Monday, December 1, 2014

TOMORROW! Seminar: "Self-phase modulation in lithium niobate waveguides" by Dr. Roland Schiek 12.2.14/11:00am-12:00pm/ CREOL 103

Seminar: "Self-phase modulation in lithium niobate waveguides" by Dr. Roland Schiek
Tuesday, December 2, 2014 11:00 AM to 12:00 PM
CREOL Room 103

Dr. Roland Schiek
Ostbayerische Technische Hochschule Regensburg
Regensburg, Germany

Abstract:
Self-phase modulation in lithium niobate waveguides with cascaded quadratic and cubic nonlinearities is characterized by comparison of amplitude and phase of input and output pulse envelopes and spectra. Cubic nonlinear susceptibility coefficients of lithium niobate were determined from the measured nonlinear phase shifts. 
In non-centrosymmetric crystals typical cubic nonlinear effects like soliton propagation, modulational instability and supercontinuum generation are observed at power levels well below the expected values corresponding to the cubic nonlinear susceptibility. Responsible is a cascading of the quadratic non-linearity which mimics the third-order nonlinearity. Often considered relevant only close to phase-matching of the quadratic mixing, it was recently pointed out that the cascaded nonlinearity dominates the third-order nonlinearity in a much wider range. The most basic experimental evidence of a cubic nonlinearity is self-phase modulation (SPM). The first measurements of SPM in pure cubic nonlinear fibers needed long interaction lengths and were performed only in the spectral domain. Therefore, the most distinguished characteristic of SPM, the similarity of the variation in time of both, the pulse intensity and the nonlinear phase shift were not observed directly. With a measurement of the complex pulse envelope of pulses propagating in lithium niobate (LiNbO3) waveguides in addition to spectral measurements a complete characterization of SPM was performed in only cm-long samples. The contribution of different orders of the dielectric nonlinearity to the non-linear refraction could be identified and separated for a wide phase-mismatch range because the cubic nonlinearity is independent of the phase-mismatch in contrast to the changing cascaded quadratic nonlinearity. For specific geometries the cascaded nonlinearity dominates the cubic nonlinearity also far from phase-matching. By comparing quadratic and cubic contributions important elements of the cubic nonlinear susceptibility tensor of lithium niobate at wavelengths of 1.32mm and 1.55mm were determined.

For additional information:
Dr. Demetrios Christodoulides

407-882-0074

Friday, November 21, 2014

TODAY! Seminar: "Novel femtosecond lasers for driving attosecond generation" by Dr. Zhiyi Wei 11.21.14/11:00am-12:00pm/ CREOL 103

Seminar: "Novel femtosecond lasers for driving attosecond generation" by Dr. Zhiyi Wei
Friday, November 21, 2014 11:00 AM to 12:00 PM
CREOL Room 103

Zhiyi Wei
Institute of Physics, Chinese Academy of Sciences

 Abstract
Development of femtosecond lasers operating at new wavelengths has attracted great attention for increasing photon energy and flux of attosecond pulses. We have generated isolated 160 as pulses with carrier envelope phase controlled sub-5 fs laser at 800nm. In this talk I will introduce our recent works on laser frequency extension. By using 4H-SiC as the nonlinear crystal in femtosecond OPA experiment, 17 mJ pulses centered at 3.7mm were obtained. Choosing BBSAG as the nonlinear crystal in sum frequency generation, high conversion efficiency at 200 nm was achieved. These light sources can be used as attosecond driving lasers.

 Biography
Dr. Zhiyi Wei was born in Gausu Province, China in 1963. He obtained Ph.D Degree from Xian Institute of Optics and Fine Mechanics, Chinese Academy of Sciences in 1991. After two years postdoctoral fellow at Ultrafast Laser Spectroscopy Lab at Sun Yat-Sen University in China, he worked at the Rutherford Appleton Lab in UK, the Chinese University of Hong Kong, the Hong Kong University of Science and Technology, University of Groningen in the Netherland as a visiting scholar from May 1993 to March 1997. He joined the Laboratory of Optical Physics, Institute of Physics, Chinese Academy of Sciences in 1997. From April 2000 to Sept 2002, he was also employed by the National Institute of Advanced Industrial Science and Technology (AIST) in Japan as a NEDO fellowship researcher. His research interests focus on the generation, phase control, amplification and compression of femtosecond laser pulses. Presently he is the group leader of Ultrafast Laser Group at the Institute of Physics, Chinese Academy of Sciences. He is also the international advisory member of the IoP journal for Measurement Science and Technology, member of C2 (Symbol and Constants) sub-committee of International Union of Pure and Applied Physics (IUPAP).

