more love for chap 4 (thx richard)

2025-03-05 09:31:39 -05:00 · 2022-09-23 20:50:28 +02:00 · 2022-09-23 20:50:28 +02:00 · fa914c5394
commit fa914c5394
parent 2c72051a9c
2 changed files with 247 additions and 101 deletions
--- a/references.bib
+++ b/references.bib
@ -1663,3 +1663,130 @@
  publisher =    {Multidisciplinary Digital Publishing Institute},
  doi =          {10.3390/e24030352}
 }
@article{ChengMarkovianApproximationRelaxation2005,
  title =        {Markovian {{Approximation}} in the {{Relaxation}} of
                  {{Open Quantum Systems}}},
  author =       {Cheng, Y. C. and Silbey, R. J.},
  year =         2005,
  month =        nov,
  journal =      {The Journal of Physical Chemistry B},
  volume =       109,
  number =       45,
  pages =        {21399--21405},
  issn =         {1520-6106, 1520-5207},
  doi =          {10.1021/jp051303o},
  langid =       {english}
 }
@article{GaspardSlippageInitialConditions1999,
  ids =          {Slippageinitialconditions1999},
  title =        {Slippage of Initial Conditions for the {{Redfield}}
                  Master Equation},
  author =       {Gaspard, P. and Nagaoka, M.},
  year =         1999,
  month =        oct,
  journal =      {The Journal of Chemical Physics},
  volume =       111,
  number =       13,
  pages =        {5668--5675},
  issn =         {0021-9606, 1089-7690},
  doi =          {10.1063/1.479867},
  abstract =     {For a slow open quantum subsystem weakly coupled to
                  a fast thermal bath, we derive the general form of
                  the slippage to be applied to the initial conditions
                  of the Redfield master equation. This slippage is
                  given by a superoperator which describes the
                  non-Markovian dynamics of the subsystem during the
                  short-time relaxation of the thermal bath. We verify
                  in an example that the Redfield equation preserves
                  positivity after the slippage superoperator has been
                  applied to the initial density matrix of the
                  subsystem. For {$\delta$}-correlated baths, the
                  Redfield master equation reduces to the Lindblad
                  master equation and the slippage of initial
                  conditions vanishes consistently.},
  keywords =     {Matrix equations},
  file =         {/home/cima/Zotero/storage/9FR2GNPV/1999 - Slippage
                  of initial conditions for the Redfield
                  ma.pdf;/home/cima/Zotero/storage/VWC84D6E/Gaspard
                  und Nagaoka - 1999 - Slippage of initial conditions
                  for the Redfield
                  ma.pdf;/home/cima/Zotero/storage/9KVCUA3H/1.html;/home/cima/Zotero/storage/SITD7UR2/1.html}
 }
@article{HaakeAdiabaticDragInitial1983,
  title =        {Adiabatic Drag and Initial Slip in Random Processes},
  author =       {Haake, Fritz and Lewenstein, Maciej},
  year =         1983,
  month =        dec,
  journal =      {Physical Review A},
  volume =       28,
  number =       6,
  pages =        {3606--3612},
  doi =          {10.1103/PhysRevA.28.3606},
  abstract =     {We describe a method for the solution of
                  initial-value problems for random processes arising
                  through adiabatic approximations from Markov
                  processes of higher dimension. In applications to
                  overdamped Brownian motion and to the single-mode
                  laser we calculate correlation functions and discuss
                  initial slips.},
  file =         {/home/cima/Zotero/storage/LWXZ4NTQ/Haake und
                  Lewenstein - 1983 - Adiabatic drag and initial slip
                  in random
                  processe.pdf;/home/cima/Zotero/storage/24H57FUB/PhysRevA.28.html}
 }
@article{SuarezMemoryEffectsRelaxation1992,
  title =        {Memory Effects in the Relaxation of Quantum Open
                  Systems},
  author =       {Su{\'a}rez, Alberto and Silbey, Robert and
                  Oppenheim, Irwin},
  year =         1992,
  month =        oct,
  journal =      {The Journal of Chemical Physics},
  volume =       97,
  number =       7,
  pages =        {5101--5107},
  issn =         {0021-9606},
  doi =          {10.1063/1.463831},
  file =         {/home/cima/Zotero/storage/4QKGH7XP/Suárez et al. -
                  1992 - Memory effects in the relaxation of quantum
                  open
                  s.pdf;/home/cima/Zotero/storage/QNZCSDPY/1.html}
 }
@article{YuPostMarkovMasterEquation2000,
  title =        {Post-{{Markov}} Master Equation for the Dynamics of
