A scheme of terahertz (THz) radiation generation is proposed by beating of two spatial-triangular laser beams in plasma with a spatially periodic density when electron–neutral collisions have taken into account. In this process, the laser beams exert a ponderomotive force on the electrons of the plasma and impart the oscillatory velocity at the difference frequency in the presence of a static magnetic field which is applied parallel to the direction of the lasers. We show that higher efficiency and stronger THz radiation are achieved when the parallel magnetic field is used to compare the perpendicular magnetic field. The effects of beam width of lasers, collision frequency, periodicity of density ripples, and magnetic field strength are analyzed for strong THz radiation generation. The THz field of the emitted radiations is found to be highly sensitive to collision frequency and magnetic field strength. In this scheme with the optimization of plasma parameters, the efficiency of order 21% is achieved.

1.
Y. C.
Shen
,
T.
Lo
,
P. F.
Taday
,
B. E.
Cole
,
W. R.
Tribe
, and
M. C.
Kemp
,
Appl. Phys. Lett.
86
,
241116
(
2005
).
2.
H.
Zhong
,
A.
Redo-Sanchez
, and
X. C.
Zhang
,
Opt. Express
14
,
9130
(
2006
).
3.
V. L.
Bartman
,
A. G.
Litvak
, and
E. V.
Suvorov
,
Phys.-Usp.
54
,
837
(
2011
).
4.
E.
Pickwell
and
V. P.
Wallace
,
J. Phys. D: Appl. Phys.
39
,
R301
(
2006
).
5.
I. F.
Akyildiz
,
J. M.
Jornet
, and
C. H.
Han
,
Phys. Commun.
12
,
16
32
(
2014
).
6.
M. C.
Beard
,
G. M.
Turner
, and
C. A.
Schmuttenmaer
,
J. Phys. Chem. B
106
,
7146
(
2002
).
7.
H.
Tao
,
W. J.
Padilla
,
X.
Zhang
, and
R. D.
Averitt
,
IEEE J. Sel. Top. Quantum Electron.
17
,
92
(
2011
).
8.
T.
Kleine-Ostmann
and
T.
Nagatsuma
,
J. Infrared, Millimeter, Terahertz Waves
32
,
143
171
(
2011
).
9.
A. Y.
Pawar
,
D. D.
Sonawane
,
K. B.
Erande
, and
D. V.
Derle
,
IEEE Drug Invent. Today
5
(
2
),
157
163
(
2013
).
10.
K. W.
Kim
,
H.
Kim
,
J.
Park
,
J. K.
Han
, and
J.-H.
Son
,
IEEE Trans. Terahertz Sci. Technol.
2
,
99
(
2012
).
11.
D.
Hashimshony
,
A.
Zigler
, and
K.
Papadopoulos
,
Appl. Phys. Lett.
74
(
12
),
1669
1671
(
1999
).
12.
J. F.
Holzman
and
A. Y.
Elezzabi
,
Appl. Phys. Lett.
83
,
2967
2969
(
2003
).
13.
I.
Al-Naib
,
G.
Sharma
,
M.
Dignam
,
H.
Hafez
,
A.
Ibrahim
,
D. G.
Cooke
,
T.
Ozaki
, and
R.
Morandotti
,
Phys. Rev. B
88
,
195203
(
2013
).
14.
Z.
Chen
,
X.
Zhou
,
C. A.
Werley
, and
K. A.
Nelson
,
Appl. Phys. Lett.
99
,
071102
(
2011
).
16.
K. L.
Vodopyanov
,
Laser Photonics Rev.
2
(
1–2
),
11
25
(
2008
).
17.
Y.
Jiang
,
D.
Li
,
Y. J.
Ding
, and
I. B.
Zotova
,
Opt. Lett.
36
,
1608
1610
(
2011
).
18.
P. U.
Jepsen
,
R. H.
Jacobsen
, and
S. R.
Keiding
,
J. Opt. Soc. Am. B
13
(
11
),
2424
2436
(
1996
).
19.
Y. S.
Lee
,
T.
Meade
,
V.
Perlin
,
H.
Winful
,
T. B.
Norris
, and
A.
Galvanauskas
,
Appl. Phys. Lett.
76
(
18
),
2505
2507
(
2000
).
