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The papers in this volume were part of the technical conference cited on the cover and title page. Papers were selected and subject to review by the editors and conference program committee. Some conference presentations may not be available for publication. Additional papers and presentation recordings may be available online in the SPIE Digital Library at SPIEDigitalLibrary.org. The papers reflect the work and thoughts of the authors and are published herein as submitted. The publisher is not responsible for the validity of the information or for any outcomes resulting from reliance thereon. Please use the following format to cite material from these proceedings: Author(s), “Title of Paper,” in Active Photonic Platforms XI, edited by Ganapathi S. Subramania, Stavroula Foteinopoulou, Proceedings of SPIE Vol. 11081 (SPIE, Bellingham, WA, 2019) Seven-digit Article CID Number. ISSN: 0277-786X ISSN: 1996-756X (electronic) ISBN: 9781510628557 ISBN: 9781510628564 (electronic) Published by SPIE P.O. Box 10, Bellingham, Washington 98227-0010 USA Telephone +1 360 676 3290 (Pacific Time) · Fax +1 360 647 1445 Copyright © 2019, Society of Photo-Optical Instrumentation Engineers. Copying of material in this book for internal or personal use, or for the internal or personal use of specific clients, beyond the fair use provisions granted by the U.S. Copyright Law is authorized by SPIE subject to payment of copying fees. The Transactional Reporting Service base fee for this volume is $21.00 per article (or portion thereof), which should be paid directly to the Copyright Clearance Center (CCC), 222 Rosewood Drive, Danvers, MA 01923. Payment may also be made electronically through CCC Online at copyright.com. Other copying for republication, resale, advertising or promotion, or any form of systematic or multiple reproduction of any material in this book is prohibited except with permission in writing from the publisher. The CCC fee code is 0277-786X/19/$21.00. Printed in the United States of America by Curran Associates, Inc., under license from SPIE. Publication of record for individual papers is online in the SPIE Digital Library. Paper Numbering: Proceedings of SPIE follow an e-First publication model. A unique citation identifier (CID) number is assigned to each article at the time of publication. Utilization of CIDs allows articles to be fully citable as soon as they are published online, and connects the same identifier to all online and print versions of the publication. SPIE uses a seven-digit CID article numbering system structured as follows:
AuthorsNumbers in the index correspond to the last two digits of the seven-digit citation identifier (CID) article numbering system used in Proceedings of SPIE. The first five 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. Adams, Wyatt, 28 Addamane, Sadhvikas, 2A Al-Ghezi, Hammid, 04 Babicheva, Viktoriia E., 13 Balakrishnan, Ganesh, 2A Banerjee, Partha P., 04 Bassa, Juvenal, 2Q Behnam, A., 0V Bienstman, Peter, 1I Blanchard, Cédric, 2F Castillo-Barake, Jorge, 2Q Chang, T.-W., 0V Chou, Jeffrey B, 1S Dambre, Joni, 1I Dowling, Jonathan P., 2V Erdil, Mertcan, 2O Fang, Zhuoran, 1Q Felbacq, Didier, 0T Feng, Philip X.-L., 11 Fernandez Laguna, Victor Manuel, 2D Freiberger, Matthias, 1I Gandan, Shumithira, 2B Gartia, M. R., 0V Ghoshroy, Anindya, 28 Gnawali, Rudra, 04 Gonçalves, Claudia, 1S Gu, Tian, 1S Güney, Durdu Ö., 28 Habteyes, Terefe G., 2A Hakala, Tommi K., 1B Haq, Sharmin, 2A Heyroth, F., 20 Hu, Juejun, 1S Huffaker, Diana L., 2B Hugonin, Jean-Paul, 2F Ince, Fatih F., 13 Irfan, M., 2I Joannopoulos, John D., 27 Joglekar, Yogesh, 0G Kang, Myungkoo, 1S Karalis, Aristeidis, 27 Katumba, Andrew, 1I Kim, Hyunseok, 2B Kling, Emmanuel, 0T Kocaman, Serdar, 2O Laporte, Floris, 1I Lebron, Claudia Rivera, 2A Li, Junying, 1S Liberman, Vladimir, 1S Liu, G. L., 0V Lugnan, Alessio, 1I Ma, Chonghuai, 1I Mahigir, A., 0V Majumdar, Arka, 1Q Malloy, Kevin J., 2A Martikainen, Jani P., 1B Martin, Suzanne, 2G, 2I Matyas, Corey T., 2V Mejía-Cortés, Cristian, 2Q Merano, Michele, 0O Mizuno, Ayana, 2J Moilanen, Antti J., 1B Morales, Juan S. D., 2B Naydenova, Izabela, 2G, 2I Nečada, Marek, 1B Novikov, A., 20 Ochalski, Tomasz J., 2B O’Faolain, Liam, 2B Ono, Atsushi, 2J Orsel, Ogulcan E., 2O Ovcharenko, Anton I., 2F Panoiu, Nicolae C., 2D Patra, Bisweswar, 2A Petrov, M., 20 Rekola, Heikki T., 1B Ren, Qun, 2D Richardson, Kathleen, 1S Ríos, Carlos, 1S Roberts, Christopher, 1S Rogers, Brian, 2G Rousseau, Emmanuel, 0T Rutckaia, V., 20 Sackesyn, Stijn, 1I Sauvan, Christophe, 2F Schilling, J., 20 Schulze, D., 20 Shalaginov, Mikhail, 1S Shaleev, M., 20 Soref, Richard, 1S Suelzer, Joseph S., 0G Talalaev, V., 20 Törmä, Päivi, 1B Väkeväinen, Aaro I., 1B Vemuri, Gautam, 0G Veronis, Georgios, 0V, 2V Wang, Chih-Feng, 2A Wang, Yanan, 11 Wilkey, Andrew, 0G Xu, Peipeng, 1Q Xu, Zhemi, 0O Yanik, Cenk, 2O You, Chenglong, 2V Zhang, Qihang, 1S Zhang, Yifei, 1S Zheng, Jiajiu, 1Q Conference CommitteeSymposium Chairs