                  Open Quantum Systems},
  author =       {Yu, Ting and Di{\'o}si, Lajos and Gisin, Nicolas and
                  Strunz, Walter T.},
  year =         2000,
  month =        feb,
  journal =      {Physics Letters A},
  volume =       265,
  number =       {5-6},
  pages =        {331--336},
  issn =         03759601,
  doi =          {10.1016/S0375-9601(00)00014-1},
  langid =       {english},
  file =         {/home/cima/Zotero/storage/Y9SG4FNN/Yu et al. - 2000
                  - Post-Markov master equation for the dynamics of
                  op.pdf}
 }
@article{Caldeira1981Jan,
  author =       {Caldeira, A. O. and Leggett, A. J.},
  title =        {{Influence of Dissipation on Quantum Tunneling in
                  Macroscopic Systems}},
  journal =      {Phys. Rev. Lett.},
  volume =       46,
  number =       4,
  pages =        {211--214},
  year =         1981,
  month =        jan,
  issn =         {1079-7114},
  publisher =    {American Physical Society},
  doi =          {10.1103/PhysRevLett.46.211}
 }
--- a/src/num_results.tex
+++ b/src/num_results.tex
@ -56,28 +56,25 @@ of this work.
 \section{Some Remarks on the Methods}
 \label{sec:meth}
 Before we begin with the applications in earnest, let us review some
 technical details.
 The figures presented may feature error funnels whose origin is,
 unless otherwise stated, estimated from the empirical standard
 deviation of the calculated quantities due to the finite sample
 size. As the quantities that are being calculated using HOPS are
 essentially Monte Carlo integrals, those statistical errors scale as
-\(1/\sqrt{N}\) with the sample size \(N\) and are therefore
+\(1/\sqrt{N}\) with the sample size \(N\) and are controllable besides
-controllable besides being simple to estimate. Note however, that a
+being simple to estimate. Note however, that a certain number of
-certain number of samples is required to estimate the standard
+samples is required to estimate the standard deviation of a single
-deviation of a single trajectory correctly.
+trajectory correctly.
 To tell whether some vector quantities\footnote{For example a time
-  series.} \(X_1, X_2\) obtained with HOPS or otherwise are compatible
+  series.} \(X_1, X_2\) obtained numerically or otherwise are
-with each other or an analytical result, we consider the quantity
+compatible with each other we introduce the quantity \(Δ=X_1 -
-\(Δ=X_1 - X_2\). Assuming all numerical errors are negligible, we
+X_2\). Assuming all numerical errors are negligible, we demand that
-demand that \(\abs{Δ} \leq σ_Δ\) for at least
+\(\abs{Δ} \leq σ_Δ\) for at least \(68\%\)\footnote{Roughly one
-\(68\%\)\footnote{Roughly one standard deviation of a Gaussian random
+  standard deviation of a Gaussian random variable.}  of the entries
-  variable.}  of the entries of the \(X_i\), where \(σ_Δ\) is the
+of the \(X_i\), where \(σ_Δ\) is the standard deviation due to the
-standard deviation due to the Monte Carlo sampling. This percentage is
+Monte Carlo sampling. This percentage is displayed as a number in
-often displayed in legends as a number in parentheses.
+parentheses in legends of plots in the following sections.
 For the estimation of mean and standard deviation from trajectory
 data, Welford's online algorithm is employed to avoid catastrophic
@ -88,21 +85,19 @@ In all simulations discussed use an Ohmic spectral density
  \label{eq:ohmic_sd}
  J(ω)=η ω \eu^{-\frac{ω}{ω_{c}}}\quad (ω>0)
 \end{equation}
-is used unless otherwise. This spectral density models an environment
+is used.  In \cref{eq:ohmic_sd} \(η\) is a scaling constant and
-with a physical energy spectrum that is bounded from below and allows
+\(ω_c\) (the cutoff frequency) regulates the decay of the spectral
-the application of the finite temperature method described
+density. Due to ambiguities that can arise when using different
-in~\cite{RichardDiss} and \cref{sec:lin_finite}. Also, \(J(0) = 0\)
+normalization schemes for the BCF as was the case for this work, we
-ensures that there is a unique zero temperature state of the
+express the coupling strength in terms of \(α(0)\) rather than giving
-bath. In~\cite{Kolar2012Aug} it is argued (under weak coupling
+values for \(η\). In the convention used above, the parameter \(η\)
-assumptions), that \(J(ω)\approx ω^γ\) with \(γ<1\) could lead to a
+may be recovered as follows
-violation of the third law.  Physically, a scaling of the spectral
+\begin{equation}
-density \(\propto ω\) is connected to acoustic
+  \label{eq:get_eta_back}
-phonons~\cite{Kolar2012Aug}.