20.
L.
Yu-Tong
,
W.
Wei-Min
,
L.
Chun
, and
S.
Zheng-Ming
,
Chin. Phys. B
21
,
095203
(
2012
).
21.
Z. M.
Sheng
,
K.
Mima
,
J.
Zhang
, and
H.
Sanuki
,
Phys. Rev. Lett.
94
,
095003
(
2005
).
22.
H.
Hamster
,
A.
Sullivan
,
S.
Gordon
,
W.
White
, and
R. W.
Falcone
,
Phys. Rev. Lett.
71
,
2725
(
1993
).
23.
H.
Hamster
,
A.
Sullivan
,
S.
Gordon
, and
R. W.
Falcone
,
Phys. Rev. E
49
,
671
(
1994
).
24.
R.
Fedele
,
U. D.
Angelis
, and
T.
Katsouleas
,
Phys. Rev. A
33
(
6
),
4412
4414
(
1986
).
25.
S.
Chauhan
and
J.
Parashar
,
Phys. Plasmas
21
,
103113
(
2014
).
26.
Y.
Chen
,
M.
Yamaguchi
,
M.
Wang
, and
X. C.
Zhang
,
Appl. Phys. Lett.
91
,
251116
(
2007
).
27.
A. K.
Malik
and
K. P.
Singh
,
Laser Part. Beams
33
,
519
524
(
2015
).
28.
T. M.
Antonsen
,
J.
Palastro
, and
H. M.
Michberg
,
Phys. Plasmas
14
,
033107
(
2007
).
29.
C.
Weiss
,
R.
Wallenstein
, and
R.
Beigang
,
Appl. Phys. Lett.
77
,
4160
(
2000
).
30.
V. A.
Kukushkin
,
Europhys. Lett.
84
,
60002
(
2008
).
31.
P.
Varshney
,
V.
Sajal
,
K. P.
Singh
,
R.
Kumar
, and
N. K.
Sharma
,
Laser Part. Beams
31
,
337
344
(
2013
).
32.
X.
Sun
and
X.-C.
Zhang
,
Appl. Phys. Lett.
104
,
191106
(
2014
).
33.
A. K.
Malik
,
H. K.
Malik
, and
S.
Kawata
,
J. Appl. Phys.
107
(
11
),
113105
(
2010
).
34.
H. K.
Malik
and
A. K.
Malik
,
Appl. Phys. Lett.
99
(
25
),
251101
(
2011
).
35.
A. K.
Malik
,
H. K.
Malik
, and
U.
Stroth
,
Phys. Rev. E
85
(
1
),
016401
(
2012
).
36.
P.
Jha
and
N. K.
Verma
,
Phys. Plasmas
21
,
063106
(
2014
).
37.
R. K.
Singh
and
R. P.
Sharma
,
Phys. Plasmas
21
,
113109
(
2014
).
38.
A. K.
Malik
,
K.
Pal Singh
, and
V.
Sajal
,
Phys. Plasmas
21
,
073104
(
2014
).
39.
M.
Singh
,
R. K.
Singh
, and
R. P.
Sharma
,
Europhys. Lett.
104
(
3
),
35002
(
2013
).
40.
D.
Singh
and
H. K.
Malik
,
Phys. Plasmas
21
,
083105
(
2014
).
41.
D.
Singh
and
H. K.
Malik
,
Plasma Sources Sci. Technol.
24
(
4
),
045001
(
2015
).
42.
A. K.
Malik
,
H. K.
Malik
, and
Y.
Nishida
,
Phys. Lett. A
375
,
1191
(
2011
).
43.
A. K.
Malik
,
H. K.
Malik
, and
U.
Stroth
,
Appl. Phys. Lett.
99
,
071107
(
2011
).
44.
A. K.
Malik
and
H. K.
Malik
,
IEEE J. Quantum Electron.
49
(
2
),
232
(
2013
).
45.
P.
Varshney
,
V.
Sajal
,
K. P.
Singh
,
R.
Kumar
, and
N. K.
Sharma
,
Laser Part. Beams
33
,
51
58
(
2015
).
46.
J. A.
Bittencourt
,
Fundamentals of Plasma Physics
, 3rd ed. (
Springer-Ver1ag
,
New York
,
2004
).
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