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3GW8218 08/26/2014 20:43:33 Page 1
EPITAXIAL QUANTUMDOT INFRAREDPHOTODETECTORS
INTRODUCTION
Infrared (IR) radiation, which was accidently discovered
by the musician and astronomer Sir Frederick William
Herschel (1738–1822), has played an ever increasing role
in improving the quality of life in living beings. The
thermometer played a key role in this discovery and can
be categorized as the first-ever infrared detector. However,
more than a century later, World War II paved the way for
the rapid development of the infrared detector technology.
IR detectors are used for various applications from astron-
omy to zoology, for example in the fields of medical diag-
nostics, environmental monitoring, thermal imaging,
military defense and offense, and space research. Early
detectors used naturally existing materials and gradually
developed to include various semiconductor compounds
such as PbS, InSb, and HgCdTe. The epitaxial growth
techniques (1) developed in the 1970s allowed the growth
of various other semiconductor compounds such as GaAs,
InGaAs, AlGaAs, InAs, and InP, promoting the develop-
ment of infrared detectors using the electronic transitions
between quantized states. The strain induced by the lattice
mismatch of the substrate and the epilayermaterials is the
key to the formation of the self-assembled quantum dots
(QDs) (2).
Theoretical predictions (3) of higher carrier lifetimes,
temperature-independent density of states, and reduced
scattering efficiencies leading to reduced dark current in
ideal zero-dimension devices due to the carrier confine-
ment increased the interest of quantum dot structures to
be used as detectors. Quantum dot infrared photodetectors
(QDIPs) employ self-assembled InAs/GaAs (QDs) in the
active region and represent an emerging detector technol-
ogy. QDIPs exploit three-dimensional confinement of car-
riers and atom-like discrete energy states in quantum dots
to achieve low dark-current levels, high operating temper-
ature, 10–100 times longer carrier lifetimes, and normal
incidence photoresponse. There are several reports on the
enhancement in QDIP performance using novel hetero-
structure designs, most of which chiefly rely on barrier
engineering. Some of these include AlGaAs (4, 5) and
InGaAs (6, 7) barriers, development of an AlAs/InAs/
GaAs QD superlattice structure, (8) submonolayer (ML)
QDs, (9) tunneling QDIP structures (10, 11), the dot-in-a-
well (DWELL) recipe (12), dot-in-double-well heterostruc-
ture (13), confinement-enhancing (CE) barriers (14), and
quaternary InAlGaAs capping with uncoupled InGaAs
QDs (15). Several researchers have attempted to realize
a multispectral response in a quantum well (QW) hetero-
structure (16), a dot-in-well photodetector (17), an InGaAs/
GaAs-based QD intersubband transition (18, 19), and
other devices. However, QDIPs that simultaneously oper-
ate over a broad spectral range and provide superior
performance are not always obtained.
In comparison with quantum well infrared photodetec-
tors (QWIPs), additional degrees of confinement in QDs of
QDIPs lead to threemajor advantages (20): 1) sensitivity to
normal-incidence radiation, which is forbidden in n-type
QWIPs due to polarization selection rules; 2) compara-
tively long (hundreds of picoseconds) effective carrier life-
times, which has been predicted by theory (21) and
confirmed by experiment (6); and 3) low dark current.
Hence, QDIPs are expected to show improved performance
characteristics such as high responsivity, high detectivity,
and high operating temperatures. The dark current of the
QDIPs has been further reduced using the resonant tun-
neling concept. In addition to the aforementioned advan-
tages, QDIPs show improved radiation hardness (22, 23)
and polarization-sensitive spectral responses (24, 25).
Although the potentials and benefits of QD-based struc-
tures as photodetectors have been identified, several areas
still need to be understood and developed. One of themajor
problems associated with QD-based devices is related to
the QD size and shape, which play a major role in QDIPs.
The growth of QDs is a self-assemble process that results in
an unintentional size fluctuation. In general, the size
fluctuation of QDs negatively affects the electrical and
optical properties of the detectors (decreasing absorption
coefficient and increasing dark current), limiting the over-
all performance (26).
QDIPs ranging from single-element detectors (17,
27–31) to focal plane arrays (FPAs) (32–34) have been
demonstrated, whereas operation at temperatures above
77K (7, 28, 35–39) indicate the possibility of developing
uncooled IR imaging systems. In a recent publication,
Matthews et al. (40) reported long carrier lifetime of
3–600 ns for a DWELL detector, which also exhibits a
photoconductive gain of 104 to 105 in the 20–100K tem-
perature range. QDIPs are being developed, in addition
to InAs/GaAs (or InGaAs/GaAs) material systems, using
SiGe/Si (41–43) and GaN/AlN material systems (44). The
behavior of QDs under an applied magnetic field (45, 46)
has recently become a point of interest to understand
physical mechanisms of QDs as well as future spintronic
devices. The spin of an electron in a QD can be used as a
qubit (47–50) for quantum information processing.
In general, an IR detector or a focal plane array camera
captures the intensity profile of the scene. However, if the
information of the scene can be captured using two or more
spectral bands, it would be useful to reconstruct the com-
plete thermal profile of the scene and reduce false posi-
tives. Hence, the development of detectors with multiband
characteristics and the ability to select spectral bands will
immensely aid various applications including land mine
detection, missile-warning sensors, identification of muz-
zle flashes from firearms, and space situational awareness.
QDIPs have become a potential choice for multiband detec-
tion applications as multiple electronic transitions in QDs
can facilitate such a detection capability.
THEORETICAL BACKGROUND
Calculation of Energy States in Quantum Dots
A substantial amount of theoretical work (51–56) has been
carried out to solve a three-dimensional (3-D) confined
J. Webster (ed.),Wiley Encyclopedia of Electrical and Electronics Engineering. Copyright# 2014 John Wiley & Sons, Inc.
3GW8218 08/26/2014 20:43:33 Page 2
quantum mechanical system, such as QDs. Finding solu-
tions for a hypothetical 3-D system is complicated but
achievable with high accuracy. However, the QDs formed
by a self-assembled process, having odd shapes, introduce
many complications for modeling. These complications
become more challenging when the stress, primarily
resulting from lattice mismatch, is involved, which in
general plays a role in the formation of QDs in the self-
assembled process. Hence, the existing theoretical models
involving complicated calculations will always present a
high uncertainty in the results. The most commonly
reported model for solving the energy spectrum of QDs
is the eight-band k.pmodel (51). This model uses the strain
in the QD, calculated using the valence force field (VFF)
model, which has been successful in calculating the strain
tensor in self-assembled QDs.
Although the calculation of the band structure and
energy states in QD system is useful to determine potential
device designs, the investigation of optical properties of a
QD system is also invaluable. The intersubband absorption
coefficient of a photon with energy �hv in a QD layer can be
expressed as (28) follows:
að�hvÞ ¼ pe2�h
e0n0cm20Vav
1
�hv
X
f i
a � pf i
�
�
�
�
2Nð�hvÞ (1)
where Van is the average QD volume, a is the polarization
of the incident light, pfi is the momentum matrix element
between energy states, andN(�hv) is the electron density of
states. Considering a Gaussian inhomogeneous broaden-
ing caused by the large fluctuation in QD size, N(�hv) is
given by N(�hv) ¼
Nð�hvÞ ¼ 1ffiffiffiffiffiffi
2pp
sexp � Ef i � �hv
� �2
2sð Þ2
!
(2)
where Efi is the energy separation between states and s is
the line width of the transition. The momentum matrix
element is calculated from the QD wavefunctions, which
can be obtained from the eight-band k.p model. The spec-
tral response of a QD-based detector is characterized by
peak wavelength (lp), peak responsivity (Rp), and the peak
quantum efficiency (QE, hp). Responsivity is given by R¼qhl/hc, where q is the electron charge, l is the wavelength,
h is the Planck constant, and c is the speed of light.
Quantum efficiency can be calculated from the absorption
coefficient and the thickness of the absorption region.
Apart from this method, several other approaches were
tested for solving a QD-based system. For example, an
energy-level calculation model for a DWELL system was
proposed by Amtout et al. (52). DWELL structures with
different QDs have been tested experimentally, and elec-
tronic spectra obtained by themodel are in good agreement
with the experimental results (52). The pyramidal shape
QDs have been confirmed by transmission electron micros-
copy. The Hamiltonian of a system with a quasi-zero-
dimensional QDplaced in a two-dimensional QW is defined
with a potential energy consisting of four terms: the poten-
tial in the QD region, the potential in the QW region, the
potential in the barrier region, and the potential from the
applied electric field. The eigenfunctions of the Hamilto-
nian are derived using a Bessel function expansion. The
DWELL detectors tested by Amtout have QDs with base
dimensions of 110 and 140A�and heights of 65 and 50A
�,
respectively. The energy spacing between the first and
second energy levels obtained from the model for the
two samples are 132 and 150meV, whereas experimental
analysis showed energy spacing of 123 and 140meV,
respectively. Although the energy states are shifted by
the electrostatic potential from the bias field, the energy
spacing between the first two energy states was not
changed significantly by the applied electric field. This
can be observed in the spectral response of many DWELL
detectors (17, 57).
Using these theoretical models, QDIPs can be designed
using the transitions of carriers between QD states. Sim-
ply, the energy spacing between QD states is adjusted by
varying the QD size, shape, and thematerials of the QD, as
well as the barrier. However, for the design to be realistic,
growth limitations, particularly the QD size, will have to
be taken into account. The most common size possible has
base dimensions of �20nm and a height of �6nm. Hence,
tailoring the operating wavelength by changing the QD
size is practically limited. Nonetheless, there is an
increased interest in growing different size QDs, and
any successful achievement would be beneficial for future
QDIP development. Keeping the growth possibilities
restrained at the current level, there will also be alterna-
tive approaches to tune the transition energy states to
achieve the desired operating wavelength. One of these
approaches is the use of intersubband electron transitions
in QDs (58), and the other approach uses resonant tunnel-
ing (10) to block the dark current selectively without
blocking the photocurrent.
Dark Current and Detectivity
Aiming for high-temperature operation, a theoretical
assessment of QDIPs, comparing QDIPs with other avail-
able detectors, has been recently carried out by Martyniuk
et al. (26). Assuming that the detection is the result of
thermal generation of carriers within the active region, the
dark current and detectivity of QDIPs are calculated using
the model proposed by Ryzhii et al. (59, 60). The 3-D
quantum confinement of electrons in QDs is the key to
increasing the lifetime and reducing the dark current,
which consequently makes QDIPs a potential choice for
high-temperature operation. A typical QD structure
consists of a number of QD layers, which are indexed as
k¼ 1, 2, . . . , K. Then, the average value of dark current
density across the entire structure, as a result of carrier
trapping into the QDs and thermionic emission from QDs,
is expressed as follows (26):
hJdarki ¼ qX
QD
Gk
pk
(3)
where SQD is the dot density, Gk is the rate of the electron
thermoexcitation from QDs in the kth layer, pk is the
capture cross section, and q is the electron charge. As
shown in Figure 1(a), the calculated dark current of QDIPs
2 Epitaxial Quantum Dot Infrared Photodetectors
3GW8218 08/26/2014 20:43:33 Page 3
is more than an order of magnitude lower than that of
HgCdTe (MCT) detectors in the 200–300K temperature
range. In this figure, the 300K background photocurrent
for a field of view (FOV) of 2p is shown for reference.
Martyniuk et al. (26) have also calculated the thermal
detectivity of QDIPs, which is expressed as follows:
D� ¼ h
2hnffiffiffiffiffiffiffiffi
Gth
p (4)
where h is the quantum efficiency, h is the Planck con-
stant, and n is the frequency of light. A similar trend for
detectivity can be observed as shown in Figure 1(b). The
calculated quantum efficiency of QDIPs is significantly
higher than that of MCT detectors within the temperature
range from 200K to 300K. However, the experimentally
demonstratedQDIPs show lowerD� values, represented by
solid symbols, indicating the predicted level of perform-
ance has yet to be reached.
Size of Self-Assembled Quantum Dots
InQDIPs, the size of QDs plays amajor role, particularly in
determining the response wavelength (frequency) range.
However, with the current growth techniques, it is not
possible to obtain QDs with any size as desired. The typical
size of the near-pyramidal InAs/GaAs self-organized
QDs (17, 36) is �60–70A�(height)/�200–250A
�(base)
with QD density varying between 5� 1010 cm�2 and
10� 1010 cm�2. For In0.4Ga0.6As/GaAs QDs (10), the typi-
cal height and base are 60 and 200A�, respectively. The
electron intersublevel energy separation in these QDs
ranges between 40 and 80meV. As reported (24), the
height of the disk-shaped QDs can also be as narrow as
25A�in the growth direction (height), whereas the base
remains around 180A�. Hence, the confinement along
the growth direction is strong, whereas the in-plane
confinement is weak. As reported by Su et al. (61), the
growth of smaller QDs (40A�of height and 130A
�of width),
leading to a large energy spacing (�124meV) between the
QD ground and first excited states, is also possible with
InAlAs/GaAs material combination. In such QDs, the
intersubband transitions between lower QD states lead
to shorter wavelength detection, whereas the transitions
from the upper states (particularly in T-QDIPs) lead to
longer wavelength detection (61). Smaller QDs also pro-
vide a large QD density for the same amount of adatom
change, which increases the absorption coefficient.
MULTIBAND DOTS-IN-A-WELL (DWELL) INFRAREDDETECTORS
In a typical DWELL structure (7, 17, 31, 52, 62–65), InAs
QDs are placed in a thin InGaAs QW, which in turn is
positioned in a GaAs matrix. The DWELL heterostructure
provides strong confinement for carriers trapped in QDs by
lowering the ground state of the QD with respect to the
GaAs band edge, resulting in low thermionic emission.
There can be one or more confined energy states in the
QD, with the position and separation of energy states
dependent on the size of the QD as well as the confinement
potential. The detection mechanism of a DWELL detector
involves the transitions of electrons from the QD ground
state to an excited state in either the QD or QW. Energy
states associated with the QW can be bound, quasi-bound,
or part of the continuum. These different possible transi-
tions lead to multicolor characteristics. A schematic dia-
gram of the conduction band (CB) profile of a DWELL
structure is shown in Figure 2, along with different tran-
sitions between energy states as indicated by the arrows.