+  η=\frac{α(0) π}{ω_{c}^{2}}.
 \end{equation}
-In \cref{eq:ohmic_sd} \(η\) is a scaling
+The corresponding bath correlation function (BCF) is
 constant and \(ω_c\) (the cutoff frequency) regulates the decay of the
 spectral density. The corresponding bath correlation function (BCF)
 is
 \begin{equation}
  \label{eq:ohmic_bcf}
  α(τ) = \frac{1}{π} ∫\dd{ω} J(ω) \eu^{-\iu ωτ} =
@ -112,6 +107,17 @@ We see that higher cutoff frequencies correspond to a faster decay of
 the bath correlation function. This parameter provides control over
 the ``Markovianity'' of the bath.
 The ohmic spectral density models an environment with a physical
 energy spectrum that is bounded from below and allows the application
 of the finite temperature method described in~\cite{RichardDiss} and
 \cref{sec:lin_finite}. Also, \(J(0) = 0\) ensures that there is a
 unique zero temperature state of the bath. In~\cite{Kolar2012Aug} it
 is argued (under weak coupling assumptions), that \(J(ω)\approx ω^γ\)
 with \(γ<1\) could lead to a violation of the third law.  Physically,
 a scaling of the spectral density \(\propto ω\) is connected to
 acoustic phonons~\cite{Kolar2012Aug}.
 It may be remarked, that~\cref{eq:ohmic_bcf} does not correspond to a
 simple sum of exponentials. As such it exercises the HOPS method and
 serves as a model for a general bath correlation function. For use
@ -138,24 +144,26 @@ bath energy flow.
 We begin with the simplest possible model of a harmonic oscillator
 coupled to a single zero temperature bath.  For the simulations with
 HOPS the model \cref{eq:one_ho_hamiltonian} was made dimensionless by
-choosing \(Ω=1\). Simulations were run for both for zero temperature
+choosing \(Ω=1\). Simulations were run for both zero temperature and
-and a finite temperature with varying bath correlation functions.
+finite temperature with various parameters of the bath correlation
-
+function.
 \begin{figure}[t]
  \centering
  \includegraphics{figs/analytic_comp/flow_comp_zero.pdf}
  \caption{\label{fig:comp_zero_t} The bath energy flow \(-J\) for
    different parameters of the ohmic bath correlation function
-    \cref{eq:ohmic_bcf}. The right panel shows the short time behaviour
+    \cref{eq:ohmic_bcf}. The right panel shows the short time
-    of the flow. The solid lines have been obtained with HOPS and the
+    behaviour of the flow. The solid lines have been obtained with
-    dashed lines using the analytic solution. A good agreement is
+    HOPS and the dashed lines using the analytic solution. A
-    evident visually and corroborated by the consistency values in the
+    strikingly good agreement is evident visually and corroborated by
-    legend (see \cref{sec:meth} for an explanation).  The simulation
+    the consistency values in parentheses the legend (see
-    with \(ω_{c}=3\) (orange) stands out for its slow long term decay,
+    \cref{sec:meth} for an explanation).  The simulation with
    \(ω_{c}=3\) (orange) stands out for its slow long term decay,
    whereas the same simulation with longer bath correlation time
-    (blue) initially decays much slower but falls below its orange
+    (blue) decays much slower initially but falls below its orange
    counterpart for longer times.}
 \end{figure}
 \paragraph{Zero Temperature}
 The bath energy flow \(J=-∂_t\ev{H_\bath}\), from here on called
 simply ``the flow'' or ``bath energy flow'', for the zero temperature
@ -173,13 +181,13 @@ The simulation was run with a hierarchy depth of
 harmonic oscillator Hilbert space was truncated to \(15\) dimensions
 in the energy basis. As the initial state the first excited state of
 the oscillator was chosen so that some nontrivial energy flow would
-occur. Some \(N=5000\) trajectories have been computed and lead to a
+occur. A reasonable number of \(N=5000\) trajectories have been
-quite satisfactory statistical error that is small enough to be
+computed and lead to a quite satisfactory statistical error that is
-invisible in \cref{fig:comp_zero_t}. The normalized standard deviation
+small enough to be invisible in \cref{fig:comp_zero_t}. The normalized
-of the bath energy flow follows the usual one-over-square-root rule as
+standard deviation of the bath energy flow follows the usual
-is illustrated in \cref{fig:sqrt_conv}. Even after just \(N=1000\)
+one-over-square-root rule as is illustrated in
-trajectories the normalized statistical error is on the order of
+\cref{fig:sqrt_conv}. Even after just \(N=1000\) trajectories the
-\(10^{-3}\).
