[INVITED] Biomimetic photonic structures for optical sensing

被引:20
|
作者
Martin-Palma, Raul J. [1 ,2 ]
Kolle, Mathias [3 ]
机构
[1] Penn State Univ, Dept Mat Sci & Engn, University Pk, PA 16802 USA
[2] Univ Autonoma Madrid, Dept Fis Aplicada, Madrid, Spain
[3] MIT, Dept Mech Engn, Cambridge, MA 02139 USA
来源
OPTICS AND LASER TECHNOLOGY | 2019年 / 109卷
基金
美国国家科学基金会;
关键词
Biomimetics; Optical sensor; Infrared sensor; Chemical sensor; Aerospace; Mechanical sensor; CONVERGENT EVOLUTION; INFRARED DETECTION; IRIDESCENCE; HYDROGELS; COLORS; SQUID; COLORATION; INSECTS; SENSORS; DESIGN;
D O I
10.1016/j.optlastec.2018.07.079
中图分类号
O43 [光学];
学科分类号
070207 ; 0803 ;
摘要
This perspective reviews a selection of optical sensors, which have been developed using biomimetic photonic structures. In particular, we discuss how biomimetic-based design strategies have led to the successful fabrication of infrared, chemical, and mechanical sensors, as well as sensors for aerospace applications and robotics.
引用
收藏
页码:270 / 277
页数:8
相关论文
共 50 条
  • [41] Index Guiding Photonic Crystal Fibers for Optical Sensing
    Nandan, Pushkar
    Mahanta, Lipsa
    Kumar, Pranaw
    PROCEEDINGS OF THE 2018 IEEE INTERNATIONAL CONFERENCE ON COMMUNICATION AND SIGNAL PROCESSING (ICCSP), 2018, : 327 - 330
  • [42] The field enhancement and optical sensing in the surface photonic chrystal
    Ivanov, Andrey V.
    Boginskaya, Irina A.
    Vaskin, Alexander V.
    Afanas'ev, Konstantin N.
    Ryzhikov, Ilya A.
    Lagarkov, Andrey N.
    Sarychev, Andrey K.
    Kurochkin, Ilya N.
    Budashov, Igor A.
    PROCEEDINGS OF THE INTERNATIONAL CONFERENCE DAYS ON DIFFRACTION 2015, 2015, : 146 - 149
  • [43] Sensing with optical vortices in photonic-crystal fibers
    Demas, J.
    Grogan, M. D. W.
    Alkeskjold, T.
    Ramachandran, S.
    OPTICS LETTERS, 2012, 37 (18) : 3768 - 3770
  • [44] Research progress of on-chip integrated optical sensing technology (Invited)
    Chen Q.
    Nan X.
    Liang W.
    Zheng Q.
    Sun Z.
    Wen L.
    Hongwai yu Jiguang Gongcheng/Infrared and Laser Engineering, 2022, 51 (01):
  • [45] Photonic microwave measurements (Invited)
    Lu B.
    Zou X.
    Hongwai yu Jiguang Gongcheng/Infrared and Laser Engineering, 2021, 50 (07):
  • [46] Silicon photonic structures with embedded polymers for novel sensing methods
    E. V. Osipov
    I. L. Martynov
    D. S. Dovzhenko
    P. S. Ananev
    G. E. Kotkovskii
    A. A. Chistyakov
    Optics and Spectroscopy, 2017, 122 : 74 - 78
  • [47] Silicon photonic structures with embedded polymers for novel sensing methods
    Osipov, E. V.
    Martynov, I. L.
    Dovzhenko, D. S.
    Ananev, P. S.
    Kotkovskii, G. E.
    Chistyakov, A. A.
    OPTICS AND SPECTROSCOPY, 2017, 122 (01) : 74 - 78
  • [48] Nanophotonic Structures for Sensing: Exploiting Photonic Crystal and Metamaterial Concepts
    De La Rue, Richard M.
    Lahiri, Basudev
    McMeekin, Scott G.
    Johnson, Nigel P.
    2012 INTERNATIONAL CONFERENCE ON FIBER OPTICS AND PHOTONICS (PHOTONICS), 2012,
  • [49] Tunable porous photonic bandgap structures for chemical and biological sensing
    Kim, Sung Jin
    Chodavarapu, Vamsy P.
    Kamal, Firdous
    Hsiao, Vincent K. S.
    Cartwright, Alexander N.
    Swihart, Mark T.
    Prasad, Paras N.
    Bunning, Timothy J.
    TUNING THE OPTIC RESPONSE OF PHOTONIC BANDGAP STRUCTURES III, 2006, 6322
  • [50] Optical Sensing of Ion Flux through Biomimetic Carbon Nanotube Channels
    Zheng, Pengyu
    Noy, Aleksandr
    Wanunu, Meni
    Yao, Yun-Ciao
    BIOPHYSICAL JOURNAL, 2019, 116 (03) : 243A - 243A
12345