mirror of
https://github.com/vale981/HOPSFlow-Paper
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205 lines
7 KiB
TeX
205 lines
7 KiB
TeX
\documentclass[reprint,aps,superscriptaddress]{revtex4-2}
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\usepackage[unicode=true,bookmarks=true,bookmarksnumbered=false,bookmarksopen=false,breaklinks=false,pdfborder={0 0 1}, backref=false,colorlinks=true]{hyperref}
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\usepackage{orcidlink}
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\usepackage{microtype}
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\usepackage{mathtools}
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\usepackage{graphicx}
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\usepackage{physics}
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\usepackage{cleveref}
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\usepackage{bm}
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\bibliographystyle{apsrev4-2}
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% HOPS/NMQSD
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\def\sys{\ensuremath{\mathrm{S}}}
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\def\bath{\ensuremath{\mathrm{B}}}
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\def\inter{\ensuremath{\mathrm{I}}}
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\def\nth{\ensuremath{^{(n)}}}
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% unicode math
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\iftutex
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\usepackage{unicode-math}
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\else
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\usepackage{amssymb}
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\def\z"{}
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\def\UnicodeMathSymbol#1#2#3#4{%
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\ifnum#1>"A0
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\DeclareUnicodeCharacter{\z#1}{#2}%
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\fi}
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\input{unicode-math-table}
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\let\muprho\rho
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\def\BbbR{\mathbb{R}}
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\fi
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\begin{document}
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\preprint{APS/123-QED}
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\title{Quantifying Energy Flow in Arbitrarily Modulated Open Quantum Systems}
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\date{12.12.2100}
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% fixme
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\newcommand{\fixme}[1]{\marginpar{\tiny\textcolor{red}{#1}}}
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\author{Valentin Boettcher\,\orcidlink{0000-0003-2361-7874}}
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\affiliation{McGill University}
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\altaffiliation[formerly at ]{TU Dresden}
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\email{valentin.boettcher@mail.mcgill.ca}
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\author{Konstantin Beyer\,\orcidlink{0000-0002-1864-4520}}
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\email{konstantin.beyer@tu-dresden.de}
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\affiliation{TU Dresden}
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\author{Richard Hartmann\,\orcidlink{0000-0002-8967-6183}}
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\email{richard.hartmann@tu-dresden.de}
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\affiliation{TU Dresden}
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\author{Walter T. Strunz\,\orcidlink{0000-0002-7806-3525}}
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\email{walter.strunz@tu-dresden.de}
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\affiliation{TU Dresden}
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\begin{abstract}
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\end{abstract}
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\maketitle
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\tableofcontents
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\section{Introduction}
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\label{sec:introduction}
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The field of quantum thermodynamics has attracted much interest
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recently~\cite{Talkner2020Oct,Rivas2019Oct,Riechers2021Apr,Vinjanampathy2016Oct,Binder2018,Kurizki2021Dec,Mukherjee2020Jan,Xu2022Mar}.
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Quantum thermodynamics is, among other issues, concerned with
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extending the standard phenomenological thermodynamic notions to
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microscopic open systems.
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The general type of model that is being investigated in this field is
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given by the Hamiltonian
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\begin{equation}
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\label{eq:4}
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H = H_{\sys} + ∑_{n} \qty[H_{\inter}^{(n)} + H_{\bath}^{(n)}],
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\end{equation}
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where \(H_{\sys}\) models a ``small'' system (from here on called
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simply the \emph{system}) of arbitrary structure and the
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\(H_{\bath}^{(n)}\) model the ``large'' bath systems with simple
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structure but a large number of degrees of freedom. The
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\(H_{I}^{(n)}\) acts on system and bath, mediating their interaction.
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In this setting may make be possible to formulate rigorous microscopic
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definitions of thermodynamic quantities such as internal energy, heat
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and work that are consistent with the well-known laws of
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thermodynamics. Currently, there is no consensus on this matter yet,
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as is demonstrated by the plethora of proposals and discussions in
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\cite{Rivas2019Oct,Talkner2020Oct,Motz2018Nov,Wiedmann2020Mar,Senior2020Feb,Kato2015Aug,Kato2016Dec,Strasberg2021Aug,Talkner2016Aug,Bera2021Feb,Bera2021Jun,Esposito2015Dec,Elouard2022Jul}.