+normalized statistical error is on the order of \(10^{-3}\).
 \begin{figure}[htp]
  \centering
  \includegraphics{figs/analytic_comp/sqrt_convergence.pdf}
@ -218,18 +226,20 @@ separate fit was made rather than using the fit from
 Interestingly, the solutions using a BCF expansion with three terms or
 fewer lead to an unphysical non-zero steady state bath energy
 flow. Considering specifically the case of one expansion term, this
-may be related to the fact that now the BCF term so that
+may be related to the fact that now the corresponding spectral density
-\(α(τ)=G \exp(-Wτ)\) is related to a Lorentzian spectral density that
+of \(α(τ)=G \exp(-Wτ)\) also has a finite value for negative
-also includes unphysical negative frequencies. To correctly reproduce
+frequencies and will have negative parts when \(\Im G \neq 0\), making
-the steady state, the fit must model the decay of the BCF on the
+it unphysical.  In general, the fit must model the decay of the BCF on
-appropriate time scales.
+the appropriate time scales, to correctly reproduce the steady state.
 Although the simulations are primarily intended as a benchmark for
 HOPS and a verification for the results of \cref{chap:flow} some
 observations can be made in \cref{fig:comp_zero_t}.
 First, the flows for different parameters all feature the
-characteristic spike in the flow, not unlike an ``initial slip''. As
+characteristic spike in the flow, not unlike the phenomenon known and
 discussed in the literature as ``initial
 slip''~\cite{ChengMarkovianApproximationRelaxation2005,GaspardSlippageInitialConditions1999,HaakeAdiabaticDragInitial1983,SuarezMemoryEffectsRelaxation1992,YuPostMarkovMasterEquation2000}. As
 the initial state is a product state which is unaware of the
 bath-system interaction, the state undergoes some short time dynamics
 to compensate the change of the effective oscillator dynamics due to
@ -255,10 +265,10 @@ takes the form \cite{Weiss2008Mar}
  H_{\mathrm{C}} \sim ∑_{λ}\frac{\abs{g_{λ}}^{2}}{ω_{λ}} q^{2}.
 \end{equation}
 When \cref{eq:counter_term} is included in \cref{sec:oneosc}, our
-model becomes the Caldiera-Legget Model.  The counter term balances
+model becomes the Caldiera-Legget Model~\cite{Caldeira1981Jan}.  In
-the renormalization of the system potential due to the bath. It is
+many cases, the counter term balances the renormalization of the
-therefore an interesting question how the initial slip behaves in its
+system potential due to the bath. It is therefore an interesting
-presence.
+question how the initial slip behaves in its presence.
 The time dependence of the flow also varies both with the shape of the
 BCF and the coupling strength. For longer correlation times
@ -270,9 +280,9 @@ situation is reversed and the simulation cuttoff frequency \(ω_{c}=3\)
 strengths we can observe a ``backflow'' of energy out of the bath as
 can be observed for the red line in the right panel of
 \cref{fig:comp_zero_t}. In all cases the flow features some
-oscillations and decays to zero which is physical for the situation of
+oscillations and decays to zero which is physically reasonable for the
-a harmonic oscillator that loses most of its energy into a zero
+situation of a harmonic oscillator that loses most of its energy into
-temperature bath.
+a zero temperature bath.