Symposium Co-chairs
Conference Chairs
Conference Program Committee
Session Chairs
IntroductionThe Active Photonic Platforms XI conference took place in San Diego, California, between August the 11th and 15th 2019. This was another most exciting event of this conference series with more than 100 keynote, invited and contributed presentations and many lively discussions focusing on the most recent developments on active or dynamic light manipulation with natural and structured photonic materials. We hope the brief conference overview we give below will provide the reader with a flavor of the fascinating research that was presented in the conference and a useful navigation guide for the associated papers and presentation recordings enclosed in this proceedings volume. Before we discuss the conference outline, with great sadness we note that in January 2019, Prof. Joseph (Joe) Haus, a program committee member of the conference, passed away. Dr. Haus was a Professor in the Electro-Optics and Photonics department at the University of Dayton, Dayton, Ohio (United States) and also a fellow of SPIE, APS and OSA. The conference started with a special session dedicated to his memory, which was organized and chaired by one of his long-time collaborators, Dr. Michael Scalora. We sincerely thank all collaborators and friends of Prof. Haus, Dr. Michael Scalora from US Army in Redstone Arsenal, Prof. Paras Prasad from University of Buffalo (United States), and Profs. Partha Banerjee and Andrew Sarangan from University of Dayton (United States), who made it possible to celebrate Prof. Haus’s life and achievements. The special session paid tribute not only to Prof. Haus’s exceptional body of work in non-linear and structured-material photonics but also to his tremendous service to the photonics discipline and his exemplary and inspiring dedication as a Professor and teacher. Prof. Haus was an incredible scientist and an incredible person. His bright example will most certainly be missed by everyone who knew him! One of the central themes of this conference involved the role of symmetry in photonics, how it emerges in real space or phase (wavevector) space and how it guides the design of new unprecedented paradigms for nanolasers and non-linear systems. Specifically, there were four sessions dedicated to topology and symmetry in photonics,– sessions 2, 3, 4 and 6[1]–, showcasing different unconventional light control effects with topological photonic states, non-reciprocal responses as well as conserved or broken parity-time (PT) symmetry in gain-loss non-Hermitian photonic platforms. A notable keynote presentation in session 4, inspired by counterpart systems in quantum mechanics, introduced a newfound route to photonic mode design: that of supersymmetry. Seemingly different photonic systems can be designed to be “twins”, in some respects, with completely aligned eigen-spectra, but with strategically engineered differences that can enable monomodal lasing operation via dissipation of parasitic modes. It is amazing that quantum mechanics has been a source of inspiration for photonic design since the advent of photonic crystals in the late 1980’s and apparently continues to be so to this date. Apart from photonic supersymmetry and PT symmetry, quantum mechanics spurred research in photonic bound states in continuum (BIC). These BICs look like optical trapped modes inaccessible by external light excitations either because of the symmetry or because of accidental destructive interference of any outgoing radiation channels. New extraordinary BIC-related phenomena, such as BIC for enhanced second harmonic generation (SHG), single-sided BIC, merged symmetry-protected and accidental BIC were discussed