Geometry of quantum hydrodynamics in theoretical chemistry
- URL: http://arxiv.org/abs/2009.13601v1
- Date: Mon, 28 Sep 2020 19:58:33 GMT
- Title: Geometry of quantum hydrodynamics in theoretical chemistry
- Authors: Michael S. Foskett
- Abstract summary: This thesis investigates geometric approaches to quantum hydrodynamics (QHD) in order to develop applications in theoretical quantum chemistry.
The momentum map approach to QHD is then applied to the nuclear dynamics in a chemistry model known as exact factorization.
A new mixed quantum-classical model is then derived by considering a generalised factorisation ansatz.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: This thesis investigates geometric approaches to quantum hydrodynamics (QHD)
in order to develop applications in theoretical quantum chemistry.
Based upon the momentum map geometric structure of QHD and the associated
Lie-Poisson and Euler-Poincar\'e equations, alternative geometric approaches to
the classical limit in QHD are presented. These include a new regularised
Lagrangian which allows for singular solutions called 'Bohmions' as well as a
'cold fluid' classical closure quantum mixed states.
The momentum map approach to QHD is then applied to the nuclear dynamics in a
chemistry model known as exact factorization. The geometric treatment extends
existing approaches to include unitary electronic evolution in the frame of the
nuclear flow, with the resulting dynamics carrying both Euler-Poincar\'e and
Lie-Poisson structures. A new mixed quantum-classical model is then derived by
considering a generalised factorisation ansatz at the level of the molecular
density matrix.
A new alternative geometric formulation of QHD is then constructed.
Introducing a $\mathfrak{u}(1)$ connection as the new fundamental variable
provides a new method for incorporating holonomy in QHD, which follows from its
constant non-zero curvature. The fluid flow is no longer irrotational and
carries a non-trivial circulation theorem, allowing for vortex filament
solutions.
Finally, non-Abelian connections are then considered in quantum mechanics.
The dynamics of the spin vector in the Pauli equation allows for the
introduction of an $\mathfrak{so}(3)$ connection whilst a more general
$\mathfrak{u}(\mathscr{H})$ connection is introduced from the unitary evolution
of a quantum system. This is used to provide a new geometric picture for the
Berry connection and quantum geometric tensor, whilst relevant applications to
quantum chemistry are then considered.
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