Your search keyword '"Seridonio, Antonio C."' showing total 11 results

1. Unveiling the interdisciplinary character of negative pressure

Author

Barbosa, Francisco F., Squillante, Lucas, Ricco, Luciano, Lagos-Monaco, Roberto E., Seridonio, Antonio C., and de Souza, Mariano

Subjects

Condensed Matter - Statistical Mechanics

Abstract

We explore the concept of negative pressure and its relevance in a variety of physical contexts: the expansion of the universe, mixture theory, cavitation, and the capillary effect in plants. Using thermodynamic arguments, we discuss the intricate connection between negative pressure and negative thermal expansion. We highlight the fact that metastable states and competing phases are often associated with the emergence of negative pressure. We also propose a new link between the effective Gr\"uneisen parameter and nucleation theory., Comment: 15 pages, 5 figs, comments are welcome

Published

2024

2. Higgs-like stiffness and fractons on the verge of phase transitions

Author

Squillante, Lucas, Seridonio, Antonio C., Lagos-Monaco, Roberto E., and de Souza, Mariano

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

In condensed matter Physics, massive longitudinal Higgs modes emerge from fluctuations of the order parameter. A few years ago, the Higgs mode was \emph{caught} experimentally in the vicinity of an insulator-to-superconductor quantum phase transition [Nat. Phys. $\textbf{11}$, 188 (2015)]. Here, we propose, in analogy to the Higgs mode, the concept of Higgs-like stiffness (HLS), which emerges close to both classical and quantum phase transitions as a universal manifestation of matter. We build up a Landau free energy for the dielectric response function to demonstrate that \emph{any} complex physical quantity can be used to infer the presence of the HLS. Our analysis is corroborated by experimental results of the quasi-static dielectric constant for the (TMTTF)$_2$SbF$_6$ Fabre salt. Yet, we discuss the appearance of fractons in connection with the locking of particular molecular rotational degrees of freedom., Comment: 8 pages, 2 figures. Comments are welcome

Published

2024

3. Cellular Griffiths-like phase

Author

Squillante, Lucas, Mello, Isys F., Ricco, Luciano S., Minicucci, Marcos F., Ukpong, Aniekan Magnus, Seridonio, Antonio C., Lagos-Monaco, Roberto E., and de Souza, Mariano

Subjects

Physics - Biological Physics, Condensed Matter - Statistical Mechanics

Abstract

Protein compartmentalization in the frame of a liquid-liquid phase separation is a key mechanism to optimize spatiotemporal control of biological systems. Such a compartmentalization process reduces the intrinsic noise in protein concentration due to stochasticity in gene expression. Employing Flory-Huggins solution theory, Avramov/Casalini's model, and the Gr\"uneisen parameter, we unprecedentedly propose a cellular Griffiths-like phase (CGLP), which can impact its functionality and self-organization. The here-proposed CGLP is key ranging from the understanding of primary organisms' evolution to the treatment of diseases. Our findings pave the way for an alternative Biophysics approach to investigate coacervation processes., Comment: 13 pages, 2 figures, suppl. material upon request

Published

2024

4. Exploring the expansion of the universe using the Gr\'uneisen parameter

Author

Squillante, Lucas, Gomes, Gabriel O., Mello, Isys F., Nogueira, Guilherme, Seridonio, Antonio C., Lagos-Monaco, Roberto E., and de Souza, Mariano

Subjects

General Relativity and Quantum Cosmology, Condensed Matter - Statistical Mechanics

