delay between pulses is merely due to differences in triggering in dual beam oscilloscopes. In fact no measureable delay exists between the radiation pulse and onset of the diode response. Figures 4 and 5 give the diode output power in the nominal Q cavity for the silicon and GaAs diodes during the radiation pulse for various dose rates and bias currents. The fitted curves are used later to facilitate comparison with the theoretical
diode bias circuit.
results. Figure 6 gives similar results for the silicon diode in the high Q cavity which exhibits output power saturation at high bias currents with no radiation. The change in frequency due to the radiation pulse is given in Figs. 7 and 8 for diodes A and B in the nominal Q cavity. The data given is the difference between the measured frequency during the radiation pulse and the cw frequency at the bias current shown. Again. the fitted curves are for later theoretical correlation. The frequency shift of the silicon diode mounted in the high Q cavity was so small that the change in cw frequency with bias current obscured the data for all except the highest bias current. The frequency shift during the radiation pulse is reduced by a factor of about 3 in the high Q cavity compared to the frequency shift for the same diode in the nominal Q cavity. 500 1
Dose
rate
(rads
40
53
/set
Y IO’)
1 30
BIOS
60
current,
70
80
mA
Fig. 4. Output power vs bias current for various radiation dose rates, diode A in the nominal Q cavity.
IMPATToscillators
500 r
Dose Dose
rote
(radslsec
rate
(rods
/set
x IO91
x IO’)
14
ZeK,
0.5
/;j’, o-3
0
//
0
o-95
,J
/o’2
I.5
3.4
40
50
60
70
/
// -.J’
/i
40
50
BIOS
60
current,
70
rote
(rods
Bias
current,
mA
shift during the radiation A in the nominal Q cavity.
pulse,
diode
mA
Fig. 5. Output power vs bias current for various radiation dose rates, diode B in the nominal Q cavity.
Dose
Fig. 7. Frequency
/set
20 Dose
rote
(rads/sec
x10’)
r
x log)
0.95
Zero
/
0 0
/
60
0
o 0.3
0 /
OL’!do BIOS
Fig. 8. Frequency 30 BIOS
40 current.
xl
60
510 6io current,
;o
mA
shift during the radiation in the nominal Q cavity.
pulse, diode B
mA
Fig. 6. Output power vs bias current for various radiation dose rates, diode A in the high Q cavity.
The voltage across the IMPATT diode during the radiation pulse was measured to monitor the change in bias current through the diode. The net change in diode current was found in all cases to be less than 2 mA. In no case could the change in bias current have caused an RF output power reduction of more than five percent of the measured decrease at the highest bias current and of more than 10 per
cent at the lowest bias current at which diodes were tested. The change in frequency of oscillation due to the decrease in bias current was less than 10 per cent of the measured frequency shift at the maximum bias current used for both diodes and at worst 30 per cent for the lowest bias current for which data is presented. 4.
THEORETICAL
Complete model In this section
DIODE
an extension
MODEL
of the large signal,
P. E. COTTRELL, J. M. BORREGOand R. J. GUTMANN
6
IMPATT model proposed by Mouthaan[3,4] will be used to characterize the IMPATT diode with leakage current. The model derived is circuit oriented. that is composed of identifiable circuit elements. With this approach, the large signal effects of leakage current can be easily evaluated and interpreted without obscuring the device physics. A one sided Read [ I I] structure is assumed and the resulting equation which describes the avalanche region particle current and its limitations is well established[l2-141
The component is
of avalanche
current
at frequency
w
L(t)
(8)
= iI sin (wt) - i2 cos (wt)
where i, = 21,M
xk
(3) and where I,, is the avalanche particle current, I, is the leakage current, 6 is the effective ionization rate, W,, is the avalanche width, and u, is the saturated carrier drift velocity. The effective ionization rate, is described by 6 = cu,,+ cu’E,,
(4)
where E,, is the RF electrical field in the avalanche region and LY’is the derivative of the ionization rate with respect to the electric field. If the time dependent voltage across the avalanche region is a single frequency sinusoid. V,,(t) = V,, sin wt
(5)
the steady state, avalanche particle current I,,(t) can be found by solving equation (3) with (4).
