This PDF file contains the front matter associated with SPIE Proceedings Volume 9921, including the Title Page, Copyright information, Table of Contents, Introduction, and Conference Committee listing.
Kawata and Tsai: Front Matter: Volume 9921

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Author(s), “Title of Paper,” in Plasmonics: Design, Materials, Fabrication, Characterization, and Applications XIV, edited by Satoshi Kawata, Din Ping Tsai, Proceedings of SPIE Vol. 9921 (SPIE, Bellingham, WA, 2016) Six-digit Article CID Number.

ISSN: 0277-786X

ISSN: 1996-786X (electronic)

ISBN: 9781510602335

ISBN: 9781510602342 (electronic)

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Numbers in the index correspond to the last two digits of the six-digit citation identifier (CID) article numbering system used in Proceedings of SPIE. The first four digits reflect the volume number. Base 36 numbering is employed for the last two digits and indicates the order of articles within the volume. Numbers start with 00, 01, 02, 03, 04, 05, 06, 07, 08, 09, 0A, 0B...0Z, followed by 10-1Z, 20-2Z, etc.

Ahmadi, A. R., 27

Appusamy, Kanagasundar, 2Z

Bae, Ji Yong, 29

Bance, S., 1X

Bergman, David J., 0E

Bernasconi, G. D., 0W

Bianco, Giuseppe Valerio, 2Y

Black, Charles T., 38

Blair, Steve, 2Z

Bolorizadeh, M. A., 27

Bruno, Giovanni, 2Y

Buckanie, Niemma M., 10

Butet, J., 0W

Cennamo, N., 1A

Chaikina, Elena, 37

Chakrabarti, Subhananda, 2P

Chang, Ki Soo, 29

Chang, Robert P. H., 1M

Chavez, Marco, A., 24

Chen, Kuo-Ping, 22

Chu, Shi-Wei, 0D

Corso, Alain Jody, 1A, 3B

de Ceglia, Domenico, 2B, 2Y

de la Vega-Cobos, Armando, 24

De Los Santos García, S. I., 33, 3E

Diroll, Benjamin T., 1M

Donazzan, Alberto, 3B

D'Orazio, Antonella, 2Y

Eguchi, Akira, 0X

Escobedo, P. I., 24

Farhi, Asaf, 0E

Fernandez-Garcia, R., 1X

Fuentes, María E., 24

Gan, C. H., 1X

García Guzman, A., 33

García-Zárate, Marco A., 37

García, Raúl, 24

Gaspar Armenta, Jorge A., 24

Ghadi, Hemant J., 2P

Gibbs, W. E. Keith, 25

Grande, Marco, 2Y

Gu, Wenhua, 2H

Gubbins, M. A., 1X

Guo, Peijun, 1M

Guruswamy, Sivaraman, 2Z

Hardy, M. J., 1X

Hoseinian, M., 27

Jensen, Flemming, 0J

Jeong, Chan Bae, 29

Juodkazis, Saulius, 25

Kahl, Philip A., 10

Kawata, Y., 1H

Ketterson, John B., 1M

Khomenko, Anatoly V., 37

Kim, Geon-hee, 29

Kim, Youngsik, 0X

Kumar, Manish, 2V

Lai, Senfeng, 2H

Larsen, Pernille V., 0J

Lavrinenko, Andrei V., 0J

Li, Hui, 2F

Liapis, Andreas C., 38

López-Bastidas, Catalina, 30

Lu, Phat, 0X

Machorro, Roberto, 30

Makris, Andreas, 10

Malureanu, Radu, 0J

Mao, Jieying, 2Z

Mar, Mikkel D., 0J

Martin, O. J. F., 0W

Martínez Niconoff, G., 33, 3E

Martínez Vara, P., 3E

McClean-Ilten, Éadaoin, 1Z

Meyer zu Heringdorf, Frank J., 10

Milster, Tom D., 0X

Nam, Ki-Hwan, 29

Nápoles-Duarte, J. M., 24

Neira, A., 1X

Nihashi, S., 1H

Ono, A., 1H

Palodiya, Vikram, 2V

Pandey, Sushil Kumar, 2P

Pelizzo, Maria Guglielmina, 1A, 3B

Perera, M. Nilusha M. N., 25

Petranovskii, Vitalii P., 30

Podbiel, Daniel, 10

Raghuwanshi, Sanjeev K., 2V

