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RESEARCH PRODUCT
Algorithmic cooling of nuclear spins using long-lived singlet order
Lynda J. BrownChristian BengsKirill F. SheberstovAlexandra V. YurkovskayaBogdan A. RodinKonstantin L. IvanovMalcolm H. LevittAlexey S. KiryutinRichard C. D. Brownsubject
PhysicsThermal equilibriumZeeman effect010304 chemical physicsSpinsAntisymmetric relationNuclear TheoryRelaxation (NMR)Quantum superpositionGeneral Physics and Astronomy010402 general chemistry7. Clean energy01 natural sciences0104 chemical sciencessymbols.namesakeOpen quantum system13. Climate action0103 physical sciencessymbolsSinglet statePhysical and Theoretical ChemistryAtomic physicsdescription
Algorithmic cooling methods manipulate an open quantum system in order to lower its temperature below that of the environment. We achieve significant cooling of an ensemble of nuclear spin-pair systems by exploiting the long-lived nuclear singlet state, which is an antisymmetric quantum superposition of the "up" and "down" Zeeman states. The effect is demonstrated by nuclear magnetic resonance (NMR) experiments on a molecular system containing a coupled pair of near-equivalent 13C nuclei. The populations of the system are subjected to a repeating sequence of cyclic permutations separated by relaxation intervals. The long-lived nuclear singlet order is pumped well beyond the unitary limit. The pumped singlet order is converted into nuclear magnetization which is enhanced by 21% relative to its thermal equilibrium value.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2020-04-30 | The Journal of Chemical Physics |