Abstract

For a perfect fluid, pressure $p$ and energy density $\rho$ are related via the equation of state (EOS) $\omega = p/\rho$, where $\omega$ is the EOS parameter, being its interpretation usually constrained to a numerical value for each universe era. Here, based on the Mie-Gr\"uneisen EOS, we show that $\omega$ is recognized as the effective Gr\"uneisen parameter $\Gamma_{eff}$, whose singular contribution, the so-called Gr\"uneisen ratio $\Gamma$, quantifies the barocaloric effect. Our analysis suggests that the negative $p$ associated with dark-energy implies a metastable state and that in the dark-energy-dominated era $\omega$ is time-dependent, which reinforces recent proposals of a time-dependent cosmological constant. Furthermore, we demonstrate that $\Gamma_{eff}$ is embodied in the energy-momentum stress tensor in the Einstein field equations, enabling us to analyse, in the frame of an imperfect fluid picture, anisotropic effects of the universe expansion. We propose that upon going from decelerated- to accelerated-expansion, a phase transition-like behavior can be inferred. Yet, our analysis in terms of entropy, $\Gamma$, and a by us adapted version of Avramov/Casalini's model to Cosmology unveil hidden aspects related to the expansion of the universe. Our findings pave the way to interpret cosmological phenomena in connection with concepts of condensed matter Physics via $\Gamma_{eff}$., Comment: 11 pages, 1 figure, comments are welcome

Published

2024

5. Gr\'uneisen parameter as an entanglement compass and the breakdown of the Hellmann-Feynman theorem

Author

Squillante, Lucas, Ricco, Luciano S., Ukpong, Aniekan Magnus, Lagos-Monaco, Roberto E., Seridonio, Antonio C., and de Souza, Mariano

Subjects

Quantum Physics, Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons

Abstract

The Gr\"uneisen ratio $\Gamma$, i.e., the singular part of the ratio of thermal expansion to the specific heat, has been broadly employed to explore both finite-$T$ and quantum critical points (QCPs). For a genuine quantum phase transition (QPT), thermal fluctuations are absent and thus the thermodynamic $\Gamma$ cannot be employed. We propose a quantum analogue to $\Gamma$ that computes entanglement as a function of a tuning parameter $\lambda$ and show that QPTs take place only for systems in which the ground-state energy depends on $\lambda$ non-linearly. Furthermore, we demonstrate the breakdown of the Hellmann-Feynman theorem in the thermodynamic limit at any QCP. We showcase our approach using the quantum 1D Ising model with transverse field and Kane's quantum computer. The slowing down of the dynamics and thus the "creation of mass" close to any QCP/QPT is also discussed., Comment: 5 pages, 3 figures, comments are wellcome!

Published

2023

6. Epidemics, the Ising-model and percolation theory: a comprehensive review focussed on Covid-19

Author

Mello, Isys F., Squillante, Lucas, Gomes, Gabriel O., Seridonio, Antonio C., and de Souza, M.

Subjects

Quantitative Biology - Populations and Evolution, Condensed Matter - Statistical Mechanics, Physics - Physics and Society

Abstract

We revisit well-established concepts of epidemiology, the Ising-model, and percolation theory. Also, we employ a spin $S$ = 1/2 Ising-like model and a (logistic) Fermi-Dirac-like function to describe the spread of Covid-19. Our analysis reinforces well-established literature results, namely: \emph{i}) that the epidemic curves can be described by a Gaussian-type function; \emph{ii}) that the temporal evolution of the accumulative number of infections and fatalities follow a logistic function, which has some resemblance with a distorted Fermi-Dirac-like function; \emph{iii}) the key role played by the quarantine to block the spread of Covid-19 in terms of an \emph{interacting} parameter, which emulates the contact between infected and non-infected people. Furthermore, in the frame of elementary percolation theory, we show that: \emph{i}) the percolation probability can be associated with the probability of a person being infected with Covid-19; \emph{ii}) the concepts of blocked and non-blocked connections can be associated, respectively, with a person respecting or not the social distancing, impacting thus in the probability of an infected person to infect other people. Increasing the number of infected people leads to an increase in the number of net connections, giving rise thus to a higher probability of new infections (percolation). We demonstrate the importance of social distancing in preventing the spread of Covid-19 in a pedagogical way. Given the impossibility of making a precise forecast of the disease spread, we highlight the importance of taking into account additional factors, such as climate changes and urbanization, in the mathematical description of epidemics. Yet, we make a connection between the standard mathematical models employed in epidemics and well-established concepts in condensed matter Physics, such as the Fermi gas and the Landau Fermi-liquid picture., Comment: 33 pages, 10 figures, 2 tables (new sections and new figs. were added, review paper with new aspects of epidemics)