 When the bath memory is short however, the short-term energy flow is
 of less magnitude. Correspondingly, the system energy decays slower
@ -293,17 +303,18 @@ in frequency space.
    dynamics. The strongest coupling simulation (red) converges to a
    markedly different steady state.}
 \end{figure}
-The ``backflow'' observed in \cref{fig:comp_zero_t} for stronger
+The ``backflow'' of energy out of the bath observed in
-coupling seems to diminish the advantage of stronger coupling over
+\cref{fig:comp_zero_t} for stronger coupling seems to diminish the
-larger bath memories. The decay of the red curve in the right panel of
+advantage of stronger coupling over larger bath memories when it comes
-\cref{fig:ho_zero_entropy} is barely faster than the decay of the blue
+to reducing the system energy. The decay of the system energy of the
-curve, despite much larger coupling strength in the red case. This may
+model with the largest coupling strength \(α(0)\) (red curve) in the
-be due to the system interacting ``too long'' with a given portion of
+right panel of \cref{fig:ho_zero_entropy} is barely faster than the
-the bath. Here we observe this behaviour for stronger coupling which
+decay of the energy of the more weakly coupled model with longer
-shortens the timescale of the energy exchange. In
+memory (blue curve), despite much larger coupling. Here backflow is
-\cref{sec:one_bath_cutoff} we will see, that these oscillations occur
+observed for stronger coupling which shortens the timescale of the
-generically for long bath memories and stronger coupling and how they
+energy exchange. In \cref{sec:one_bath_cutoff} we will see, that this
-might be exploited.
+phenomenon generically occurs for long bath memories in combination
 with stronger coupling and learn how they might be exploited.
 Note also, that the steady state is not a product state as can be
 determined from the residual entropy in \cref{fig:ho_zero_entropy} for
@ -317,7 +328,7 @@ qualitatively different steady state than the one with the same cutoff
 but weaker coupling strength (green line). This also manifests in a
 higher expected system energy in the steady state.
-\begin{wrapfigure}[18]{o}{0.4\textwidth}
+\begin{wrapfigure}[-4]{O}{0.4\textwidth}*
  \centering
  \includegraphics{figs/analytic_comp/timescale_comparison}
  \caption{\label{fig:timescale_comp} A comparison of bath vs
@ -326,18 +337,19 @@ higher expected system energy in the steady state.
    in \cref{fig:ho_zero_entropy}. The orange line is set far apart
    from the other simulations.}
 \end{wrapfigure}
-The time dependence of the entropy the expectation value of the system
+The time dependence of the system entropy and the system energy
-energy is markedly different for the cutoff \(ω_c=3\) (orange
+expectation value is markedly different for the cutoff \(ω_c=3\)
-line). Although the coupling strength is similar to the
+(orange line). Although the coupling strength is similar to the
 \(α(0)=0.32,\, ω_c=1\) case (blue line) the energy loss of the system
 is much slower and the initial energy gain is less pronounced. This is
-consistent with the flow in \cref{fig:comp_zero_t}. The case is set
+consistent with the flow in \cref{fig:comp_zero_t} which has a smaller
-apart by the long interaction timescale \(τ_{\inter}\) due to the
+overall magnitude. The case is set apart by the long interaction
-weaker coupling strength \(\sim α(0)^{-1/2}\) and the short bath
+timescale \(τ_{\inter}\) due to the weaker coupling strength
-timescale \(τ_{\bath}\sim ω_{c}^{-1}\). Of course absolute values of
+\(\sim α(0)^{-1/2}\) and the short bath timescale
-these time scales of no great value here. A comparison of relative
+\(τ_{\bath}\sim ω_{c}^{-1}\). Of course absolute values of these time
-time scales \(\sqrt{α(0)}/ω_{c}\sim τ_{\bath}/τ_{\inter}\) can be
+scales are of no great value here. A comparison of relative time
-found in \cref{fig:timescale_comp} supporting the above argument.
+scales \(\sqrt{α(0)}/ω_{c}\sim τ_{\bath}/τ_{\inter}\) can be found in
 \cref{fig:timescale_comp} supporting the above argument.
 \paragraph{Finite Temperature}
 \begin{figure}[t]
@ -445,28 +457,28 @@ and compare the results with the analytical solution.
