Your search keyword '"Arun K. Sagotra"' showing total 7 results

1. Room-temperature mechanocaloric effects in lithium-based superionic materials

Author

Arun K. Sagotra, Dewei Chu, and Claudio Cazorla

Subjects

Science

Abstract

Large mechanocaloric effects are disclosed in lithium-ion superionic conductors at room temperature. These occur in the absence of any structural phase transition, which is beneficial from a practical point of view, and are related to stress-induced variations in the ionic conductivity.

Published

2018

2. Mechanocaloric effects in superionic thin films from atomistic simulations

Author

Arun K. Sagotra, Daniel Errandonea, and Claudio Cazorla

Subjects

Science

Abstract

Mechanocaloric effects are a promising path towards solid-state cooling. Here the authors perform atomistic simulations on the well-known fast-ion conductor silver iodide and computationally predict a sizeable mechanocaloric effect under biaxial strain.

Published

2017

3. High-Pressure Phase Diagram and Superionicity of Alkaline Earth Metal Difluorides

Author

Claudio Cazorla, Arun K. Sagotra, Daniel Errandonea, and Meredith C. King

Subjects

Alkaline earth metal, Materials science, Ionic radius, Difluoride, Thermodynamics, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Fluorite, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, General Energy, Phase (matter), High pressure, Orthorhombic crystal system, Physical and Theoretical Chemistry, 0210 nano-technology, Phase diagram

Abstract

We study the high-pressure–high-temperature phase diagram and superionicity of alkaline earth metal (AEM) difluorides (AF2, A = Ca, Sr, Ba) with first-principles simulation methods. We find that the superionic behavior of SrF2 and BaF2 at high pressures differ appreciably from that previously reported for CaF2 [Phys. Rev. Lett. 2014, 113, 235902]. Specifically, the critical superionic temperature of SrF2 and BaF2 in the low-pressure cubic fluorite phase is not reduced by effect of compression, and the corresponding high-pressure orthorhombic contunnite phases become superionic at elevated temperatures. We get valuable microscopic insights into the superionic features of AEM difluorides in both the cubic fluorite and orthorhombic contunnite phases by means of ab initio molecular dynamics simulations. We rationalize our findings on the structural and superionic behavior of AF2 compounds in terms of simple ionic radii arguments and generalize them across the whole series of AEM dihalides (AB2, A = Mg, Ca, Sr...

Published

2018

4. Stress-Mediated Enhancement of Ionic Conductivity in Fast-Ion Conductors

Author

Claudio Cazorla and Arun K. Sagotra

Subjects

Phase transition, Materials science, Condensed matter physics, Biaxial tensile test, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Crystallographic defect, 0104 chemical sciences, Ion, Stress (mechanics), Antiperovskite, Computational chemistry, Fast ion conductor, Ionic conductivity, General Materials Science, 0210 nano-technology

Abstract

Finding solid-state electrolytes with high ionic conductivity near room temperature is an important prerequisite for developing all-solid-state electrochemical batteries. Here, we investigate the effects of point defects (vacancies) and biaxial stress on the superionic properties of fast-ion conductors (represented by the archetypal compounds CaF2, Li-rich antiperovskite Li3OCl, and AgI) by using classical molecular dynamics and first-principles simulation methods. We find that the critical superionic temperature of all analyzed families of fast-ion conductors can be reduced by several hundreds of degrees through the application of relatively small biaxial stresses (|σ| ≤ 1 GPa) on slightly defective samples (cv ∼ 1%). In AgI, we show that superionicity can be triggered at room temperature by applying a moderate compressive biaxial stress of ∼1 GPa. In this case, we reveal the existence of a σ-induced order–disorder phase transition involving sizable displacements of all the ions with respect to the equil...

Published

2017

5. Copper Diffusion Rates and Hopping Pathways in Superionic Cu 2Se: Implications for Thermoelectricity

Author

Yulou Ouyang, Sheik Md. Kazi Nazrul Islam, Claudio Cazorla, Richard A. Mole, Robert A. Robinson, David L Cortie, Jie Chen, Dehong Yu, Arun K. Sagotra, Xiaolin Wang, Michael B. Cortie, Prince Mayank, and Meng Li

Subjects

Molecular dynamics, Tetragonal crystal system, Materials science, Thermal conductivity, Condensed matter physics, Phonon, Anharmonicity, Neutron scattering, Diffusion (business), Order of magnitude

Abstract

The ultra-low thermal conductivity of Cu2Se is well established, but there is so far no consensus on the underlying mechanism. One proposal is that the fast-ionic diffusion of copper suppresses the acoustic phonons. The diffusion coefficients reported previously, however, differ by two orders of magnitude between the various studies and it remains unclear whether the diffusion is fast enough to impact the heat-bearing phonons. Here, a two-fold approach is used to accurately re-determine the diffusion rates. Ab-initio molecular dynamics simulations, incorporating landmark analysis techniques, were closely compared with experimental quasielastic/inelastic neutron spectroscopy. Reasonable agreement was found between these approaches, consistent with the experimental coefficient of 3.1 ± 1.3 10-5 cm2.s-1 and an activation barrier of 140 ± 60 meV. The hopping mechanism includes short 2 A hops between tetragonal and interstitial octahedral sites. This process forms dynamic Frenkel defects, however, there is no indication of additional broadening in the density-of-states indicating the intrinsic anharmonic interactions dictate the phonon lifetimes.