The photocurrent, a result of the photoexcitation of carri-
ers, is proportional to the product of the oscillator strength
and the carrier escape probability. A response peak
Figure 1. (a) Comparison between the dark current density of HgCdTe photodiodes and QDIPs as a function of wavelength. Thebackground-generated photocurrent is also shown. (b) Calculated detectivity (D�) of QDIPs andHgCdTe photodetectors at 200K, 250K, and300K temperatures. Background-limited detectivity (FOV¼ 2p, TBLIP¼ 300K, and h¼1) is also shown for comparison. The symbolsrepresent experimental data gathered from literature and data from commercially available detectors (see Reference 26 for details). After
Reference 26.
Epitaxial Quantum Dot Infrared Photodetectors 3
3GW8218 08/26/2014 20:43:34 Page 4
resulting from a bound-to-bound transition has stronger
oscillator strength and a smaller escape probability than a
response peak resulting from a bound-to-continuum tran-
sition. However, the escape probability can be increased by
applying an external electric field. Hence, a bound-to-
continuum peak can be observed even at low biases,
whereas a bound-to-bound peak dominates at high applied
fields because of the enhanced escape probability by field-
assisted tunneling. The energy states in the QD and the
QWcan be adjusted independently by changing the param-
eters associated with each. As a result, DWELL structures
open up a variety of possible designs, leading to multiband
IR detectors. In this section, three-color InAs/InGaAs
DWELL detectors with different well widths are discussed
as previously reported by Ariyawansa et al. (62) Three
DWELL detectors (labeled as DWELL1, DWELL2, and
DWELL3) with different well widths (90A�, 110A
�, and
120A�, respectively) were studied and reported. These
detectors showed response peaks at three distinct wave-
lengths in the mid-wavelength infrared (MWIR), long-
wavelength infrared (LWIR), and very-long-wavelength
infrared (VLWIR) regions.
DWELL Device Structure
The DWELL detector structures reported by Ariyawansa
et al. (62) (DWELL1, DWELL2, and DWELL3) were grown
(66) in a VG-80 solid-sourcemolecular beam epitaxy (MBE)
system with a cracked As2 source at the University of New
Mexico. The GaAs layers were grown at a substrate tem-
perature Tsub¼ 580�C, whereas the In0.15Ga0.85As QW and
the InAs QDs were grown at Tsub¼ 480�C. The tempera-
ture was measured using an optical pyrometer. Using
standard lithography, metal evaporation and wet etching
techniques, n� i�n detector mesas were fabricated for
top-side illumination. Mesas with various circular opti-
cally active areas (diameters ranging from 25–300mm)
were fabricated to test for leakage current and uniformity
of structures. A more detailed discussion on the growth
process can be found in Reference 66. The structure of the
DWELL3 detector is shown in Figure 3. The QDs were
doped n-type with silicon to a sheet density of
5� 1011 cm�2, which corresponds to about 1 electron per
QD. The QW was not intentionally doped. It has been
found (65) that the optimal doping concentration for
DWELL detectors corresponds to about one electron per
QD. The size of the QDs is a critical parameter in the
detector design and is controlled by growth conditions,
especially the temperature and growth rate. Any
inhomogeneous QD size fluctuation will lead to a broaden-
ing of spectral response peaks. The width of the QW, i.e.,
the combined thickness of In0.15Ga0.85As layers, is denoted
byw. The other two detectors (DWELL1 andDWELL2) are
identical to theDWELL3 sample except for thewidth of the
QW. In DWELL2 and DWELL1 detectors structures, the
thickness of the bottom In0.15Ga0.85As layer is 50A�and
30A�, respectively, whereas the top In0.15Ga0.85As layer
thickness is the same (60A�) for both structures, thus
providing a 110 and 90A�well width, respectively.
Figure 2. Conduction band profile of a DWELL structure (a) under zero bias and (b) under negative bias. The energy states correspondingto possible transitions leading to spectral response peaks are indicated by arrows.
Figure 3. Structure of a DWELL detector. The width of the QW,i.e., the combined thickness of In0.15Ga0.85As layers (indicated aswin the figure), is different for each detector. Structures DWELL1,DWELL2, and DWELL3 have well widths of 90, 110, and 120A
�
respectively, whereas all other parameters are the same. After
Reference 62.
4 Epitaxial Quantum Dot Infrared Photodetectors
3GW8218 08/26/2014 20:43:34 Page 5
Effects of the Well Width on Response Peaks
To explain the transition between energy states leading to
response peaks, the experimental results of the three
DWELL detectors reported by Ariyawansa et al. (62) are
discussed. A comparison of dark current voltage (I-V)
characteristics for all three structures is shown inFigure 4.
The sample DWELL3 showed the lowest dark current, and
it increased when the width of the QW was decreased. The
spectral responsivity for the DWELL3 detector under dif-
ferent bias voltages is shown in Figure 5. The band dia-
gram, with corresponding transitions indicated by arrows,
is shown in the inset to Figure 5. The origin of each peak
will be explained in detail in the following sections. The
spectral response of the three detectors in the MWIR/
LWIR regions for�0.5V and�1.4V bias voltages is shown
in Figure 6. All three detectors showed two distinct peaks
in this wavelength range. The DWELL1 detector exhibited
the first peak at �4.2mm and the second peak at �8.1mm.
A semiempirical estimate based on the photoluminescence
spectra with a 60:40 split of the bandgap difference gives a
225–250meV (�4.9–5.5mm) energy separation between
the ground-state of the QD and the conduction band
edge of GaAs. Hence, the 4.2-mm peak is probably a result
of transitions from the ground state of the QD to the
continuum state of the QW, and the second peak is a result
of transitions from the ground state of the QD to a bound
state in the QW, as shown in Figure 2. Moreover, it has
been shown (67) that the line width (Dl/l) of a peak
resulting from transitions from bound-to-bound states is
narrower than that of transitions from bound-to-contin-
uum states. The line width of the 4.2-mm peak is approxi-
mately 42%, whereas the line width of the 8.1-mm peak is
approximately 28%; this observation is consistent with the
aforementioned description. The escape probability of car-
riers excited to a bound state increases with increasing
bias because of field-assisted tunneling. Thus, the bound-
to-bound peak (at 8.1mm) shows a stronger dependency on
the applied bias than the bound-to-continuum peak (at
4.2mm), as evident from Figure 6.
When the width of a QW is increased, the energy
spacing between the states in QW decreases; as a result,
the energy spacing between QD ground state and states in
QW also decreases. Thus, a red shift of the first and second
peaks is observed. The results for the DWELL1 and
DWELL3 detectors confirm this notion. In addition, the
DWELL3 detector exhibits a quasi-bound state close to the
band edge of the GaAs barrier, and hence, the first peak of
the DWELL3 detector is a result of transitions from the
ground state of the QD to the quasi-bound state in the QW.
This can be confirmed by the red shift and the reduced line
width for the first peak of the DWELL3 detector compared
with the first peak of the DWELL1 detector. Based on
width of the QW in detector DWELL2, its peaks are
expected to be located in between the peaks of DWELL1
and DWELL3 detectors. However, the experiment showed
a longer red shift than expected in both the first and the
second peaks of the DWELL2 detector with respect to the
DWELL1 detector. This discrepancy in the result for the
DWELL2 detector could be explained by an unintentional
–2 –1 0 1 2 310
–10
10–8
10–6
10–4
DWELL1
DWELL2
DWELL3
Dark
Curr
ent (A
)
Bias Voltage (V)
T = 4.6 K
Figure 4. A comparison of dark I-V characteristics of threeDWELL structures (DWELL1, DWELL2, and DWELL3) at4.6K. The mesas tested have the same electrical area. The sampleDWELL3showed the lowest dark current and a decrease of darkcurrent is observed as the width of the QW increases. Modified
after Reference 62.
Figure 5. Three color response of DWELL3 detector under dif-ferent bias voltages at 4.6K. Band diagrams with the correspond-ing transitions indicated by arrows are shown in the inset. After
Reference 62.
4 6 8 10 12 140
10
0
5
10
0
1
2
3
248 meVX 5
4.2 µm
8.1 µm
DWELL1
Wavelength ( µm)
248 meV
X 4
9.67 µm6.25 µm
DWELL2
R
esponsiv
ity (
mA
/W)
4.6 K
10.5 µm
6.25 µm DWELL3
–1.4V
–0.5V
Figure 6. The first two peaks of the three DWELL detectorsbiased with �1.4V and �0.5V at 4.6K. Arrows indicate thepeak positions and the “�” sign implies that the curve has beenmultiplied by the specified number. Modified after Reference 62.
Epitaxial Quantum Dot Infrared Photodetectors 5
3GW8218 08/26/2014 20:43:34 Page 6
change in the QD size during the growth process. Further
discussion on this will be given in following sections.
Moreover, several unexplained features in the responsivity
spectra, such as line splitting, were also observed. Based
on doping concentration and sheet density of QDs, it has
been found (31) that a single QD consists of one electron.
Multiple electrons within a QD could lead to a splitting of
photoresponse peaks because of intralevel and interlevel
Coulomb interactions (68). Therefore, the secondary peaks
superimposed on the primary peaks may result from
either different QD sizes in the same DWELL structure
or Coulomb interactions between multiple electrons in
the QD. The expected red shift caused by the Coulomb
interaction with an applied electric field could be compen-
sated by the blue shift caused by the Stark effect (68).
Splitting of absorption peaks is also possible through
interdot coupling (69), which depends on the random
distribution of QDs.
The spectral responsivity of the third peak of detectors
in the VLWIR region is shown in Figure 7. For QDs with a
base diameter of 20nm and a height of 7–8nm, the energy
separation between the ground state and first excited state
calculated from an eight-band k.p model (51) is about
50–60meV. Thus, it is believed that the VLWIR peak is
a result of transitions between two bound states within the
QD. Moreover, the VLWIR peak for DWELL1 and
DWELL3 detectors occurs at approximately the same
wavelength (�23.3mm). Changing the width of the QW
does not affect the energy states in theQD, thus confirming
that the VLWIR peak is a result of transitions between QD
states. However, the VLWIR peak of the DWELL2 detector
appeared at 25.5mm and is red shifted with respect to the
VLWIR peaks of DWELL1 and DWELL3 detectors. This
observation was attributed to the unintentional increase of
QD size in the DWELL2 detector during the growth pro-
cess, resulting in decreased energy spacing between the
ground and the first excited states in the QD. In addition,
this would also decrease the energy spacing between the
ground state in the QD and the bound state in the QW. As a
result, the first two peaks will appear at longer wave-
lengths than expected. This shift was observed in the
spectral response curves of the DWELL2 detector (see
Figure 6).
It is also reported that the VLWIR peak of the DWELL2
detector could be obtained up to 60K, whereas the VLWIR
peaks of DWELL1 and DWELL3 detectors were observed
up to 80K. The highest observed detectivity for the
DWELL3 detector at 23.3mm under a �2.2V bias at
4.6K was reported as �7.9� 1010 cmHz1/2/W. At 80K, a
detectivity of 3.2� 108 cmHz1/2/W was reported under a
�1.4V bias for the DWELL3 detector, whereas DWELL3
detector exhibited lower responsivity and a lower noise
current than those of the DWELL1 detector, resulting in a
higher detectivity for the DWELL3 detector than for the
DWELL1 detector. The improvement in operating temper-
ature of the VLWIR response (up to 80K), compared
with a typical VLWIR QWIP (70) operating at �10–20K,
demonstrates the benefit of a quasi-zero-dimensional
confinement.
Voltage-Tunable Dual-Band DWELL Detector
Some of the other multiband quantum dot Infrared
detectors reported in the literature include a voltage
tunable 3–5mm and 8–12mm dual-band detector with
InAs/Al0.3Ga0.7As/In0.15Ga0.85As confinement-enhanced
DWELL device with response peaks at 5.0mm and
8.6mm operating up to a temperature of 140K. (71). At
77K, the response ratio of the 8.6mm peak over the
5.0mm peak changes from 0.29 at �3V to 5.8 at
þ4.8V. Combined quaternary In0.21Al0.21Ga0.58As and
GaAs capping that relieves strain and maintains strong
carrier confinement was used to demonstrate a four-color
infrared response with peaks in the MWIR (5.7mm),
LWIR (9.0mm and 14.5mm), and far-infrared region
(17mm) (72).
MULTIBAND TUNNELING QUANTUM DOT STRUCTURES
Currently, most of the commercially available IR detectors
do not have low enough dark current to work at higher
temperatures than cryogenic (liquid nitrogen) tempera-
ture. In general, a detector’s dark current should be lower
than its background-limited current at the operating tem-
perature. For some imaging applications, the background
current, which also depends on optics and operating tem-
perature, will determine the highest operating tempera-
ture given the dark current is lower than the background
current. However, there are some other applications that
can benefit from uncooled detectors mainly because of the
reduced complexity and cost. In that case, the detectors
should exhibit low dark current to be eligible for uncooled
operations, which is a challenge as the rate of thermal
excitations leading to the dark current increases exponen-
tially with temperature. Although a QD-based structure is
a potential choice, conventional QDIP structures have not
yet shown adequate performance above 150K. At temper-
atures above 150K, electron occupation is dominated by
the excited states in the QDs; as a result, the reduction in
the dark current is not significant. As a solution, Bhatta-
charya et al. (10) have explored a new resonant tunnel-
based QD device architecture, demonstrating room-tem-
perature IR detection at 6 and 17mm.
20 25 30 350
20
40
60 w = 90
120
110
Re
sp
on
siv
ity (
mA
/W)
Wavelength (µm)
DWELL1
DWELL2
DWELL3
Figure 7. Comparison of the VLWIR response peak of DWELLdetectors. After Reference 62.
6 Epitaxial Quantum Dot Infrared Photodetectors
3GW8218 08/26/2014 20:43:34 Page 7
Aslan et al. (73) has observed resonant tunneling
through a QD layer. In general, any device structure
designed to reduce the dark current will also reduce the
photocurrent. Recently reported tunneling QDIPs (T-
QDIPs) (10, 61, 74, 75) use resonant tunneling to collect
the photocurrent generated within the QDs selectively,
whereas the tunneling barriers (double barriers) block the
majority of carriers contributing to the dark current. The
characteristics of the room-temperature T-QDIP reported
by Bhattacharya et al. (10), showing two-color response at
wavelengths of �6 and �17mm, are discussed in this
section.
