IEEE Distinguished Seminar: "Space-Time Dualities and Temporal Imaging of Optical Waveforms" by Dr. Brian H. Kolner, 11.10.16/11:30-12.30PM/CREOL RM 103

IEEE Distinguished Seminar: "Space-Time Dualities and Temporal Imaging of Optical Waveforms" by Dr. Brian H. Kolner

Thursday, November 10, 2016 11:30 AM to 12:30 PM
CREOL Room 103

 

Prof. Brian H. Kolner

Abstract:There is an intriguing duality between the equations of Fresnel diffraction and narrowband dispersion. In addition, a quadratic time phase modulation applied to an optical waveform produces the dual of a lens; therefore, it can be thought of as a “time lens”. By combining appropriate dispersion before and after the time lens we can create the temporal analog of an imaging system which allows for magnification, demagnification and local time reversal of optical waveforms while preserving their envelope profiles. Time lenses can be realized by electro-optic modulation as well as optical parametric processes of both second and higher order. The requisite dispersion is realized by the natural dispersion available in optical fibers or with delay lines based on prisms or gratings. In this lecture I will develop the dualities between the diffraction and dispersion problems, present the defining characteristics of time lenses and develop the equations of temporal imaging, magnification, resolution, etc. Interesting applications include stretching time waveforms from the femtosecond to picosecond scale, pulse compression, signal processing and even temporal cloaking. The historical timeline for temporal imaging appears to have its roots in chirp radar, although all of the mathematics were available long before the advent of radar.

Biography:Brian Kolner received the B.S. degree in Electrical Engineering from the University of Wisconsin, Madison, in 1979 and the M.S. and Ph.D. degrees in Electrical Engineering from Stanford University, Stanford, CA, in 1981 and 1985, respectively. He was a Member of the Technical Staff at Hewlett-Packard Laboratories, Palo Alto, CA, from 1985 to 1991, and in 1991, he joined the Electrical Engineering Department at the University of California, Los Angeles (UCLA), and became Vice Chairman for Undergraduate Affairs in 1993. At UCLA, he taught courses in microwave theory and measurements, Fourier optics, and quantum mechanics and conducted research on space-time duality and temporal imaging. In 1996, he moved to the University of California, Davis, where he held joint appointments in the Departments of Applied Science, Electrical and Computer Engineering, and the Lawrence Livermore National Laboratory. His current research interests are in optical clocks, laser phase and amplitude noise, space-time analogies and terahertz spectroscopy. In 2015 he became a Visiting Scholar at the W. W. Hansen Laboratory of Experimental Physics at Stanford University where he collaborates on high-stability optical clocks. Dr. Kolner was awarded a David and Lucile Packard Foundation Fellowship in 1991. In 1996 and 2003 he served as Guest Editor for the IEEE Journal of Special Topics in Quantum Electronics. In 2009 Dr. Kolner shared an R&D 100 Award for developing the time-microscope, in 2010 he became a Fellow of the Optical Society of America and in 2012 he was elected a Fellow of the IEEE. He has been an IEEE Distinguished Lecturer for the Photonics Society for the 2015-2016 year and was recently named one of 125 People of Impact from the University of Wisconsin Electrical and Computer Engineering Department on occasion of their 125th anniversary.

For more information:
Juan He

OSA Graduate Research Symposium, 11.02.16/12:30-1:30PM/CREOL RM 103

OSA Graduate Research Symposium

Wednesday, November 2, 2016, 12:30-1:30 pm

CREOL Room 103

Ever wonder what the strange noises coming from the lab next to you are? Don’t really know what your friends and colleagues are actually working on? Come to the CREOL Graduate Research Symposium hosted by your OSA Student Chapter! This is a monthly symposium for CREOL students to present their work to other CREOL students. It’s a great opportunity to learn about other research being conducted within CREOL and to stimulate discussions and collaborations across different specializations. As a presenter, this provides a friendly informal atmosphere to polish your technical presenting skills or practice for an upcoming conference.

This month’s symposium features presentations by Peng Zhao from Dr. Eric Van Stryland/Dr. David Hagan ’s Nonlinear Optics group and Yangyang Sun from Dr. Shuo “Sean” Pang’s Optical Imaging Systems Laboratory group.