Published

2020

6. Influence of lattice dynamics on lithium-ion conductivity: A first-principles study

Author

Arun K. Sagotra, Claudio Cazorla, and Dewei Chu

Subjects

Condensed Matter - Materials Science, Materials science, Physics and Astronomy (miscellaneous), Condensed matter physics, Phonon, Ionic bonding, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Omega, Ion, Lattice (order), 0103 physical sciences, Fast ion conductor, Ionic conductivity, General Materials Science, Density functional theory, 010306 general physics, 0210 nano-technology

Abstract

In the context of novel solid electrolytes for solid-state batteries, first-principles calculations are becoming increasingly more popular due to their ability to reproduce and predict accurately the energy, structural, and dynamical properties of fast-ion conductors. To accelerate the discovery of new superionic conductors is convenient to establish meaningful relations between ionic transport and simple materials descriptors. Recently, several experimental studies on lithium fast-ion conductors suggested a correlation between lattice softness and enhanced ionic conductivity due to a concomitant decrease in the activation energy for ion migration ${E}_{a}$. In this article, we employ extensive ab initio molecular dynamics simulations based on density functional theory to substantiate the links between ionic transport and lattice dynamics in a number of structurally and chemically distinct lithium superionic conductors. Our first-principles results show no evidence for a direct and general correlation between ${E}_{a}$, or the hopping attempt frequency ${\ensuremath{\nu}}_{0}$, and lattice softness. However, we find that, in agreement with recent observations, the pre-exponential factor of lithium diffusivity ${D}_{0}$, which is proportional to ${\ensuremath{\nu}}_{0}$, follows the Meyer-Neldel rule $\ensuremath{\propto}exp\left({E}_{a}/\ensuremath{\langle}\ensuremath{\omega}\ensuremath{\rangle}\right)$ where $\ensuremath{\langle}\ensuremath{\omega}\ensuremath{\rangle}$ represents an average phonon frequency. Hence, lattice softness can be identified with enhanced lithium diffusivity, but only within families of superionic materials presenting very similar migration activation energies due to an increase in ${D}_{0}$ (or, equivalently, in ${\ensuremath{\nu}}_{0}$). On the technical side, we show that neglecting temperature effects in the estimation of ${E}_{a}$ may lead to huge inaccuracies of $\ensuremath{\sim}10%$. The limitations of zero-temperature harmonic approaches in describing the vibrational properties of lithium-ion conductors are also illustrated.

Published

2018

7. Mechanocaloric effects in superionic thin films from atomistic simulations

Author

Daniel Errandonea, Arun K. Sagotra, and Claudio Cazorla

Subjects

Materials science, Science, General Physics and Astronomy, Ionic bonding, 02 engineering and technology, Cooling capacity, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, chemistry.chemical_compound, 0103 physical sciences, Thin film, lcsh:Science, 010306 general physics, Adiabatic process, Electrical conductor, Multidisciplinary, Silver iodide, Refrigeration, Biaxial tensile test, General Chemistry, 021001 nanoscience & nanotechnology, chemistry, Chemical physics, lcsh:Q, 0210 nano-technology

Abstract

Solid-state cooling is an energy-efficient and scalable refrigeration technology that exploits the adiabatic variation of a crystalline order parameter under an external field (electric, magnetic, or mechanic). The mechanocaloric effect bears one of the greatest cooling potentials in terms of energy efficiency owing to its large available latent heat. Here we show that giant mechanocaloric effects occur in thin films of well-known families of fast-ion conductors, namely Li-rich (Li3OCl) and type-I (AgI), an abundant class of materials that routinely are employed in electrochemistry cells. Our simulations reveal that at room temperature AgI undergoes an adiabatic temperature shift of 38 K under a biaxial stress of 1 GPa. Likewise, Li3OCl displays a cooling capacity of 9 K under similar mechanical conditions although at a considerably higher temperature. We also show that ionic vacancies have a detrimental effect on the cooling performance of superionic thin films. Our findings should motivate experimental mechanocaloric searches in a wide variety of already known superionic materials., Mechanocaloric effects are a promising path towards solid-state cooling. Here the authors perform atomistic simulations on the well-known fast-ion conductor silver iodide and computationally predict a sizeable mechanocaloric effect under biaxial strain.

Published

2017