Ramírez-Rodríguez, L. P., 24

Raß, Nicolai, 10

Rawool, Harshal, 2P

Rodríguez, Luz M., 24

Scalora, Michael, 2B, 2Y

Schaller, Richard D., 1M

Schmidt, Daniel, 25

Sfeir, Matthew Y., 38

Shkondin, Evgeniy, 0J

Smolentseva, Elena, 30

Stoddart, Paul R., 25

Sugita, A., 1H

Takayama, Osamu, 0J

Torres Rodríguez, M. A., 33, 3E

Tyagi, Lavi, 2P

Valencia-Caicedo, Cindy J., 37

Vargas Morales, M., 33, 3E

Vincenti, Maria A., 2B, 2Y

Wang, Yunshan, 2Z

Wu, Wen, 2H

Wu, Yongfeng, 2F

Yang, Jhen-Hong, 22

Yang, K.-Y., 0W

Yu, Changqiu, 2F

Yuan, Ping, 2F

Zapato-Chavez, Emiliano, 24

Zeni, L., 1A

Zerulla, Dominic, 1Z

Zhang, Yundong, 2F

Zuppella, Paola, 1A, 3B

Conference Committee

Symposium Chairs

  • Harry A. Atwater Jr., California Institute of Technology (United States)

  • Nikolay I. Zheludev, Optoelectronics Research Centre (United Kingdom) and Nanyang Technological University (Singapore)

Symposium Co-chairs

  • David L. Andrews, University of East Anglia (United Kingdom)

  • James G. Grote, Air Force Research Laboratory (United States)

Conference Chairs

  • Satoshi Kawata, Osaka University (Japan)

  • Din Ping Tsai, National Taiwan University (Taiwan)

Conference Program Committee

  • Martin Aeschlimann, Technische Universität Kaiserslautern (Germany)

  • Harry A. Atwater Jr., California Institute of Technology (United States)

  • David J. Bergman, Tel Aviv University (Israel)

  • Allan D. Boardman, University of Salford (United Kingdom)

  • Che Ting Chan, Hong Kong University of Science and Technology (Hong Kong, China)

  • Yun-Chorng Chang, Academia Sinica (Taiwan)

  • Harald W. Giessen, Universität Stuttgart (Germany)

  • Jean-Jacques Greffet, Institut d'Optique Graduate School (France)

  • Naomi J. Halas, Rice University (United States)

  • Martti Kauranen, Tampere University of Technology (Finland)

  • Fritz Keilmann, LASNIX (Germany)

  • Dai-Sik Kim, Seoul National University (Korea, Republic of)

  • Laurens K. Kuipers, FOM Institute for Atomic and Molecular Physics (Netherlands)

  • Mikhail Lapine, The University of Sydney (Australia)

  • Ai Qun Liu, Nanyang Technological University (Singapore)

  • Olivier J. F. Martin, Ecole Polytechnique Fédérale de Lausanne (Switzerland)

  • Peter Nordlander, Rice University (United States)

  • Lukas Novotny, University of Rochester (United States)

  • Vahid Sandoghdar, ETH Zurich (Switzerland)

  • George C. Schatz, Northwestern University (United States)

  • Tigran V. Shahbazyan, Jackson State University (United States)

  • Vladimir M. Shalaev, Purdue University (United States)

  • Gennady B. Shvets, Institute for Fusion Studies (United States)

  • Niek F. van Hulst, ICFO - Institut de Ciències Fotòniques (Spain)

  • Hongxing Xu, Wuhan University (China)

  • Nikolay I. Zheludev, University of Southampton (United Kingdom)

  • Joseph Zyss, Ecole Normale Supérieure de Cachan (France)

Session Chairs

  • 1 Novel Concepts of Plasmonics

    Nicholas I. Smith, Osaka University (Japan)

  • 2 Chiral Plasmonics

    Takuo Tanaka, RIKEN Center for Advanced Photonics (Japan)