(IO)
I.
The total current in the conduction current due to between two parallel plates the displacement current voltage
drift region L(t) is the a space charge moving at constant velocity and due to a time varying
i,,(r) = I,$++e !~,,~“rl~,,l’
MWT<, X cos (kwt) + k2 sin (kwt)
I
M
where
I
is
the
multiplication
l-w \ 1 I~ ” cxcldx , u!,, is the normalized
J
factor
II
(‘3 M=
J,M
Id(r) = - ii sin (wt) - LCOS (wt) + Cd %
avalanche
0 ! t region voltage L’,,= (Y’V,,/WT~~.r,, is the avalanche transit time r,, = W,,/u\,and the 1;s are modified Bessel functions of the first kind. When the bias current i is supplied by a current source it is independent of the RF voltage and can be found by considering the d.c. component of the avalanche current
i =
where Wd is the length of the drift region, Cd is the drift region capacitance and Vd is the voltage across the drift region. Substituting the fundamental component of I,(t) into equation (I 1)
(7)
(12)
where
i, =
_
ii
sin (WTd)
+
iz
SinZ
~
2 OTd i-i 2 t
SinZ 3 sin (07~) i 2 > i4= i, + 120 07d 0 2
J
(13)
(14)
IMPATToscillators
7
and 7d = Wd/ve. With the addition of the displacement current through the avalanche capacitance, C,, a complete steady state, circuit model for operation of an IMPATT diode at angular frequency o has been derived and is shown in Fig. 9(a). Although the model is complicated, it is instrucive to see what effect each current generator has on IMPATT diode operation. Current generator iI increases in value with increasing leakage current and represents an ohmic loss in the avalanche region. Current generator iz represents the avalanche inductance of the IMPATT diode which decreases slightly with increasing leakage current. The negative resistance of the circuit is derived from generator ii. Its value decreases with increasing leakage current and thus reduces the RF voltage and output power. Current generator i4 decreases the capacitive susceptance of the diode with increased leakage current. This has the effect of increasing the frequency of oscillation with increasing leakage current. In the case of the leakage current approaching zero, this circuit model is identical to the circuit model derived by Mouthaan[4]. In the small signal case with leakage current the model reduces to that of Sanderson and Jordan[lS].
can be truncated for k > 1 with little loss of accuracy. With some algebraic manipulation equations (7), (9), (lo), (13) and (14) become
Approximate model Simplification of the model can be easily achieved by assuming a leakage current much smaller than the bias current while retaining the large RF voltage level. Since Zk(x) > L+,(x) the summation terms in the expressions for the current generators of the model decrease at least as fast as (kw~,M/2) ~I. For reasonable values of normalized avalanche voltage, avalanche transit time and leakage current the current generator expressions
Further simplification can be achieved for reasonable physical parameters and operating conditions. The displacement current through the junction capacitance is much greater than the reactive currents produced by avalanche dynamics. Elimination of the reactive current generators give the circuit shown in Fig. 9(b). Thus, the simplified model consists of only one active element with the parameters given by equations (IS), (lg), (20), and
z= Z,MZ$2V,)
(15)
i, = 2Z/3 cos 4 sin 4
(16)
iz = 2Z/3 co? 4
(17)
i, = 2Z/3 cos 4
sin C-1 2 sin
(-1 WTd 2
w7L ( 2
(18)
41
i4 = 2Z/3 cos 4
(19)
WTd
(-) 2 where
cot 4 =-
MWT” 2
(20)
and p=- Z1(2U”) Z0(2v, )’
(21)
(21). 0 +
V V
I
Fig. 9(a). Complete
IMPATTdiode
I
0
circuit
model.
