Geometry-based classical mapping for two-level systems reveals coupling-dependent transition from oscillatory to tunneling-suppressed dynamics and turns isolated symmetric systems into environment-assisted asymmetric ones.
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A long-ranged parity-nonconserving interaction in a chiral environment induces energy splitting between enantiomers and amplifies time-averaged population differences in a central chiral molecule via non-linear Schrödinger dynamics.
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Dissipative evolution of a two-level system through a geometry-based classical mapping
Geometry-based classical mapping for two-level systems reveals coupling-dependent transition from oscillatory to tunneling-suppressed dynamics and turns isolated symmetric systems into environment-assisted asymmetric ones.
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Chiral environment effects on the dynamics of a central chiral molecule
A long-ranged parity-nonconserving interaction in a chiral environment induces energy splitting between enantiomers and amplifies time-averaged population differences in a central chiral molecule via non-linear Schrödinger dynamics.