  • 3 Molecular Plasmonics

    Shi-Wei Chu, National Taiwan University (Taiwan)

  • 4 Fundamentals of Plasmonics I

    Chen-Bin Huang, National Tsing Hua University (Taiwan)

  • 5 Fundamentals of Plasmonics II

    Yun-Chorng Chang, Research Center for Applied Sciences - Academia Sinica (Taiwan)

  • 6 Nanofabrication

    Zouheir Sekkat, Moroccan Foundation for Advanced Science, Innovation and Research (Morocco)

  • 7 Metamaterials and Metasurface I

    Dangyuan Lei, The Hong Kong Polytechnic University (Hong Kong, China)

  • 8 Nonlinear Plasmonics I

    Yi-Jun Jen, National Taipei University of Technology (Taiwan)

  • 9 Ultrafast Phenomenon

    Cheng Hung Chu, Academia Sinica (Taiwan)

  • 10 Plasmonics Sensing and Imaging I

    Fabrice Vallee, University Claude Bernard Lyon 1 (France)

  • 11 Plasmonics Sensing and Imaging II

    Atsushi Taguchi, Osaka University (Japan)

  • 12 Fundamentals of Plasmonics III

    Yun-Chorng Chang, Research Center for Applied Sciences - Academia Sinica (Taiwan)

  • 13 Nonlinear Plasmonics II

    Dai-Sik Kim, Seoul National University (Korea, Republic of)

  • 14 Graphene and Dielectrics Plasmonics

    Toshiharu Saiki, Keio University (Japan)

  • 15 Fundamentals of Plasmonics IV

    Min-Hsiung Shih, Academia Sinica (Taiwan)

  • 16 Plasmonics Applications I

    Ai Qun Liu, Nanyang Technological University (Singapore)

  • 17 Plasmonics Applications II

    Shulin Sun, Fudan University (China)


This proceedings volume contains papers presented at the 2016 SPIE Optics + Photonics conference on Plasmonics: Design, Materials, Fabrication, Characterization, and Applications XIV held 28 August–1 September 2016 in San Diego, California. The aim of the conference was to bring together specialists from diverse research areas and to provide a forum for the exchange of information on the latest progress of plasmonics, to accelerate their applications and to look at the directions in which research in this field is leading us.

The conference was divided into 17 sessions. In the first session, papers were related to novel concepts of plasmonics, such as catenary optical nano-structures, electrical tuning of an optical antenna, and 3D metamaterial absorber for attomole molecular detection.

The second session was chiral plasmonics as well, including plasmonic generators and angular momentum for light matter interactions, creation and application of surface plasmon vortices, extraordinary local angular momentum near metallic nanoparticles, and optical chirality in symmetrical plasmonic nanoparticles via geometrical transformation.

The third session was molecular plasmonics, transferring energy between molecules seven microns apart using surface plasmons and intracellular plasmonics by laser generation of nano-probes.

The fourth session dealt with fundamentals of plasmonics: strong coupling of dye molecules with surface plasmons and cavities; nonlinear scattering in plasmonic nanostructures; expanding the electric field in the eigenfunctions of the full Maxwell equations for a two-constituent composite medium with general external sources applied to a setup of a slab in a medium; high-precision Green’s function FDTD based on nonstandard finite differences for photonics design; and characterization of solid-supported ultrathin films and molecular interactions using MP-SPR.

The fifth session was on fundamentals of plasmonics, such as engineering ultra-narrow plasmon resonances, fabrication of deep-profile AZO one- and two-dimensional lattices as plasmonic elements, and fano resonances arising from coupled surface plasmon polariton and waveguide modes.

The sixth session’s topic was nanofabrication, including large-scale nanofabrication of periodic nanostructures using nanosphere-related techniques for applications in green technology; large-area arrays of gold nanostructures from azopolymer templates; ultrasonic spray coating as a scale-up technique for the deposition of hybrid magnetic-plasmonic nanocomposites; and surface enhanced Raman scattering (SERS) based on entrapment of plasmonic nanoparticles using local heating induced surface bubbles.

