Tuesday, 3 May 2011 - CLEO
Tuesday, 3 May 2011 - CLEO
Tuesday, 3 May 2011 - CLEO
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Room 318-320 Room 321-323 Room 324-326 Room 314<br />
<strong>CLEO</strong>: QELS-<br />
Fundamental Science<br />
<strong>CLEO</strong>: Science<br />
& Innovations<br />
JOINT<br />
QTuE • Plasmonic Optical<br />
Devices—Continued<br />
QTuF • Frequency Combs<br />
and Carrier-Envelope Phase<br />
Phenomena—Continued<br />
CTuG • Semiconductor<br />
Nanolasers—Continued<br />
JTuC • Joint Symposium on<br />
Quantum Communications II:<br />
Networks—Continued<br />
QTuE4 • 12:00<br />
Hybrid Plasmonic-photonic Resonators for<br />
Sensing and Spectroscopy, <strong>May</strong>samreza Chamanzar<br />
1 , Ehsan Shah Hosseini 1 , Siva Yegnanarayanan 1 ,<br />
Ali Adibi 1 ; 1 Georgia Inst. of Technology, USA. Design<br />
and experimental characterization of a hybrid<br />
resonator consisting of nanolithographically fabricated<br />
gold nanoparticles integrated with a Silicon<br />
Nitride photonic microresonator for sensing and<br />
spectroscopy applications is discussed.<br />
QTuE5 • 12:15<br />
Integrated Electrochromic Nanoplasmonic<br />
Optical Switch, Amit Agrawal 1,3 , Ceren Susut 1 ,<br />
Gery Stafford 2 , Benjamin McMorran 1 , Henri Lezec 1 ,<br />
A. Alec Talin 1 ; 1 Center for Nanoscale Science and<br />
Technology, National Inst. of Standards and Technology,<br />
USA; 2 Materials Science and Engineering<br />
Lab, National Inst. of Standards and Technology,<br />
USA; 3 Maryland Nanocenter, Univ. of Maryland,<br />
USA. We demonstrate active switching of light<br />
through a nanoslit based plasmonic devices using<br />
electrochromic Prussian blue nanocrystals, and<br />
achieve large (~95%) transmission modulation<br />
by switching the nanocrystals between oxidized<br />
and reduced states.<br />
QTuF5 • 12:00<br />
Effect of Carrier-Envelope Phase on Bound-State<br />
Atomic Excitation by Multi-Cycle Pulse, Pankaj<br />
K. Jha 1,2 , Yuri Rostovtsev 1,3 , Hebin Li 1 , Vladimir A.<br />
Sautenkov 1,4 , Marlan O. Scully 1,2 ; 1 Physics, Texas<br />
A&M Univ., USA; 2 Mechanical and Aerospace<br />
Engineering, Princeton Univ., USA; 3 Physics, Univ.<br />
of North Texas, USA; 4 Physics, P.N.Lebdev Inst.,<br />
R.A.S, Russian Federation. We present an experimental<br />
and theoretical study of Carrier-Envelope<br />
Phase effects on bound state atomic excitation. We<br />
investigated the influence of CEP on multiphoton<br />
transitions between the Zeeman sublevels of the<br />
ground state of Rb.<br />
QTuF6 • 12:15<br />
Passively Carrier-Envelope Phase stable mid-<br />
IR OPCPA source at 100 kHz repetition rate,<br />
Alexandre Thai 1 , Olivier Chalus 1 , Philip K. Bates 1 ,<br />
Jens Biegert 1,2 ; 1 ICFO, Spain; 2 ICREA-Institució<br />
Catalana de Recerca i Estudis Avançats,, Spain. We<br />
present a carrier-envelope stable, 100 kHz source<br />
of intense 6 cycle mid-IR pulses at 3.2 microns.<br />
The CEP stability is sub-100 mrad RMS over 1<br />
million pulses.<br />
CTuG2 • 12:00 Invited<br />
Room Temperature CW Operation of Metal-<br />
Semiconductor Plasmonic Nanolasers with<br />
Subwavelength Cavity, Zhicheng Liu 1 , Kang Ding 1 ,<br />
Leijun Yin 1 , Martin Hill 2 , Milan J. Marell 2 , Rene<br />
J. van Veldhoven 2 , Richard Noetzel 2 , Cun-Zheng<br />
Ning 2 ; 1 School of Electrical, Computer, and Energy<br />
Engineering, Arizona State Univ., USA; 2 COBRA<br />
Research Inst., Technische Universiteit Eindhoven,<br />
Netherlands. We report the first room temperature,<br />
continuous wave operation of the electrical<br />
injection nanolasers with subwavelength cavity.<br />
The lasing mode is confined in an InP/InGaAs-<br />
SiN-Silver cavity of rectangular cross section<br />
operating at 1.55 μm.<br />
JTuC3 • 12:00<br />
Practical Quantum Key Distribution Over<br />
100 km Using Sinusoidally Gated InGaAs/InP<br />
Avalanche Photodiodes, Naoto Namekata 1 , Hiroki<br />
Takesue 2 , Toshimori Honjo 2 , Yasuhiro Tokura 2 ,<br />
Shuichiro Inoue 1 ; 1 Inst. of Quantum Science, Nihon<br />