Fig. 9(b).
Simplified
IMPATT
4 diode circuit
model.
8
COTTRELL,
P. E. The models
derived
do not account field
by
the
saturation
RF
voltage
approximation calculation
They
and
as
thus.
power
depletion
width
rate precludes
the
of the change in d.c. diode voltage
of the ionization
due
to rectification
of the RF current
variation
of
However,
the principal
ionization
on the performance oscillation
rate
by the nonlinear
with
effects
held. current
of IMPATT
diode
parameters
are well described
electric
of leakage
Fig. IO. Simplified RF circuit model
by these large signal
models. Evaluation
of the simplified
X-band
silicon
the simplified
complete output
model (Fig. 9(b)) and
model (Fig. 9(a)) was carried
the complete show
model power
IMPATT
model
for
out for a
diode.
Results
in agreement
prediction
at leakage
of the
current
At
higher
densities to the
leakage
the difference increasing
truncated
from
equation
influence
of
the complete
quently.
diode
RF
below
bias
I
the predict
large due terms
The
measured diode
the
leakage
current
buildup
of the avalanche
timing
is not
agreement
particle
a
causes
current
maintained.
and thus optimum
These
results
arc
in
with those of Misawa[l6]. (‘OMPARISON
OF
In order calculate diode
with
RF
enhanced
sary to consider connected in
output
leakage
obtained
from
10
inductance.
L.,
where R,
the
to
in the nominal
package
resistance,
is represented
and R, I-
by
correctly with
predicts
The package capacitance
C,, was neglected
expected
inductance
current
almost
series
resonant
with
the diode
L,
is
capacitive
Once the microwave diode performance can he predicted ties
measurement impedance function
for
condition.
at which
circuit impedance
according a given
diodes
or theoretical of
a
diode
Unfortunately
IMPATT typical
of frequency
is known.
to the derived structure
and
at the frcquenare
prediction oscillator
is extremely
model
most
useful,
of the RF circuit
difficult.
as a In this
and for
as no saturation
the
the silicon Compari-
diode
current
and
for the silicon
nominal Q cavity
Q cavities
and
power-
saturation levels fat
This is to be
effects except for leakage agreement
measured
output
of output
for the power
for the model.
quantitative
KF
.A\ can be
between
power- with
the
Icakage
diode
in both the high and
GaAs
diode in the nominal
is quite good.
The fr-equency
shifts measured
during the radia
tion pulse are more than an order of magnitude than can be predicted reactance
are GaAc
show that the theory
variation
except
were considered
predicted
susceptance.
operating
seen.
with
and the
current
shown at the highest hias current
case
package
leakage
the silicon diode in the high Q cavity.
in this
the
current
and measured
the
hias current
effects
previ-
power
respectively.
power with no leakage current
the
of RF
cavity
of Fig. 9(a)
This is shown
1.
I I-13 for the silicon and
diode in the high Q cavity.
jX, (0).
since
with
cry’,WI\
assumptions
model with no leakage model
data1 171.
[ IX]. The value of the
the prediction
diode
bias. The
( W,,. W,,) were
coctlicient.
and
circuit
circuit.
reverse
are listed in Table
in Figs.
diodes
work
W,
of the diode current
width
son of the predicted
parasitic
circuit
model IMPATT
in
data.
width
and Haddad’s
parameters
discussed
complete
depletion
with
region
it is neces-
represents
the total
microwave
diode of the
en-
given
from published
and total
of the ionization
parameters
Using
plotted
with
A. W,,. W,,. CY’ and r, were
Schroeder
The derivative above
to
subse-
described
development
current.
the equivalent
to the microwave
Fig.
the
power
AND
RESLITS
to use the theoretical the
the
variation
ously
THEORETIC-\L
EXPISRIhIENT.41~
A
and drift
Mouthaan’s 5.