A T-QDIP structure can be considered as an extended
DWELL structure. That is, a DWELL structure coupled
with a double-barrier transforms into a T-QDIP structure,
which has several advantages over DWELL structures.
Conventional QDIPs have inherently low dark current,
which can be further reduced using a DWELL structure.
Compared with DWELL detectors, T-QDIPs exhibit lower
dark current as a result of the dark current blocking by the
double barrier. As a result, T-QDIPs have the potential to
achieve the highest possible operating temperature. Addi-
tionally, photocurrent filtering by means of resonant tun-
neling in T-QDIPs offers a solution for low quantum
efficiency, which has been observed in other QD-based
devices. Quantum efficiency can be increased even more
through resonant cavity enhancement (76–78), which
increases the absorption in the active region without
increasing the dark current. In addition, several other
important properties of T-QDIPs include the tunability
of the operating wavelength and the multicolor (band)
nature of the photoresponse based on different transitions
in the structure. The operating wavelength can be tailored
by changing the device parameters of QW, QD, and double
barrier. Using transitions between the energy levels of the
QD and the energy levels of QW, it is possible to obtain
detectors with multiple distinct response peaks.
Modeling T-QDIP Structures
A typical T-QDIP consists of InGaAs QDs embedded
in a AlGaAs/GaAs QW, which is then coupled to a
AlGaAs/InGaAs/AlGaAs double barrier. The T-QDIP
structure [reported by Bhattacharya et al. (10)] and its
conduction band profile under an applied reverse bias are
schematically shown in Figure 8. Pulizzi et al. (79) have
reported resonant tunneling phenomena for a similar QD-
based structure coupled with a double barrier. The photo-
current generated by a transition from a state in the QD
(E0, E1 or E2) to a state in the QW, which is coupled with a
state in the double barrier, can be collected by resonant
tunneling. In this discussion, the energy state in the QW is
denoted as the resonant state Er because it is associated
with resonance tunneling. The double barrier blocks the
majority of carriers contributing to the dark current (car-
riers excited to any state other than the resonant state in
the QW). It can be shown that the tunneling probability is
near unity for carriers excited by radiation with energy
equal to the energy difference between the QD ground
state and the resonant state.
The first step in designing a T-QDIP is the calculation of
the QD energy levels as explained before. The size of QDs
and their barrier material (the confinement potential)
determine the energy spacing between QD bound states.
The width and the confinement potential of QW are
adjusted to obtain the resonant state at the right location
with respect to the QD ground state. In addition, the
doping concentration in QDs should be sufficiently high
to populate all the states that take part in the detection
mechanism. The energy states in the QW with the pres-
ence of the wetting layer and the double-barrier system
are calculated by solving the one-dimensional Schr€odinger
equation. The transmission probability for the double-
barrier structure is calculated using the transfer matrix
method (80). The double barrier (AlGaAs/InGaAs/AlGaAs)
is integrated with each QD layer of the QDIP and is
designed such that the resonant state coincides with a
bound state in the double barrier under certain bias
conditions. In this way, a higher potential barrier for
thermal excitations can be introduced, whereas the
photoexcitation energy remains very low. Because of
the energy-dependent tunneling rate of the double
barrier, the dark current resulting from carriers with a
broad energy distribution is suppressed. Thus, the dark
Figure 8. (a) Structure of a T-QDIP grown by MBE. InGaAs QDs are placed in a GaAs/AlGaAs QW. The AlGaAs/InGaAs/AlGaAs layersserve as a double-barrier system to decouple the dark and photocurrents. The letter “i” stands for intrinsic. (b) Schematic diagram of theconduction band profile of a T-QDIP structure under bias.E0,E1, andE2 are the energy level positions in theQDwith respect to the resonantstate Er. Only the carriers excited to the resonant state contribute to the photocurrent. Modified after Reference 10.
Epitaxial Quantum Dot Infrared Photodetectors 7
3GW8218 08/26/2014 20:43:35 Page 8
current can be significantly reduced, particularly at high
temperatures.
To achieve background limited infrared performance
(BLIP) conditions at high temperatures, the detector
should exhibit an extremely low dark current density. A
TQDIP detector designed to have strong resonant tunnel-
ing can achieve high BLIP temperatures. The dark current
Id of a T-QDIP structure at a bias V is given (74) by
IdðVÞ ¼ evðVÞnemðVÞA (5)
where A is the device area, and v and nem (given by Eqs. 6
and 7 are the average electron drift velocity in the barrier
material and the concentration of electrons excited out of
the QD, respectively. The electron drift velocity is given by
vðVÞ ¼ mFðVÞffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
1þ mFðVÞvs
� �2r (6)
where m is the electron mobility, F is the electric field, and
vs is the electron saturation velocity. The excited electron
density from the QD is given by
nemðVÞ ¼Z 1
�1NðEÞf ðEÞTðE;VÞdE (7)
where f(E) is the Fermi-Dirac distribution function,T(E, V)
is the tunneling probability calculated by the transfer
matrix method (80), and N(E) is the density of states,
which is given by the following equation.
NðEÞ ¼X
i
2Nd
Lp
1ffiffiffiffiffiffiffiffiffi
2psp exp
�ðEf i � EÞ22s2
( )
þ 4pm
Lph2HðE� EWÞ
þ 8pffiffiffi
2p
h3ðm�Þ32
ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
E� ECHp
ðE� ECÞ ð8Þ
where the first term is the density of states of the QD state
and Nd is the surface density of QDs. The second term is
the density of the wetting layer states, where EW is the
wetting layer state andH(x) is a step function withH(x)¼ 1
for x� 0 andH(x)¼ 0 for x< 0. The third term describes the
density of states in the barrier material, where EC is the
conduction band edge of the barrier material.
For efficient dark current blocking, the broadening of
the resonant state has to be at a minimum. That is, the
resonant state should be strongly bound. The basic param-
eters should be adjusted so that the tunneling probability
remains close to unity and the carrier escape lifetime is
smaller than the carrier recombination lifetime. The Fermi
level in the QD (hence QD ground state) should be below
the band edge of the QW; however, adjusting the ground
state will change the energy difference between the QD
ground state and the resonant state, which will affect the
peak response wavelength. Thus, all these factors need to
be taken into account to design an optimized detector
exhibiting low dark current.
Two-Color Room Temperature T-QDIP Detector
As reported by Bhattacharya et al. (10) a T-QDIP structure
(TQDIP1) was grown by MBE and then characterized
using I-V, spectral response, and noise measurements.
The results demonstrated the detector’s ability to operate
at room temperature because of the resonant tunneling
phenomenon present in the structure. The detector showed
a two-color response at wavelengths of �6 and �17mm up
to room temperature. A detailed explanation of the device
structure, spectral response and device performance are
given in the following sections.
Device Structure and Dark Current Characteristics. The
T-QDIP structure, TQDIP1, is schematically shown in
Figure 8. Self-assembled In0.4Ga0.6As QDs were grown
on a GaAs substrate. A stack of Al0.3Ga0.7As/
In0.1Ga0.9As/Al0.3Ga0.7As layers serve as the double bar-
rier. The GaAs and AlGaAs layers were grown at 610�Cand the InGaAs or InAlAs QD layers were grown at 500�C.Dark I-V characteristics of TQDIP1, at different tempera-
tures ranging from 80–300K, are shown in Figure 9.
Positive (or negative) bias denotes positive (or negative)
polarity on the top contact. For comparison, the dark
current density between DWELL (DWELL3) at 80K is
also shown in Figure 9. Dark current densities at a bias
of �2V are 3� 10�1 and 1.8� 10�5A/cm2 for DWELL and
T-QDIP, respectively. The reduction in dark current of the
T-QDIP is associated with dark current blocking by the
double barrier in the structure.Moreover, the dark current
densities for TQDIP1 at a bias of 1V were 0.21, 0.96, and
1.55A/cm2 at 240K, 280K, and 300K, respectively. These
dark current density values are lower than the dark cur-
rent values of other IR detectors operating in comparable
wavelength regions at the same temperature. Based on the
dark current variation as a function of bias, negative
conductance peaks were not visible even though resonant
tunneling takes place in the structure. This observation
can be expected for T-QDIPs because sequential resonant
tunneling through ground state is not possible. In T-QDIP
structures, there is no coupling between the QD ground
state and states in the double barrier [unlike in super-
lattice structures (81)]. Also, each active region of the T-
QDIP is separated by a thick spacer layer (400A�GaAs),
which does not allow any significant coupling between two
–4 –2 0 2 4
10–6
10–4
10–2
100
DWELL3
(T = 80 K) Dark
Curr
ent D
ensity (
A/c
m2)
300 K
280
240
200
160
120
80
Bias (V)
Figure 9. Dark current density of the T-QDIP (TQDIP1) as afunction of bias in the temperature range of 80–300K. The darkcurrent density of the DWELL detector (DWELL3) at 80K is alsoshown for comparison. The reduction in dark current observed forT-QDIP is attributed to the blocking barrier in the architecture.
Modified after Reference 10.
8 Epitaxial Quantum Dot Infrared Photodetectors
3GW8218 08/26/2014 20:43:35 Page 9
active regions (two periods). Thus, I-V curves are not
expected to display negative conductance regimes. Fur-
thermore, it is important to underline the thin AlGaAs
barriers (30 or 40A�) on both sides of the QW. Even though
the double barrier is placed only on one side of the QW,
tunneling through the single barrier on the opposite side is
also possible. However, the transmission through this
barrier is lower compared with that through the double
barrier. Therefore, an asymmetric I-V characteristic was
observed.
Spectral Responsivity. The spectral response of TQDIP1
at 80K, 200K, 240K, 280K, and 300K under different bias
values is shown in Figure 10(a), and the variation of the
peak responsivity at 6.2mm is shown in Figure 10(b).
Based on calculations, the allowed confined energy
states in the QD E0, E1, and E2 are located at �161,
�103, and �73meV with respect to the resonant state
(see Figure 8(b)). Thus, the peak at �6mm is a result of
transitions from the ground state of the QD to the resonant
state in the structure, which is consistent with the calcu-
lated energy spacing between corresponding states (DE¼ 161meV). The peak responsivity and the external quan-
tum efficiency (the product of quantum efficiency and the
photoconductive gain) of the 6mm peak at 80K and �4.5V
are �0.75A/W and 16%, respectively. Under reverse bias
(top contact is negative), the photoexcited electrons tunnel
through the double barrier by resonant tunneling. Simi-
larly, under forward bias, photoexcited electrons tunnel
through the single barrier (on the opposite side of the
double barrier). Because of the variations in transmission
through the single and double barriers, the response under
reverse bias is significantly higher than the response
under forward bias, as evident from Figure 10(b). How-
ever, the responsivity shows a strong dependence on the
applied bias in both positive and negative directions. This
behavior is attributed to resonant tunneling similar to that
of double-barrier superlattice structures (73, 82). Applying
a bias across the structure can fine tune the alignment of
the bound state in the QW (resonant state) and the bound
state in the double barrier, allowing for resonant tunneling
conditions. The observed bias dependence of the respon-
sivity indicates that resonant conditions are satisfied over
a considerable range of applied bias voltages. This behav-
ior could be associated with thin barriers and the broad-
ening of the energy states (dE) in the system.
At high temperatures, two distinct peaks centered
around �6 and �17mm were observed, and a weak
response around 11mm was also present. The peak at
17mm results from transitions between the second excited
state of the QD and the resonant state (DE¼ 73meV). The
line width is �26meV, which corresponds to the
inhomogeneous broadening of QD states at 300K. Because
of the symmetry of QD geometry, excited-states have a
higher degeneracy (8) than the ground state (2). The
carrier density in excited-states increases with increasing
temperature, as compared to that in the ground-state. As a
result, the 17mm peak was dominant above 200K. The
weak response at �11mm corresponds to the energy sepa-
ration between the first excited QD state and the resonant
state (DE¼ 102meV).
Noise Characteristics and Detectivity. In general, the
total noise current is a contribution of Johnson noise, 1/f
noise, and generation-recombination noise (g-r) compo-
nents. However, QWIPs (83–85) and QDIPs (4) are
expected to show very low 1/f noise characteristics. The
frequency dependent noise spectrum, which is due to 1/f
and generation-recombination noise components, has the
form (86, 87)
Sðf Þ ¼ Cþ B
fþ A
1þ ff c
� �2(9)
where A, B, and C are constants. The cut-off frequency fc is
given by fc¼ 1/2ptwhere t is the electron lifetime, which is
given by
t / T�2 expEA
kT
�
(10)
where T is the temperature, k is the Boltzmann constant
and EA is the activation energy of the thermally activated
trap level. Noise current density spectra are used to deter-
mine the variation of t with temperature. Based on
equation 8, a plot of log(t/T2) against 1/T would result in
5 10 15 20
0.00
0.05
0.10
0.15
0.20
(a)
V = –2 V
Responsiv
ity (
A/W
)
Wavelength (µm)
300 K
280 K
240 K
200 K
80 K
System Noise Level @ 300 K
–6 –4 –2 0 2 4 610–4
10–3
10–2
10–1
100
Responsiv
ity (
A/W
)
Bias (V)
(b) T = 80 K
Figure 10. (a) Spectral responsivity of T-QDIP (TQDIP1) in thetemperature range of 80–300K under a �2V bias. Two distinctpeaks centered around �6 and �17mm can be observed at hightemperatures, and a weak response around 11mm is also visible.(b) Variation of the peak responsivity at 6mmwith applied bias at80K. Modified after Reference 10.
