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=== [[Intro in Korean]] === | === [[Intro in Korean]] === | ||
− | === Quantum Control === | + | === Ultrafast Quantum Control === |
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[[Image:QC.jpg|right|120px]] | [[Image:QC.jpg|right|120px]] | ||
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<td> Recent advances in ultrafast laser and optical pulse shaping techniques have brought the use of shaped pulses of optical frequency for the manipulation of quantum systems. This field, known as quantum control, though being started as a theoretical exercise, has rapidly become an experimental reality in a vast variety of materials extending from atoms and molecules to condensed matter and biological materials. [[Quantum Control|latest results]] | <td> Recent advances in ultrafast laser and optical pulse shaping techniques have brought the use of shaped pulses of optical frequency for the manipulation of quantum systems. This field, known as quantum control, though being started as a theoretical exercise, has rapidly become an experimental reality in a vast variety of materials extending from atoms and molecules to condensed matter and biological materials. [[Quantum Control|latest results]] | ||
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=== Rydberg atom quantum computation === | === Rydberg atom quantum computation === | ||
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Revision as of 07:48, 17 February 2017
Intro in Korean
Ultrafast Quantum Control
Recent advances in ultrafast laser and optical pulse shaping techniques have brought the use of shaped pulses of optical frequency for the manipulation of quantum systems. This field, known as quantum control, though being started as a theoretical exercise, has rapidly become an experimental reality in a vast variety of materials extending from atoms and molecules to condensed matter and biological materials. latest results |
Rydberg atom quantum computation
Quantum computing has developed, during the last two decades, from a visionary idea to one of the most fascinating areas of modern physics. Being considered as one of the most impactful future technologies, quantum computers are studied by research scientists around the world. Numerous unseen technical problems that are involved with the quantum nature of many entangled particles are being challenged. We focus on neutral-atom based quantum computation, for which we have developed our own method of making arbitrary atom lattice configurations with optical micro-traps. The number of atomic qubits exceeds N=40 with pairwise or trio entanglements. latest results |
Miscellaneous
Lab Photos
1. Quantum Control Lab in Physics 3317
2. Ultrafast Spectroscopy Lab in KI Basement