Expansion in Lorentzian functions of spectra of quantum autocorrelations

Barocchi, F.; Bafile, Ubaldo

doi:10.1103/physreve.87.062133

Cited by 22 publications

(10 citation statements)

References 23 publications

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“…We follow the theoretical approach recently presented [21][22][23], which states that the generalized Langevin equation for a normalized autocorrelation function C(t) of a classical many-body system has an exact solution written as an infinite sum of exponential functions (we need to consider positive t only, as C(t) is an even function), i.e.,…”

Section: Multiexponential Analysismentioning

confidence: 99%

“…In this paper, we pursue this goal by applying a substantially different method, not attempted so far. This is based on a recently presented general theory [21][22][23] that describes the time dependence of any correlation function of dynamical variables in many-particle Hamiltonian systems as an infinite series of (complex and/or real) exponentials. This theoretical approach, which does not resort to any a priori hypotheses on what dynamical regimes occur in the fluid, also applies naturally to the VAF and evidently opens an interesting issue with respect to the current schemes of interpretation.…”

Section: Introductionmentioning

confidence: 99%

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Time dependence of the velocity autocorrelation function of a fluid: An eigenmode analysis of dynamical processes

et al. 2015

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The velocity autocorrelation function (VAF), a key quantity in the atomic-scale dynamics of fluids, has been the first paradigmatic example of a long-time tail phenomenon, and much work has been devoted to detecting such long-lasting correlations and understanding their nature. There is, however, much more to the VAF than simply the evidence of this long-time dynamics. A unified description of the VAF from very short to long times, and of the way it changes with varying density, is still missing. Here we show that an approach based on very general principles makes such a study possible and opens the way to a detailed quantitative characterization of the dynamical processes involved at all time scales. From the analysis of molecular dynamics simulations for a slightly supercritical Lennard-Jones fluid at various densities, we are able to evidence the presence of distinct fast and slow decay channels for the velocity correlation on the time scale set by the collision rate. The density evolution of these decay processes is also highlighted. The method presented here is very general, and its application to the VAF can be considered as an important example.

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Section: Multiexponential Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Time dependence of the velocity autocorrelation function of a fluid: An eigenmode analysis of dynamical processes

et al. 2015

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“…As mentioned, among our aims is trying to understand what information S(Q, ω) actually brings when some rigor is applied in the spectral analysis of both experimental and simulation data, and which models are appropriate for silver with varying Q, looking for analogies with or differences from the case of gold and other metals. We will show, as in the case of other important functions for the dynamics of the liquid state, that a multiexponential analysis [41][42][43] of the intermediate scattering function F (Q, t ) [or, equivalently, a multi-Lorentzian analysis of the dynamic structure factor S(Q, ω)] is once again extremely accurate, ensuring the fulfillment of the first few sum rules along with excellent descriptions of the addressed function, and leading to a clear characterization of the main dynamical properties of the system. Thus the multimode representation is demonstrated here to account very well not only for single-particle (self-) quantities like the VAF, Z (t ), [23,[44][45][46], or the self-intermediate scattering function, F self (Q, t ) [24], but also for a collective function as F (Q, t ).…”

Section: Introductionmentioning

confidence: 94%

“…In recent years we have shown the effectiveness of the exponential series representation [41][42][43] in accounting for the behavior of time correlation functions of classical [23,24,44] and quantum [45,46] fluids. The power of the method lies not only in its providing excellent descriptions of the most relevant functions in liquid state physics, but also in its merit to facilitate the imposition of, at least a few, physical constraints, thus largely increasing the reliability of the results.…”

Section: Multimode Analysis Of the Aimd Simulationsmentioning

confidence: 99%

“…Of course, the same holds for their respective spectra, Z (ω), S self (Q, ω), and S(Q, ω). For the sake of clarity and understanding of what follows, it is useful to recall that the mentioned GH and VE models, both corresponding to a (physically constrained) finite sum of Lorentzians, comply with realistic applications of the general multimode representation [41][42][43]. Indeed, most used models of the second-order memory function [3,25] can be shown to lead to a spectrum given by a sum of an appropriate number of Lorentzian lines [25], although this universal property of the line shape has long remained unnoticed.…”

Section: Introductionmentioning

confidence: 99%

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Neutron Brillouin scattering and ab initio simulation study of the collective dynamics of liquid silver

et al. 2020

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We present a thorough investigation of the collective dynamics of liquid Ag combining neutron Brillouin scattering and ab initio molecular dynamics (AIMD) determinations of the dynamic structure factor S(Q, ω). The main scope of this work is not only to provide experimental results for some important dynamical properties of this liquid metal in the wave-vector range 4 < Q < 16 nm −1 , but also to inquire about the scarce detectability of shear waves apparently characterizing two elements of group IB, differently from other metals. In fact, as in the case of Au, a transverse-like dynamics is not deducible from the experimental S(Q, ω) of Ag, despite the indisputable quality of the neutron data collected on the BRISP spectrometer at the Institut Laue Langevin in Grenoble. However, the significant agreement between experiment and AIMD calculations allowed for an indepth study of the simulated S(Q, ω) in a Q range overlapping and extending the experimental one. A multimode analysis, already proven very successful in the description of various dynamical properties of fluid systems, is shown to be extremely effective also to analyze the intermediate scattering function predicted by AIMD at the various Q values, and eventually enables a reliable determination of both longitudinal and transverse branches in the dispersion curve of this liquid. Throughout the paper we highlight the importance of referring to theoretically well-founded models for S(Q, ω) and of imposing physical constraints in a fit-based analysis: These ensure that the used models obey fundamental properties of the dynamic structure factor.

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Searching for a second excitation in the inelastic neutron scattering spectrum of a liquid metal: a Bayesian analysis

Francesco

Bafile

Cunsolo

et al. 2021

Sci Rep

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When probed at nanometer and picosecond scales, the properties of a liquid present striking analogies with the ones of the corresponding solid, one of the most surprising is the ability of supporting shear wave propagation, as a rigid medium. Although this evidence is being reported by a growing number of terahertz scattering measurements, it remains an open question whether it is universal or rather typical of some liquids only. Furthermore, given its elusive signatures in the scattering signal, the detection of this effect appears as a typical case where an unintentional “bias of confirmation” can mislead experimentalists. We thus decided to use a Bayesian inference approach to achieve a probabilistically grounded and evidence-based lineshape modeling of the inelastic neutron scattering spectra from liquid silver, whose simulated density autocorrelations bear evidence of a shear mode propagation over very short distances. The result of our analysis indicates that the observation of any additional, non-longitudinal, acoustic modes in this simple system goes beyond the accuracy of the used scattering method.

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Expansion in Lorentzian functions of spectra of quantum autocorrelations

Cited by 22 publications

References 23 publications

Time dependence of the velocity autocorrelation function of a fluid: An eigenmode analysis of dynamical processes

Time dependence of the velocity autocorrelation function of a fluid: An eigenmode analysis of dynamical processes

Neutron Brillouin scattering and ab initio simulation study of the collective dynamics of liquid silver

Searching for a second excitation in the inelastic neutron scattering spectrum of a liquid metal: a Bayesian analysis

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