Recent Advances in the Calculation of Dynamical Correlation Functions

Florencio, J.; Bonfim, O. F. de Alcantara

doi:10.3389/fphy.2020.557277

Cited by 10 publications

(7 citation statements)

References 104 publications

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“…the set W(k) is solved in a self-consistent way as, for example, in the self-consistent mode-coupling theory [38][39][40][41][42], and no approximations of these time correlation functions by any model functions with free parameters are required [43]. This also becomes possible when the entire infinite set of sum rules (2) [or (3)] is known [31,36,[44][45][46]. In the case we consider here, the theoretical procedure is nonperturbative, which is especially appropriate for the description of the systems we are dealing with here.…”

Section: Theoretical Formalismmentioning

confidence: 99%

Self-consistent relaxation theory of collective ion dynamics in Yukawa one-component plasmas under intermediate screening regimes

2022

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The self-consistent relaxation theory is employed to describe the collective ion dynamics in strongly coupled Yukawa classical one-component plasmas. The theory is applied to equilibrium states corresponding to intermediate screening regimes with appropriate values of the structure and coupling parameters. The information about the structure (the radial distribution function and the static structure factor) and the thermodynamics of the system are sufficient to describe collective dynamics over a wide range of spatial scales, namely, from the extended hydrodynamic to the microscopic dynamics scale. The main experimentally measurable characteristics of the equilibrium collective dynamics of ions-the spectrum of the dynamic structure factor, the dispersion parameters, the speed of sound, and the sound attenuation-are determined within the framework of the theory without using any adjustable parameters. The results demonstrate agreement with molecular dynamics simulations. Thus a direct realization is presented of the key idea of statistical mechanics: for the theoretical description of the collective particle dynamics in equilibrium fluids it is sufficient to know the interparticle interaction potential and the structural characteristics. Comparison with alternative or complementary theoretical approaches is provided.

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Section: Theoretical Formalismmentioning

confidence: 99%

Self-consistent relaxation theory of collective ion dynamics in Yukawa one-component plasmas under intermediate screening regimes

2022

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“…的最有效的方法之一 [34][35][36] 。该方法最初用来求解广义 Langevin 方程，之后被逐渐用于研究自旋系统的动力学，例如多粒子系统、电子气、谐振子链、简单流体等系统 [37] 。下面简述递推关系方法。…”

Section: 模型及方法unclassified

Effects of trimodal random magnetic field on spin dynamics of quantum Ising chain

Yuan¹

2023

Acta Phys. Sin.

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It is of fundamental importance to know the dynamics of quantum spin systems immersed in external magnetic fields. In this work, the dynamical properties of one-dimensional quantum Ising model with trimodal random transverse and longitudinal magnetic fields are investigated by the recursion method. The spin correlation function \[C\left( t \right) = \overline {\left\langle {\sigma _j^x\left( t \right)\sigma _j^x\left( 0 \right)} \right\rangle } \] and the corresponding spectral density \[\emptyset \left( \omega \right) = \int_{ -\infty }^{ + \infty } {dt{e^{iwt}}} C\left( t \right)\] are calculated. The model Hamiltonian can be written as \[H = -\frac{1}{2}J\sum\limits_i^N {\sigma _i^x\sigma _{i + 1}^x} -\frac{1}{2}\sum\limits_i^N {{B_{iz}}\sigma _i^z} -\frac{1}{2}\sum\limits_i^N {{B_{ix}}\sigma _i^x} \]. Where <img border=0 > are Pauli matrices at site i, J is the nearest-neighbor exchange coupling. Biz and Bix denote the transverse and longitudinal magnetic field, respectively. They satisfy the following trimodal distribution, \[\rho = \left( {{B_{iz}}} \right) = p\delta \left( {{B_{iz}} -{B_p}} \right) + q\delta \left( {{B_{iz}} -{B_p}} \right) + r\delta \left( {{B_{iz}}} \right)\] and \[\rho = \left( {{B_{i{\rm{x}}}}} \right) = p\delta \left( {{B_{ix}} -{B_p}} \right) + q\delta \left( {{B_{ix}} -{B_p}} \right) + r\delta \left( {{B_{ix}}} \right)\].The value interval of the coefficients p, q and r is [0,1], and the coefficients satisfy the constraint condition p+q+r=1. For the case of trimodal random Biz (consider Biz≡0 for simplicity), the exchange couplings are supposed to be J≡0 to fix the energy scale. The reference values are set Bp=0.5<J and Bq=1.5>J. The coefficient r can be considered as the proportion of non-magnetic impurities. When r=0, the trimodal distribution degrades into the bimodal distribution. The dynamics of the system exhibits a crossover from the central-peak behavior to the collective-mode behavior as qincreases, which consistent with the previous work. As r increases, the crossover between different dynamical behaviors changes obviously (e.g., the crossover from central-peak to double-peak when r=0.2), and the presence of non-magnetic impurities favors low-frequency response. Due to the competition between the non-magnetic impurities and transverse magnetic field, the system tends to exhibit multi-peak behavior in most cases, e.g., r=0.4, 0.6 or 0.8. However, the multi-peak behavior disappear when r→1. That is because the system's response to the transverse field is limited when the proportion of non-magnetic impurities are large enough. Interestingly, when the parameters satisfy qBq=pBp, the central-peak behavior can be maintained. What makes sense is that the conclusion is universal. For the case of trimodal random Bix, the coefficient r is no longer represent the proportion of non-magnetic impurities when Bix and Biz (Biz≡1) coexist here. In the case of weak exchange coupling, the effects of longitudinal magnetic field on spin dynamics are obvious, so J≡0.5 is set here. The reference values are set Bp=0.5<Biz and Bq=0.5<Biz. When ris small (r=0, 0.2 or 0.4), the system undergoes a crossover from the collective-mode behavior to the double-peak behavior as q increases. However, the low-frequency responses gradually disappear, while the high-frequency responses are maintained as r increases. Take the case of r=0.8 for example, the system only behaves a collective-mode behavior. The results indicate that increasing r is no longer conducive to the low-frequency response, which is contrary to the case of trimodal random Bix. The r branch only regulates the intensity of the trimodal random Bix. Our results indicate that using trimodal random magnetic field to manipulate the spin dynamics of the Ising system may be a new try.