by
taken from Goedhloed‘s
premature
performance
by evaluation
avalanche
due to the finite leakage current.
used
and,
This procedure
were determined and capacitance
the peak to peak avalanche
were
impedance
or calculated
area
of
fixed.
current.
characteristics
,4.
of
is reduced
circuit
is justified
either
output current
the diode
leakage
Appendix
power
leakage
RF
Evaluation
current
RF
The diode parameters
current
summation
model.
determine hanced
up to
in results become
insignificant
(6) shows that with the d.c. component
current Also,
or
the diode
with
the
levels
current
work.
with
per cent of the bias current densities of 500 A/cm’or less.
GUTMlNh
R. .t.
[ 141 are not modeled. The use of a linear
modulation
typical
and
of the d.c. electric
swing
such
BORREGO
M.
here have limitations.
for perturbation
effects
J.
during the radiation
I,C tuned circuit
less
from the change in the diode pulse using
:I
simple
model. This simply means that the
IMPATT
9
oscillators
500 r
Leakage 400
current
(mA)
/
-
Zero
Data Theory
---
300% i al
i
a,
zoo-
z a
5 a
:
::
60
40-
IOOzo-
BIOS
current,
mA
Leakage
400
current
(mA)
/
”
/,
40
30
Fig. 1 I. Comparison of theoretical and experimental variation of output power with bias current, diode A in the nominal Q cavity.
Doto ---Theory
alas
Fig. 13. Comparison of theoretical variation of output with bias current, Q cavity.
alas
current,
mA
nominal
Q
cavity.
waveguide cavity tends to stabilize the frequency of the diode with a rapidly varying reactance with frequency. For small frequency deviations, Ao, from the angular frequency oo, the RF circuit reactance can be expressed as X(o)
= X(w) + X’(w,,)Aw
50
60
mA
and experimental diode A in the high
where X,,(w,J is the cavity reactance at the cw oscillation frequency and X’(w) is the rate of change of cavity reactance with frequency. Since the diode susceptance is largely due to junction capacitance it can, to first order, be considered linear with frequency. Using the fact that the diode reactance is approximately equal in magnitude to the lead reactance, wL,, the fractional oscillation frequency shift can be found from the circuit
AW -= WI,
Fig. 12. Comparison of theoretical and experimental variation of output power with bias current, diode B in the
current.
AXz, X‘l 3 + X’(& T
(22)
where AXd is the change in diode reactance due to the enhanced leakage current and XI is the diode reactance with no leakage current. The theoretical curves shown in Figs. 14 and IS have been calculated using equation (22) developed from the RF circuit model shown in Fig. IO and a value of X’/L calculated from one frequency shift data point taken at one radiation dose rate and RF output power level for each diode. The resulting values ranged from 10-30. It can be seen that indeed the diode frequency shift due to enhanced leakage current is proportional to the change in diode reactance and that the proportionality constant is on the order of 10. Although the equivalent
P. E. COTTRELL, J. M. B~RREGO and
I0
lated
40
current
Leakoge
(mA)
R. J.
GUTM.~NN
by irradiation
energy irradiation
-
Data ---Theory
hole-electron The
high
current
during
current,
mA
Fig. 14. Comparison of theoretical and experimental frequency shift with leakage current, diode A in the nominal Q cavity.
diode
Comparison
power
as a function
show
good
for the GaAs
current
(ma)
diode
agreement 0.64 /
/
/
/
/
/
/
/
/
/
02
/’ /
BlQS
mA
current,
Fig. 15. Comparison of theoretical and experimental frequency shift with leakage current, diode B in the nominal Q cavity. of the disc and post waveguide
circuit
not been derived
from
analysis indicates
that the proportionality
obtained within
are
the
first principles,
reasonable[l9].
limits
of experimental
The
cavity
has
a simplified constants
agreement
is
error.