For additional information:
Dr. Zenghu Chang

407-823-4442

TODAY! Seminar "Space-Division Multiplexed Transmission over Few-Mode-Fiber" by Dr. Nicolas Fontaine 11.21.14/2:00-3:00pm/ CREOL 103

Seminar "Space-Division Multiplexed Transmission over Few-Mode-Fiber" by Dr. Nicolas Fontaine
Friday, November 21, 2014 2:00 PM to 3:00 PM
CREOL Room 103

Dr. Nicholas Fontaine
Bell Laboratories
Crawford Hill, NJ

Abstract
Space-division multiplexed (SDM) systems use the multiple spatial modes in either multi-core fiber (separated modes), or the spatially overlapping but orthogonal modes in few-mode fibers to either increase the capacity or photon-efficiency of fiber links.The new challenges in SDM are how to couple into and out of the various SDM fibers without insertion loss (IL) or mode-dependent loss (MDL), and building components that have comparable performance to, and that offer a cost advantage over systems using multiple single-mode fibers.  I will show several components for space-division multiplexing in few-mode fibers including "photonic lantern" spatial multiplexers which are lossless adiabatic single-mode to multi-mode converters, and wavelength selective switches for routing signals in few-mode fiber. These components enable transmission of signals across multi-mode fiber using up to 12 spatial and polarization modes.

Biography
Nicolas Fontaine obtained his Ph. D. in 2010 at the University of California, Davis in the Next Generation Network Systems Laboratory [http://sierra.ece.ucdavis.edu] in Electrical Engineering. In his dissertation he studied how to generate and measure the amplitude and phase of broadband optical waveforms in many narrowband spectral slices. Since June 2011, he has been a member of the technical staff at Bell Laboratories at Crawford Hill, NJ in the advanced photonics division.  At Bell Labs, he develops devices for space-division multiplexing in multi-core and few mode fibers, builds wavelength crossconnects and filtering devices, and investigates spectral slice coherent receivers for THz bandwidth waveform measurement. Nicolas Fontaine has been author or co-author on over 100 publications, including several post-deadline and invited papers at OFC, ECOC, and CLEO.

For additional information
Dr. Rodrigo Amezcua

407-823-6853

Tuesday, November 18, 2014

LightPath Technologies to Present at LD Micro Conference on December 2nd


FOR IMMEDIATE RELEASE:


LightPath Technologies to Present at LD Micro Conference on December 2nd



ORLANDO, FL -- November 18, 2014 -- LightPath Technologies, Inc. (NASDAQ: LPTH) (“LightPath”, the “Company” or “we”), a global manufacturer, distributor and integrator of proprietary optical components, infrared lenses and high-level assemblies, announced today that Jim Gaynor, President and Chief Executive Officer, will present at the LD Micro investor conference on Tuesday, December 2, 2014 at 4:00 PM PST/7:00 PM EST.


"We are honored to have LightPath Technologies present at the Main Event this year." stated Chris Lahiji, Founder of LD Micro.


About LD Micro

LD Micro is an investment newsletter firm that focuses on finding undervalued companies in the micro-cap space. Since 2002, the firm has published reports on select companies throughout the year. The firm also hosts the LD Micro Invitational. It is a non-registered investment advisor. For more information, please contact 408-457-1042 or visit www.ldmicro.com.


About LightPath Technologies
LightPath manufactures optical products including precision molded aspheric optics, GRADIUM® glass products, proprietary collimator assemblies, laser components utilizing proprietary automation technology, higher-level assemblies and packing solutions. The Company's products are used in various markets, including industrial, medical, defense, test and measurement and telecommunications. LightPath has a patent portfolio that has been granted or licensed to it in these fields. For more information visit www.lightpath.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.  


Contacts:
Jim Gaynor, President & CEO
LightPath Technologies, Inc.
Tel: 407-382-4003

Dorothy Cipolla, CFO
LightPath Technologies, Inc.
Tel: 407-382-4003 x305

Jordan Darrow
Darrow Associates, Inc.
Tel: 631-367-1866


Saturday, November 15, 2014

SPIE Start-up Challenge at Photonics West - DEADLINE APPROACHING - DECEMBER 1st

Are you a Florida company or start-up that might be interested in an opportunity to pitch their company for cash prices in front of VC's and industry leaders?

http://spiestartup2015.istart.org/

The SPIE Start-up Challenge for photonics technology is held annually at the Photonics West conference in San Francisco. This competitive event invites new entrepreneurs to pitch their light-based technology business plan to a team of business development experts and venture capitalists. Applicants selected to pitch at Photonics West are invited to attend an entrepreneur boot camp for training, networking, and refining their business plan. The best pitch presenters receive cash prizes and are provided support to attend additional entrepreneurship training to continue refining ideas and make further contacts with experts.

Applications are due by 1 December.

Wednesday, November 12, 2014

Seminar "Space-Division Multiplexed Transmission over Few-Mode-Fiber" by Dr. Nicolas Fontaine 11.21.14/2:00-3:00pm/ CREOL 103

Seminar "Space-Division Multiplexed Transmission over Few-Mode-Fiber" by Dr. Nicolas Fontaine
Friday, November 21, 2014 2:00 PM to 3:00 PM
CREOL Room 103

Dr. Nicholas Fontaine
Bell Laboratories
Crawford Hill, NJ

Abstract
Space-division multiplexed (SDM) systems use the multiple spatial modes in either multi-core fiber (separated modes), or the spatially overlapping but orthogonal modes in few-mode fibers to either increase the capacity or photon-efficiency of fiber links.The new challenges in SDM are how to couple into and out of the various SDM fibers without insertion loss (IL) or mode-dependent loss (MDL), and building components that have comparable performance to, and that offer a cost advantage over systems using multiple single-mode fibers.  I will show several components for space-division multiplexing in few-mode fibers including "photonic lantern" spatial multiplexers which are lossless adiabatic single-mode to multi-mode converters, and wavelength selective switches for routing signals in few-mode fiber. These components enable transmission of signals across multi-mode fiber using up to 12 spatial and polarization modes.

