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We have created microcavity polaritons with a lifetime of about 200 ps, which allows them to condense in the ground state of a ring trap. Optical measurements show they have quantized vorticity.
The near-field tip-antenna enhanced signal transduction with femtosecond laser pulses allows for spatio-spectral and spatio-temporal imaging and quantum coherent control with the perspective to reach the single electronic or vibrational quantum level.
Quantum teleportation [1] is a cornerstone of quantum information science due to its essential role in several important tasks such as the long-distance transmission of quantum information using quantum repeaters [2–4]. In this context, a challenge of paramount importance is the distribution of entanglement between remote nodes, and to use this entanglement as a resource for long-distance light-to-matter...
Terahertz radiation permits resonant and sensitive probing of electron transport, spin precession and ion vibration in solids. Recently developed sources of strong-field terahertz pulses even allow one to gain control over these fundamental modes.
Challenges for building a quantum repeater system using a nitrogen vacancy center in diamond are overviewed and the futures are discussed. Our approach for further development of quantum repeater network is also presented with experimental demonstrations of quantum entanglement detection between a photon and an electron spin in an NV center for quantum entanglement swapping.
We investigate and optimize three generations of quantum repeater protocols for long distance quantum communication, which can overcome the major challenges of photon loss and operational imperfections.
This presentation will review the latest linear microscopy techniques applied to imaging the living retina, as well as the normal and pathological retinal structures that can now be visualized non-invasively. This presentation will review the latest linear microscopy techniques applied to imaging the living retina, as well as the normal and pathological retinal structures that can now be visualized...
We demonstrate all-optical coherent manipulation of a quantum dot spin through coherent population trapping with a sub-linewidth spin splitting, enabled by the hyperfine interaction with a mesoscopic nuclear spin ensemble.
We present analysis of electromechanical effects associated with collective optical excitation of electrons in plasmonic nanoparticles, with emphasis on the enhanced transfer of angular momentum and nonlinear hydrodynamics such as vortex pairs.
I will discuss recent progress on new near-field probe geometries, including the “campanile” geometry, which has been used in recent hyperspectral imaging experiments, providing nanoscale spectral information distinct from what is obtained with other methods.
Light fields with shapes similar to those produced from RF function generators are realized. Such fields may be used to dictate the microscopic motion of charged particles in atoms and molecules and in matter.
Deep tissue multiphoton microscopy (MPM) using solitons generated from optical fibers are reviewed. The main characteristics of the excitation source for deep tissue MPM, such as wavelength, pulse energy, and repetition rate, are discussed.
Advanced data centers require high throughput I/O processing for servers and storage devices connectivity. Silicon photonics technology offering low-cost, low-power, and high-performance is a promising solution for interconnection applications. In this talk, we will review the latest progress of the highly integrated Silicon photonics devices for 4×25 Gb/s active optical cables and transceivers. This...
We discuss silicon photonic integrated circuits for telecommunications that integrate many elements. We include transmitters, receivers, transceivers, and add-drop filters. Advanced modulation formats and coherent systems are especially investigated.We discuss silicon photonic integrated circuits for telecommunications that integrate many elements. We include transmitters, receivers, transceivers,...
First-principles calculations show that phonon-assisted Auger recombination and its interplay with the polarization fields in polar nitride LEDs play an important role in the efficiency-droop and green-gap problems of these devices.
Lasers are an indispensable tool for current XUV and X-ray free electron light sources and are key to future laser driven accelerator technology. We discuss the role of fiber-laser technology in this emerging field.
Entanglement plays a central role in fundamental tests of quantum mechanics as well as in the burgeoning field of quantum information processing. Particularly in the context of quantum networks and communication, an outstanding challenge is the efficient generation of entanglement between stationary (spin) and flying (photon) qubits. In this talk, I will first show the observation of quantum entanglement...
We show how tailored few-cycle lightwaves with near relativistic intensity (∼1018W/cm2) can be used to control the attosecond electron dynamics of plasma mirrors and to produce beam manifolds of fully synchronized attosecond EUV light pulses.
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