some touchups on the outro

src/outro.tex

@@ -3,57 +3,68 @@
 
 In this work, we set out to find a way of accessing bath related
 observables, such as the expected bath energy change and the
-interaction energy expectation value, using the
+interaction energy expectation value using the
 NMQSD\footnote{Non-Markovian Quantum State
   Diffusion}/HOPS\footnote{Hierarchy of Pure States} framework which
-we introduced in \cref{chap:intro}.  This endeavor was indeed
+we introduced in \cref{chap:intro}.
-successful as was laid out in \cref{chap:flow}.
 
-In \cref{chap:flow} we presented a solution to a well known model for
+This endeavour was indeed successful, as we laid out in
-quantum Brownian motion. Using this solution, we were able to derive
+\cref{chap:flow}. The crucial point is, that we still have access to
-expressions for the bath energy change \(∂_{t}\ev{H_{\bath}}\).
+the bath degrees of freedom \emph{before} performing a stochastic
+average over the NMQSD/HOPS trajectories. This allows us to compute
+the expectation values of observables which contain the bosonic bath
+operators collectively.
+
+In \cref{chap:flow} we presented an analytic solution to a well known
+model for quantum Brownian motion. Using this solution, we were able
+to derive expressions for the bath energy change
+\(∂_{t}\ev{H_{\bath}}\) for models with one and two baths.
 
 This enabled us to verify the results of \cref{chap:flow} in
 \cref{chap:numres} by solving the same model numerically using
-HOPS. Excellent agreement was found in
+HOPS. Excellent agreement was found in \cref{sec:hopsvsanalyt}.
-\cref{sec:hopsvsanalyt}.
 
 Turning to the spin-boson model in \cref{sec:prec_sim}, we used energy
 conservation to verify again, that we can consistently and efficiently
-compute bath related observables with HOPS. In the cases where the
+compute bath related observables with HOPS upon the example of the
-consistency condition was not met, we nevertheless found that
+interaction energy expectation value. In the cases where the
-qualitatively correct results had been reached. The direct calculation
+consistency condition was not met, we nevertheless found that the
-of the interaction energy by the use of \cref{sec:intener} gives
+results were qualitatively correct. When choosing less precise
-results that are more precise than the ones obtained through energy
+numerical parameters, the direct calculation of the interaction energy
-conservation.
+by the use of \cref{sec:intener} yields results that are generally
+much more precise than the ones obtained through energy conservation.
 
 We continued to explore the energy transfer behavior of the zero
 temperature spin-boson model and found that energy transfer
 performance for strong coupling has a complicated dependence on the
-spectral density of the bath. Energy transfer performance can be
+shape of the spectral density of the bath. Energy transfer performance
-optimized longer bath memories and resonant baths when the interaction
+can be optimized through longer bath memories and resonant baths when
-is turned off at the right time.
+the interaction is switched off at the right time. Switching the
+interaction off in finite time leads to cooling of the system,
+especially when the steady state had been reached.
 
-The short time dynamics of the bath energy change can be explained by
+Having explained short time dynamics of the bath energy change in
-neglecting the system Hamiltonian, which we verified for the
+\cref{sec:pure_deph} neglecting the system Hamiltonian, which we
-spin-boson model. It was also found, that this short time behaviour is
+verified for the spin-boson model in
-already present on the trajectory level so that there are no
+\cref{sec:initial-slip-sb,sec:moder-init-slip}. It was further found,
-stochastic fluctuations for short times. During this initial period,
+that this short time behaviour is already present on the trajectory
-the auxiliary states of the HOPS are being populated.
+level so that there are no stochastic fluctuations for short
+times. Instead, the auxiliary states of the HOPS are being populated
+during this initial period.
 
-In \cref{sec:singlemod} we turned to issues of quantum
+In \cref{sec:singlemod} we turned to some issues of quantum
-thermodynamics. We reviewed some general analytical results that
+thermodynamics. We reviewed general analytical results that bounded
-bounded energy extraction from open systems in
+energy extraction from open systems in \cref{sec:basic_thermo}, both
-\cref{sec:basic_thermo}, both for the single-bath and the multi-bath
+for the single-bath and the multi-bath case. We then turned to some
-case. We then turned to some more challenging applications of the HOPS
+more challenging applications of the HOPS method. First, a driven
-method. First, a driven spin-boson model was considered. We found that
+spin-boson model was considered. We found that a not insignificant
-a not insignificant fraction of the theoretical maximum of energy can
+fraction of the upper bound on the ergotropy can be extracted by
-be extracted by modulating the coupling and providing a bath with long
+modulating the coupling and providing a bath with long memory time. We
-memory time. We also demonstrated quantum friction, a quantum speed
+also demonstrated quantum friction, a quantum speed limit and a bath
-limit and a bath resonance phenomenon.
+resonance phenomenon.
 
-Finally, we treated a model with multiple baths in \cref{sec:otto} and
+Finally, we treated a model with multiple baths and non-harmonic
-non-harmonic smooth modulation. A cyclic modulation protocol was
+smooth modulation in \cref{sec:otto}. A cyclic modulation protocol was
 implemented upon a two level system coupled to two baths in a
 spin-boson like fashion. We achieved finite power with finite
 efficiency and verified a Gibbs-like inequality
@@ -66,19 +77,20 @@ optimization for optimal power which leads to the
 Novikov–Curzon–Ahlborn efficiency \(η_{ca}=1-\sqrt{T_{c}/T_{h}}\) is
 interesting in the case of stronger coupling.
 
-Another cycle to study would be a Carnot-type cycle, where the
+Another cycle to study would be a Carnot-type process, where the
 modulation of the system and the thermalization with the bath occur at
 the same time. Interpolating between Otto and Carnot, as well as
 studying the effect of overlapping and shifting strokes is a
 fascinating avenue for future exploration.
 
-Also, more interesting working media, such as a three level system are
+Also, more interesting working media, beginning with a three level
-of interest. In \refcite{Uzdin2015Sep} it is shown, that in certain
+system, are of interest. In \refcite{Uzdin2015Sep} it is shown that
-regimes quantum coherence can lead to superior power output. In the
+in certain regimes quantum coherence can lead to superior power
-same regime different types heat engines are equivalent. Both these
+output. In the same regime different types heat engines are
-effects have been observed experimentally in \refcite{Klatzow2019Mar}. It
+equivalent. Both these effects have been observed experimentally in
-would be interesting to see if the slight deviations from theory in
+\refcite{Klatzow2019Mar}. It would be interesting to see if the slight
-\cite{Klatzow2019Mar} could be explained using HOPS.
+deviations from theory in \cite{Klatzow2019Mar} could be explained
+using HOPS.
 
 The so called Anti-Zeno Effect occurring in systems under fast
 modulation has recently received some attention
@@ -86,8 +98,8 @@ modulation has recently received some attention
 due to the broadening of the resonance criterion which we have
 observed in
 \cref{sec:one_bath_cutoff,sec:modcoup_reso,sec:otto}. Being a
-consequence of the energy time uncertainty it is being argued, that
+consequence of the energy time uncertainty it is argued that the
-the origin of this advantage is truly quantum. The tools for the
+origin of this advantage is truly quantum. The tools for the
 exploitation of this effect and its verification are provided in this
 work. However, a strong coupling analysis has already been performed
 using HEOM in \refcite{Xu2022Mar}.
@@ -97,13 +109,17 @@ of finite ergotropy by letting energy flow through the working medium
 and then extracting this ergotropy in a separate stroke. This work
 could be verified and expanded to the non-Markovian regime.
 
-A useful improvement of the method would be the ability to snapshot
+A useful technical improvement of the method would be the ability to
-the total state of system and bath and then propagate this state with
+snapshot the total state of system and bath and then propagate this
-different modulation protocols. Also, exploring the thermofield method
+state with different modulation protocols. Also, exploring the
-for finite temperature to avoid the slow convergence of the flow may
+thermofield method for finite temperature to avoid slow convergence
-be worthwhile. However, at least for coupling that is not hermitian,
+would be helpful. However, at least for coupling that is not
-this would only trade computational effort for memory, as the number
+hermitian, this would likely only trade computational effort for
-of hierarchy states would increase.
+memory, as the number of hierarchy states would increase.
+
+The splitting up of the stochastic process to calculate, for example, the
+energy change of parts of the bath as discussed at the end of
+\cref{sec:general_obs} is also very interesting.
 
 Finally, in the spirit of~\cite{Esposito2015Dec} one could employ the
 HOPS to verify whether a given definition of internal energy that