in couple of fascinating keynote presentations in sessions 12 and 15 but also an exciting invited presentation in session 6. Moreover, an interesting poster presentation explored a semi-analytical tool for the study of BIC phenomena based on Bloch-wave interference that permits an easier sweeping of the parameter space to identify accidental BICs. Tunable and dynamic photonic effects with structured photonic platforms are built upon the tunable and dynamic photonic responses of their material constituents. Atomically thin materials such as graphene, transition metal dichalcogenides (TMDs) as well as hBN are most promising for tunable and dynamic photonic responses due to their inherent sensitivity to external stimuli or optomechanical responses. Furthermore, metal oxides, metal nitrides and metal hydrides can have tunable permittivity responses that in some cases can be potentially dynamically controlled. A number of interesting keynote, invited and contributed presentations in sessions 5, 7 and 8 discussed such exciting capabilities for tunability and dynamic photonic effects with these material. Specifically, the presentations in these sessions reported on theoretical and experimental studies that further our understanding of the photonic responses of these materials as well as advance the know-hows for the practical realization of relevant photonic platforms that integrate these materials. Additionally, achievement of new or enhanced photonic functionalities with traditional platforms that integrate quasi-2D material were discussed. Other promising structuring routes to achieve enhanced tunable responses with photonic platforms that includes also systems with active semiconductor constituents and optomechanical tunability was explored by a diverse set of presentations in session 9. Furthermore, the conference featured two sessions (sessions 11 and 14) on photonics with phase-change materials (PCMs) which are materials that can change their structural and electronic properties with heating/cooling. These changes in structure and electronic properties may be volatile or non-volatile, depending on the particular material, affecting the respective photonic responses. The engaging keynote, invited, and contributed talks of these two sessions reported how to utilize PCMs for reconfigurable and switchable platforms including memories and infrared absorbers. In addition to such type of applications, one invited presentation also reported very promising research on how to improve the photonic responses of PCMs in the sense of improving the tunability of the refractive index without the adverse cost of simultaneously introducing a stronger extinction, i.e. higher photonic losses. Couple of presentations presented also results of electrically switchable PCM platforms, even with VO2 which is typically switched between its phases optically. This electrical phase control offers versatility and is promising for PCM-based integrated photonics. Emitters in complex photonic environments is an essential component to engineering nanoscale sources as well as for optical-based quantum computing applications. Several fascinating presentations in sessions 10, 15 and 18 focused both on advancing knowledge and theoretical tools to shed light on the intricate interactions between emitters and diverse photonic environments including 2D/quasi-2D materials as well as proposed platforms for room temperature quantum nanophotonics, helical-wave sources and nanolasing. Furthermore, nanolasing, non-linear and gain-material photonics were the overarching theme of sessions 16 and 18 that included amongst other topics intriguing reports on gain metamirrors and directional lasing. On the other hand, electromagnetic enhancement was discussed by presentations in session 17 within the context of applications for sensing, imaging and energy. The recent rapid pace of progress in machine and deep learning spurred explorations of related operations and neuromorphic signal processing with photonic platforms. Cross-cutting keynote and invited talks in sessions 12 and 13 discussed analog optical computing with nanophotonic platforms, advances in neuromorphic photonics including non-linear electro-optic activation functions and silicon photonics reservoir computing as well as plasmonic-nanoantennae-based encoding for high-density data storage. A fascinating