Epitaxial Quantum Dot Infrared Photodetectors 9
3GW8218 08/26/2014 20:43:35 Page 10
a straight line with a slope of EA/k, which can be used to
calculate the activation energy of the trap level. Further-
more, the electronic states, carrier capture, and carrier
transport properties in a QD-based structure have
been studied (88) using capacitance-voltage spectroscopy
(89, 90) and deep-level transient spectroscopy (91, 92). A
strong negative capacitance phenomenon, which is origi-
nated from carrier capture and emission at interface
states, has been observed in homojunction (93) and
QWIP (94) detector structures. The specific detectivity
(D�) of TQDIP1 detector at different temperatures and
applied biases was obtained from the measured peak
responsivity and noise density spectra. At 80K and under
a bias of �2V, the maximum D� was found to be 1.2� 1010
cmHz1/2/W. The variation in D� at 6.2mm with changing
bias at 80K is shown in Figure 11. The rate of increasing
noise current with increasing bias was much higher than
the rate of increasing responsivity with increasing bias,
resulting in lowerD� at higher bias voltages (beyond2V).
This variation in D� as a function of bias is expected for a
typical photodetector. The value of D� at 17mm and 300K
was of the order of 107 cmHz1/2/W, and with some redesign-
ing of the device heterostructure, a higher D� could be
obtained for the same conditions.
Bias-Selectable Tricolor T-QDIP Detector
Following the same idea of the T-QDIP described previ-
ously, Ariyawansa et al. (95) reported a multicolor T-QDIP
that not only responds at three wavelengths but also
provides a response wavelength selectivity based on the
applied bias voltage. The structure uses two double barri-
ers coupled with QDs through the top and bottom. The
structure of this detector grown bymolecular beam epitaxy
(MBE) is shown in Figure 12. The active region consists of
pyramidal-shape In0.4Ga0.6As QDs sandwiched between
two double barriers that consist of an In0.1Ga0.9As quan-
tum well in 30-A�thick Al0.2Ga0.8As barriers. The widths of
the In0.1Ga0.9As wells in bottom-double barrier and top-
double barrier systems are 60 and 40 A�, respectively. There
are 10 periods of these QDs coupled with double barriers,
and each period is separated with an undoped 400-A�thick
GaAs layer. The GaAs and AlGaAs layers were grown at
610�C. The In0.4Ga0.6AsQDswere grown at 500�C on top of
a 3-mL wetting layer. QDs with height and base dimen-
sions of the �6nm and �20nm, respectively, are n-doped
to 1018 cm�3 using Si as the dopant, whereas all other
layers are undoped except the GaAs bottom and top contact
layers (n-doped to 2� 1018 cm�3).
The band structure for the tricolor T-QDIP detector
with calculated energy levels in the QDs and double-bar-
rier systems is shown in Figure 13(a), (b), and (c) for zero,
forward (top contact is positive), and reverse (bottom con-
tact is positive) bias conditions, respectively. There are
three bound states located at �0.156, �0.065, and
�0.026 eV (ground, first excited, and second excited state,
respectively) with respect to the GaAs conduction band
edge (¼0 eV). The energy states in the wetting layer (pur-
ple dashed line [Color version is available online]) and the
double barriers (blue short dashed lines) are also shown in
Figure 13. Although these states are localized in the
corresponding regions, they also can extend across the
whole structure, especially the wetting layer state. As
shown in Figure 13(a), photoabsorption takes place in
the QDs and electrons are excited from the QD ground
state to the first QD excited state (transition 3 with DE�91meV), to the secondQD excited state (transition 2with
DE �130meV), and to the wetting layer state (transition
1). The electric field-dependent tunneling of excited carri-
ers leads to a selectivity for photoresponse peaks. Under a
certain forward bias condition [see Figure 13(b)], the sec-
ond QD excited state will overlap with the state in the top
double barrier. Hence, the carriers excited to the second
QD state (DE¼ 130meV) will have the maximum tunnel-
ing probability and will be collected as the photocurrent,
leading to a photoresponse at 9.5mm. Similarly, under a
–4 –2 0 2 4 610
7
108
109
1010
D*(
cm
Hz
0.5/W
)
Bias (V)
= 6.2 µm
T = 80 K
Figure 11. Variation of detectivity of the T-QDIP detector(TQDIP1) at 6.2mm as a function of bias at 80K. The rate ofincreasing noise current with bias is much higher than the rate ofincreasing responsivity with bias, resulting in lower D� at higherbias voltages (above 2V).
Figure 12. A 3-D view of a processed tricolor T-QDIP structuregrown by MBE. In0.4Ga0.6As QDs are placed in between two DBs(top and bottom double-barrier systems are indicated by TDB andBDB, respectively). The letter “i” indicates that the layer isintrinsic. After Reference 95.
10 Epitaxial Quantum Dot Infrared Photodetectors
3GW8218 08/26/2014 20:43:36 Page 11
certain reverse bias condition [see Figure 13(c)], the first
QD excited state will overlap with a state in the bottom
double barrier leading to a response peak at 13.6mm(DE¼ 91meV). Under both forward and reverse bias con-
ditions, the carriers excited to the wetting layer also can
tunnel through the barriers. Hence, a short wavelength
peak in the 4.5–5mm range is also expected.
The measured and calibrated spectral response for for-
ward and reverse bias at 50K is shown in Figure 14(a).
Under forward bias (2V), two peaks were observed at
4.5 and 9.5mm because of the transitions from QD ground
state to thewetting layer state and to the secondQDexcited
state, respectively. Under reverse bias (�3.25V), two
peaks were observed at 4.9 and 16.9mm because of the
transitions from QD ground state to the wetting layer state
and to the firstQDexcited state,whereas the peak at 9.5mm(observed for forward bias) is not apparent. The observed
peak selectivity is consistent and in good agreement with
the theoretical calculations, as explained previously. The
shift of the peak associated with the wetting layer is also
expected and in good agreementwith the calculated results.
The calculated transition energies (DE for transition 1) are
264 and 249meV for forward and reverse bias, respectively.
This change is caused by the energy shift of the wetting
layer state by the applied electric field relative to the QD
states. Also, the carriers excited to the wetting layer can
escape even under nonresonant conditions because this
state is close to the top band edge of the barriers. Compared
with the calculated peak positions, the observed peak posi-
tions are in reasonably good agreement and any deviation
can be associated with the uncertainty in structure param-
eters (such asmaterial composition, layer thickness in DBs,
and size of QDs) and the uncertainty in the calculation. It is
also shownthatall thepeakswith thepeakselectivity canbe
observed up to 80K [Figure 14(b)], whereas the short peak
(4.5–5mm) can be observed up to 100K. The dark current
densities at 80K and 300K are �4� 108A/cm2 at 4V and
�8� 104A/cm2 at 2V, respectively. This comparatively
(96) low dark current is attributed to dark current blocking
by the double barriers. The detectivity values at 50K for the
peaks at 4.5 (2V), 9.5 (2V), and 16.9mm (�3.25V) are 3.0,
1.6, and 6.0� 1012 Jones, respectively.
SUPERLATTICE QUANTUM DOT DETECTORS
Anew quantum dot structure-superlattice quantum dot
infrared photodetector (SL-QDIP), which can detect
(c) Reverse Bias
∆E1= 264 meV
∆E2= 130 meV
(b) Forward Bias(a) Zero BiasBD B
–0.3
–0.2
–0.1
0.0
0.1
0.2
E (m
eV
) 1
23
T DB
QD
2
1
∆E1= 249 meV
∆E3= 91 meVQD
3
1
QD
QDDBWL
Figure 13. Schematic diagram of the conduction band profile of the T-QDIP structure under (a) zero, (b) forward, and (c) reverse biasconditions. The calculated bound state energies in the dots (red solid lines), wetting layer (pink dashed lines), and double barriers (blue shortdashed lines) are also indicated. The photoexcited carriers are collected by resonant tunneling through the double barriers. AfterReference
95. DB¼double barrier.
5 10 15
1
2
Responsiv
ity (
mA
/W)
Wavelength (µm)
9.5 µm
16.9 µm
–3.25 V
2 V
T = 50 K
5 10 150.00
0.05
0.10
6420–2–4–610
–9
10–7
10–5
10–3
50 K
Dark
Cu
rre
nt D
ensity (
A/c
m2)
Bias Voltage (V)
300 K
2 VResponsiv
ity (
mA
/W)
Wavelength (µm)
T = 80 K
–3.5 V
)b()a(
Figure 14. (a) Spectral responsivity of the T-QDIP detector at 50K under 2 and�3.25V bias and (b) variation of the peak responsivity withapplied bias. By alternating the bias polarity, the detector can be operated at 9.5 or 16.9mm. The peak response becomes maximumwhen resonant tunneling condition is met for a certain bias value (2 and �3.25V for 9.5 and16.9mm peaks, respectively). Spectralresponsivity at 80K under 2 and �3.5V bias is shown in the inset. After Reference 95.
Epitaxial Quantum Dot Infrared Photodetectors 11
3GW8218 08/26/2014 20:43:36 Page 12
radiation in two spectral bands with improved wavelength
selection capability, is reported by Ariyawansa et al. (97).
As an additional advantage compared with the bias-select-
able multiband T-QDIP (95), the SL-QDIP provides
response wavelength tunability at the detector design
stage without changing the QD size. Compared with the
previously reported superlattice QWIP structure (98),
which showed a response at 10K with either 45-incidence
configuration or corrugated geometry, the SL-QDIP shows
a similar responsivity at 80Kwith normal incidence geom-
etry. Hence, SL-QDIP demonstrates a significant improve-
ment in the operating temperature with normal incidence
detection.
A schematic diagram of the SL-QDIP structure grown
by MBE is shown in Figure 15. The structure consists of
two QD-SLs (labeled as top and bottom QD-SL) separated
by a graded AlxGa1�xAs barrier (x¼ 0.09–0.3), which are
sandwiched in two highly doped (n¼ 2� 1018 cm�3) GaAs
contact layers. The two QD-SLs are identical and consist of
self-assembled In0.4Ga0.6As QDs placed in a superlattice
made of five periods of 90A�GaAs/30A
�Al0.4Ga0.6As quan-
tumwells. The pyramidal shape QDs have height and base
dimensions of �6 and �20nm, respectively, and they were
n-doped to 1.5� 1018 cm�3 using Si. The GaAs and AlGaAs
layers were grown at 610�C, whereas the In0.4Ga0.6As QDs
were grown at 500�C on top of a wetting layer with a
thickness of �3 monolayers. Although this structure con-
sists of one active period (top-QD-SLs/graded barrier/bot-
tom-QD-SL), it is also possible to use multiple periods,
which can be expected to show high performance because
of the increase in light absorption. However, the number of
periods has to be determined to optimize the performance,
taking growth issues into account.
In Figure 16(a), a band diagram with the bound states
in QDs calculated by an eight-band k.pmodel (51) (E0, E1,
andE2) andminibands (M1 andM2) in both SLs are shown.
The approach to calculate the minibands in the two SLs is
explained elsewhere (80). These bound states in the QDs
(E0, E1, and E2) are located at �0.156, �0.065, and
�0.026 eV with respect to the GaAs conduction band
edge. The SLs exhibit two minibands located at 0.093
and 0.269 eV with respect to the GaAs conduction band
edge. In both SLs, the effect of the wetting layer has been
taken into account. As the QDs are doped and the highly
doped GaAs contact layers are separated only by a thin
AlGaAs layer, all the QD energy states are filled with
carriers. In this structure, optical absorption takes place
in the SLs, exciting carriers from all QD states (E0, E1, and
E2) to the minibands. Two sets of closely spaced peaks are
expected because of the excitations from QD states to M1
and M2 minibands. The excited carriers escape over the
graded barrier with the support of the applied electric field
and are collected at the contacts as the photocurrent. The
most important fact is that only one SL becomes active for
photocurrent generation under a given bias direction (for-
ward or reverse). As shown in Figure 16(b), under forward
bias (top-positive), a response resulted in three peaks at
5.1, 7.8, and 10.5mm is expected because of the electronic
transitions from QD states to the lower miniband state
(M1). Similarly, under reverse bias (top-negative), a
response resulted in three peaks at 2.9, 3.7, and 4.2mmis expected because of the electronic transitions from QD
states to the upper miniband (M2). Under this condition,
the carriers excited to the lower miniband (M1) cannot
escape the AlGaAs graded barrier and do not contribute to
the photocurrent.
The experimentally observed response peaks of the SL-
QDIP at 80 and 120K closely follow the theoretical predic-
tions, as shown in Figure 17. A response with three peaks
at 2.9, 3.2, and 4.9mm with the 4.9 peak being the domi-
nant one was observed under reverse bias. The longer
wavelength threshold was observed at�6mm. These peaks
are in good agreement with the theoretically predicted
peaks at 2.9, 3.7, and 4.2mm for reverse bias. Similarly,
a response due to three peaks at 4.3, 7.4, and 11mm with
the 7.4mm peak being the dominant one was observed
Figure 15. Structure of a SL-QDIP detector. Two QD-SLs (top and bottom QD-SLs) are separated by a thick, linearly graded AlxGa1�xAs(x¼ 0.09–0.3) barrier, which in turn are sandwiched between twohighly doped (n¼1.5�1018 cm�3) GaAs contact layers. Each SL consists offive n-doped (1.5� 1018 cm�3) In0.4Ga0.6As QD layers placed in GaAs/Al0.4Ga0.6As wells, as shown in the expanded view. AfterReference97.
12 Epitaxial Quantum Dot Infrared Photodetectors
3GW8218 08/26/2014 20:43:36 Page 13
under forward bias. The long wavelength threshold for this
response bandwas observed at�13mm. This set of peaks is
also in good agreement with the predicted peak locations
(5.1, 7.8, and 10.5mm). As in the band diagram shown in
Figure 16, a response from the transition from the M1
miniband to theM2miniband sensitive to normal incidence
radiation could also be expected. However, in this struc-
ture, electron transition from M1 is not observed because
the doping is such that the Fermi level is kept below M1,
leaving theM1miniband empty. If theM1-to-M2 transition
occurs, then based on the calculated miniband locations
(mentioned before), it should correspond to a peak around
�7mm, and this peak should be dominant for forward bias.
However, this was not observed for forward bias, confirm-
ing that M1-to-M2 transition does not take place in this
structure. As an overall comment, the dominant response
peaks were based on the electronic transitions from the
upper QD states, implying that the transitions from upper-
most states are more efficient. However, for the response
under forward bias, the transition from the E3 state is
weaker than that from theE2 state. This observation could
be due to incomplete carrier occupancy in the E3 state.
