Analyzing the polarization of a circularly polarized light is a critical issue. We have fabricated a spiral nano-structure on the Au film by using focused ion beam etching technique. The fabricated structure can be used as a plasmonic circular polarization analyzer. By designing the relative orientation of two nano-apertures in the spiral structural unit, the propagation direction of the surface plasmon polaritons excited by circularly polarized light of opposite handedness can be controlled. Therefore, the spiral structure could be used to accurately determine the helicity of the excited circularly polarized light. Based on the results of scanning near-field optical microscopy, the obtained circular polarization extinction ratio of this structure was above 500. This structure can be used for a flexible detecting size and a very wide spectrum.

1.
W. L.
Barnes
,
A.
Dereux
, and
T. W.
Ebbesen
,
Nature (London)
424
,
824
(
2003
).
2.
Z. Y.
Fang
,
Q.
Peng
,
W. T.
Song
,
F. H.
Hao
,
J.
Wang
,
P.
Nordlander
, and
X.
Zhu
,
Nano Lett.
11
,
893
(
2011
).
3.
G. M.
Lerman
,
A.
Yanai
, and
U.
Levy
,
Nano Lett.
9
,
2139
(
2009
).
4.
B.
Lee
,
S.
Kim
,
H.
Kim
, and
Y.
Lim
,
Prog. Quantum Electron.
34
,
47
(
2010
).
5.
A. L.
Falk
,
F. H. L.
Koppens
,
C. L.
Yu
,
K.
Kang
,
N. D.
Snapp
,
A. V.
Akimov
,
M. H.
Jo
,
M. D.
Lukin
, and
H.
Park
,
Nat. Phys.
5
,
475
(
2009
).
6.
T.
Holmgaard
,
J.
Gosciniak
, and
S. I.
Bozhevolnyi
,
Opt. Express
18
,
23009
(
2010
).
7.
V. S.
Volkov
,
S. I.
Bozhevolnyi
,
K.
Leosson
, and
A.
Boltasseva
,
J. Microsc.
210
,
324
(
2003
).
8.
A. L.
Pyayt
,
B.
Wiley
,
Y. N.
Xia
,
A.
Chen
, and
L.
Dalton
,
Nat. Nanotechnol.
3
,
660
(
2008
).
9.
K.
Kneipp
,
Y.
Wang
,
H.
Kneipp
,
L. T.
Perelman
,
I.
Itzkan
,
R.
Dasari
, and
M. S.
Feld
,
Phys. Rev. Lett.
78
,
1667
(
1997
).
10.
J.
Yang
,
X.
Xiao
,
C.
Hu
,
W. W.
Zhang
,
S. X.
Zhou
, and
J. S.
Zhang
,
Nano Lett.
14
,
704
(
2014
).
11.
V. A.
Zenin
,
V. S.
Volkov
,
Z. H.
Han
,
S. I.
Bozhevolnyi
,
E.
Devaux
, and
T. W.
Ebbesen
,
Opt. Express
20
,
6124
(
2012
).
12.
Z. Y.
Fang
,
C. F.
Lin
,
R. M.
Ma
,
S.
Huang
, and
X.
Zhu
,
ACS Nano
4
,
75
(
2010
).
13.
W. T.
Song
,
Z. Y.
Fang
,
S.
Huang
,
F.
Lin
, and
X.
Zhu
,
Opt. Express
18
,
14762
(
2010
).
14.
J.
Lin
,
J. P. B.
Mueller
,
Q.
Wang
,
G. H.
Yuan
,
N.
Antoniou
,
X. C.
Yuan
, and
F.
Capasso
,
Science
340
,
331
(
2013
).
15.
F. J.
Rodriguez-Fortuno
,
G.
Marino
,
P.
Ginzburg
,
D.
O'Connor
,
A.
Martinez
,
G. A.
Wurtz
, and
A. V.
Zayats
,
Science
340
,
328
(
2013
).
16.
Y. M.
Liu
,
S.
Palomba
,
Y.
Park
,
T.
Zentgraf
,
X. B.
Yin
, and
X.
Zhang
,
Nano Lett.
12
,
4853
(
2012
).
17.
W. B.
Chen
,
D. C.
Abeysinghe
,
R. L.
Nelson
, and
Q. W.
Zhan
,
Nano Lett.
10
,
2075
(
2010
).
18.
E. D.
Palik
,
Handbook of Optical Constants of Solids
(
Academic
,
New York
,
1985
).
19.
Y.
Gorodetski
,
A.
Niv
,
V.
Klieiner
, and
E.
Hasman
,
Phys. Rev. Lett.
101
,
043903
(
2008
).
20.
N.
Shitrit
,
S.
Nechayev
,
V.
Kleiner
, and
E.
Hasman
,
Nano Lett.
12
,
1620
(
2012
).
21.
K. Y.
Bliokh
,
Y.
Gorodetski
,
V.
Klieiner
, and
E.
Hasman
,
Phys. Rev. Lett.
101
,
030404
(
2008
).
You do not currently have access to this content.