Hesam Arabzadeh scite author profile

All-solid-state rechargeable sodium (Na)-ion batteries are promising for inexpensive and high-energy-density large-scale energy storage. In this contribution, new Na solid electrolytes, Na 3−y PS 4−x Cl x , are synthesized with a strategic approach, which allows maximum substitution of Cl for S (x = 0.2) without significant compromise of structural integrity or Na deficiency. A maximum conductivity of 1.96 mS cm −1 at 25 °C is achieved for Na 3.0 PS 3.8 Cl 0.2 , which is two orders of magnitude higher compared with that of tetragonal Na 3 PS 4 (t-Na 3 PS 4 ). The activation energy (E a ) is determined to be 0.19 eV. Ab initio molecular dynamics simulations shed light on the merit of maximizing Cldoping while maintaining low Na deficiency in enhanced Na-ion conduction. Solid-state nuclear magnetic resonance (NMR) characterizations confirm the successful substitution of Cl for S and the resulting change of P oxidation state from 5+ to 4+, which is also verified by spin moment analysis. Ion transport pathways are determined with a tracer-exchange NMR method. The functional detects that promote Na -ion transport are maximized for further improvement in ionic conductivity. Full-cell performance is demonstrated using Na/Na 3.0 PS 3.8 Cl 0.2 /Na 3 V 2 (PO 4 ) 3 with a reversible capacity of ≈100 mAh g −1 at room temperature.

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Molecular Dynamics and Free Energy Calculations of Dicyclohexano-18-crown-6 Diastereoisomers with Sm²⁺, Eu²⁺, Dy²⁺, Yb²⁺, Cf²⁺, and Three Halide Salts in Tetrahydrofuran and Acetonitrile Using the AMOEBA Force Field

Arabzadeh

Walker

Sperling

et al. 2022

J. Phys. Chem. B

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With the continual development of lanthanides (Ln) in current technological devices, an efficient separation process is needed that can recover greater amounts of these rare elements. Dicyclohexano-18-crown-6 (DCH18C6) is a crown ether that may be a promising candidate for Ln separation, but additional research is required. As such, molecular dynamics (MD) simulations have been performed on four divalent lanthanide halide salts (Sm2+, Eu2+, Dy2+, and Yb2+) and one divalent actinide halide salt (Cf2+) bound to three diastereoisomers of DCH18C6. Dy2+, Yb2+, Cf2+, DCH18C6, and tetrahydrofuran (THF) solvent were parameterized for the AMOEBA polarizable force field for the first time, whereas existing parameters for Sm2+ and Eu2+ were utilized from our previous efforts. A coordination number (CN) of six for Ln2+/An2+–O solvated in THF indicated that the cations interacted almost entirely with the oxygens of the polyether ring. A CN of one for Ln2+/An2+-N solvated in acetonitrile for systems containing iodide suggested that the N atom of acetonitrile was competitive with I– for cation interactions. Fluctuation between five and six CNs for Dy2+ and Yb2+ suggested that although the cations remained in the polyether ring, the size of the ring may not be an ideal fit as these cations possess comparatively smaller ionic radii. Gibbs binding free energies of Sm2+ in all DCH18C6 diastereoisomers solvated in THF were calculated. The binding free energy of the cis-syn-cis diastereoisomer was the most favorable, followed by cis-anti-cis, and then trans-anti-trans. Finally, two major types of conformation were observed for each diastereoisomer that were related to the electrostatic interactions and charge density of the cations.

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Hydration of divalent lanthanides, Sm²⁺ and Eu²⁺: A molecular dynamics study with polarizable AMOEBA force field