Moreover, the variation of the responsivity with bias volt-
age at 7.4mm for forward and at 4.9mm for reverse bias is
shown in the inset in Figure 17(a). Also, the response at
120K for reverse and forward bias is shown in Figure 17(b)
and (c), respectively.
The experimental dark current density up to 200K is
shown in Figure 18(a). The asymmetry in the dark current
can be attributed to the difference in the effective barrier
for the electrons in the two QD-SLs. The wavelength
threshold, which corresponds to the activation energy
obtained from Arrhenius model, is shown in Figure 18
(b). For low bias (�0.5V), the wavelength threshold agrees
with the theoretically predicted response, and it rapidly
increases with bias. This could be caused by tunneling
M2
M1
n+ G
aA
s T
C
Top QD-SLAlGaAs Graded
Barrier
(x= 0.09–0.3)
n+ G
aA
s B
C
Bottom QD-SL
E0
E1
E2
E0
E1
E2
n-In0.4
Ga0.6
As
QDs
M2
M1
(b) Forward Bias (c) Reverse Bias
(a)
Bottom QD-SL
Top QD-SL Bottom QD-SL
Top QD-SL
Figure 16. The conduction band profile of the SL-QDIP under (a) zero, (b) forward (top positive), and (c) reverse bias conditions. The boundstates in QDs (E0, E1, and E2) and minibands (M1 andM2) in both SLs are also shown. In (b) and (c), possible transitions from QD states tominibands leading to spectral response peaks are indicated by vertical arrows, whereas escape of carriers is indicated by horizontal arrows.
After Reference 97.
5 10 150
1
2
Wavelength (µm)
T = 120 K
V = –2 V
(b)
5 10 150
2
4
T = 120 K
V = 1.5 V(c)
(a)
5 10 150.0
0.5
1.0
1.5
2.0
0
50
100
2.9
7.4
–2 V
Re
sp
on
siv
ity (
mA
/W)
Responsiv
ity (
mA
/W)
T = 80 K
4.9
11 4.4
3.2
2 V
20–2
0.1
1
10
100
Re
sp
on
siv
ity (
mA
/W)
Bias Voltage (V)
T = 80 K
Figure 17. Calibrated spectral response of the SL-QDIP underforward and reverse bias conditions at 80K. Peaks at 4.9 and7.4mm are observed because of the transitions of electrons fromQD states to the upper (for reverse bias) and lower minibands (forforward bias), respectively. Variation in the responsivity with biasvoltage at 7.4mm for forward bias and at 4.9mm for reverse bias isshown in the inset. The response at 120K is shown in (b) forreverse and (c) for forward bias. After Reference 97.
Epitaxial Quantum Dot Infrared Photodetectors 13
3GW8218 08/26/2014 20:43:36 Page 14
dominant dark current as opposed to thermal, at high bias.
However, the threshold for forward bias is longer than that
of reverse bias, as expected. Using the measured noise
current spectra, the detectivity values were obtained as
3.2� 109 and 2.6� 109 Jones at 80K for the peaks at
4.9mm (under �2V bias) and 7.4mm (under 2V bias),
respectively. Assuming that the photoconductive gain is
similar12 to the noise gain, the quantum efficiency of the
SL-QDIP was obtained to be �0.4 and 5% at 4.9 and
7.4mm, respectively.
Sensitivity of QDIPs to polarized light is an area that
has not been extensively studied. As reported by Aslan
et al. (24), polarization-dependent electron transitions
exist in QDIPs and only the response peaks sensitive to
in-plane polarized light provide the benefit of normal
incidence detection. To carry out a direct comparison
between 90�-angle (normal) and 45�-angle incidence
responses, a separately processed SL-QDIP with a 45�-angle polished facet was used. The 90�-angle incidence
response of this detector, shown in Figure 19(a), is consist-
ent with the results discussed earlier in this section,
whereas it exhibits a factor of 3 increase in response for
45�-angle incidence radiation over 90�-angle incidence
radiation. This observation can be either because of the
quantum well nature of QDs, although not expected, or
because of the nature of particular electronic transitions
leading to the response peaks [transitions from QD states
(3-D) to superlattice minibands (1-D)]. To investigate the
polarization sensitivity, the response of the SL-QDIP was
measured by varying the angle of polarization of the inci-
dent light. As shown in Figure 19(b), both peaks (4.9 and
7.4mm) have shown a polarization extinction ratio of
about 100:40, which is comparable with typical QWIPs.
The measurement geometry is also shown in the inset to
Figure 19(b). A detailed analysis to this effect would be
beneficial to the advancement of QDIP detectors.
P-TYPE QUANTUM DOT DETECTORS
Despite its promising characteristics, a major challenge
associated with QDIPs is the lowQE (99). For example, the
typical QE was obtained to be about 2%. (100) Optimiza-
tion to 12% can be achieved by using bound-to-bound
transitions in a GaAs-based n-type DWELL structure
(101) that, however, is still less than the QE of HgCdTe
and type II superlattice detectors (99). The relatively low
QE of QDIPs results in part from the large fluctuation of
the dot size in the Stranski-Krastanov growth mode. This,
along with the low QD density compared with the density
of dopants in QWIPs (102), gives rise to the lower absorp-
tion efficiency than expected. Designing optimized struc-
tures to improve QE may include a change of operating
carrier type frommajority electrons to holes, which offers a
few unique characteristics, such as optical transitions
associated with three valence bands and higher effective
mass of the holes. The former leads to a broad response
allowing for convenient tailoring of the spectral response.
The latter features increased the density of states and thus
enhanced absorption, as a great number of holes are
allowed in QDs. Also, a higher effective mass of holes
means the lower dark current compared with conduction
through electrons (103). For conduction through holes
versus conduction through electrons, the higher effective
mass can reduce the photocurrent as well. However, for the
tunneling current, the higher effective mass is an advan-
tage. In addition, although the photocurrent is reduced
because of the higher effective mass, a recent experiment
210–1–2
10
20
Wa
ve
len
gth
Thre
sh
old
(µm
)
Bias Voltage (V)
(a)
(b)
420–2–410
–8
10–6
10–4
10–2
100
Da
rk C
urr
en
t
Density (
A/c
m2)
200 K
160
120
80
20–20.0
0.2
0.4
0.6
No
ise
Ga
in
(c)
Figure 18. Dark current density of the SL-QDIP at temperaturesbetween 80 and 200K. (b) Variation in the wavelength thresholdwith bias calculated based on the Arrheniusmodel. (c) Variation inthe noise gain based on the measured noise current and darkcurrent. After Reference 97.
9060300–30–60–900.2
0.4
0.6
0.8
1.0 s-Polarized
No
rma
lized
Re
spo
nse
(a
.u.) 4.9 µm
7.3 µm
Plarization Angle
p-Polarized
Detector
Substrate
s
p
14121086420.0
0.2
0.4
0
10
20
30
Normal
45-Angle
7.4 µm4.9 µm
0.5 V
Re
sp
on
siv
ity (
mA
/W)
Wavelength (µm)
T = 80 K
–1 V
Re
sp
on
siv
ity (
mA
/W)
(a)(b)
Figure 19. (a) The response of the SL-QDIP at 80K for 90� angle (normal) and 45� angle incidence radiation. (b) The sensitivity of the SL-QDIP to polarized light when the polarization angle is varied. The measurement geometry is shown in the inset. The point at u¼ 0�
corresponding to s-polarized light and u¼90� corresponds to p-polarized light, as indicated by vertical arrows.
14 Epitaxial Quantum Dot Infrared Photodetectors
3GW8218 08/26/2014 20:43:36 Page 15
has demonstrated higher efficiencies for p-type QDIPs
(104). A schematic structure of the p-type QDIP grown
by molecular beam epitaxy is shown in Figure 20(a). The
absorbing region consists of 10 periods of InAs QDs,
between which is an 80-nm-thick undoped GaAs barrier.
The pyramidal shapeQDs have the height and base dimen-
sions of 5 and �20–25nm, respectively. The dot density
is about 5� 1010 cm�2. Free holes are introduced by a
d-doping technique. A sheet density of 5� 1011 cm�2
p-type dopants is placed above the QDs, with a 15-nm-
thick spacer (GaAs) between them, which gives about 10
holes per dot.
The hole states in QDs were calculated as shown in
Figure 20(b) by using an 8� 8k�p model described in
Reference 51. In contrast to only one electron state in
the CB, many hole states are allowed in the dots. From
numerical computation point of view, thismeans amassive
number of Eigenvalues to be solved simultaneously from
the eight-band Hamiltonian, which becomes even difficult
in the higher hole energy range where dense states are
included. To facilitate the computation, the spin-orbit
split-off (SO) states were obtained by treating the QD as
aQWand using an effective-massmethod. Themuchwider
in-plane dimension of the dots than the height partially
validates such a treatment. The comparison of QD and
QW states for the heavy-hole (HH) level, as shown in
Figure 20(b), indicates that the obtained ground states
from two approaches are close to each other. We use the
QWSO state to represent for the QD SO hole and interpret
the spectral response, which should be acceptable for
analysis on distinguishing respective contributions of
valence-band (VB) hole transitions to the response.
The computed electronic structure of QDs is used to
interpret the spectral response of p-QDIP, as shown in
Figure 21(a), displaying two primary response bands at
1.5–3 and 3–10mm. The overall spectral profile is analogy
with that of the p-type GaAs heterojunction detector (105)
[Figure 21(b)]. However, the responsivity of p-QDIP is
about 10–20 times higher than that of the heterojunction
detector, as shown in Figure 21(b) and (c), even though
QDIP contains a much thinner absorbing region than the
heterojunction. This characteristic indicates that the ori-
gin of response should be dominant because of the QDs but
not the p-type GaAs contact layers [Figure 20(a)], benefit-
ing from the longer hole lifetime of QDs. The small spacing
between hole states (<30meV) leads to varying responses
with the photon energy in accordance with the band struc-
ture of InAs/GaAs. For example, the two response bands lie
above and below the SO splitting energy of InAs (0.39 eV or
3.2mm in wavelength). The experimental short-wave-
length response peak at 0.552 eV corresponds to the hole
transition from the HH ground state to the SO state
[0.609 eV by calculation as indicated by transition I of
Figure 20(b)], whereas the long-wavelength peak at
0.247 eV [also see inset of Figure 21(a)] corresponds to
the hole transition from the HH ground state to the state
Figure 20. (a) Schematic of the p-typeQDIP structure. Free holesare introduced into QDs by d-doping above the QD layer.(b) Computed valence band structure of the QDs, where solidlines represent for hole states obtained by using an 8�8k�pmodel.The thick lines are the band edges. The dashed lines are the holeground states of a QW, which has the same thickness as the QDheight. The QW states were obtained using an effective-massmethod, with the potential confinement adopted from that ofthe QD in the growth direction through the dot center. The statesbeyond the LH level become denser because of the larger holeeffectivemass and because of the LH confinement potential, whichleads to a quasi-continuum of tenuously bound states. Threetransitions (I, II, and III) indicated contribute to the responseas observed experimentally, where the transition III only observedat higher biases has the much weaker contribution compared withthe other two. After Reference 104.
Figure 21. (a) Spectral response of the p-type QDIP at 78K. Tworesponse bands at 1.5–3 and 3–10mm originate from hole transi-tions between the SO-HH and HH-HH QD levels, respectively.Inset: Gaussian fits to the spectral response show lower-energyresponse peak at 0.148 eV because of the LH-HH transition.(b) Comparison between the response of the p-type QDIP andheterojunction detector (105). The bias voltages are selected suchthat they lead to nearly the same electric field. The heterojunctiondetector consists of 30 periods of p-type GaAs (3� 1018 cm�3,18.8nm) and Al0.28Ga0.72As (60nm). Its spectral response wasreported elsewhere (105). (c) The variation of peak responsivitywith the electric field. The responsivity of p-QDIP is about 10–20times higher than that of the heterojunction detector. After Ref-
erence 104.
Epitaxial Quantum Dot Infrared Photodetectors 15
3GW8218 08/26/2014 20:43:37 Page 16
near the GaAs barrier [transition II, calculated as
0.260 eV]. In view of the assumed ideal pyramidal shape
in the calculations, the experiment and computed elec-
tronic structure results agree reasonably well.
The hole transition which contributes to the primary
response peak at 0.247 eV may end up to quasi-bound
states. It can be seen from Figure 20(b) that hole states
become denser (106) at the higher energy portion of theHH
confinement potential, partly because of the larger hole
effective mass and the light-hole (LH) confinement poten-
tial, which leads to a continuum of tenuously bound states
(107). This characteristic is consistent with the broad
nature of the response peak with Dl/l¼ 0.42, where land Dl are 5.2mm and 2.2mm, respectively. However,
the HH-bound-to-HH quasi-bound transition may domi-
nate over the HH bound-to-LH continuum transition, as
the bound-to-quasi-bound transition has the higher
absorption than the bound-to-continuum transition
(101). Compared to the HH to HH response, the short-
wavelength response contributed by the HH to SO transi-
tion is not as strong as in the heterojunction case, as shown
in Figure 21(b). A possible cause is the impact of strain on
the local band edges (108), leading to a much shallower SO
confinement potential than the HH band and giving rise to
continuum SO states. Additionally, scattering events are
required to transfer holes in the SO states to the HH states
of the barrier to facilitate transport, which somewhat
reduces the escape efficiency.
Typical QDIPs display bias-dependent multiple-wave-
length responses as a result of the change between bound-
to-bound and bound-to-continuum transitions. Such an
effect is less pronounced in the present p-type detector
compared with n-type QDIP (18). It was observed that a
long-wavelength response tail rises at higher bias as
shown in Figure 21(a), the Gaussian fit of which [inset
of Figure 21(a)] gives its peak at 0.148 eV. In view of its
width (Dl/l¼ 0.23, where l and Dl are 8.3mm and 1.9mm,
respectively), this response originates from the HH bound-
to-LH bound transition as indicated by transition III of
Figure 20(b) (0.160 eV by calculation).
