Friethjof Theel scite author profile

We unravel the correlated tunneling dynamics of an impurity trapped in a double well and interacting repulsively with a majority species of lattice trapped bosons. Upon quenching the tilt of the double well it is found that the quench-induced tunneling dynamics depends crucially on the interspecies interaction strength and the presence of entanglement inherent in the system. In particular, for weak couplings the impurity performs a rather irregular tunneling process in the double well. Increasing the interspecies coupling it is possible to control the response of the impurity which undergoes a delayed tunneling while the majority species effectively acts as a material barrier. For very strong interspecies interaction strengths the impurity exhibits a self-trapping behavior. We showcase that a similar tunneling dynamics takes place for two weakly interacting impurities and identify its underlying transport mechanisms in terms of pair and single-particle tunneling processes.

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Many-body collisional dynamics of impurities injected into a double-well trapped Bose-Einstein condensate

Theel

Keiler

Mistakidis

et al. 2021

Phys. Rev. Research

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Counterflow dynamics of two correlated impurities immersed in a bosonic gas

Theel¹,

Mistakidis

Keiler³

et al. 2022

Phys. Rev. A

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The fractal geometry of Hartree-Fock

Theel

Karamatskou

Santra

2017

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The Hartree-Fock method is an important approximation for the ground-state electronic wave function of atoms and molecules so that its usage is widespread in computational chemistry and physics. The Hartree-Fock method is an iterative procedure in which the electronic wave functions of the occupied orbitals are determined. The set of functions found in one step builds the basis for the next iteration step. In this work, we interpret the Hartree-Fock method as a dynamical system since dynamical systems are iterations where iteration steps represent the time development of the system, as encountered in the theory of fractals. The focus is put on the convergence behavior of the dynamical system as a function of a suitable control parameter. In our case, a complex parameter λ controls the strength of the electron-electron interaction. An investigation of the convergence behavior depending on the parameter λ is performed for helium, neon, and argon. We observe fractal structures in the complex λ-plane, which resemble the well-known Mandelbrot set, determine their fractal dimension, and find that with increasing nuclear charge, the fragmentation increases as well.

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Induced attractive and repulsive interactions between two distinguishable Bose polarons

Theel¹,

Mistakidis²

2023

Preprint

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Friethjof Theel

Entanglement-assisted tunneling dynamics of impurities in a double well immersed in a bath of lattice trapped bosons

Many-body collisional dynamics of impurities injected into a double-well trapped Bose-Einstein condensate

Counterflow dynamics of two correlated impurities immersed in a bosonic gas

The fractal geometry of Hartree-Fock

Induced attractive and repulsive interactions between two distinguishable Bose polarons

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