6. SUMMARY
The major an IMPATT in
RF
effect of enhanced
leakage
current
in
diode has been shown to be a decrease
power
oscillation.
and
Enhanced
an
increase leakage
in
frequency
current
of
the
and predicted
testing
RF
between
current and
experiment
and silicon diodes mounted The
high
results
cavity
are
effects
The
in
qualitative
dominate
measured
is proportional change
to the constant analysis
at the
oscillation predicted
due to enhanced
;I qualitative
in
for the silicon
leakage that is in
of
the RF
REFERENCES
,/’
/
parameter%
and leakage
a proportionality
with
current.
D. Decker. C. Nunn and H. Frost. IEEE ‘Trc~r~,\. Electron Deuices ED-l& 141 (1971). 3 ‘1‘. Misawa, Solid-Sr. Electrorl. 13, 1369 (1970). -. 3. K. Mouthaan. Phil. Rcs. Rrp. 25. 31 (1970). IEEE Trctns. MicrowcIw Theorq cutd 4. K. Mouthnan, Techniques. MTT-IX, 853 (1970). 5. T. Cameron. N. Suntharalingam and C;. Kcnncy. ThermolL~minescrnt Dosimetry. University of Wi\consin Press (1968). E#ect.s ;,I Srmic.orltllrc.to,- Drricuc. 6. Larin, Radiution Wiley, New York (1968). 7. C. Klein, J. uppl. Phvs. 39. 3029 (1968). 8. T. Misawa and N. D. Kenyon, IEEE Trtrns. Microwctoe Theory urtd Techniques MTT-18. 969 (1970). 9. R. Chaffin. IEEE 7’run.s. Nucleur Science NS-1X. 436 (1971). fEEE Tmm. Microwc~w Theory md IO. R. Mohn. Techniques MTT-11. 263 (1963). I I. W. T. Read, Bell Spst. Tech. J. 37. 401 (IY%). Lee,J. uppl. Phys.41, 1743 (1970). 12. R. KuvasandC. 13. J. Nigrin. Proc. IEEE 60, 916 (1972). and G. Haddad. IEEE Proc. 61. 153 14. W. Schroeder (1973). and A. Jordan, Solid-St. Electron. IS. 15 A. Sanderson 140 (1972). Electron. 13. 1363 (1970). 16. T. Misawa, So/id-St. and G. Haddad, IEEE Prw. 59, 1245 17. W. Schroeder (1971). Solid-Sf. Eleclron. 15. 635 (1972). 18. J. Goedhloed, Ph.D. di\s. Rensselaer Polytehnic lnstiI9 P. Cottrell, tute. Troy. New York (1973). I
/’
with
diodes were
circuit.
/
/
shift
reactance
current
-Data ---Theory
of bia\
currents.
the
leakage
or
of this model were derived
but saturation
bias
frequency
the
region
from
of a model proposed
electrical
Q cavity.
of
pulse.
leakage
agreement
in
pairs
photo
of measured
theory
mounted
depletion
and structural
non-destructive
higher Leokaqe
to include electrical
diode\.
the nominal
distribution
effects in IMPATT
for evaluation
agreement
the a
the radiation
diode\ The high
the semiconductor.
ionized
by an extension
by Mouthaan necessary
in
the
creating
current
characterized
from
field
sweep
volume
Leakage
The
ionizes a uniform
electric
depletion
IMPATT electrons.