The dark current-voltage characteristic of the p-QDIP is
shown in Figure 22 and is used, along with the experi-
mentally measured noise current (in), to obtain the noise
gain (g) through the expression: g ¼ i2n=4eId, where Id is the
dark current. Figure 22(b) plots the noise gain as a function
of bias. Assuming that the photoconductive gain equals the
noise gain, the value of QE can be calculated from the
relationship between the responsivity (R) and gain: QE¼Rhn/eg, where hn is the photon energy. As shown in
Figure 22(c), QE reaches the maximum of 17% at
�0.6V. The specific detectivity is given by D�¼R(A�Df)1/2/in, where A is the device area and Df is the band-
width. The detectivity at 78K for the response peak at
5mm as a function of bias is shown in Figure 23, with a
maximum value of 1.8� 109 cmHz1/2/W at �0.4V.
It was reported that the bias at which the maximum
detectivity is obtained progressively varies with the tran-
sition type. The optimum operating bias of the bound-to-
continuum transition is close to 0V (101). A recently
demonstrated p-type Ge/Si(001) QDIP (109) based on the
bound-to-continuum transition also confirmed this opera-
tion. For the InAs/GaAs p-QDIP reported here, the bias-
dependent detectivity as shown in Figure 23 indicates the
bound-to-quasi-bound transition as the primary transition
contributing to the response, in agreement with the
prior analysis based on computed electronic structure
(Figure 20).
It should be noted that the demonstrated p-QDIP
does not employ a dark current blocking layer [see
Figure 20(a)]. This causes the dark current to be more
than three order of magnitudes higher than that of typical
n-QDIPs using a blocking layer (14). Although the current-
blocking layer also reduces the responsivity, the noise is
suppressedmore effectively, leading to increased signal-to-
noise ratio and detectivity. Based on the current, struc-
ture, further improvement on the QE is possible through
optimizing the transition type and enhancing the absorp-
tion. Barve et al. (101) reported the QE values for the
Figure 22. (a) Dark current density of the p-type QDIP at differ-ent temperatures. (b) and (c) (shown as insets) are the noise gainand QE, respectively. The noise gain is calculated by using exper-imentally measured noise current and dark current. QE isobtained by assuming that the photoconductive gain equals thenoise gain. After Reference 104.
Figure 23. The specific detectivity of the p-type QDIP for theresponse peak at 5mm, plotted as a function of the bias. After
Reference 104.
16 Epitaxial Quantum Dot Infrared Photodetectors
3GW8218 08/26/2014 20:43:38 Page 17
bound-to-continuum, bound-to-quasi-bound, and bound-
to-bound transitions, the maximums of which are 2%,
6%, and 12%, respectively. It is therefore expecting an
increase in the QE of the p-QDIP by operating based on
the bound-to-bound hole transitions. The enhancement of
absorption could be attained by optimizing the QDs, such
as the number, density, and uniformity of the dot layers
and by employing a resonant cavity (105).
TERAHERTZ QUANTUM DOT ANDQUANTUM RINGDETECTORS
With an increasing interest in the terahertz region of the
spectrum (0.1–3.0THz), there is a need for terahertz detec-
tors exhibiting low dark current and high operating tem-
peratures for applications in imaging, communication,
security, and defense. The primary challenge in developing
terahertz detectors is the reduction of dark current
(because of thermal excitations) as the energy correspond-
ing to the terahertz detection mechanism is few meV.
Currently, terahertz detectors such as Ge BIB detectors
(110), photoconductors triggered by femtosecond laser
pulses (111), QWIP detectors (112), homojunction detec-
tors (113), heterojunction detectors (114), and thermal
detectors, such as bolometers and pyroelectric detectors,
are being studied. However, all of these detectors operate
at low temperatures. A typical detector structure, in which
the transitions leading to terahertz detection occur
between two electronic states with an energy difference
of DE (� 4.1meV for 1THz), would not be suitable for high-
temperature terahertz detection because the dark currents
from thermal excitations become dominant even at 77 K
because of the small DE. A T-QDIP structure (61), in which
the photocurrent is selectively collected while the dark
current is blocked, can be adjusted to obtain terahertz
response, thus offering a suitable platform for high-oper-
ating-temperature terahertz detectors. Huang et al. (58)
have reported a QDIP structure using intersubband detec-
tion, which has reduced complexity in the device structure.
Advancing quantum dot growth process further, a process
in which quantum dots are transformed into quantum
rings by postepitaxy thermal annealing has been reported
(115), also demonstrating the feasibility of terahertz detec-
tion using the electronics transitions in quantum rings
(116–119). The following discussion has more details about
those three approaches.
Tunneling Quantum Dot Structures for Terahertz Detection
Su et al. (61) have explored a resonant tunneling QDIP
device architecture demonstrating a detector sensitive to
6THz. The basic idea is same as other T-QDIPs discussed
previously, but in the terahertz T-QDIP structure, smaller
QDs are used to accommodate electronic transitions lead-
ing to terahertz detection. The structure and conduction
band profile of the structure reported by Su et al. (61) is
illustrated in Figure 24. In this approach, the transition
energy between the E1 state and the Er state corresponds
to 5THz radiation. The energy spacing for this transition
can be adjusted by changing the GaAs QW parameters
without changing the QDparameters. Hence, this provides
an advantage when the QD size and other parameters are
restrained by the growth technique. Flexibility for reduc-
ing the QD size would raise the upper energy states closer
to the Er state. However, to obtain a strong transition
between these two states, the carrier occupancy in the
E1 state should be increased. One possibility is to adjust
the doping concentration in the QDs so that the Fermi level
rises above the E1 state. Also, in this case the photores-
ponse can be enhanced by increasing the temperature,
similar to the T-QDIP detectors discussed before.
The structure of the MBE grown terahertz T-QDIP
detector contains self-organized In0.6Al0.4As QDs grown
on a GaAs layer and doped with Si. The stack of
Al0.3Ga0.7As/In0.1Ga0.9As/Al0.3Ga0.73As layers served as
the double-barrier system. The GaAs and AlGaAs layers
were grown at 610�C and the rest of the structure was
grown at 500�C. The top and bottom GaAs contact layers
were n-doped with Si to a level of 2� 1018 cm�3. To obtain a
transition leading to a response in terahertz region, the
excited states in the QD was pushed toward the resonant
state by forming smaller QDs. The QDswere doped to raise
the Fermi level so that photoexcitations take place from an
upper state in the QD to the resonant state. To reduce QD
size, In0.6Al0.4As was used instead of InGaAs because the
Figure 24. (a) Structure of a T-QDIPTHz detector. In0.6Al0.4AsQDs aren-dopedwith Si. The growth of smallerQDs comparedwith InAs orInGaAs QDs was achieved using InAlAs material. The QD size has been considerably reduced to 40A
�(height) and 130A
�(width).
(b) Conduction band profile of the THz T-QDIP under reverse applied bias along with the calculated bound state energies in the dots andwells. After Reference 61.
Epitaxial Quantum Dot Infrared Photodetectors 17
3GW8218 08/26/2014 20:43:39 Page 18
Al-containing islands (QDs) are smaller in size compared
with InAs (or InGaAs) islands because of the smaller
migration rate of Al adatoms on the growing surface
during epitaxy. The QD size was reported (61) to be 40A�
(height) and 130A�(width).
The dark current density of terahertz T-QDIP at differ-
ent temperatures is shown in Figure 25. At �2V bias, the
dark current density values are 6.5� 10�8, 7.9� 10�2, and
8.3A/cm2 at 4.2, 80, and 150K, respectively. At tempera-
tures above 80K, this terahertz T-QDIP detector showed a
lower dark current density compared with other terahertz
detectors (120, 121) operating in the 15-5THz (�20–60mm)
range irrespective of the bias voltage. However, compared
with the terahertz QD-based detector, which will be dis-
cussed in the next section, this T-QDIP has a lower dark
current density at low temperatures irrespective of the
bias. At high temperatures (above 80K), it showed a lower
dark current density only for bias voltages above 1V. This
variation of the dark current for the T-QDIP with bias
voltage is attributed to dark current blocking from the
tunneling barriers.
Referring to the conduction band profile of the structure
shown in Figure 24(b), this structure exhibits only two
bound states in the QD because of the reduced dot size. The
electrons excited from the upper bound state (E1) to the
resonant state (Er) lead to the photocurrent. The location of
the upper bound state is �24.6meV (5.5 THz, 54.6mm)
with respect to the resonant state and a response peak
centered around 5.5THz is theoretically expected. At the
frequency of 6 THz, the measured spectral response of the
detector at 80 and 150K showing responsivities of 6 and
0.6mA/W is shown in Figure 26. The sharp dip around
8.1THz (37mm) is due to the Reststrahlen band of GaAs,
which is present in all GaAs-based photon detectors (114,
121). The observed full width at half maximum (FWHM) of
the spectral response is�35meV. This spectral broadening
arises from the inhomogeneous size distribution of self-
organized QDs. Whereas this broadening is useful to
obtain a broad spectral response, it will weaken the reso-
nant conditions. For efficient resonant tunneling leading to
low dark current, tight resonant conditions are required.
Hence, the QD size and shape fluctuations need to be
minimum, which could be achieved using improved growth
techniques in the future. Furthermore, the measured
detectivity of the terahertz T-QDIP at 6 THz was
�5� 107 Jones at 80K under a bias of 1V. Although
this value of D� is not high enough for applications, higher
D� could be achieved through design and growth optimi-
zation. To achieve terahertz detection in 1–3THz region at
high temperatures, several issues need to be resolved such
as the growth of small QDs with reduced size fluctuation,
optimization of structure parameters, and tight resonant
conditions to maintain low dark current without reducing
the photocurrent.
Intersub-Band Terahertz QDIP
The theoretical calculations carried out in Reference 58
show that the In0.4Ga0.6As QDs in GaAs barriers exhibit
multiple confined electronic energy states. The transitions
of electrons from these energy states to the continuum
would lead to multiple response peaks, with at least one
falling in the terahertz region. Using those transitions,
Huang et al. (58) reported a In0.4Ga0.6As/GaAs QD-based
terahertz detector exhibiting two color characteristics with
response peaks in the 3–13 and 20–55mm (15–5.4THz)
ranges and operating up to 150K. With this detector
structure, two major disadvantages have been overcome:
One is the use of a simple heterostructure compared with
complicated terahertz detector structures (61, 122) and the
other is the higher temperature operation for the terahertz
region compared with terahertz QWIPs (112, 121, 122).
The schematics of the In0.4Ga0.6As/GaAs QDIP hetero-
structure grown by MBE on a (001)-oriented semi-insulat-
ing GaAs substrate is shown in Figure 27(a). The near-
pyramidal (61) shape QDs had an average base width of
21nm and a height of 5nm as estimated from atomic force
microscopy measurements (61). The active region con-
sisted of 20 periods of In0.4Ga0.6As/GaAs QD layers
3210–1–2–310
–8
10–6
10–4
10–2
100
150 K
80 KD
ark
Cu
rre
nt
De
nsity (
A/c
m2)
Bias Voltage (V)
4.2 K
Figure 25. The dark current density of THz T-QDIP as afunction of bias in the temperature range 4.2–150K. In thereported response range, the T-QDIP detector shows a lowerdark current density compared to other THz detectors operatingin the �20–60mm range. After Reference 61.
0
4
8
12
80 K, 2 V
80 K, 1 V
150 K, 1 V
20 40 5030
1014 6
Responsiv
ity (
mA
/W)
Frequency (THz)
Wavelength (µm)
Figure 26. Spectral responsivity of THz T-QDIP in the tempera-ture range 80–150K. The dip at 37mm is the Reststrahlen regionof GaAs. The calculated energy difference between the two energylevels leading to the response is 24.6meV (50.4mm). The peakresponsivity at 80 and 150K are 6 and 0.6mA/W, respectively.
After Reference 61.
18 Epitaxial Quantum Dot Infrared Photodetectors
3GW8218 08/26/2014 20:43:39 Page 19
separated by a 500-A�-thick GaAs spacer layer. The QDs
and the spacer layers were grown continuously at 500�C.One of the critical parameters in this design is the doping
concentration because the electron occupancy in the bound
states is important for various transitions at different
temperatures. QDs were doped with silicon as the dopant
to a level of 1 electron per QD. The active layers were then
sandwiched between 0.2- and 0.8-mm-thick highly doped
(2� 1018 cm�3) GaAs layers, which act as top and bottom
contact layers, respectively.
Theoretical calculations based on the eight-band k.p
model (51) exhibited four bound states (E0, E1, E2, and E3)
for this structure as shown in Figure 27(b). The locations of
the energy states with respect to the GaAs band edge and
two sets of possible transitions in the QDs are also shown
in the figure. One set includes the transitions of electrons
from any of the states to the continuum, leading to
response peaks at 37.5, 17.6, 15.8, and 5.2THz (8, 17,
19, and 58mm), whereas the other set consists of the
transitions to the third excited state (E3) leading to
response peaks at 32.6, 12.6, and 10.7THz (9.2, 23.8,
and 28mm). The photocurrent observed from transitions
to the E3 state is weak, as these excited carriers are still
bound. Also, a few of the transitions in the two sets overlap
in the energy scale (wavelength) resulting in only a few
dominant response peaks.
The dark IV characteristics of this detector, as shown in
Figure 28, show a typical variation of current density with
the temperature. At high temperatures (80K and above),
the dark current density is lower compared with any other
detector (excluding T-QDIPs) responding in comparable
wavelength regions. At�2V bias, the dark current density
values are 6.5� 1�6, 5.5� 10�2, and 2.3A/cm2 at 4.2K,
80K, and 150K, respectively. This observed dark current
reduction is attributed to the high carrier confinement in
QDs. The calibrated responsivity at 5.4K, 80K, and 120K
is shown in Figure 29. The agreement of calculated and
experimental data confirms the validity of the k.pmodel for
pyramidal QDs. The peak centered around 11.5THz
(26mm) could be matched with the transition from the
E2 state to the E3 state [DE¼ 44meV (28mm)], whereas
the shoulder around 13.6THz (22mm) was assigned to
transition from the E1 state to the E3 state [DE¼ 52meV
(23.8mm)]. The peak centered around 6THz (50mm) was
assigned to the transitions from E3 state to the continuum
[DE¼ 21.3meV (58mm)]. In addition, there is a clear peak
at 37.5THz (8mm) as shown in Figure 29(b) (this has not
been measured at 5.4K, although expected). This peak
matched with the transition from the E0 state to the
continuum [DE¼ 155meV (8mm)]. The sharp dip at
8.1THz (�37mm) is a result of the longitudinal optical
phonon absorption in GaAs.
