Intersubband absorption in coupled GaN/AlGaN double quantum wells (DQWs) has been measured. The samples were grown by molecular-beam epitaxy on a sapphire substrate and with large (0.65 or 0.9) AlN-mole fraction in the barriers. Peak absorption wavelengths as short as 1.35 and 1.52 μm were measured for a symmetric DQW of 12 Å wide wells coupled by a 10 Å wide barrier, which also showed evidence of excited-state anticrossing. As expected, asymmetric DQWs displayed no such anticrossing, and the ground-state anticrossing energies were found to be much smaller, as a result of the comparatively large effective electron mass, than the energy broadening of individual transitions. Degenerate doping of the DQWs was used to establish a common reference energy at the Fermi level, which allows overcoming uncertainties related to intrinsic internal electric fields. The asymmetric DQWs displayed peak absorption wavelengths between 1.5 and 2.9 μm.

Topics
Quantum wells, Epitaxy, Semiconductor device fabrication, Chemical properties, Doping
1.
N.
Suzuki
and
N.
Iizuka
,
Jpn. J. Appl. Phys., Part 2
36
,
L1006
(
1997
);
Google Scholar
 
N.
Suzuki
and
N.
Iizuka
,
Jpn. J. Appl. Phys., Part 2
38
,
L369
(
1999
);
Google Scholar
 
N.
Iizuka
,
K.
Kaneko
,
N.
Suzuki
,
T.
Asano
,
S.
Noda
, and
O.
Wada
,
Appl. Phys. Lett.
77
,
648
(
2000
);
Google Scholar
 
R. Kehl-Sink, G. Bahir, A. Abare, S. DenBaars, and J. Bowers, Technical Digest of the 1997 Electronic Materials Conference, 25–27 June 1997, Fort Collins, CO, Wide Bandgap Nitrides: Devices and Processing (1997);
T. Mozume, H. Yoshida, A. Neogi, N. Georgiev, K. Asakawa, and M. Kudo Proceedings of the 25th International Symposium on Compound Semiconductors, Nara, Japan (IOP, Publishing, Bristol, 1998);
C. P.
Garcia
,
A.
De Nardis
,
V.
Pellegrini
,
J. M.
Jancu
,
F.
Beltram
,
B. H.
Mueller
,
L.
Sorba
, and
A.
Franciosi
,
Appl. Phys. Lett.
77
,
3767
(
2000
);
Google Scholar
 
R.
Akimoto
,
Y.
Kinpara
,
K.
Akita
,
F.
Sasaki
, and
S.
Kobayashi
,
Appl. Phys. Lett.
78
,
580
(
2001
).
Google Scholar
 
2.
C.
Gmachl
,
H. M.
Ng
,
S.-N. G.
Chu
, and
A. Y.
Cho
,
Appl. Phys. Lett.
77
,
3722
(
2000
).
Google Scholar
 
3.
N.
Iizuka
,
K.
Kaneko
,
N.
Suzuki
,
T.
Asano
,
S.
Noda
, and
O.
Wada
,
Appl. Phys. Lett.
77
,
648
(
2000
).
Google Scholar
 
4.
C.
Gmachl
,
S. V.
Frolov
,
H. M.
Ng
,
S.-N. G.
Chu
, and
A. Y.
Cho
,
Electron. Lett.
37
,
378
(
2001
).
Google Scholar
 
5.
N.
Grandjean
,
B.
Damilano
,
S.
Dalmasso
,
M.
Leroux
,
M.
Laugt
, and
J.
Massies
,
J. Appl. Phys.
86
,
3714
(
1999
);
Google Scholar
 
F.
Bernardini
,
V.
Fiorentini
, and
D.
Vanderbilt
,
Phys. Rev. B
56
,
R10024
(
1997
).
Google Scholar
 
6.
H. M.
Ng
,
C.
Gmachl
,
S. N. G.
Chu
, and
A. Y.
Cho
,
J. Cryst. Growth
220
,
432
(
2000
);
Google Scholar
 
H. M.
Ng
,
S. N. G.
Chu
, and
A. Y.
Cho
,
J. Vac. Sci. Technol. A
19
,
292
(
2001
).
Google Scholar
 
7.
F.
Capasso
,
C.
Gmachl
,
R.
Paiella
,
A.
Tredicucci
,
A. L.
Hutchinson
,
D. L.
Sivco
,
J. N.
Baillargeon
,
A. Y.
Cho
, and
H. C.
Liu
,
IEEE J. Sel. Top. Quantum Electron.
6
,
931
(
2001
).
Google Scholar
 
8.
C.
Gmachl
,
H. M.
Ng
, and
A. Y.
Cho
,
Appl. Phys. Lett.
77
,
334
(
2000
).
Google Scholar
 
This content is only available via PDF.
© 2001 American Institute of Physics.
2001
American Institute of Physics
You do not currently have access to this content.