Temporal and amplitude modulation at C-band region using Bi2Te3-based optical modulator

被引：4

作者：

Ahmad, Harith ^{[1
,2
,3
]}

Yusoff, Norazriena ^{[1
]}

San Lim, Hwee ^{[4
]}

Jafri, Mohd Zubir Mat ^{[4
]}

Zulkifli, Mohd Zamani ^{[5
]}

Tiu, Zian Cheak ^{[6
]}

机构：

[1] Univ Malaya, Photon Res Ctr, Kuala Lumpur 50603, Malaysia

[2] Univ Malaya, Dept Phys, Kuala Lumpur 50603, Malaysia

[3] Airlangga Univ, Fac Sci & Technol, Dept Phys, Surabaya, Indonesia

[4] Univ Sains Malaysia, Sch Phys, George Town, Malaysia

[5] Univ Islam Antarabangsa Malaysia, Kulliyyah Sci, Kuantan, Malaysia

[6] Persialran Kewajipan USJ1, Fac Engn, SEGi Coll Subang Jaya, Uep Subang Jaya, Selangor, Malaysia

来源：

JOURNAL OF MODERN OPTICS | 2020年 / 67卷 / 07期

关键词：

Topological insulator; Q-switched; fibre laser; pulse modulator; amplitude modulator; C-band region; TOPOLOGICAL INSULATOR; FIBER LASER; GRAPHENE;

D O I：

10.1080/09500340.2020.1760955

中图分类号：

O43 [光学];

学科分类号：

070207 ; 0803 ;

摘要：

A temporal and amplitude modulator based on few-layers bismuth telluride (Bi2Te3) flakes is demonstrated for C-band operation. The few-layers thick Bi2Te3 flakes are prepared by mechanically exfoliating a Bi2Te3 crystal. As an optical pulse modulator, the Bi2Te3-based saturable absorber (SA) provides stable Q-switching operation at 1561.1 nm with a maximum repetition rate of 70.92 kHz and minimum pulse width of 2.38 mu s. As an optical amplitude modulator, two linear regions at different pump power ranges are obtained in the regression line of the peak intensity. The first linear region covers a pump power range from 0.0 to 80.32 mW and corresponds to a modulation efficiency of 0.05 dB/mW, while the second linear region covers a pump power range of 80.32-98.64 mW with a modulation efficiency of 0.81 dB/mW.

引用

页码：638 / 646

页数：9

共 50 条

[1] Tungsten disulfide-chitosan film as optical pulse and amplitude modulator in C-band region
Ahmad, H.
Ooi, S. I.
Yusoff, N.
Lim, H. S.
MatJafri, M. Z.
Thambiratnam, K.
Tiu, Z. C.
LASER PHYSICS, 2019, 29 (10)
[2] Segmented Generator Modules Using Bi2Te3-Based Materials
L. I. Anatychuk
L. N. Vikhor
L. T. Strutynska
I. S. Termena
Journal of Electronic Materials, 2011, 40 : 957 - 961
[3] Segmented Generator Modules Using Bi2Te3-Based Materials
Anatychuk, L. I.
Vikhor, L. N.
Strutynska, L. T.
Termena, I. S.
JOURNAL OF ELECTRONIC MATERIALS, 2011, 40 (05) : 957 - 961
[4] Bi2Te3-based 2 Te 3-based fl exible thermoelectrics
Chen, Mengran
Mao, Zhendong
Ji, Yuru
Zong, Peng-an
Zhang, Qihao
MATERIALS TODAY ENERGY, 2024, 44
[5] A thermoelectric cooling/heating knife using Bi2Te3-based bulks
Arakawa, K.
Yamaguchi, S.
STUDENT POSTERS (GENERAL) - 216TH ECS MEETING, 2010, 25 (33): : 75 - 80
[6] Electrochemical deposition of Bi2Te3-based thin films
Qiu, Liqin
Zhou, Jian
Cheng, Xuan
Ahuja, Rajeev
JOURNAL OF PHYSICS AND CHEMISTRY OF SOLIDS, 2010, 71 (08) : 1131 - 1136
[7] Complex Band Structures and Lattice Dynamics of Bi2Te3-Based Compounds and Solid Solutions
Fang, Teng
Li, Xin
Hu, Chaoliang
Zhang, Qi
Yang, Jiong
Zhang, Wenqing
Zhao, Xinbing
Singh, David J.
Zhu, Tiejun
ADVANCED FUNCTIONAL MATERIALS, 2019, 29 (28)
[8] Hygrothermal Stability of Bi2Te3-based Thermoelectric Materials
Xiao Yani
Lyu Jianan
Li Zhenming
Liu Mingyang
Liu Wei
Ren Zhigang
Liu Hongjing
Yang Dongwang
Yan Yonggao
JOURNAL OF INORGANIC MATERIALS, 2023, 38 (07) : 800 - +
[9] Progress in Bi2Te3-Based Superlattice Thermoelectric Materials
Bulman, Gary E.
Stokes, C. David
Barletta, Philip T.
Venkatasubramanian, Rama
ENERGY HARVESTING AND STORAGE: MATERIALS, DEVICES, AND APPLICATIONS II, 2011, 8035
[10] Fundamental and progress of Bi2Te3-based thermoelectric materials
Hong, Min
Chen, Zhi-Gang
Ziou, Jin
CHINESE PHYSICS B, 2018, 27 (04)

← 1 2 3 4 5 →