To confirm the terahertz mechanism in this structure,
the temperature dependence of the peaks at 11.5 and 6THz
can be considered. At low temperatures, carrier occupancy
in upper states, for example E3, is relatively low. Hence,
the transitions from upper states are weak, and as a result,
the peak at 6THz is relatively weak at 5.4K. At high
temperatures, because the carrier density in upper states
becomes high, an enhanced responsivity was expected for
the response peak originating from upper states (6THz
peak). This effect of the temperature is evident from
Figure 29. However, at 80K and 120K, the separation
of the two peaks (11.5 and 6THz) is not clear. The thermal
broadening of the energy states and the enhanced transi-
tions from upper states resulted in a combined broad peak
in the 15–5.26THz (20–57mm) range instead of two sepa-
rate peaks. Moreover, it is clear that the responsivity at
6THz has increased, whereas the responsivity at 11.5THz
has decreased drastically when the temperature was
increased from 5.4K to 120K. The specific detectivity
(D�), which is a measure of the signal-to-noise ratio of
the device, for the 37.5THz peak were reported to be
2� 109 Jones at 80K under �3V bias and 7.2� 107 Jones
at 120K under �2V bias. For the 7.5THz peak, the values
of D� were 1.3� 108 Jones at 80K under �3V bias,
Figure 27. (a) Structure of the terahertz QDIP detector. (b) Conduction band profile along with the energy states and possible electronictransitions between states. After Reference 58.
3210–1–2–310
–8
10–6
10–4
10–2
100
150 K
80 K
Dark
Curr
ent D
ensity (
A/c
m2)
Bias Voltage (V)
4.2 K
Figure 28. Dark current density of the terahertz QDIP at 4.2, 80,and 150K. After Reference 58.
Epitaxial Quantum Dot Infrared Photodetectors 19
3GW8218 08/26/2014 20:43:41 Page 20
2.8� 107 Jones at 120K under�2V bias, and 2� 107 Jones
at 150K under�2V bias. TheseD� values for the terahertztransition are larger compared with terahertz QWIPs. It
can be concluded that the 5THz detection up to 150K in
the QD-based detector have been achieved based on a
thermal-assisted mechanism in QDs.
Terahertz Quantum Ring Infrared Detectors
An observation of the intermixing and shape changes
during the growth of InAs QDs has been reported (123),
and growth of self-organized InGaAs QRs on GaAs sub-
strate was proposed by Lorke et al. (115). This process
starts with growth of QDs capped by a thin GaAs layer.
Then, a short annealing process is performed, which is the
critical step for transforming QDs to QRs. It is also
reported that the ring morphology is preserved even after
the growth of cladding layers on top of InGaAs islands.
Utilizing this process, a number of quantum ring (QR)
detectors, mainly sensitive to terahertz, has been recently
demonstrated (116–119). The QRs can be incorporated into
device structures, just like QDs in QDIP structures, in
which the electronic transitions from confined energy
states in QRs lead to the detection of infrared radiation.
Dai et al. (118) reported a terahertz QRIP sensitive in the
3–100THz range with a peak responsivity of 127mA/W at
23mm (detectivity of 2.3� 1011 cmHz1/2/W) at 10K. This
work was followed by the demonstration of another ter-
ahertz QRIP by the same authors (119). This detector
exhibits three peaks at 7.1, 3.5, and 2.3THz (42, 85, and
130mm, respectively) with the lowest frequency response
peak showing a cut-off of 1.7THz (175mm). Electronic
transitions, leading to the three peaks, are from the ground
state in QRs to the continuum (first peak) and to two
subbands (second and third peaks). Through an analysis,
it is shown that the observed spectral characteristics are
from QRs, but not from conventional QDs, which proves
the existence of QRs. This detector also showed a BLIP
temperature of 50K. In a recent article, Zavvari et al. (124)
presented a theoretical work on modeling QRIP detectors,
calculating their absorption, responsivity, and dark cur-
rent characteristics. Electronic energy states and wave-
functions are numerically calculated using effective mass
approximation and an intersubband absorption coefficient
of QRs is obtained. A clear dependence of spectral charac-
teristic on QR size, described by the height, inner diame-
ter, and outer diameter, has been observed, providing
various design options of QRs for covering the terahertz
spectrum.
In the work reported by Huang et al. (116), a tunnel
quantum ring detector sensitive to terahertz radiation in
the 3–8THz range up to 120K is demonstrated. The
height, inner diameter, and outer diameter of QRs are
approximately 2–4, 50, and 80nm, respectively. The detec-
tion mechanism is exactly same as that in a TQDIP struc-
ture (illustrated in Figure 24), and it involves transition of
electrons from the top-most quantum ring state to the
resonant state. As reported (116), the detector showed
low dark current density values (�5� 10�5, 4.7� 10�2
and 3.5� 10�1A/cm2 under a �1V bias, at 4.2, 80 and
300K, respectively). Three prominent response peaks were
observed at �6.5, 10, and 12.5THz up to 120K. The
detectivity values for the 10 THz response peak at 5 and
80K were 4.9� 109 and 9.5� 107 Jones, respectively, at a
bias of �2V.
Followed by the work by Huang et al., Bhowmick et al.
(117) have reported a terahertz QRIP based on intersub-
band electronic transitions in small QRs. With small QRs,
the top-most energy state was pushed close enough to the
edge of the GaAs barrier to achieve terahertz detection at
1.82THz. This is the lowest frequency (longest wave-
length) among all the terahertz detectors discussed in
this article. This detector containing multiple QR layers
was grown by MBE on semi-insulating (001) GaAs sub-
strates. The growth parameters for the initial InAs quan-
tum dots and the anneal conditions to convert them to
quantum rings were carefully tuned to produce the desired
smaller size of these nanostructures. First, a 0.8-mmGaAs
buffer layer was grown at 600�C. The substrate tempera-
ture was then lowered to 530�C and 2.1monolayers of InAs
20 30 40 50 60
14 12 10 8 6 50.0
0.5
1.0
1.5
2.0
20 30 40 50
15 100.00
0.05
0.10
Frequency (THz)
Wavelength (µm)
Re
sp
on
siv
ity (
A/W
)
7.5
Frequency (THz)
Wavelength (µm)
T = 5.4 K
V = –3 V
Responsiv
ity (
A/W
)
0.0
0.2
0.4
0.6
0.8
20 30 40 50 605 10 15
Frequency (THz)
Wavelength (µm)
Responsiv
ity (
A/W
)
Responsiv
ity (
A/W
)
GaAs-Like
Phonon
15 10 50.00
0.05
0.10
2550150 7.5
80 K, –3 V
120 K, –2 V
)b()a(
Figure 29. (a) Calibrated spectral response of the terahertz QD-based detector at 5.4K. The observed peak positions are indicated byvertical arrows. The response around 6THz (50mm) has been expanded in the inset. (b) Calibrated spectral response of the terahertz QD-based detector at 80 and 120K. The response below 20THz (15mm) is scaled with left vertical axis, while the response above 15THz (20mm)is scaled with the right vertical axis. After Reference 58.
20 Epitaxial Quantum Dot Infrared Photodetectors
3GW8218 08/26/2014 20:43:41 Page 21
was deposited at a rate of 0.08 monolayer/s. Self-organized
quantum dots were formed after the growth of 1.8 mono-
layers of InAs wetting layer. A 10A�AlAs cap layer was
grown on the InAs islands at 530�C. Growth was inter-
rupted and the capped islands were annealed at 580�C for
30 s under an As2 flux to form quantum rings. The function
of the AlAs layer was to reduce the surface mobility of
group III atoms on the AlAs surface because AlAs has a
higher bonding strength than GaAs. Consequently, the
ring shape is better preserved during the annealing pro-
cess. The complete detector heterostructure, as shown in
Figure 30(a), consists of 10 quantum ring layers grown and
formed under the conditions described previously. The 50-
nm GaAs barrier layers shown in this figure are grown
immediately after the formation of the quantum rings. A
single Al0.2Ga0.8As barrier is inserted at the top to reduce
the dark current without substantially affecting the pho-
tocurrent. In Figure 30(b), an AFM image of small quan-
tum rings is shown. It was estimated that the density of the
rings is 1010 cm�2 and the rings have a height in the range
of 1.2–1.5 nm and inner and outer radii of 25 and 40nm,
respectively.
Carrier confinement in the rings primarily results from
their width and height. With the dimensions considered,
there is only one bound state in the potential well, which is
also the ground state. Then, the transition energy from the
ground state to the continuum in the ring corresponds to
the frequency range of 1–3THz. It is important to note that
a single confined state in QRs can be obtained only if they
are made small. The measured dark current character-
istics for this detector at 4.2K and 80K are shown in
Figure 31(a), whereas the dark current density values
observed here can be considered extremely low (�10�8A/
cm2 and 10�6A/cm2 at 4.2K for bias of �2V and þ2V,
respectively). The calibrated spectral response of this ter-
ahertz QRIP at 5.3K and 10K is also shown in Figure 31(b).
The peak at 1.82THz (165mm) corresponds to an energy of
7.52meV, which agrees well with the calculated ground
state-to-continuum transition energy for a ring with height
of 1.25nm. It is reported that the peak external quantum
efficiencies (internal quantum efficiency� gain) are �15
and 19% at �1 and 1V bias values, respectively. Moreover,
the values of specific detectivity at a bias of 1V are 1� 1016
and 3� 1015 Jones at 5.2K and 10K, respectively. These
Figure 30. (a) Heterostructure of the terahertz QRIP grown by MBE. It has 10 layers of InAs quantum rings in the active region and asingle Al0.2Ga0.8As barrier at the top. (b) AFM image of InAs quantum rings formed by postepitaxy thermal annealing of quantum dots.Inset shows a magnified image and dimensions. Modified after Reference 117.
43210–1–2–3–4–5
10–6
10–4
10–2
T = 80 K
Dark
Curr
ent D
ensity (
A/c
m2)
Bias Voltage (V)
T = 4.2 K
300250200150100500
5
10
15
20
25
100 200 3000
1
2
314 4 2
Frequency (THz)1
T = 10 K
V = 1 V
Re
sp
on
siv
ity (
A/W
)
Wavelength (µm)
14 4 2Frequency (THz)
1
T = 5.2 K
V = 1 V
Responsiv
ity (
A/W
)
Wavelength (µm)
)b()a(
Figure 31. (a) dark current characteristics and (b) measured spectral responsivity of the terahertz QRIP at 5.2K under 1V bias (insetshows the responsivity at 10K under 1V bias). Modified After Reference 117.
Epitaxial Quantum Dot Infrared Photodetectors 21
3GW8218 08/26/2014 20:43:41 Page 22
valuesofdetectivity,whicharehigher thanthedetectivityof
bolometers (�1014 Jones), prove that quantum ring detec-
tors are another alternative for terahertz detectors,
especially where detection at a specific terahertz frequency
is required.
IMPROVEMENT OF QDIP PERFORMANCE
Potential approaches to improve QDIP performance
include using multiple periods of QD active layers (75),
resonant cavity (RC) enhancement (78), and photonic crys-
tal cavity (PhC) (125) enhancement. To increase IR absorp-
tion, Chakrabarti et al. (75) have reported an MBE grown
QDIP consisting of 70 periods of QD active layers. A 400A�
Al0.3Ga0.7As current-blocking barrier was incorporated
underneath the GaAs top-contact layer. A low dark current
density (1.83� 10�2Acm�2 at 175K under a �2.0V bias)
was observed at high operating temperatures. The
response in the 2–6mm range, peaking at 3.9mm, was
caused by transitions of electrons from the QD ground
state to the continuum state. At 150K, a peak responsivity
of 0.12A/W was observed. A maximum detectivity of
1011 cmHz1/2/W at 100K for �2V, which is reasonably
high at this temperature, was also reported. The improve-
ment in detector performance was a result of the increased
number of QD active layers.
Using photonic crystals as amicrocavity resonator (125)
has demonstrated a significant improvement in the
responsivity, conversion efficiency, and detectivity for a
DWELL detector. A two-dimensional array of holes (PhC)
with a 2–3mmdiameter and a lattice spacing of 2.4mmwas
fabricated on the DWELL structure using e-beam lithog-
raphy. A schematic diagram and an image of a hexagonal
PhC are shown in Figure 32(a) and (b). PhCs provide a
photonic bandgap for normal incidence radiation. By intro-
ducing a defect into the crystal, a cavity can be built, which
operates in the wavelength range corresponding to the
photonic bandgap. The above parameters were chosen
(125) to obtain resonant cavity effects at 8.1mm. Two
structures, a DWELL detector and a PhC-DWELL detector
(125), were tested and performance was compared to deter-
mine the effects of PhC. The DWELL detector exhibited
two-color response characteristics with peaks at 6 and
10mm. The 6-mmpeak (dominant at a low bias) was caused
by transitions from the QD ground state to the continuum,
whereas the 10-mm peak (dominant at high bias) origi-
nated from transitions from the QD ground state to a
bound state in the QW. These electronic transitions and
corresponding response peaks are similar to those of the
DWELL detectors reported previously in this chapter. An
increase in photocurrent by an order of magnitude was
reported for PhC-DWELL, whereas both DWELL and
PhC-DWELL had the same dark current. A comparison
of the responsivity of a PhC-DWELL and a standard
DWELL is shown in Figure 32(c). It should be noted
that the spectra have been scaled for comparison of spec-
tral shape and the y-axis does not represent the true
relative response between the two spectra. At 9mm and
78K under a �2.6V bias, the PhC-DWELL detector had a
conversion efficiency of 95%, as opposed to the conversion
efficiency of 7.5% for the DWELL detector. Using conven-
tional optical lithography, PhCs with 2–3mm hole diame-
ter can be easily incorporated into FPA fabrication.