pairs throughout
continuously
BIOS
of operating
with 100 nsec pulses of 10 MeV
was
of
simu-
11
IMPATToscillators APPENDIX
Relationship between RF circuit output characterizution
A
impedance
ment of the oscillation starting current, oscillation frequency and RF output power at a known bias current can be used to determine the RF circuit impedance at frequency w. This has been done for the diodes used in this study and the results are given in Table 3. In general, the characteristics with enhanced leakage current can be predicted by a solution of the tuning conditions, [equation (Al)], the circuit model (Fig. 9(a)), and the constant current condition [equation (7)], for a given diode and operating point. This involves, however, the simultaneous solution of three coupled, transcendental equations with three unknowns. However, certain simplifications can be made. Since the diode reactance is largely passive junction capacitance, to first order the diode oscillation frequency can be considered constant as leakage current is varied. Thus, the terms WT,, and ~7~ in the active elements of the model can be replaced by constant transit angles 0, = OG-,, and &, = ti17~. This eliminates one variable (w) and one transcendental equation (X, = - X,) when calculating the diode operating characteristics with leakage current. Furthermore for small frequency deviations the real part of the RF circuit impedance can be considered constant and the value derived from the cw measurement previously described can be used to find the diode operating characteristics with leakage current. Solving the tuning condition for a fixed frequency and RF circuit resistance for the simple model with leakage current in Fig. 9(b) gives the following result for a diode with enhanced leakage current
and diode RF
The IMPATT model can be related to the RF circuit by solution of the tuning condition equationl4J Z,, = - Z,
= ~ (R,%+ R, + jX, ).
(Al)
When this expression is evaluated for the diode with no leakage current, the results relate the normalized avalanche voltage to the physically measurable oscillation starting current I,,.,,, and the bias current 1141
of RF where I..,,,,, is a function electrical and structural parameters, RF circuit impedance
frequency, the diode and the real part of the
(A3
where Q = [WC, (Rs + R, )J-‘.
(A4)
The reactive part of the circuit impedance determines the frequency of oscillation which in this case is independent of the RF voltage and bias currentf41
c,, - = cos $J P
This equation with equation (20) can be solved simultaneously with equation (15) for D, and M. The diode output power, P, with enhanced leakage current can now be calculated as it is proportional to the square of the normalized voltage. The RF output power P at a bias current I is
Measurement of the oscillation starting current and the frequency of oscillation for a diode with known electrical and physical parameters, therefore, determines the total load RF resistance, R, + R ,, and the load reactance X,,. The RF output power is given by[4]
P P,=
If the RF output power is also measured for a given bias current, the RF load resistance, R,. can be determined from equations (A?). (A3) and (A6). Thus, the measure3. Derived
and measured
((3%~) (2x1 Diode A Nominal Q Diode B Nominal Q Diode A High Q
tj”> (G 1
where P,, is a measured reference power at reference current I,, v,,
(A6)
Table.
(A7)
diode operating
parameters
I,,
P,,
R,_ + Rs
R,.
X0
(mA)
(mW)
(a)
(fl)
(fi)
IO.6
33.5
63
324
1.98
I.17
- 40.0
8.9
32.0
64
316
I.91
1.88
~ 25.8
9.8
22.5
44
68
I ,57
0.285
- 42.4
12
P. E. COITRELL, J. M.
BORREGO and R. J. GUTMANN
above calculation can be easily done by hand as only a few iterations are necessary to solve equations (A7) and (15). The calculated value of normalized avalanche voltage can now be used to find the values of the current generators, actual avalanche voltage. and the diode impedance. If the change in transit angle is small, the increase in oscillation frequency due to enhanced leakage current can now be calculated from the change in diode impedance if the variation of RF circuit impedance with frequency i\ known a\; the tuning condition must be still met. The model described by Fig. 9(a) and equations (7). (9). (10). (13) and (14) can be evaluated by iterative ~imultaneoux solution or by systematic evaluation. If again the frequency shift is considered small. the real part
of the RF circuit impedance is considered constant and the use of the transit angles 0,. and (Id simplify the calculation of diode impedance. Assuming the RF circuit resistance constant with frequency the value of the real part of the diode impedance with no leakage current can be matched to the calculated diode impedance with leakage current. The diode output power is then P = &I<,
*R,
(A%
where I,, is the total diode current. Again the oscillation frequency shift can be calculated from the tuning condition and the evaluated circuit model if the RF circuit impedance as a function of frequency is known. The above procedure is used in calculating the theoretical results presented in this paper.