visual
visual

세미나

  • HOME
  • >
  • 소식
  • >
  • 세미나
날짜 2018-04-13 10:00 
연사  
장소 #1323 (E6-2, 1st fl.) 

Physics Seminar

 

Quantum meets Mechanics: from Quantum Information to Fundamental Research

 

Dr. Sungkun Hong

Vienna Center for Quantum Science and Technology, University of Vienna

 

April 13 (Fri.), 10am

#1323 (E6-2, 1st fl.)

 

 

Abstract:

Studying quantum aspects of macroscopic moving bodies is a new emerging field in quantum physics. The main experimental approach is cavity optomechanics, where photons in the cavity are used to measure and manipulate motional states of mechanical oscillators. Cavity optomechanics, together with advancements in microfabrication of mechanical devices, has allowed us to observe and control mechanical resonators at the quantum level. This opens new exciting possibilities for quantum information science and for studying quantum physics in hitherto untested macroscopic scales.

In this talk, I will describe two different quantum optomechanics experiments that I have been doing in Vienna. First, I will present our progress in utilizing on-chip optomechanical devices as a new resource for quantum information. Using micro-fabricated silicon structures, we demonstrated the generation of quantum-correlated photon-phonon pairs, the generation and retrieval of single phonons, and the remote entanglement between two mechanical modes, paving the way for telecom-compatible optical quantum networks. Future directions of the work will also be discussed. Next, I will introduce a novel, hybrid optomechanical system consisting of optically levitated nanoparticles and micro-fabricated photonic crystal cavity. The system combines ultra-high mechanical quality of the levitated nanoparticle and strong optical transduction from the optical cavity. It thus will allow for quantum coherent experiments on particle’s motions even at room temperature. I will discuss the current status of the experiment as well as future plans of the work, particularly the matter-wave interferometry in an unexplored mass regime.

 

Contact: Yongseop Kang, Administration Team (T.2599)

 

Department of Physics

번호 날짜 연사 제목
공지 2025-02-24 16:00    2025년 봄학기 콜로키움 안내
공지 2025-02-27 16:00    2025년 봄 물리학과 특별세미나 (광학/응집물리 분야)
425 2022-10-06 13:00    Counting States with Global Symmetry
424 2022-08-12 10:00    Twisted Bilayer Magnets file
423 2022-08-12 10:00    Twisted Bilayer Magnets file
422 2016-04-26 16:00    Transport spectroscopy for electronic bands in carbon-based nanomaterials with weak-bond contacts
421 2018-05-11 16:00    암페어 단위 재정의와 단전자 펌프 소자 개발 file
420 2025-04-22 16:00  Dr. Nanse Esaki (The University of Tokyo)  Spin Nernst and thermal Hall effects of topological triplons in quantum dimer magnets on the maple-leaf and star lattices file
419 2016-06-01 10:30    Welcome to Nature Photonics
418 2018-07-02 15:00    High Precision Magnetic Field Measurement for the Muon g-2 Experiment file
417 2015-10-16 15:00    High Magnetic Fields to Probe the sub-eV range of Particle/Astroparticle Physics - From the OSQAR experiments at CERN up to new perspectives at LNCMI-Grenoble
416 2018-11-09 14:30    Moiré superlattices – from twisted bilayer graphene to quasicrystal file
415 2024-05-30 10:00    Quasiperiodic Effects in Quasicrystals
414 2024-05-16 14:30    [Astrophysics Seminar] Observational Cosmology with Superconducting Sensors
413 2022-03-29 10:00    Non-reciprocal phase transitions file
412 2022-03-31 10:00    Weiss fields for Quantum Spin Dynamics file
411 2020-10-15 17:00    Time crystals, quasicrystals, and time crystal dynamics in the superfluid universe file
410 2023-05-03 16:00    Probing microscopic origins of axions by the chiral magnetic effect
409 2022-11-09 16:00    Radio Astronomy, Radio Interferometry, and Multi-wavelength Studies on Relativistic Jets
408 2017-06-02 16:00    Maxwell's demon in quantum wonderland file
407 2015-12-03 16:00    Hybrid solid state spin qubits in wide bandgap semiconductors
406 2025-01-08 16:00  Dr. SangEun Han  Quantum impurity model for two-stage multipolar ordering and Fermi surface reconstruction