Two-Path Interference for Enantiomer-Selective State Transfer of Chiral Molecules

Jin Lei Wu; Yan Wang; Jin Xuan Han; Cong Wang; Shi Lei Su; Yan Xia; Yongyuan Jiang; Jie Song

doi:10.1103/PhysRevApplied.13.044021

Two-Path Interference for Enantiomer-Selective State Transfer of Chiral Molecules

Jin Lei Wu
, Yan Wang
, Jin Xuan Han
, Cong Wang
, Shi Lei Su
, Yan Xia
, Yongyuan Jiang
, Jie Song

School of Physics

School of Physics, Harbin Institute of Technology
Zhengzhou University
Fuzhou University
Ministry of Industry and Information Technology

Research output: Contribution to journal › Article › peer-review

58 Scopus citations

Abstract

Using a microwave-regime cyclic three-state configuration, enantiomer-selective state transfer (ESST) is carried out through two-path interference between a direct one-photon coupling and an effective two-photon coupling. A phase difference of π in the one-photon process between the two enantiomers makes the interference constructive for one enantiomer but destructive for the other. Therefore only one enantiomer is excited into a higher rotational state, while the other remains in the ground state. The scheme allows flexibility in the pulse waveforms and the time order of the two paths. We simulate the scheme for a sample of cyclohexylmethanol (C7H14O) molecules. The simulation results show that robust high-fidelity ESST can be obtained when experimental concerns are considered. Finally, we propose to employ the ESST scheme to implement enantioseparation and determine enantiomeric excesses.

Original language	English
Article number	044021
Journal	Physical Review Applied
Volume	13
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevApplied.13.044021
State	Published - Apr 2020

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10.1103/PhysRevApplied.13.044021

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title = "Two-Path Interference for Enantiomer-Selective State Transfer of Chiral Molecules",

abstract = "Using a microwave-regime cyclic three-state configuration, enantiomer-selective state transfer (ESST) is carried out through two-path interference between a direct one-photon coupling and an effective two-photon coupling. A phase difference of π in the one-photon process between the two enantiomers makes the interference constructive for one enantiomer but destructive for the other. Therefore only one enantiomer is excited into a higher rotational state, while the other remains in the ground state. The scheme allows flexibility in the pulse waveforms and the time order of the two paths. We simulate the scheme for a sample of cyclohexylmethanol (C7H14O) molecules. The simulation results show that robust high-fidelity ESST can be obtained when experimental concerns are considered. Finally, we propose to employ the ESST scheme to implement enantioseparation and determine enantiomeric excesses.",

author = "Wu, \{Jin Lei\} and Yan Wang and Han, \{Jin Xuan\} and Cong Wang and Su, \{Shi Lei\} and Yan Xia and Yongyuan Jiang and Jie Song",

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doi = "10.1103/PhysRevApplied.13.044021",

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T1 - Two-Path Interference for Enantiomer-Selective State Transfer of Chiral Molecules

AU - Wu, Jin Lei

AU - Wang, Yan

AU - Han, Jin Xuan

AU - Wang, Cong

AU - Su, Shi Lei

AU - Xia, Yan

AU - Jiang, Yongyuan

AU - Song, Jie

PY - 2020/4

Y1 - 2020/4

N2 - Using a microwave-regime cyclic three-state configuration, enantiomer-selective state transfer (ESST) is carried out through two-path interference between a direct one-photon coupling and an effective two-photon coupling. A phase difference of π in the one-photon process between the two enantiomers makes the interference constructive for one enantiomer but destructive for the other. Therefore only one enantiomer is excited into a higher rotational state, while the other remains in the ground state. The scheme allows flexibility in the pulse waveforms and the time order of the two paths. We simulate the scheme for a sample of cyclohexylmethanol (C7H14O) molecules. The simulation results show that robust high-fidelity ESST can be obtained when experimental concerns are considered. Finally, we propose to employ the ESST scheme to implement enantioseparation and determine enantiomeric excesses.

AB - Using a microwave-regime cyclic three-state configuration, enantiomer-selective state transfer (ESST) is carried out through two-path interference between a direct one-photon coupling and an effective two-photon coupling. A phase difference of π in the one-photon process between the two enantiomers makes the interference constructive for one enantiomer but destructive for the other. Therefore only one enantiomer is excited into a higher rotational state, while the other remains in the ground state. The scheme allows flexibility in the pulse waveforms and the time order of the two paths. We simulate the scheme for a sample of cyclohexylmethanol (C7H14O) molecules. The simulation results show that robust high-fidelity ESST can be obtained when experimental concerns are considered. Finally, we propose to employ the ESST scheme to implement enantioseparation and determine enantiomeric excesses.

UR - https://www.scopus.com/pages/publications/85084184205

U2 - 10.1103/PhysRevApplied.13.044021

DO - 10.1103/PhysRevApplied.13.044021

M3 - 文章

AN - SCOPUS:85084184205

SN - 2331-7019

VL - 13

JO - Physical Review Applied

JF - Physical Review Applied

IS - 4

M1 - 044021

ER -

Two-Path Interference for Enantiomer-Selective State Transfer of Chiral Molecules

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