Difference between revisions of "Research"
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== [[Quantum Control]] == | == [[Quantum Control]] == | ||
[[Image:QC.jpg|right|100px]] 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. | [[Image:QC.jpg|right|100px]] 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. | ||
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== [[Ultra-cold Molecular Quantum Computing]] == | == [[Ultra-cold Molecular Quantum Computing]] == | ||
[[Image:MOT.jpg|right|100px]] Quantum computing seeks to write, process, and read information on quantum level. We envision that the phase evolution of vibration wave-packets of ultra-cold diatomic molecules captured in magneto optical trap is used to compute quantum algorithms. | [[Image:MOT.jpg|right|100px]] Quantum computing seeks to write, process, and read information on quantum level. We envision that the phase evolution of vibration wave-packets of ultra-cold diatomic molecules captured in magneto optical trap is used to compute quantum algorithms. | ||
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== miscellaneous == | == miscellaneous == | ||
Revision as of 04:40, 19 June 2011
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.
Terahertz Optics
Terahertz science and technology has attracted much interest because of its many up-and-coming applications in communications, material characterization, and imaging. The left figure shows our latest invention of THz coherent optical computation imaging.
Ultra-cold Molecular Quantum Computing
Quantum computing seeks to write, process, and read information on quantum level. We envision that the phase evolution of vibration wave-packets of ultra-cold diatomic molecules captured in magneto optical trap is used to compute quantum algorithms.
miscellaneous