Similar to PhC-DWELL, an RC-DWELL, in which the
active QD region was placed in a Fabry–P�erot resonant
cavity, was reported by Attaluri et al. (78) This allows
radiation to pass multiple times through the active region
within the cavity. The RC was designed to increase the
optical field strength at the peak wavelength of a standard
DWELL detector. The RC-DWELL consists of a regular
DWELL (including top-and bottom-contact layers) grown
on a distributed Bragg reflector (bottom reflector), as
shown in Figure 33(a). The top reflector was the semi-
conductor-air interface (top-contact layer), which has
about 30% reflectivity. The DWELL detector showed two
response peaks at 6 and 10mm. The resonant optical cavity
was active at 9.5mm, consequently, the RC-DWELL
showed an enhance response at 9.5mm (see Figure 33(b)).
A peak responsivity of 0.76A/W, detectivity of
Figure 32. (a) Photonic crystal resonant cavity comprising of a hexagonal pattern of air holes. (b) Image of a PhC defined in a DWELLdetector. (c) A comparison of the spectral responsivity of a PhC-DWELLand a standardDWELLdetector at 50Kunder a�3V bias. It shouldbe noted that the spectra have been scaled for comparison of spectral shape and the y-axis does not represent the true relative responsebetween the two spectra. After Reference 125.
22 Epitaxial Quantum Dot Infrared Photodetectors
3GW8218 08/26/2014 20:43:42 Page 23
1.4� 1010 cmHz1/2/W, and 10%conversion efficiencyat 1.4V
bias and 77K were reported for RC-DWELL, whereas
DWELL showed only 1.25% conversion efficiency at
10mm under the same conditions. The detectivity of the
RC-DWELL was 3� 109 cmHz1/2/W at 77K under a 1.2V
bias, showing a factor of 3 improvements comparedwith the
conventional DWELL detector. Another important feature
of incorporating an RC into a DWELL structure is the
increase in photocurrent without increasing the dark
current.
By controlling the excited state energy between the CE
barriers and the continuum level, thin AlGaAs barrier
layers in the quantum dots in a well heterostructure
enhanced the quantum confinement of carriers in the
excited energy level, while maintaining high escape prob-
ability (14). A reported postgrowth technique for improv-
ing the peak detectivity is to implant the structure with a
low energy light ions(H�) (126). A proposed simulation of a
resonant cavity enhanced quantum dot infrared photo-
detector consisting of a conventional n-i-n QDIP sand-
wiched by a bottom GaAs/Al2O3 distributed Bragg
reflector and a top mirror of Ge/SiO2 subwavelength gra-
ting predicts an enhanced external quantum efficiency
more than 50% (127).
PRESENT PERFORMANCE AND CAPABILITIES OF QDIPs
Pal et al. (128) reported a superlattice QDIPwith 50-period
InAs/GaAs QD active layers and an AlGaAs current-block-
ing layer to suppress the dark current. The spectral
responsivity and detectivity of this detector is shown in
Figure 34(a) and (b). Gunapala et al. (33) have demon-
strated up to 1A/W response at 77K for a DWELL detector
coupled with a grating. A two-color DWELL detector with
response peaks at 3.2 and 4.1mm operating up to room
Figure 33. (a) Schematic structure of a RC-DWELL detector with eight-period QD active layers (InAs/In0.15Ga0.85As). (b) A comparison ofthe spectral responsivity of a RCDWELL detector and a standard DWELL (without the photon reflector) detector at 30K under a �1.8Vbias. After Reference 78.
Figure 34. (a) Spectral responsivity of a QDIP with a current-blocking layer composed of an Al0.3Ga0.7As layer. This enabled operation upto 220K. (b) Variation of the peak detectivity with bias. The peak responsivity as a function of bias at 100K is shown in the inset. After
Reference 128.
Epitaxial Quantum Dot Infrared Photodetectors 23
3GW8218 08/26/2014 20:43:42 Page 24
temperature was demonstrated by Lim et al. (39). Also,
there are few other reports demonstrating QDIPs (6, 75)
operating at high temperatures. A historical analysis of
the QDIP development shows rapid progression toward
high-performance detectors capable of room-temperature
operation.
In a recent investigation by Jayaweera et al. (129), a
new concept for developing photon detectors, based on the
displacement currents in a QD-embedded dielectric media,
operating at room temperature has been reported. A pre-
liminary detector structure along with its photoresponse
results was also reported. The detector structure consists
of PbS QDs embedded in a dielectric thin film, which is
sandwiched between two conducting glass contacts. The
dielectric thin film was made of paraffin wax, which has a
high dielectric constant. The incident photons are absorbed
in QDs, generating an electron-hole pair. When an electric
field applied across the contacts, the electrons drift toward
the positive contact, while holes drift toward the negative
contact. Because carrier transport through the dielectric
medium is not possible, there will be a charge separation in
the medium.
This polarizability with photon absorption, which
changes the capacitance of the device, is the key detection
mechanism in the structure proposed by Jayaweera et al.
QDs in a dielectric medium has shown several orders of
magnitude higher polarizability than atoms and mole-
cules. The incident radiation is modulated and the photo-
generated displacement current is measured under an
applied bias across the contacts. The displacement cur-
rent is a direct measurement of the incident radiation
intensity and does not contain any contribution from the
dark current. Hence, this approach is suitable for devel-
oping room-temperature detectors. At 300K and 40V
bias, the responsitivity and the detectivity at the peak
absorption (lP¼ 540 nm) were found to be 195V/W and
3� 108 cmHz1/2/W, respectively. As an advantage, sophis-
ticated growth and fabrication techniques are not
required for this type of detector development. However,
in this approach the incident light has to be modulated in
order to obtain a photoresponse. A closely related device
structure, which operates in photocurrent mode, has
been reported by Konstantatos et al. (130). The device
structure consists of spin-coating colloidal PbS QDs fab-
ricated onto interdigitated gold electrodes. Detectivity in
the order of 1013 cmHz1/2/W has been reported at 1.3mmat room temperature. A high photo-conductive gain
(�10,000) and consequently a high responsivity of
103A/W were observed at room temperature.
QUANTUM DOT FOCAL PLANE ARRAYS
The development of FPAs using successful single-element
detector structures has remarkably increased potential
applications in IR imaging. Multi-color FPAs would lead
to additional detection capabilities such as the construc-
tion of a true thermal map of a target. FPAs operating in
atmospheric windows (3–5 and 8–14mm) are required for a
number of applications including night vision cameras and
missile tracking, whereas FPAs operating in the FIR
region are particularly suited for applications in astron-
omy and space situational awareness (131). Most high-
performance FPAs developed so far have been based on
InSb, MCT, and QWIPs; however, QD-based FPAs have
also attracted the attention of infrared community because
of the development of successful single-element QDIPs
(6, 39, 128). Krishna et al. (132) have reported a
320� 256 pixel two-color FPA using an InAs/InGaAs
DWELL detector. According to Krishna et al., one of the
major drawbacks in developing QD-based FPAs is the
growth of thick active layers, providing sufficient absorp-
tion of radiation without causing misfit dislocations. The
growth of self-assembled QDs needs sufficient strain in the
QD regions, reducing the possibility of growing thick QD
layers. The two-color DWELL detector, which was used for
the FPA, showed wavelength selectivity with applied bias,
where a 5.5-mm peak was enabled at low bias and 8- to 10-
mm peak was activated by high biases. This has a peak
responsivity of 1A/W and D� of 2–7� 1010 cmHz1/2/W.
Thermal imaging using the FPA was demonstrated at
80K with different optical filters (3–5 and 8–12mm). More-
over, the operability of the FPA was reported to be greater
than 99%, and the noise equivalent temperature difference
(NEDT) was estimated to be less than 100mK for f/1 (for 3–
5mm) and f/2 (5–9mm) optics.
Gunapala et al. (33) have demonstrated a 640� 512
pixel QD-based IR imaging FPA operating in the LWIR
region. The detector was modeled on a DWELL structure,
where In-GaAs QDs were placed in a GaAs/AlGaAs QW.
The 30-stack DWELL detector has shown a peak absorp-
tion quantum efficiency of 2.7%. Under normal incidence
configuration, the detector had a much stronger (almost
one order of magnitude) responsivity compared to the
responsivity of a typical QWIP under 45� incidence config-
uration. In addition, it was found that the 45� incidence
responsivity of the detector (�1A/W) was four to five times
stronger than the normal incidence responsivity, as shown
in Figure 35(a). DWELL detectors can be fabricated with a
reflection grating to couple normal incidence light to the z-
polarization sensitive absorption mechanism in the
DWELL structure. A DWELL detector (reported by Guna-
pala et al. (33)) fabricated with a reflecting grating showed
a factor of 3–4 enhancement in the responsivity, as shown
in Figure 35(b). Peak detectivity of 1� 1010 cmHz1/2/W at
8.1mm and 77K was reported. Using this detector struc-
ture, a 640� 512 pixel FPA has been fabricated. Addition-
ally, a LWIR imagery system with a noise-equivalent
temperature difference of 40mK at 60K showing a
high uniformity was constructed. A 3-inch GaAs wafer
with twelve 640� 512 pixels QDIP FPAs is shown in
Figure 36(a), while an image of a human target
taken with the 640� 512 pixels FPA camera is shown in
Figure 36(b).
In a recent publication, Razeghi’s group demonstrated
(34) a 320� 256 pixel MIR focal plane array operating at
temperatures up to 200K. The FPA was based on a
DWELL structure (39), which consists of InAs QDs
imbedded in a InGaAs/InAlAs QW. It was reported that
the detector has two color characteristics up to room
24 Epitaxial Quantum Dot Infrared Photodetectors
3GW8218 08/26/2014 20:43:42 Page 25
temperature with response peaks at 3.2 and 4.1mm, as
shown in Figure 37. The photoresponse peak at 4.1mm
originated from bound-to-bound intersubband transitions
between delocalizedmixed states in the QD andQWunlike
the bound-to-bound transitions between pure QD states
and QW states for DWELL structures. The detector had a
peak responsivity of 34mA/W and maximum D� of
2.8� 1011 cmHz1/2/W at 120K, whereas a D� of 6� 107
cmHz1/2/W was obtained at 300K. The DWELL FPA
showed imaging capabilities at 120K and 200K. A conver-
sion efficiency of 1.1% and a noise equivalent temperature
difference of 344mK at 120K were observed. The FPA
camera is capable of imaging human targets up to 150K.
The images of a human target and a hot soldering iron
taken with the FPA camera at 130K and 200K, respec-
tively, are shown in Figure 38. Based on these results, it
Figure 35. (a) A comparison between the spectral responsivity of a DWELL detector measured under normal incidence and 45� incidenceconfigurations. (b) Normal incidence spectral responsivity with and without reflection gratings. After Reference 33.
Figure 36. (a) A 3-in. GaAs wafer with twelve 640� 512 pixels QDIP FPAs. (b) An image of a human target takenwith the 640�512 pixelsQDIP FPA camera. After Reference 33.
Figure 37. (a) Spectral responsivity of a DWELL detector at different temperatures under a (a) �1V bias and (b) �5V bias (response atroom temperature was obtained under a �2V bias). The variation of the response at room temperature is shown in the inset. After
Reference 39.
Epitaxial Quantum Dot Infrared Photodetectors 25
3GW8218 08/26/2014 20:43:48 Page 26
can be concluded that the development of QD-based FPAs
is feasible, even though the present QDIP FPAs show
lower overall performance as compared to MCT and
QWIP FPAs. Major improvements in QDIP FPAs include
high responsivity and low dark current at high tempera-
tures, improved growth quality, and uniformity in detector
material for large wafer sizes and device processing.
CONCLUSION
The electronic transitions between energy states in the QD
and QW give rise to multicolor response in DWELL detec-
tor structures. Response peaks experimentally obtained
from each detector correspond to the energy spacing cal-
culated by theoretical models. By changing the well width
and the size of the QD, detectors can be designed to operate
at different wavelength regions depending on the applica-
tion. The operating wavelength can be selected by varying
the applied bias. Advantages of DWELL detectors over
typical n-type QWIPs include their ability to operate under
normal incidence and at high temperatures particularly in
the VLWIR/FIR region. In a different approach, T-QDIP
detectors designed for room temperature operation and
terahertz detection were reported. As evident from the
results, T-QDIPs exhibit lower dark current, and higher
operating temperatures compared to typical QDIPs, which
were made possible by the incorporation of double-barriers
into the structure. A 17-mm T-QDIP detector that can
operate at room temperature and a 6 terahertz detector
operating at 150K were demonstrated. T-QDIPs are pho-
ton detectors, which are inherently fast, and do not use
slower thermalization processes, which is the primary
detection mechanism in thermal detectors such as bolom-
eter or TGS. In comparison with the Si BIB detectors, the
main advantage will be in the increase in operating tem-
perature to 77K or higher, which will greatly reduce the
cooling requirements. This would be an important feature
for space-based applications where moving from 20K to
higher temperatures is a major design advantage. Fur-
thermore, T-QDIP structures open up a wide range of
possible modifications and designing options to aid in
wavelength tuning and performance optimization.
Superlattice QDIP is another successful device architec-
ture for the bias-selectable dual-band detectors discussed
in this article. A SL-QDIP detector, showing the proof of
concept, exhibits two response peaks at 4.9 and 7.4mm,
which can be selected by changing the applied bias voltage.
In order to increase the quantum efficiency, a strategy
discussed here includes the use of p-type doped quantum
dots. Another region of the spectrum covered in this article
is the terahertz region and three different types of tera-
hertz structures (T-QDIP, intersubband QDIP, and QRIP)
were discussed. Among the three terahertz structures,
QRIP which utilized quantum rings (instead of quantum
dots) as light-absorbing domains showed the shortest
detection frequency (1.8THz). Promising results have
been observed for QD-based FPAs, even though the overall
performance is low compared with MCT and QWIP FPAs.
ACKNOWLEDGMENT
This work is supported in part by the National Science
Foundation under Grant ECCS 1232184. The authors
acknowledge the contributions of Prof. P. Bhattacharya
and his group at the University of Michigan and Prof. S.
Krishna and his group at University of New Mexico, and
the group members at GSU, especially Dr. Y. Lao and
Mr. S. Wolde.
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A. G. U. PERERA
Georgia State University, Atlanta
G. ARIYAWANSA
UES Inc., Dayton, Ohio, USA
30 Epitaxial Quantum Dot Infrared Photodetectors