et al. 2022

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The chemistry of divalent lanthanides, Ln2+, is a growing sub‐field of heavy element chemistry owing to new synthetic approaches. However, some theoretical aspects of these unusual cations are currently underdeveloped, especially as they relate to their dynamic properties in solution. In this work, we address the hydration of two of the classical Ln2+ cations, Sm2+ and Eu2+, using atomic multipole optimized energetic for biomolecular applications (AMOEBA) force fields. These cations have not been parameterized to date with AMOEBA, and few studies are available because of their instability with respect to oxidation in aqueous media. Coordination numbers (CN's) of 8.2 and 8.1 respectively for Sm2+ and Eu2+, and 8.8 for both Sm3+ and Eu3+ have been obtained and are in good agreement with the few available AIMD and X‐ray absorption fine structures studies. The decreased CN of Ln2+ compared with Ln3+ arises from progressive water exchange events that indicates the gradual stabilization of 8‐coordinate structures with respect to 9‐coordinate geometries. Moreover, the effects of the chloride counter anions on the coordination of Ln2+ cations have been studied at different chloride concentrations in this work. Lastly, water exchange times of Ln2+ cations have been calculated to provide a comprehensive understanding of the behavior of Eu2+ and Sm2+ in aqueous chloride media.

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Application of a Novel Ultrasonic Technology to Improve Oil Recovery with an Environmental Viewpoint

Arabzadeh¹,

Amani²

2017

J Pet Environ Biotechnol

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It is proven by recent studies that sonication has a positive influence over the oil flow within the porous media. Accordingly, the researchers in this paper evaluated the influence of sonication over the oil recovery by means of free fall gravity drainage. Furthermore, the influence of sonication on the oil permeability was assessed in three samples that had different bead size in average. By use of the Hagroot backward method and Matlab simulation, the optimal petrophysical situation for sonication was determined. The authors concluded that sonication positively affects the oil recovery for the non-asphaltenic samples, while it has a reverse effect on the asphaltenic samples because of increasing the viscosity in long-term. Furthermore, it was witnessed that gravity drainage was heightened by increase of beads' size in the non-asphaltenic sample. Accordingly, this mechanism can be useful in oil recovery by means of gravity drainage, specifically in fracture reservoirs.

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Free Energy Calculations and Conformational Analysis of Dibenzo-30-crown-10 with Sm²⁺, Eu²⁺, and Three Halide Salts in THF Using the AMOEBA Force Field

et al. 2023

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Crown ether complexes have been tailored for use in industrial separations of lanthanides (Ln) as a part of rare earth mining and refining. Dibenzo-30-crown-10 (DB30C10) is one of the most efficient complexants for the separation of rare earth mixtures based on the cation size. To understand the origin of this complexation, molecular dynamics (MD) simulations of DB30C10 have been performed using different combinations of divalent Sm and Eu and three halide salts Cl–, Br–, and I– in tetrahydrofuran (THF) solvent. DB30C10 was parameterized here for the polarizable atomic multipole optimized energetics for biomolecular simulation (AMOEBA) force field, and the existing parameters of THF, Sm2+, and Eu2+ were employed from our previous efforts. The large conformational fluctuations present in the DB30C10 systems were found to be dependent both on the identity of the lanthanide and halide complexes. For Cl– and Br– systems, there were no observed conformational changes at 200 ns, while in I– systems, there were two conformational changes with Sm2+ and one with Eu2+ within that same timeframe. In SmI2-DB30C10, there were three stages of conformational changes. In the first stage, the molecule is unfolded, in the second stage, the molecule is partly folded, and finally, in the third stage, the molecule is completely folded. Lastly, the Gibbs binding free energies of DB30C10 with SmBr2 and EuBr2 have been computed, which resulted in nearly identical ΔG comp values for each lanthanide with Sm2+ being slightly more favorable. Considering the folding mechanism of the SmI2 system with DB30C10, the Gibbs binding free energies of DB30C10 and dicyclohexano-18-crown-6 (DCH18C6) with SmI2 were calculated separately and compared to probe their complexation affinities, in which the former was found to be more favorable.

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Hesam Arabzadeh

Studies of Functional Defects for Fast Na‐Ion Conduction in Na₃₋_yPS₄₋_xCl_x with a Combined Experimental and Computational Approach

Molecular Dynamics and Free Energy Calculations of Dicyclohexano-18-crown-6 Diastereoisomers with Sm²⁺, Eu²⁺, Dy²⁺, Yb²⁺, Cf²⁺, and Three Halide Salts in Tetrahydrofuran and Acetonitrile Using the AMOEBA Force Field

Hydration of divalent lanthanides, