Time-Rescaling of Dirac Dynamics: Shortcuts to Adiabaticity in Ion Traps and Weyl Semimetals

Roychowdhury, Agniva; Deffner, Sebastian

doi:10.3390/e23010081

Cited by 17 publications

(14 citation statements)

References 65 publications

(116 reference statements)

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“…To keep the system on target, we need to use one of the CD concentration protocols given by Eq. (43). For example, consider the one associated with tree 1, which means setting Φ 1 (t) = 0 at all t, so that from Eq.…”

Section: A Repressor-corepressor Modelmentioning

confidence: 99%

“…In recent years a great deal of theoretical and experimental work has been dedicated to mathematical tools and practical schemes to suppress nonequilibrium excitations in finite-time, nonequilibrium processes. To this end, a variety of techniques have been developed: the use of dynamical invariants [20], the inversion of scaling laws [21], the fast-forward technique [22][23][24][25][26][27][28][29], optimal protocols from optimal control theory [30][31][32][33], optimal driving from properties of quantum work statistics [34], "environment" assisted methods [35], using the properties of Lie algebras [36], and approximate methods such as linear response theory [37][38][39][40], fast quasistatic dynamics [41], or time-rescaling [42,43], to name just a few. See Refs.…”

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confidence: 99%

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Shortcuts in stochastic systems and control of biophysical processes

İlker¹,

Güngör²,

Kuznets-Speck³

et al. 2021

Preprint

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The biochemical reaction networks that regulate living systems are all stochastic to varying degrees. The resulting randomness affects biological outcomes at multiple scales, from the functional states of single proteins in a cell to the evolutionary trajectory of whole populations. Controlling how the distribution of these outcomes changes over time-via external interventions like timevarying concentrations of chemical species-is a complex challenge. In this work, we show how counterdiabatic (CD) driving, first developed to control quantum systems, provides a versatile tool for steering biological processes. We develop a practical graph-theoretic framework for CD driving in discrete-state continuous-time Markov networks. We illustrate the formalism with examples from gene regulation and chaperone-assisted protein folding, demonstrating the possibility that nature can exploit CD driving to accelerate response to sudden environmental changes. We generalize the method to continuum Fokker-Planck models, and apply it to study AFM single-molecule pulling experiments in regimes where the typical assumption of adiabaticity breaks down, as well as an evolutionary model with competing genetic variants subject to time-varying selective pressures. The AFM analysis shows how CD driving can eliminate non-equilibrium artifacts due to large force ramps in such experiments, allowing accurate estimation of biomolecular properties.

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Section: A Repressor-corepressor Modelmentioning

confidence: 99%

mentioning

confidence: 99%

Shortcuts in stochastic systems and control of biophysical processes

İlker¹,

Güngör²,

Kuznets-Speck³

et al. 2021

Preprint

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“…Recent years have seen an explosion of work on, for instance, counterdiabatic driving [12][13][14][15][16][17][18][19], the fast-forward method [20][21][22][23], time-rescaling [24,25], methods based on identifying the adiabatic invariant [26][27][28][29], and even generalizations to classical dynamics [30][31][32]. For comprehensive reviews of the various techniques, we refer to the recent literature [9][10][11].…”

Section: Introductionmentioning

confidence: 99%

Environment-Assisted Shortcuts to Adiabaticity

Touil

Deffner

2021

Entropy

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Envariance is a symmetry exhibited by correlated quantum systems. Inspired by this “quantum fact of life,” we propose a novel method for shortcuts to adiabaticity, which enables the system to evolve through the adiabatic manifold at all times, solely by controlling the environment. As the main results, we construct the unique form of the driving on the environment that enables such dynamics, for a family of composite states of arbitrary dimension. We compare the cost of this environment-assisted technique with that of counterdiabatic driving, and we illustrate our results for a two-qubit model.

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“…Fast-forward scaling theory (FFST) provides a systematic way for optimally designing control parameters which accelerate, decelerate, or reverse the dynamics of a quantum system [1,2]. The formalism of FFST has previously been extended with great effect to many-body [3] and discrete systems [4][5][6], systems of charged particles [7,8], tunneling dynamics [9,10], Dirac dynamics [11,12] and for the acceleration of adiabatic dynamics [13][14][15].…”

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confidence: 99%

“…The virtual trajectory satisfies f 2 (0) = f 2 (T F ) = 0 and β FF (t, f 2 ) ≃ 0 for all times throughout the system's evolution. ω FF m can then be calculated for any given virtual trajectory by substituting the corresponding f 2 (t) and f 1 (t) = 0 into equation (12). While both ω FF 1 and ω FF 2 may be time-dependent in general, only the difference between the angular frequencies, ∆ω FF = ω FF 1 − ω FF 2 , is of physical importance in this subspace.…”

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confidence: 99%

Acceleration and deceleration of quantum dynamics based on inter-trajectory travel with fast-forward scaling theory

Masuda¹,

Koenig²,

Steele³

2021

Preprint

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Quantum information processing requires fast manipulations of quantum systems in order to overcome dissipative effects. We propose a method to accelerate quantum dynamics and obtain a target state in a shorter time relative to unmodified dynamics, and apply the theory to a system consisting of two linearly coupled qubits. We extend the technique to accelerate quantum adiabatic evolution in order to rapidly generate a desired target state, thereby realizing a shortcut to adiabaticity. Further, we address experimental limitations to the rate of change of control parameters for quantum devices which often limit one's ability to generate a desired target state with high fidelity. We show that an initial state following decelerated dynamics can reach a target state while varying control parameters more slowly, enabling more experimentally feasible driving schemes.

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Time-Rescaling of Dirac Dynamics: Shortcuts to Adiabaticity in Ion Traps and Weyl Semimetals

Cited by 17 publications

References 65 publications

Shortcuts in stochastic systems and control of biophysical processes

Shortcuts in stochastic systems and control of biophysical processes

Environment-Assisted Shortcuts to Adiabaticity

Acceleration and deceleration of quantum dynamics based on inter-trajectory travel with fast-forward scaling theory

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