Biography
Nicolas Fontaine obtained his Ph. D. in 2010 at the University of California, Davis in the Next Generation Network Systems Laboratory [http://sierra.ece.ucdavis.edu] in Electrical Engineering. In his dissertation he studied how to generate and measure the amplitude and phase of broadband optical waveforms in many narrowband spectral slices. Since June 2011, he has been a member of the technical staff at Bell Laboratories at Crawford Hill, NJ in the advanced photonics division.  At Bell Labs, he develops devices for space-division multiplexing in multi-core and few mode fibers, builds wavelength crossconnects and filtering devices, and investigates spectral slice coherent receivers for THz bandwidth waveform measurement. Nicolas Fontaine has been author or co-author on over 100 publications, including several post-deadline and invited papers at OFC, ECOC, and CLEO.

For additional information
Dr. Rodrigo Amezcua

407-823-6853

Workshop for Two-Year College Faculty and Staff Interested in Optics & Photonics Technician Education - December 10, 2014 in Farmington, CT - Register Today!

OP-TEC

Please join us for a Workshop on
Optics and Photonics Technician Education!
December 10, 2014
Tunxis Community College
Farmington, Connecticut
Workshop hosted by OP-TEC and Camden County College


Workshop Information:
This workshop will provide an opportunity to get in on the ground floor in educating technicians for one of the most exciting and fastest growing technologies - PHOTONICS! 

Optics and photonics applications are rapidly transforming the way we work and live. Photonics, and its applications, involve the cutting-edge use of lasers, optics, fiber-optics, sensors, cameras, and electro-optical devices.  Photonics has many applications in manufacturing, medicine, aerospace, communications, security, solid-state lighting, and other high-tech fields.  Thus it represents a broad, commercially viable area in which American employers require a steady supply of well-qualified technicians.

This regional national workshop is targeted to community and technical college faculty, staff, and administrators, as well as industry/workforce trainers.  While this workshop will be focused on photonics in the Northeast/New England region, the concepts will be applicable and interesting to educators nationwide.  Participants will be provided information on the growing need for photonics technicians and postsecondary programs to educate them.  OP-TEC staff will explain the opportunities for attendees to create new AAS programs in photonics and/or to infuse optics and photonics instruction into existing technical programs in technologies that are enabled by photonics.  Attendees will also learn about OP-TEC materials and services available for planning and implementing photonics education at their institutions.  Please visit our website for more details and to register today!

Date:  Wednesday, December 10, 2014  (10:00 AM - 3:00 PM)

Location:  Tunxis Community College, Farmington, CT

Intended Audience:
  Community and Technical College Faculty, Staff, & Administration (and representatives from their feeder high schools); and Industry/Workforce Trainers to learn about courses, materials, and educational/training opportunities sponsored by OP-TEC.

Cost:  No registration fees!  Space is limited and registration is required.  Lunch will be provided both days of the workshop.  Participants are responsible for lodging, meals, and all travel expenses.
A $200.00 travel stipend will be available for the first 15 colleges that register and attend.
Registrants will receive an information packet via email containing hotel and travel information.
 


  

NSFNSF/ATE National Center of Excellence



Sunday, November 9, 2014

LPTH Press Release: LightPath Technologies Announces Financial Results for First Quarter Fiscal 2015


ORLANDO, FL -- November 6, 2014 -- LightPath Technologies, Inc. (NASDAQ: LPTH) (“LightPath”, the “Company” or “we”), a global manufacturer, distributor and integrator of proprietary optical components, infrared lenses and high-level assemblies, announced today its financial results for the fiscal first quarter ended September 30, 2014.



First Quarter 2015 Highlights:
·         12 month backlog increased approximately 25% to $5.3 million at September 30, 2014 as compared to June 30, 2014.
·         Bookings for optical lenses in the first quarter of fiscal 2015 were $3.45 million, the highest level in ten quarters. Bookings in Asia increased by 73% in the first quarter of 2015 as compared to the first quarter of fiscal 2014.
·         Revenue for the first quarter of fiscal 2015 decreased 7% to approximately $2.60 million compared to approximately $2.81 million for the first quarter of fiscal 2014 reflecting the more moderate economic growth in the Chinese market and a large delayed order from a major US defense contractor.
·         Gross margin as a percent of revenue for first quarter fiscal 2015 was 38% as compared to 47% in the first quarter of fiscal 2014. Lower gross margin was a result of duplicative manufacturing operations as we transition between our two facilities in China and a coating vendor yield issue
·         For the first quarter of fiscal 2015, net loss was approximately $(579,000), or $(0.04) per share, compared to net loss of $(80,000), or $(0.01) per share for the first quarter of fiscal 2014.
·         Adjusted EBITDA for the first quarter of fiscal 2015 was approximately ($380,000) compared to approximately $168,000 in the first quarter of fiscal 2014.