For more information:

Sepehr Benis

TOMORROW! OSA Student Chapter Seminar: "Casimir-like forces between particles under fluctuating optical fields" by J.J. Saenz

OSA Student Chapter Seminar: "Casimir-like forces between particles under fluctuating optical fields" by J.J. Saenz

Wednesday, October 26, 2016 12:00 PM to 1:00 PM
CREOL Room 103

J.J. Sáenz
Donostia International Physics Center (DIPC)

Abstract:

We review some basic concepts related to the optical forces on small (subwavelength) particles, focusing on the interplay between scattering asymmetry and momentum transfer. We show that artificially created random fluctuating light fields can be used to induce and control isotropic Casimir-like forces between small colloidal particles.

Biography:

Prof. Juan Jose Saenz is Ikerbasque Research Professor at the Donostia International Physics Center (DIPC) in San Sebastian (Spain). He was involved in the first works on magnetic force microscopy (MFM) in collaboration with Prof. Güntherodt’s group in Basel. He got his PhD at Universidad Auto´noma de Madrid (UAM) in 1987 and completed his postdoctoral research at IBM-Zurich in Dr. H. Rohrer’s group. In 2003 he was Invited Professor at École Centrale Paris and Professor in the Condensed Matter Physics Department at UAM until 2015. His research interests include theoretical work on nano-optics, optical forces, modelling of scanning probe microscopies (SPM) and wave transport and molecular imaging in complex media. He has published over 180 papers with more than 4700 citations (Web of Science’s H-factor 42). He is member of the Optical Society of America (OSA).

For more information:

Midya Parto 

TODAY! Seminar: "You and PRL" By Samindranath Mitra, 10.25.16/12:00PM-1:00PM/CREOL RM 103

Seminar: "You and PRL" By Samindranath Mitra

Tuesday, October 25, 2016 12:00 PM to 1:00 PM
CREOL Room 103

Samindranath Mitra
Editor, Physical Review Letters

Abstract:

As the focus of science journals changes from dissemination of research to validation of it, why should you continue to submit your best work to Physical Review Letters? What "added value" does and should the journal provide? How do its editors determine which of the approximately 10,000 papers that it receives each year to publish? I plan to address -- with plenty of interspersed Q & A and free-flowing discussion -- these and related issues.

Biography:

Samindranath (Sami) grew up in Kolkata and Delhi, and received his Ph.D. at Indiana University (Bloomington) in 1994 on theoretical aspects of the quantum Hall effect. After working on chemical physics at the Albert Einstein College of Medicine in New York City, he joined Physical Review Letters. In addition to overseeing much of condensed matter physics submissions for the journal, he handles papers on transport properties in semiconductors, 2D materials, and mesoscopic systems.

For additional information:

Dr. Aristide Dogariu

Seminar: "Highly nonlinear crystals for efficient mid-IR frequency conversion" by Peter G. Schunemann, 10.24.16/11:00AM-12:00PM/CREOL RM 103

Seminar: "Highly nonlinear crystals for efficient mid-IR frequency conversion" by Peter G. Schunemann

Monday, October 24, 2016 11:00 AM to 12:00 PM
CREOL Room 103

Peter G. SchunemannBAE Systems, Inc.

Abstract:

Advances in growth of the birefringent crystals ZnGeP₂ and CdSiP₂, as well as all-epitaxial processing of orientation-patterned semiconductors GaAs (OP-GaAs) and GaP (OP-GaP), are extending solid-state laser output deep into the mid-infrared. These materials exhibit the highest nonlinear coefficients and broadest infrared transparency ranges among all practical nonlinear optical crystals. In this review paper we describe the attractive properties of these materials, along with the unique capabilities and novel crystal growth and processing that continue to provide record-breaking conversion efficiencies and output powers in the mid-infrared.

Biography:

Peter G. Schunemann has been a leading researcher in nonlinear optical materials for the last 30 years, authoring or co-authoring over 300 publications and 6 patents in the field. He is best known for developing the NLO chalcopyrite semiconductor ZnGeP2 (ZGP) for 2-micron-pumped mid-IR optical parametric oscillators (OPOs) for defense applications, primarily infrared countermeasures (IRCM). He was the first to grow large, crack-free, ZGP single crystals with sufficient quality for devices. He patented horizontal gradient freeze (HGF) growth in high-temperature transparent furnaces, and applied novel defect compensation and processing to achieve > 10-fold improvements in absorption loss, laser damage threshold, and 3-5-µm output power (world record–classified). He scaled his R&D process for production of ZGP crystals fielded in hundreds of IRCM laser systems mounted on military aircraft, successfully protecting against simultaneous multi-missile attacks.He has since demonstrated transparent HGF growth of exotic ternary and multinary compounds (AgGa1-xInxSe2, AgGaGeS4, AgGaTe2, HgGa2S4, CdGa2S4, CdGa2Se4, CaGa2S4, SrGa2S4, CaGa2Se4, GaSe) and applied understanding of defect chemistry to dramatically reduce optical losses in two other NLO chalcopyrites: CdGeAs2 (the highest d-coefficient of any known inorganic compound) and AgGaSe2, resulting in record conversion efficiencies for frequency doubling CO2-lasers. Mr. Schunemann rcenetly patented a new NLO chalcopyrite, CdSiP2, with the highest NLO coefficient of any crystal transparent and phase-matchable at 1064 nm and 1550 nm. In addition to birefringent materials, he successfully transitioned all-epitaxial growth of orientation-patterned gallium arsenide (OP-GaAs) – the first practical quasi-phasematched (QPM) semiconductor - from Stanford/AFRL to industry. He established dedicated MBE systems with auxiliary chambers for QPM template growth, and constructed a $3M Hydride Vapor Phase Epitaxy (HVPE) growth facility. He scaled OP-GaAs to 3” wafers with thicknesses up to 3.5 mm, reduced absorption losses by 4X, demonstrated multi-watt mid-IR output, the first cw OP-GaAs OPO, and the first cw OPO in any material pumped at a wavelength > 1.55 µm. External collaborations have achieved efficient THz output and femtosecond mid-IR frequency combs using OP-GaAs. This technology has recently been extended to orientation-patterned gallium phosphide (OP-GaP), an OP-GaAs analog that can be pumped at 1 µm or 1.55 µm with transparency out to 12 µm for next-generation LWIR devices. Numerous fs frequency converters in the 412 µm range have been demonstrated based on OP-GaP.

For more information:

Dr. Kenneth Schepler

OSA Student Chapter Seminar: "Casimir-like forces between particles under fluctuating optical fields" by J.J. Saenz, 10.26.16/12:00PM-1:00PM/CREOL RM 103

OSA Student Chapter Seminar: "Casimir-like forces between particles under fluctuating optical fields" by J.J. Saenz

Wednesday, October 26, 2016 12:00 PM to 1:00 PM
CREOL Room 103

J.J. Sáenz
Donostia International Physics Center (DIPC)
juanjo.saenz@dipc.org

Abstract:

We review some basic concepts related to the optical forces on small (subwavelength) particles, focusing on the interplay between scattering asymmetry and momentum transfer. We show that artificially created random fluctuating light fields can be used to induce and control isotropic Casimir-like forces between small colloidal particles.

Biography:

Prof. Juan Jose Saenz is Ikerbasque Research Professor at the Donostia International Physics Center (DIPC) in San Sebastian (Spain). He was involved in the first works on magnetic force microscopy (MFM) in collaboration with Prof. Güntherodt’s group in Basel. He got his PhD at Universidad Auto´noma de Madrid (UAM) in 1987 and completed his postdoctoral research at IBM-Zurich in Dr. H. Rohrer’s group. In 2003 he was Invited Professor at École Centrale Paris and Professor in the Condensed Matter Physics Department at UAM until 2015. His research interests include theoretical work on nano-optics, optical forces, modelling of scanning probe microscopies (SPM) and wave transport and molecular imaging in complex media. He has published over 180 papers with more than 4700 citations (Web of Science’s H-factor 42). He is member of the Optical Society of America (OSA).

For more information:

Midya Parto 

LightPath Technologies Selected as a Recommended Lens Supplier for ULIS Micro80 Gen2TM Thermal Sensor Array

