Your search keyword '"Floß, J."' showing total 4 results

1. Atom-diatom scattering dynamics of spinning molecules.

Author

Eyles, C. J., Floß, J., Averbukh, I. Sh., and Leibscher, M.

Subjects

*ATOMS, *SCATTERING (Physics), *QUANTUM mechanics, *NUCLEAR spin, *LASER pulses, *ISOMERS

Abstract

We present full quantum mechanical scattering calculations using spinning molecules as target states for nuclear spin selective atom-diatom scattering of reactive D+H2 and F+H2 collisions. Molecules can be forced to rotate uni-directionally by chiral trains of short, non-resonant laser pulses, with different nuclear spin isomers rotating in opposite directions. The calculations we present are based on rotational wavepackets that can be created in this manner. As our simulations show, target molecules with opposite sense of rotation are predominantly scattered in opposite directions, opening routes for spatially and quantum state selective scattering of close chemical species. Moreover, two-dimensional state resolved differential cross sections reveal detailed information about the scattering mechanisms, which can be explained to a large degree by a classical vector model for scattering with spinning molecules. [ABSTRACT FROM AUTHOR]

Published

2015

2. Nuclear spin selective laser control of rotational and torsional dynamics.

Author

Floß, J., Grohmann, T., Leibscher, M., and Seideman, T.

Subjects

*NUCLEAR spin, *TORSION, *POLYATOMIC molecules, *ULTRASHORT laser pulses, *ANGULAR momentum (Mechanics)

Abstract

We explore the possibility of controlling rotational-torsional dynamics of non-rigid molecules with strong, non-resonant laser pulses and demonstrate that transient, laser-induced torsional alignment depends on the nuclear spin of the molecule. Consequently, nuclear spin isomers can be manipulated selectively by a sequence of time-delayed laser pulses. We show that two pulses with different polarization directions can induce either overall rotation or internal torsion, depending on the nuclear spin. Nuclear spin selective control of the angular momentum distribution may open new ways to separate and explore nuclear spin isomers of polyatomic molecules. [ABSTRACT FROM AUTHOR]

Published

2012

3. Laser-induced molecular alignment in the presence of chaotic rotational dynamics.

Author

Floß J and Brumer P

Abstract

Coherent control of chaotic molecular systems, using laser-assisted alignment of sulphur dioxide (SO 2 ) molecules in the presence of a static electric field as an example, is considered. Conditions for which the classical version of this system is chaotic are established, and the quantum and classical analogs are shown to be in very good correspondence. It is found that the chaos present in the classical system does not impede the alignment, neither in the classical nor in the quantum system. Using the results of numerical calculations, we suggest that laser-assisted alignment is stable against rotational chaos for all asymmetric top molecules.

Published

2017

4. Nuclear spin selective laser control of rotational and torsional dynamics.

Author

Floss J, Grohmann T, Leibscher M, and Seideman T

Abstract

We explore the possibility of controlling rotational-torsional dynamics of non-rigid molecules with strong, non-resonant laser pulses and demonstrate that transient, laser-induced torsional alignment depends on the nuclear spin of the molecule. Consequently, nuclear spin isomers can be manipulated selectively by a sequence of time-delayed laser pulses. We show that two pulses with different polarization directions can induce either overall rotation or internal torsion, depending on the nuclear spin. Nuclear spin selective control of the angular momentum distribution may open new ways to separate and explore nuclear spin isomers of polyatomic molecules.

Published

2012