Jim Gaynor, President and Chief Executive Officer of LightPath, commented, “The first quarter of fiscal year 2015 is best summarized as one of mixed results. Our bookings for the quarter were $3.45 million, the highest level in the last ten quarters.  This led to our 12 month backlog increasing by 25% from the beginning of our current fiscal year. This growth outlook confirms the necessity for the investment that has been made to build and staff our recently completed manufacturing facility in China.”

“Our revenue in the first quarter of fiscal 2015 was less than our projections; however, our focused segments of precision molded optics in the Asian market and infrared, experienced growth. In the first quarter of 2015, revenue for precision molded optics business sold in Asia grew by 9% compared to the same period in the prior year and we achieved better than expected growth in our infrared revenue as that business was up in the quarter by more than 47% year-over-year. Revenues from sales in the U.S. during the first quarter of 2015 decreased by 14% from the same period last year, impacted by the delay of a $230,000 order from a U.S. defense contractor. This order is now planned for the second quarter.”

“We planned for lower gross margins in the first quarter compared to the fourth quarter due to expected impacts from the continued transition of manufacturing processes from our Shanghai factory to our new Zhenjiang factory, and the ramp-up of producing higher infrared volumes. We also experienced an unexpected vendor related yield issue during the quarter for infrared products that has been resolved. The cost of these issues is estimated at approximately $100,000.  We also incurred $50,000 of additional expense due to overlapping staff in both of our China locations during this transition period, while our Zhenjiang facility staff continues training. Together, these items impacted our gross margin by approximately 5 percentage points. In the long term, we expect our margins to surpass prior levels as production at the Zhenjiang facility reaches an optimal rate.”

 “We actively managed our working capital in the first quarter, continuing to make important capital investments while taking a balanced approach managing our receivables, inventory and payables.  While Adjusted EBITDA was negative ($380,000) in the quarter, our cash usage from operations was only ($100,000).”

“Addressing the previously disclosed securities purchase agreement with Pudong Science & Technology Investment (Cayman), Co. Ltd.,” Mr. Gaynor added, “we have continued to work with the U.S. government concerning the proposed investment.  We remain optimistic that we will receive the necessary governmental approvals to close the proposed transaction.  As we have previously stated, the proceeds from the sale of common stock are intended to provide working capital to support our continued growth through global expansion.”
Financial Results for Three Months Ended September 30, 2014
Revenue for the first quarter of fiscal 2015 totaled approximately $2.60 million, which was a decrease of $206,000, or 7%, as compared to the same period of the prior fiscal year.   The decrease from the first quarter of the prior fiscal year was attributable to a decrease in sales of our precision molded lenses primarily due to the laser tool market in China and a delayed order from a major U.S. defense contractor, offset by an increase in sales of infrared and Gradium products. Despite the slowdown in the Asian laser tool market in the first quarter of fiscal 2015, the Company still expects further growth in sales of industrial tool products based on recent order activity.  Orders for infrared products are also expected to continue to grow.

The gross margin percentage in the first quarter of fiscal 2015 was 38%, compared to 47% in the first quarter of fiscal 2014. Total manufacturing costs of $1.63 million increased by approximately $135,000 in the first quarter of fiscal 2015 compared to the same period of the prior fiscal year. The increase was primarily due to higher wages associated with the ramp up in infrared production and the overlapping manufacturing workforces during the transition of production between our two China facilities. During the first quarter of fiscal 2015, the Company also experienced an isolated yield issue with one of its coating vendors that resulted in additional expense. This yield issue is now resolved.

During the first quarter of fiscal 2015, total costs and expenses increased by approximately $107,000 compared to the same period of the prior year. The increase was primarily due to an increase of approximately $70,000 in wages in support of the infrared business and approximately $30,000 in higher travel expenses associated with business development initiatives.  Total operating loss for the first quarter of fiscal 2015 was approximately $511,000 compared to an operating loss of approximately $62,000 for the same period in fiscal 2014.

In the first quarter of fiscal 2015, the Company recognized a non-cash expense of approximately $54,000 related to the change in the fair value of derivative warrants issued in connection with the June 2012 private placement. In the first quarter of fiscal 2014, the Company recognized a non-cash expense of approximately $19,000 related to the change in the fair value of these warrants. The warrants have a five year life and this fair value will be re-measured each reporting period until the warrants are exercised or expire.
Net loss for the first quarter of fiscal 2015 was approximately $(579,000) (including the $54,000 non-cash expense for the change in value of the warrant liability) or $(0.04) per basic and diluted common share, compared with a net loss of $(80,000) (including the $19,000 non-cash expense for the change in value of the warrant liability) or $(0.01) per basic and diluted common share for the same period in fiscal 2014. Weighted-average basic shares outstanding increased to 14,312,061 in the first quarter of fiscal 2015 compared to 13,567,712 in the first quarter of fiscal 2014 primarily due to the issuance of shares of common stock for the employee stock purchase plan, shares issued due to warrant exercises and shares issued upon the exercise of restricted stock units.
Cash and cash equivalents totaled approximately $787,000 as of September 30, 2014. The current ratio as of September 30, 2014 was 2.7 to 1 compared to 3.0 to 1 as of June 30, 2014. Total stockholders’ equity as of September 30, 2014 totaled approximately $6.8 million compared to $7.3 million as of June 30, 2014. 
As of September 30, 2014, the Company’s 12-month backlog was $5.3 million compared to $4.3 million as of June 30, 2014, a 25% increase. 
Investor Conference Call and Webcast Details:
LightPath will host an audio conference call and webcast on Thursday, November 6, at 4:30 p.m. ET to discuss the Company’s financial and operational performance for the first quarter of fiscal 2015.
Conference Call Details
Date: Thursday, November 6, 2014
Time: 4:30p.m. (ET)
Dial-in Number: 1-800-860-2442
International Dial-in Number: 1-412-858-4600

It is recommended that participants dial-in approximately 5 to 10 minutes prior to the start of the 4:30 p.m. call. A transcript archive and webcast of the event will be available for viewing or download on the Company web site shortly after the call is concluded.
About LightPath Technologies
LightPath manufactures optical products including precision molded aspheric optics, GRADIUM® glass products, proprietary collimator assemblies, laser components utilizing proprietary automation technology, higher-level assemblies and packing solutions. The Company's products are used in various markets, including industrial, medical, defense, test and measurement and telecommunications. LightPath has a patent portfolio that has been granted or licensed to it in these fields. For more information visit www.lightpath.com.
The discussions of our results as presented in this release include use of non-GAAP terms “EBITDA” and “gross margin.”  Gross margin is determined by deducting the cost of sales from operating revenue. Cost of sales includes manufacturing direct and indirect labor, materials, services, fixed costs for rent, utilities and depreciation, and variable overhead. Gross margin should not be considered an alternative to operating income or net income, which is determined in accordance with Generally Accepted Accounting Principles (“GAAP”). We believe that gross margin, although a non-GAAP financial measure is useful and meaningful to investors as a basis for making investment decisions. It provides investors with information that demonstrates   our cost structure and provides funds for our total costs and expenses. We use gross margin in measuring the performance of our business and have historically analyzed and reported gross margin information publicly. Other companies may calculate gross margin in a different manner.

EBITDA is a non-GAAP financial measure used by management, lenders and certain investors as a supplemental measure in the evaluation of some aspects of a corporation's financial position and core operating performance. Investors sometimes use EBITDA as it allows for some level of comparability of profitability trends between those businesses differing as to capital structure and capital intensity by removing the impacts of depreciation, amortization, and interest expense. EBITDA also does not include changes in major working capital items such as receivables, inventory and payables, which can also indicate a significant need for, or source of, cash. Since decisions regarding capital investment and financing and changes in working capital components can have a significant impact on cash flow, EBITDA is not a good indicator of a business's cash flows. We use EBITDA for evaluating the relative underlying performance of the Company's core operations and for planning purposes. We calculate EBITDA by adjusting net loss to exclude net interest expense, income tax expense or benefit, depreciation and amortization, thus the term "Earnings Before Interest, Taxes, Depreciation and Amortization" and the acronym "EBITDA."
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.       
Contacts:
Jim Gaynor, President & CEO
LightPath Technologies, Inc.
Tel: 407-382-4003

Dorothy Cipolla, CFO
LightPath Technologies, Inc.
Tel: 407-382-4003 x305

Jordan Darrow
Darrow Associates, Inc.
Tel: 631-367-1866



Wednesday, November 5, 2014

Seminar: "Sensing molecules with frequency combs" By Dr. Konstantin Vodopyanov 11.7.14/12:00-1:00pm/ CREOL 103

Seminar: "Sensing molecules with frequency combs" By Dr. Konstantin Vodopyanov
Friday, November 7, 2014 12:00 PM to 1:00 PM
CREOL Room 103

Abstract:
Optical frequency combs produced in the visible spectral range by ultrafast mode-locked lasers have revolutionized precision spectroscopy and time metrology, culminating in the 2005 Nobel Prize in Physics. I will present a new technique for extending frequency combs to the highly desirable yet difficult-to-achieve mid-infrared range - the region of fundamental molecular vibrational-rotational resonances (fingerprints). The technique is based on subharmonic optical parametric oscillation (OPO) that can be considered as a reverse of second harmonic generation. Using ultrafast erbium or thulium fiber lasers as a pump, we produce frequency combs that are approximately octave wide and centered around 3 µm or 4 µm in wavelength. I will talk about coherent properties of the generated mid-IR combs, as well as their applications for trace molecular detection.

Biography:
Konstantin L. Vodopyanov obtained his MS degree from Moscow Institute of Physics and Technology ("Phys-Tech") and accomplished his PhD and DSc (Habilitation) in the Oscillations Lab. of Lebedev Physical Institute (later General Physics Inst.), led by Nobel Prize winner Alexander Prokhorov. He was an assistant professor at Moscow Phys-Tech (1985-90), Alexander-von-Humboldt Fellow at the University of Bayreuth, Germany (1990-92), and a Royal Society postdoctoral fellow and lecturer at Imperial College, London, UK (1992-98). In 1998, he moved to the United States and became head of the laser group at Inrad, Inc., NJ (1998-2000), and later director of mid-IR systems at Picarro, Inc.,CA (2000-2003). His other industry experience includes co-founding and providing technical guidance for several US and European companies. In 2003 he returned to Academia (Stanford University, 2003-2013) and is now a 21st Century Scholar Chair & Professor of Optics at CREOL, College of Optics & Photonics, Univ. Central Florida. Dr. Vodopyanov is a Fellow of the American Physical Society (APS), Optical Society of America (OSA), SPIE - International Society for Optical Engineering, UK Institute of Physics (IOP), and a Senior Member of IEEE. He has > 325 technical publications and is member of program committees for several major laser conferences including CLEO (most recent, General Chair in 2010) and Photonics West (Conference Chair). His research interests include nonlinear optics, laser spectroscopy, mid-IR and terahertz-wave generation, ultra broadband frequency combs and their biomedical applications.