Univ., Japan; 2 NTT Basic Research Laboratories,<br />
Japan. We report on the quantum key distribution<br />
experiment using ultra-low-noise 2-GHz sinusoidally<br />
gated InGaAs/InP avalanche photodiodes.<br />
The detectors enabled us to distribute secure keys<br />
over 100 km with a bit rate of 24 kbps.<br />
JTuC4 • 12:15<br />
Security of Post-selection based Continuous<br />
Variable Quantum Key Distribution against<br />
Arbitrary Attacks, Nathan Walk 1 , Thomas Symul 2 ,<br />
Timothy C. Ralph 1 , Ping Koy Lam 2 ; 1 Department of<br />
Physics, Univ. of Queensland, Australia; 2 Department<br />
of Quantum Science, Australian National<br />
Univ., Australia. We analyse the security and performance<br />
of a continuous variable quantum key<br />
distribution protocol using post selection, deriving<br />
results that are unconditionally secure in the sense<br />
of no longer restricting the eavesdroppers attack.<br />
<strong>Tuesday</strong>, 3 <strong>May</strong><br />
QTuE6 • 12:30<br />
Locally-oxidized silicon surface-plasmon<br />
Schottky detector for telecom wavelengths, Ilya<br />
Goykhman 1 , Boris Desiatov 1 , Jacob B. Khurgin 2 ,<br />
Joseph Shappir 1 , Uriel Levy 1 ; 1 Hebrew Univ., Israel;<br />
2<br />
Department of Electrical & Computer Engineering,<br />
Johns Hopkins Univ., USA. We demonstrate<br />
an integrated on-chip locally-oxidized silicon<br />
surface-plasmon Schottky detector for telecom<br />
wavelengths based on the internal photoemission<br />
process. Theoretical model and experimental<br />
results will be presented and discussed.<br />
QTuF7 • 12:30<br />
Few-cycle CEP-stable source at 2.1 μm based on<br />
collinear OPA in BiB 3 O 6 , Francisco Silva 1 , Philip<br />
K. Bates 1 , Jens Biegert 1 , Adolfo Esteban-Martin 1 ,<br />
Majid Ebrahim-Zadeh 1 , Alexander Gruen 1 , Seth<br />
L. Cousin 1,2 ; 1 ICFO-Institut de Cienciès Fotióniques,<br />
Spain; 2 ICREA-Institució Catalana de Recerca i<br />
Estudis Avançats, Spain. We demonstrate a scalable,<br />
CEP stable, three-cycle source at 2.1 μm with<br />
180 μJ pulse energy from OPA in bulk BiB 3 O 6 at 3<br />
kHz repetition rate without post-compression.<br />
CTuG3 • 12:30<br />
Metal-clad Semiconductor Nanoring Lasers, Min<br />
W. Kim 1 , Pei-Cheng Ku 1 ; 1 Electrical Engineering<br />
and Computer Science, Univ. of Michigan, USA.<br />
Lasing in a metal-clad semiconductor ring laser<br />
of 0.9lambda-diameter and 0.8lambda height is<br />
demonstrated. It is experimentally shown that<br />
the metal coverage is critical in achieving the<br />
lasing threshold.<br />
JTuC5 • 12:30<br />
An Analysis of Single-Photon Detectors in an<br />
Environmentally Robust GigaHertz Clock Rate<br />
Quantum Key Distribution System, Patrick J.<br />
Clarke 1 , Robert J. Collins 1 , Aongus McCarthy 1 ,<br />
Nils J. Krichel 1 , María-José García-Martínez 1,2 ,<br />
Michael G. Tanner 1 , John A. O’Connor 1 , Chandra<br />
M. Natarajan 1 , Shigehito Miki 3 , Masahide Sasaki 3 ,<br />
Zhen Wang 3 , Ivan Rech 4 , Massimo Ghioni 4 , Angelo<br />
Gulinatti 4 , Philip A. Hiskett 1,5 , Robert H. Hadfield 1 ,<br />
Paul D. Townsend 6 , Gerald S. Buller 1 ; 1 Heriot-Watt<br />
Univ., UK; 2 Consejo Superior de Investigaciones<br />
Científicas, Spain; 3 National Inst. of Information<br />
and Communications Technology (NICT), Japan;<br />
4<br />
Politecnico di Milano, Italy; 5 SELEX Galileo, UK;<br />
6<br />
Tyndall National Inst. and Department of Physics,<br />
Univ. College Cork, Ireland. We have developed a<br />
robust, BB84, 850 nm wavelength, gigahertz clock,<br />
phase encoding quantum key distribution system.<br />
This has been analyzed using a number of singlephoton<br />
detectors and tested against predictions<br />
from our theoretical model.<br />
10:30–12:30 Market Focus: Sensors & Lasers for Defense and Security, Exhibit Hall F, 100 Level<br />
12:45–13:45 Lunch Break (concessions available in Exhibit Halls E and F, 100 Level)<br />
100<br />
<strong>CLEO</strong>: <strong>2011</strong> • 1–6 <strong>May</strong> <strong>2011</strong>