For Immediate Release: LightPath Technologies Selected as a Recommended Lens Supplier for ULIS Micro80 Gen2TM Thermal Sensor Array ORLANDO, FL – October 20, 2016 - LightPath Technologies, Inc. (NASDAQ: LPTH) (“LightPath,” the “Company” or “we”), a leading vertically integrated global manufacturer,distributor and integrator of proprietary optical and infrared components and high-levelassemblies, today announced its selection by ULIS as a recommended supplier of thermal imaging lens assemblies for use with the new ULIS Micro80 Gen2TM thermal sensor.  Based in France, ULIS produces one of the largest ranges of thermal image sensors in the world and participates in a global market for advanced sensors for smart buildings that, according to Navigant Research, will reach nearly $3.7 billion by 2020. LightPath offers a customized selection of wide field-of-view lenses compatible with the ULIS Micro80 Gen2TM sensor.  These sensors utilize LightPath’s high-quality chalcogenide glass and operate in the 8μm to 14μm long-wave infrared (LWIR) waveband.  LightPath’s engineering team has collaborated with ULIS engineers to achieve the optimal balance of performance and cost for wide field-of-view lenses.  Using chalcogenide glass, the lenses are light weight, passively athermal over a broad temperature range of -40°C to +85°C, and economically practical.  LightPath’s advanced precision glass molding expertise and proprietary tooling techniques enable a highly repeatable process that is scalable to high volume production. “LightPath is pleased to have been selected to cooperate with ULIS, which has a reputation for high quality products,” commented Steve Beninato, LightPath’s Executive Director of Global Sales and Marketing.  “As we strive to meet the needs of all of our customers, LightPath’s advanced engineering and high volume production capabilities are increasingly being recognized around the world.” ULIS, a manufacturer of innovative thermal sensors for the surveillance, thermography, firefighting, outdoor leisure and automotive markets, announced the availability of Micro80 Gen2, an advanced functionality thermal sensor. The fully digital Micro80 Gen2 not only supports standardized interfaces (i.e. I2C and HSync/VSync clocking), it also contains a series of improved characteristics, which make it ideal for large-volume applications and for easy integration into assembly processes. ULIS’ new Micro80 Gen2 multifunctional thermal sensor offers reliability thanks to the 80x80 pixel ratio. It can distinguish humans from animals or robots in all-weather and lighting conditions, 24/7 – without compromising privacy. This makes it ideal for occupancy detection in connected buildings, amongst other potential applications. About LightPath Technologies LightPath Technologies, Inc. (NASDAQ: LPTH) provides optics and photonics solutions for the industrial, defense, telecommunications, testing and measurement, and medical industries. LightPath designs, manufactures, and distributes optical and infrared components including molded glass aspheric lenses and assemblies, infrared lenses and thermal imaging assemblies, fused fiber collimators, and gradient index GRADIUM® lenses. LightPath also offers custom optical assemblies, including full engineering design support. For more information, visitwww.lightpath.com. About ULIS ULIS, a subsidiary of Sofradir, specializes in designing and manufacturing innovative thermal image sensors for commercial and defense applications. It enables makers of consumer electronics and infrared equipment to produce low weight, low power consumption and cost-effective thermal cameras in high volume. Founded in 2002, ULIS has grown to become the second largest producer of thermal image sensors (microbolometers). It offers a targeted range of microbolometers that are the key component of many top brands in thermal imaging equipment sold across Europe, Asia and North America. ULIS is active in the surveillance, thermography, firefighting, defense and outdoor leisure markets. Hundreds of thousands of its products are used to detect threats and thereby protect property, industrial sites, national borders and commuter systems as well as military personnel in combat zones. Other professionals choose thermal image devices equipped with ULIS’ products due to the affordability and quality of ULIS’ technology for mainstream commercial applications and the company’s expertise. Size, weight, low power consumption and cost reductions drive ULIS innovations, enabling the company to address new trends in smart buildings, road safety and in-cabin comfort of vehicles. ULIS is located in Veurey-Voroize, near Grenoble.https://www.ulis-ir.com This news release includes statements that constitute forward-looking statements made pursuant to the safe harbor provisions of the Private Securities Litigation Reform Act of 1995, including statements regarding our ability to expand our presence in certain markets, future sales growth, continuing reductions in cash usage and implementation of new distribution channels. This information may involve risks and uncertainties that could cause actual results to differ materially from such forward-looking statements. Factors that could cause or contribute to such differences include, but are not limited to, factors detailed by LightPath Technologies, Inc. in its public filings with the Securities and Exchange Commission. Except as required under the federal securities laws and the rules and regulations of the Securities and Exchange Commission, we do not have any intention or obligation to update publicly any forward-looking statements, whether as a result of new information, future events or otherwise.                                                                                     #### Company Contact: Steve Beninato, Executive Director of Global Sales and Marketing LightPath Technologies, Inc. Tel: 407-382-4003