For additional information:

Konstantin Vodopyanov

TOMORROW!! Seminar: "A Taxonomy of the Magneto-Optical Responses of Cyclic Plasmon-Supporting Metal Oligomers" by David J. Masiello 11.6.14/ 11:00am-12:00pm/ CREOL 103

Seminar: "A Taxonomy of the Magneto-Optical Responses of Cyclic Plasmon-Supporting Metal Oligomers" by David J. Masiello
Thursday, November 6, 2014 11:00 AM to 12:00 PM
CREOL Room 103

David J. Masiello, Assistant Professor
Department of Chemistry, University of Washington

Abstract:
The optical-frequency magnetic and electric properties of cyclic plasmon-supporting metal nanoparticle oligomers are explored through a combination of scanning transmission electron microscopy (STEM)/electron energy-loss spectroscopy (EELS) simulation and first-principles theory. A tight-binding type model is introduced to explore the rich hybridization physics in these plasmonic systems and tested with full-wave numerical electrodynamics simulations of the STEM electron probe. Building from a microscopic electric model, connection is made at the macroscopic level between the hybridization of localized magnetic moments into delocalized magnetic plasmons of controllable magnetic order and the mixing of atomic p_z orbitals into delocalized pi molecular orbitals of varying nodal structure spanning the molecule. It is found that the STEM electrons are uniquely capable of exciting all of the different hybridized eigenmodes of the nanoparticle assembly---including multipolar closed-loop ferromagnetic and antiferromagnetic plasmons, giant electric dipole resonances, and radial breathing modes---by raster scanning the beam to the appropriate position. Comparison to plane-wave light scattering and cathodoluminescence (CL) spectroscopy is made. The presented work provides a unified understanding of the complete plasmon eigenstructure of such oligomer systems as well as of the excitation conditions necessary to probe each mode.

Biography:
David J. Masiello completed a B.S. degree in mathematics from the University of Florida in 1999.  He then joined the University of Florida's Quantum Theory Project as a graduate student in chemical physics, where, in 2004, he received the Ph.D. degree working under the tutelage of Professor Yngve Öhrn.  His dissertation work explored a nonperturbative treatment of the interaction between molecules and the electromagnetic field, accounting for the redistribution of energy not only between different internal molecular degrees of freedom but also for its liberation to the dynamical electromagnetic field.  He then took two postdoctoral positions, one with Prof. William P. Reinhardt at the University of Washington (2004-2006) and the second with Professor George C. Schatz at Northwestern University (2006-2009).  Subsequently, David was hired back to the University of Washington in 2010 where he is now an assistant professor in theoretical chemistry.  Currently, Professor Masiello's research focuses on the theoretical understanding of a variety of nanoscale light-matter interactions involving the excitation of surface plasmon resonances.  Examples include electron energy-loss spectroscopy, cathodoluminescence, thermo-plasmonics, plasmon-enhanced catalysis, and plasmon-enhanced linear and nonlinear molecular optical phenomena.  As of Spring 2014, David is also a faculty member by courtesy in the Physics and Applied Mathematics departments at UW.

For more information:
Dr. Leonid Glebov

407-823-6983

Friday, October 31, 2014

LPTH Press Release: LightPath Technologies Schedules Fiscal 2015 First Quarter Conference Call


FOR IMMEDIATE RELEASE:

LightPath Technologies Schedules Fiscal 2015 First Quarter Conference Call



Financial Results to be Announced on November 6th After Close of Market


ORLANDO, FL – October 31, 2014 -- LightPath Technologies, Inc. (“LightPath”, the “Company” or “we”) (NASDAQ: LPTH), a global manufacturer, distributor and integrator of proprietary optical components, infrared lenses and high-level assemblies, today announced the scheduling of a conference call and simultaneous webcast to discuss the Company’s financial and operational results for the fiscal 2015 first quarter ended September 30, 2014.

Conference Call Details:

Date: Thursday, November 6, 2014 
Time: 4:30 PM (ET)
Dial-in Number: 1-800-860-2442  
International Dial-in Number: 1-412-858-4600 
Webcast: http://services.choruscall.com/links/lpth141106.html

Participants are recommended to dial-in or log-on approximately 10 minutes prior to the start of the event. A replay of the call will be available approximately one hour after completion through November 21, 2014. To listen to the replay, dial 1-877-344-7529 (domestic) or 1-412-317-0088 (international), and enter conference ID # 10055439.