Published

2020

7. Griffiths-like phase close to the Mott transition

Author

Mello, Isys F., Squillante, Lucas, Gomes, Gabriel O., Seridonio, Antonio C., and de Souza, M.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter

Abstract

We explore the coexistence region in the vicinity of the Mott critical end point employing a compressible cell spin-$1/2$ Ising-like model. We analyze the case for the spin-liquid candidate $\kappa$-(BEDT-TTF)$_2$Cu$_2$(CN)$_3$, where close to the Mott critical end point metallic puddles coexist with an insulating ferroelectric phase. Our results are fourfold: $i$) a universal divergent-like behavior of the Gr\"uneisen parameter upon crossing the first-order transition line; $ii$) based on scaling arguments, we show that within the coexistence region, for $any$ system close to the critical point, the relaxation time is entropy-dependent; $iii$) we propose the electric Gr\"uneisen parameter $\Gamma_E$, which quantifies the electrocaloric effect; $iv$) we identify the metallic/insulating coexistence region as an electronic Griffiths-like phase. Our findings suggest that $\Gamma_E$ governs the dielectric response close to the critical point and that an electronic Griffiths-like phase emerges in the coexistence region., Comment: 7 pages, 3 figures (suppl. material upon request). To appear in Journal of Applied Physics

Published

2020

8. Exploring the expansion of the universe using the Grüneisen parameter

Author

Squillante, Lucas, primary, Gomes, Gabriel O., additional, Mello, Isys F., additional, Nogueira, Guilherme, additional, Seridonio, Antonio C., additional, Lagos-Monaco, Roberto E., additional, and Souza, Mariano de, additional

Published

2024

9. Elastocaloric-effect-induced adiabatic magnetization in paramagnetic salts due to the mutual interactions

Author

Squillante, Lucas, Mello, Isys F., Seridonio, Antonio C., and de Souza, Mariano

Published

2021

10. Universal zero-bias conductance for the single electron transistor. II: Comparison with numerical results

Author

Yoshida, Makoto, Seridonio, Antonio C., and Oliveira, Luiz N.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

A numerical renormalization-group survey of the zero-bias electrical conductance through a quantum dot embedded in the conduction path of a nanodevice is reported. The results are examined in the light of a recently derived linear mapping between the temperature-dependent conductance and the universal function describing the conductance for the symmetric Anderson model. A gate potential applied to the conduction electrons is known to change markedly the transport properties of a quantum dot side-coupled to the conduction path; in the embedded geometry here discussed, a similar potential is shown to affect only quantitatively the temperature dependence of the conductance. As expected, in the Kondo regime the numerical results are in excellent agreement with the mapped conductances. In the mixed-valence regime, the mapping describes accurately the low-temperature tail of the conductance. The mapping is shown to provide a unified view of conduction in the single-electron transistor., Comment: Sequel to arXiv:0906.4063. 9 pages with 8 figures

Published

2009

11. Gr\'uneisen parameter as an entanglement compass

Author

Squillante, Lucas, Ricco, Luciano S., Ukpong, Aniekan Magnus, Lagos-Monaco, Roberto E., Seridonio, Antonio C., and de Souza, Mariano

Subjects

Quantum Physics, Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Statistical Mechanics

Abstract

The Gr\"uneisen ratio $\Gamma$, i.e., the singular part of the ratio of thermal expansion to the specific heat, has been broadly employed to explore both finite-$T$ and quantum critical points (QCPs). For a genuine quantum phase transition (QPT), thermal fluctuations are absent and thus the thermodynamic $\Gamma$ cannot be employed. We propose a quantum analogue to $\Gamma$ that computes entanglement as a function of a tuning parameter and show that QPTs take place only for quadratic non-diagonal Hamiltonians. We showcase our approach using the quantum 1D Ising model with transverse field and Kane's quantum computer. The slowing down of the dynamics and thus the ``creation of mass'' close to any QCP/QPT is also discussed., Comment: 5 pages, 3 figures, comments are wellcome!

Published

2023