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This is particularly true for the general case where the coupling to
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the baths may be arbitrarily strong. In this case the weak coupling
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treatment that allows separate system and bath dynamics is not
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applicable. Even the simple seeming question of how internal energy is
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to be defined becomes non-trivial~\cite{Rivas2012,Binder2018} due to
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the fact that \(\ev{H_{\inter}}\neq 0\).
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In this way the bath degrees of freedom interesting in themselves,
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which necessitates a treatment of the exact global unitary dynamics of
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system and bath.
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If no analytical solution for these dynamics is available, numerical
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methods have to be relied upon. Notably there are perturbative methods
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such as the Redfield equations for non-Markovian weak coupling
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dynamics~\cite{Davidovic2020Sep} and also exact methods like the
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Hierarchical Equations of Motion
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HEOM~\cite{Tanimura1990Jun,Tang2015Dec}, multilayer
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MCTDH~\cite{Wang2010May}, TEMPO~\cite{Strathearn2018Aug} and the
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Hierarchy of Pure States HOPS~\cite{Suess2014Oct}\footnote{See
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\cite{RichardDiss} for a detailed account.}. Although the focus of
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these methods is on the reduced system dynamics, exact treatments of
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open systems can provide access to the global unitary evolution of the
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system and the baths.
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In this work we will focus on the framework of the ``Non-Markovian
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Quantum State Diffusion'' (NMQSD)~\cite{Diosi1998Mar}, which is
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briefly reviewed in~\cref{sec:nmqsd}. We will show in \cref{chap:flow}
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that the NMQSD allows access to interaction and bath related
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quantities. This novel application of the formalism constitutes the
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main result of this work.
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Based on the NMQSD and inspired by the ideas behind HEOM, a numerical
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method, the ``Hierarchy of Pure States''
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(HOPS)~\cite{RichardDiss,Hartmann2017Dec}, can be formulated. A brief
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account of the method is given in \cref{sec:hops}.
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The results of \cref{sec:flow}, most importantly the calculation of
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bath and interaction energy expectation values, can be easily
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implemented within this numerical framework. By doing so we will
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elucidate the role of certain features inherent to the method. The
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most general case we will be able to handle is a system coupled to
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multiple baths of differing temperatures under arbitrary time
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dependent modulation. As HOPS on its own is already a method with a
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very broad range of applicability~\cite{RichardDiss}, we will find it
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to be suitable for the exploration of thermodynamical settings.
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In \cref{sec:applications} we apply this result to two simple systems.
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As an elementary application, a brief study of the characteristics of
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the energy flow out of a qubit into a zero temperature bath is
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presented in \cref{sec:qubit-relax-char}. To demonstrate the current
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capabilities of our method to the fullest we will turn to the
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simulation of a quantum Otto-like
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cycle~\cite{cite:Geva1992Feb,cite:Wiedmann2020Mar,cite:Wiedmann2021Jun}
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in \cref{sec:quantum-otto-cycle}, which features a simultaneous time
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dependence in both \(H_{\inter}\) and \(H_{\sys}\).
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\section{Energy Flow with HOPS}
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\label{sec:flow}
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Let us proceed by briefly reviewing the fundamentals of the NMQSD and
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the HOPS. A more thuro
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\subsection{The NMQSD}
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\label{sec:nmqsd}
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\subsection{The HOPS}
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\label{sec:hops}
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\subsection{Bath Observables}
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\label{sec:bath-observables}
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\subsubsection{Bath Energy Change}
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\label{sec:bath-energy-change}
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\subsubsection{General Collective Bath Observables}
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\label{sec:gener-coll-bath}
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\section{Applications}
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\label{sec:applications}
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\subsection{Qubit Relaxation Characteristics}
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\label{sec:qubit-relax-char}
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\subsection{A Quantum Otto Cycle}
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\label{sec:quantum-otto-cycle}
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\begin{itemize}
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\item see the chapter in my thesis
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\item \textbf{Ask richard about phase transitions in spin boson}
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\end{itemize}
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\section{Outlook and Open Questions}
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\label{sec:outl-open-quest}
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\begin{itemize}
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\item steady state methods
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\item energy flow for portions of the bath -> adaptive method?
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\end{itemize}
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\bibliography{index}
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\end{document}
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%%% Local Variables:
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%%% TeX-master: t
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%%% TeX-output-dir: "output"
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%%% End:
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