About LightPath Technologies

LightPath (NASDAQ: LPTH) manufactures optical products including precision molded aspheric optics, GRADIUM® glass products, proprietary collimator assemblies, laser components utilizing proprietary automation technology, higher-level assemblies and packing solutions. The Company's products are used in various markets, including industrial, medical, defense, test & measurement and telecommunications. LightPath has a strong patent portfolio that has been granted or licensed to us in these fields.  For more information, visit www.lightpath.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. 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, the Company does not have any intention or obligation to update publicly any forward-looking statements whether as a result of new information, future events or otherwise.

GRADIUM® is a registered trademark of LightPath Technologies.


###


Contacts:        Dorothy Cipolla, CFO

                        LightPath Technologies, Inc.

Tel: 407-382-4003 x305


                           Web: www.lightpath.com



                                Jordan Darrow

                                Darrow Associates, Inc.

                                jdarrow@darrowir.com

                                631-367-1866









Tuesday, October 21, 2014

Distinguished Seminar Series: "Field-Effect Liquid Crystal Displays, LC-Materials & Optical Alignment of LCs" by Martin Schadt 11.14.14/12:00-1:00pm/ CREOL 103

Distinguished Seminar Series: "Field-Effect Liquid Crystal Displays, LC-Materials & Optical Alignment of LCs" by Martin Schadt
Friday, November 14, 2014 12:00 PM to 1:00 PM
CREOL Room 103

Dr. Martin Schadt
MS High-Tech Consulting, CH-4411 Seltisberg, Switzerland

Abstract
Since the invention of the twisted nematic (TN) field-effect in 1970, the nematic liquid crystal display technology which is based on electric field-effects has made remarkable progress. Field-effects are characterized by polarization sensitive macroscopic molecular liquid crystal configurations with electrically tunable optical appearance. 
The unique electro-optical building block concept of field-effect LCDs enables the integration and individual optimization of anisotropic optical thin-films and silicon electronics in LCDs. The remarkable progress made over the past 45 years, renders today virtually all applications of the communication between man and machine possible. They range from reflective LCDs with “zero power” consumption, such as digital watch LCDs, or remotely controlled electronic price tags in Shopping centers, to iPhones and large size, ultra-high resolution 4k television LCDs. Since the beginnings in 1970 this development has been spurred by interdisciplinary R&D between physics, material sciences, synthetic chemistry, semiconductor electronics, and engineering. It includes TN-LCDs (1970), super-twisted nematic (STN)-LCDs (1980s), thin-film transistor (TFT)-addressed TN-LCDs for computer monitors in the early 1990s and beyond, and multi-domain LCD configurations. The latter became possible in the late 1990s either by electric fringe-field electrode geometries, or by photo-alignment/patterning of LC molecules. Further enhanced contrast, large angles of view and shorter response times were the result. Moreover, spin-offs into potential future types of field-effect LCDs, such as polymer stabilized blue phase LCDs and ferroelectric LCDs became possible. 
This development is reviewed with examples of the multidisciplinary R&D of the author and collaborators on electro-optical field-effects, liquid crystal materials and polarized optical alignment and alignment patterning of monomeric and polymeric liquid crystal molecules in LCDs and optical thin-films based on liquid crystal polymers.

Biography
Dr. Martin Schadt was born on 16th August 1938 in Liestal, Switzerland. After having gained practical experience as electrician Martin Schadt majored in experimental physics at the University of Basel, Switzerland, where he received his PhD in 1967. He was granted a two year post-doctoral fellowship at the National Research Council, Ottawa, Canada, where he continued his research on the electronic and optical properties of organic semiconductors. In 1969 he and D.F Williams patented the first solid state, organic light emitting display (OLED).  Dr. Schadt’s first professional association was with the watch company Omega, where he investigated atomic beam standards. In 1970 he joined the Central Research Laboratories of F. Hoffmann-La Roche Ltd., Basel. Except for two years in biophysics, his research focused on the development of electro-optical field-effects based on liquid crystals and on liquid crystal materials. 1970 Dr. Helfrich and Dr. Schadt invented the twisted nematic (TN)-effect at F. Hoffmann-La Roche. The Roche TN-field-effect patent was granted in 20 countries and was licensed world-wide to the emerging field-effect LCD industry by Roche. The invention initiated a paradigm change towards flat panel field-effect liquid crystal displays (LCDs) enabling today’s LCD industry. The search for correlations between molecular structures, material properties and display performance, which Dr. Schadt started in the early 1970s, enabled the development of new liquid crystals for TN- and subsequent field-effect applications. As a consequence the pharmaceutical company Roche established itself as a major liquid crystal materials supplier for the emerging LCD-industry. Apart from his pioneering work on OLEDs, the TN-effect and liquid crystal materials, Dr. Schadt and collaborators invented the linear photo-polymerization (LPP) technology in 1991 enabling alignment of liquid crystal molecules by light instead of mechanically. This opened up novel LCD configurations and LCD operating modes, as well as numerous anisotropic optical polymer thin-films. 
Until 1994 Dr. Schadt headed the Liquid Crystal Research Division of Roche. Based on its photo-alignment technology the Division was turned in 1994 into the spin-off company ROLIC Ltd, an interdisciplinary Research and Development Company which Dr. Schadt built-up and headed as CEO and delegate of the Board of Directors until his retirement from the operating business in October 2002. He is now active as a scientific advisor to research organisations and continues research in collaboration with partner companies as an independent inventor. He is inventor or co-inventor of 166 patent families filed in Europe (EP) and holds more than 119 US patents. He has published 191 papers in leading scientific journals, including chapters in 6 books. Dr. Schadt became a Fellow of the Society Information Display (SID) in 1992 and a Fellow of the European Academy of Sciences in 2011. He is inventor or co-inventor of 166 patent families filed in Europe (EP) and holds more than 119 US patents. He has published 193 scientific papers in leading scientific journals, has given more than 150 lectures and contributed to 6 books. He has received the following Awards: the Roche Research and Development Award (1987), a Special Recognition Award and a Best SID Paper Award (1987), the SID Karl Ferdinand Braun Award (1992). Together with W. Helfrich, he received the Aachener und Münchener Preis für Technik und angewandte Naturwissenschaften (1994) and the Robert-Wichard-Pohl Prize of the German Physical Society (1996). Together with W. Helfrich and James Fergason, he received the IEEE Jun-ichi Nishizawa Medal (2008). In 2009 he received the Eduard Rhein Technoloy Prize. The G.W. Gray Medal of the British Liquid Crystal Society and the Blaise Pascal Medal for Material Sciences of the European Academy of Sciences (2010). The Frederiks Medal, highest recognition award of the Russian Liquid Crystal Society (2011). The Charles Stark Draper Prize of the US National Academy of Sciences (known as the “Engineering Nobel Prize”) together with G. Heilmeier, W. Helfrich and P. Brody (2012). European Inventor Award 2013 for Lifetime Achievement (2013). Fellow of US National Academy of Inventors NAI (2013). Honorary Prof. of Sichuan University, Chengdu (2013). Honorary Prof. of Nanjing University, Nanjing (2013).  