 For simplicity, the parameters were chosen symmetric so that the
 frequencies of both oscillators are the same \(Ω=Λ=1\). As before,
 \(Ω\) defines the energy unit. The zero temperature bath correlation
-functions of both baths were chosen identically with a cutoff
+functions of both baths were identical with a cutoff frequency
-frequency \(ω_c=2\). The intra-oscillator coupling was chosen as
+\(ω_c=2\) and the intra-oscillator coupling was set to \(γ=0.5\). The
-\(γ=0.5\). The hierarchy was truncated so that \(\abs{\vb{k}}\leq 3\)
+hierarchy was truncated so that \(\abs{\vb{k}}\leq 3\) and a BCF
-and a BCF expansion with five terms was chosen to limit memory demands
+expansion with five terms was employed to limit memory demands.  For
-and \(10^{4}\) trajectories were integrated.
+adequate convergence \(10^{4}\) trajectories were integrated.
-To limit the variance the temperature of one of the baths was set to
+To limit the variance, the temperature of one of the baths was set to
-zero, so that only one thermal stochastic process was introduced. The
+zero, so that only one thermal stochastic process was introduced.  The
-other bath was chosen to have \(T=0.6\). The ground state of the
+other bath was initialized with the temperature \(T=0.6\) and the
-system Hamiltonian \(\ket{0}\otimes \ket{0}\) was chosen as the
+initial state of the oscillators was chosen to be the ground state of
-initial state of the oscillators.
+the system Hamiltonian \(\ket{0}\otimes \ket{0}\).
 The main challenge of simulating the model
 \cref{eq:hamiltonian_two_bath} is the dimension of the system Hilbert
 space which is constrained by the available memory. In the simulation
 discussed here, each oscillator was truncated at \(9\) levels leading
-to \(9^2 = 81\) dimensions in total\footnote{This is a naive method of
+to a Hilbert space dimension of \(9^2 = 81\) in total\footnote{This is
-  truncation, but sufficient for the purposes of this work.}. The
+  a naive method of truncation, but sufficient for the purposes of
-effect of a too drastic truncation of the system Hilbert space can be
+  this work.}. The effect of a too drastic truncation of the system
-seen in \cref{fig:insufficient_levels}. At the temperature chosen, the
+Hilbert space can be seen in \cref{fig:insufficient_levels}. At the
-mean level occupation of a harmonic oscillator is given by the Bose
+temperature chosen, the mean level occupation of a harmonic oscillator
-distribution
+is given by the Bose distribution
 \begin{equation}
  \label{eq:harm_mean_occ}
  \ev{n} = \frac{1}{\eu^{Ωβ}-1} \approx 0.23 < 1.
@ -484,12 +496,16 @@ sufficient to corroborate the validity of the results of
 \cref{sec:multibath}. With more computational effort\footnote{Mainly
  more BCF expansion terms.} and fine-tuning of parameters an even
 better agreement between the analytical and the numerical results may
-be achieved.
+be achieved. Note that the consistency figure given for the hot bath
 is higher, as the statistical error bounds are greater due to the
 finite temperature. These increased error bounds allow for more
 deviation.
 \begin{figure}[htp]
  \centering
  \begin{subfigure}[t]{.49\linewidth}
    \includegraphics{figs/analytic_comp/comparison_two_5bcf_5ho.pdf}
-    \caption{\label{fig:insufficient_levels}\(\dim\hilb_\sys=25\).}
+    \caption{\label{fig:insufficient_levels}\(\dim\hilb_\sys=25\).  No
      agreement between the analytical solution and HOPS.}
  \end{subfigure}
  \begin{subfigure}[t]{.49\linewidth}
    \includegraphics{figs/analytic_comp/comparison_two_ho.pdf}
@ -528,12 +544,15 @@ deviation of a given observable. In \cref{sec:pure_deph} we will
 discuss the short term dynamics of our general model and explain the
 peak in the flow, as seen in \cref{fig:comp_zero_t}.
-For future work there remains the generalization of the work in this
+For future work there remains the generalization of this section and
-section and \cref{chap:analytsol} to time dependent couplings and
+\cref{chap:analytsol} to time dependent couplings and
 Hamiltonians. Because the NMQSD and also HOPS are largely agnostic of
 these factors, we may safely assume that the results of the comparison
 will be similar to the ones presented here.
 Let us now turn to the short time behavior of the flow and the initial
 slip in \cref{sec:pure_deph} .
 \section{Pure Dephasing and the Initial Slip}
 \label{sec:pure_deph}
 As seen in \cref{fig:comp_finite_t,fig:comp_zero_t,fig:comp_two_bath},