The seventh session was devoted to metamaterials and metasurface, including optical coatings for metamaterials; de-magnifying hyperlens: experimental demonstration and potential applications; dependence of organic dyes PL-lifetime on distance from transverse positive and negative hyperbolic metamaterials; tunable metasurfaces and nanoantennas with liquid crystals; and dual channel fluorescence radiation engineering on nano-patterened plasmonic metasurface.

The eighth session was also related to nonlinear plasmonics, including localized surface plasmon enhanced and modulated nonlinear optical processes: second harmonic generation and upconversion emissions, new numerical methods for the design of efficient nonlinear plasmonic sources of light and nanosensors, and characterization of multiphoton emission from aggregated gold nano particles.

The ninth session was ultrafast phenomenon: ultrafast nonlinear plasmonic response of a single metal nano-object, nonlinear emission of electrons from plasmonic fields, direct measurements of the femtosecond dynamics of Tamm plasmon-polaritons, and probing carrier dynamics in wide-bandgap semiconductor-metal nanoparticle hybrids.

The tenth session was plasmonics sensing and imaging: plasmonic core-satellite assemblies with high stability and yield, near perfect light trapping in 2D metallic nano-trenches at oblique angle of incidence and its sensor application; and SERS-active substrate with nano-meso plasmonic architecture.

The eleventh session was also about plasmonics sensing and imaging. We had papers presented on near-field imaging and spectroscopy of plasmonic cavities, super-resolution optical nano imaging through transparent, on-a-chip plasmonic platform for the multiplexed quantitative detection of cancer biomakers in serum, and refractometers for different refractive index range by surface plasmon resonance sensors in multimode optical fibers with different metals.

The twelfth session was fundamentals of plasmonics, which included resolving nanophotonic spectra with quasi-normal modes, optical response of noble metal alloys, understanding plasmonic materials and geometries: confinement versus propagation length, and non-plasmonic nanostructures for subwavelength nonlinear optics.

The thirteenth session was on nonlinear plasmonics: non-von Neumann computing using plasmon particles interacting with phase change materials, grains of plasmonic probe for efficient TERS, and second-order nonlinearities of 2D periodic arrays of Au nanorods at surface plasmon resonances.

The fourteenth session was graphene and dielectrics plasmonics papers on colossal terahertz nonlinearity of tunneling van der Waals gap; nonlinear graphene plasmonics; gallium-doped zinc oxide plasmonic nanostructures for mid-IR applications; infrared perfect absorbers and filters using doping tunable zinc oxide structures; and enhanced all-optical modulation of the visible spectrum with tindoped indium oxide nanorod arrays.

The fifteenth session dealt with fundamentals of plasmonics, including manipulating the interface states between a photonic crystal and a metasurface, a new concept to design the high efficiency surface plasmon coupler, quantum interference of highly-dispersive surface plasmons, a library of planar plasmonic resonators, and shape matters: tuning plasmonic resonances in single nanoparticles and their arrays.

The sixteenth session was also devoted to plasmonics applications, such as liquid-phase tunable metasurfaces and light manipulation, high circular dichroism ultraviolet lasing from planar spiral metal-gallium-nitride nanowire cavity, the effect of Coulomb interaction on spasing conditions in small nanoparticles, and plasmonic hot carrier mediated photon upconversion in GaN/InGaN quantum wells.

The seventeenth session was also focused on plasmonics applications. We had papers presented on ultraviolet plasmonic nanolaser with hyperbolic metamaterial; design strategies for plasmonic near-field transducers in heat-assisted magnetic recording: 1D Fourier approach; selectively inducing optical magnetism; nanoscale tailored plasmonic material for optimum broadband solar harvesting; and horizontal toroidal response in three-dimensional plasmonic metamaterial.

Satoshi Kawata

Din Ping Tsai

© (2016) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE). Downloading of the abstract is permitted for personal use only.
"Front Matter: Volume 9921", Proc. SPIE 9921, Plasmonics: Design, Materials, Fabrication, Characterization, and Applications XIV, 992101 (7 December 2016); doi: 10.1117/12.2261054; https://doi.org/10.1117/12.2261054

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