For additional information:
Dr. Shin-Tson Wu

407-823-4763

Monday, October 6, 2014

TODAY!! Seminar: "Semiconductor Nanomaterials for Information and Energy Technologies" by Dr. Yajie Dong 10.6.14/ 11:00-am-12:00pm/ CREOL 103

Seminar: "Semiconductor Nanomaterials for Information and Energy Technologies" by Dr. Yajie Dong
Monday, October 6, 2014 11:00 AM to 12:00 PM
CREOL Room 103

ABSTRACT:
Low dimensional nanomaterials (1 D nanowires and 0 D quantum dots) represent important nanoscale building blocks with substantial potential for exploring new device concepts and materials for nanoelectronics, optoelectronics and energy technology applications. Three examples will be presented.  First, I will discuss my discovery of unique rectified silver/amorphous silicon/crystalline silicon (Ag/a-Si/c-Si) crossbar resistive random access memory (RRAM) effect in c-Si/a-Si core/shell nanowires and provide a comprehensive comparison between nanowire based and planar silicon based Ag/a-Si/c-Si RRAMs. The history of how this accidental nanowire based discovery solved a decades-long sneak current problem in RRAM field and eventually evolved into a game changing mainstream flash memory successor, Crossbar Memory, will be presented. Then I will report the experimental realization of high efficiency single coaxial group III-nitride heterostructured nanowire photovoltaic devices and light emitting devices. Meanwhile, a universal van der Waals epitaxial growth strategy for compound semiconductor nanowire arrays will be discussed. The vision of how the combination of nanowire array growth and heterostructured nanowire devices could possibly change the substrate limited status of III-Nitride research fields will be outlined. Lastly, I will present how quantum dots materials innovation and novel device structure design/processing helped resolve one long standing issue for organic based light emitting devices, the efficiency roll off at high driving current density. As a result, record breaking ultrabright, highly efficient, low roll off inverted red quantum dot light emitting devices (QLEDs) have been achieved (165,000Cd/m2 at <6v attack="" be="" discussed="" driving="" end.="" in="" instability="" issue="" long="" of="" only="" p="" qleds="" remaining="" strategies="" term="" the="" to="" voltage="" will="">

BIOGRAPHY:
Dr. Yajie Dong is an assistant professor in NanoScience Technology Center of University of Central Florida. He got his BS and MS degrees in Chemistry from Tsinghua University of Beijing, China. In 2010, he received his PhD degree from Prof. Charles Lieber's group at Chemistry and Chemical Biology Department of Harvard University. From 2010 to 2012, he was a postdoctoral associate working with Professors Yet-Ming Chiang and W. Craig Carter in the department of Material Science and Engineering at the Massachusetts Institute of Technology. Before joining NSTC of UCF in August 2014, he worked as a Senior Scientist for QD Vision Inc., a Nanotech Startup based on research of Professors Moungi Bawendi and Vladimir Bulovic’s groups at MIT and located in Lexington, MA. He is broadly interested in materials challenges in nanoelectronics, optoelectronics and energy technologies, particularly in nanoscale nonvolatile resistive switches for information processing and storage, compound semiconductor nanowires or quantum dots based high efficiency energy conversion (LED and PV) devices and new battery materials and architectures for large scale energy storage.

For additional information: 
Dr. Bahaa Saleh
Dean & Director, Professor of Optics
407-882-3326