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“…These are required for calculating intensities in various areas of spectroscopy [ 6–11 ] and for response functions in scattering experiments and condensed matter. [ 12–15 ] Additionally, as vector‐matrix‐vector products

\vec{a}^t {\bf A} \vec{b}

(or

\vec{a}^t {\bf A} \vec{a}

) are often relevant to classical linear algebra problems, transition probability subroutines may be useful in quantum linear algebra, [ 16–21 ] including for classical partial differential equations, [ 22–24 ] finance, [ 25,26 ] and quantum machine learning. [ 27–29 ]…”

Section: Introductionmentioning

confidence: 99%

Improved Resource‐Tunable Near‐Term Quantum Algorithms for Transition Probabilities, with Applications in Physics and Variational Quantum Linear Algebra

Sawaya

Huh

2023

Adv Quantum Tech

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Transition amplitudes and transition probabilities are relevant to many areas of physics simulation, including the calculation of response properties and correlation functions. These quantities can also be related to solving linear systems of equations. This study presents three related algorithms for calculating transition probabilities. First, a previously published short‐depth algorithm is extended, allowing for the two input states to be non‐orthogonal. Building on this first procedure, a higher‐depth algorithm based on Trotterization and Richardson extrapolation is derived that requires fewer circuit evaluations. Third, a tunable algorithm that allows for trading off circuit depth and measurement complexity is introduced, yielding an algorithm that can be tailored to specific hardware characteristics. Finally, proof‐of‐principle numerics are presented for models in physics and chemistry and for a subroutine in variational quantum linear solving (VQLS). The primary benefits of these approaches are that a) arbitrary non‐orthogonal states may now be used with small increases in quantum resources, b) they (like another recently proposed method) entirely avoid subroutines such as the Hadamard test that may require three‐qubit gates to be decomposed, and c) in some cases fewer quantum circuit evaluations are required as compared to the previous state‐of‐the‐art in NISQ algorithms for transition probabilities.

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Recent Advances in the Calculation of Dynamical Correlation Functions

Cited by 10 publications

References 104 publications

Self-consistent relaxation theory of collective ion dynamics in Yukawa one-component plasmas under intermediate screening regimes

Self-consistent relaxation theory of collective ion dynamics in Yukawa one-component plasmas under intermediate screening regimes

Effects of trimodal random magnetic field on spin dynamics of quantum Ising chain

Improved Resource‐Tunable Near‐Term Quantum Algorithms for Transition Probabilities, with Applications in Physics and Variational Quantum Linear Algebra

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