keynote presentation also reported on 3D printed diffractive optical element network designed based on the principles of deep-learning computing platforms that could perform image classification of handwritten digits and fashion products. Along with the presentations discussed above, our conference also included a bustling poster session reporting advances in a variety of topics including dynamic signal control in waveguides as well as slow light waveguides, topological photonics, bound states in continuum, dynamic photopolymer material and magnetically-doped photopolymers for holographic sensors/actuators, perfect, spectrally selective or wideband absorbers, elastic nanophotonic material for dynamic tunability, exceptional points for design of lasing platforms, optomechanical sensors, new material with controlled losses, vortex solitons, microdisk lasers, dynamic nanophotonics with microfluidic cavities, methods for nanophotonic design optimization, thermal emitter design based on phonon polaritons, non-resonant photonic platforms, as well as deterministic fabrication of quantum emitter sources. For the past 5 years this conference runs a best student presentation competition which recognizes the best contributed orals presentations that were presented by a student author. The winners of the student award competition in 2019 were selected in a two-phase process. In the first phase of the competition the contributions are judged by the program committee of the Active Photonic Platforms conference, based on the submitted abstracts. Six contributions progressed to the second phase, which competed further on-site based on the oral presentation and were judged by a jury comprising expert attendees in the conference. This year we had three finalist winners that have tied in first place, enlisted below (the student presenter name is shown with bold font): 11081-21 [110810L]: Carrier kinetic models for intensity dependent refractive index in near-zero-index media Author(s): Ray Secondo, Nathaniel Kinsey, Virginia Commonwealth Univ. (United States) 11081-63 [110811S]: Designing nonvolatile integrated photonics with low-loss optical phase change materials Author(s): Yifei Zhang, Qihang Zhang, Massachusetts Institute of Technology (United States); Richard Soref, Univ. of Massachusetts Boston (United States); Tian Gu, Juejun Hu, Massachusetts Institute of Technology (United States) 11081-64 [110811T]: Electrical tuning of optical antenna resonance based on phase change material Author(s): Yifei Wang, Patrick Landreman, Kye Okabe, H.-S. Philip Wong, Mark Brongersma, Stanford Univ. (United States) We are delighted to congratulate the best student presentation winners and thank them for contributing these most amazing talks! The three winners enlisted above received an official SPIE certificate at the awards announcement session of the conference. See also coverage by SPIE in the awards and memberships photos section in the url below: https://spie.org/conferences-and-exhibitions/optics-and-photonics/highlights-photos-and-more With this opportunity we would like to also thank all student presenters for their enthusiastic participation in this competition contributing incredibly interesting research! Active Photonic Platforms XI covered a vast topical range involving active, dynamic, and tunable control of light with structured-material platforms as well as systems involving atomically thin and phase-change materials. Novel behaviors for light waves in passive platforms that would enable new research directions in active photonics have also been featured. Theorists and experimentalists exchanged ideas, state-of-the art results and lively discussions in a rapidly evolving area of research. As conference chairs, we would like to thank the program committee members of the conference, the session chairs as well as members of the best student presentation award jury for contributing in numerous ways to the success of this conference. We also sincerely thank all the authors of the 11081 conference who made this conference an interesting and stimulating event by engaging with their attendance and questions, presentations as well as manuscript contributions. Last but not least, we would like to thank all SPIE staff for their continuing and incredible support that made this event possible. Ganapathi S. Subramania Stavroula Foteinopoulou |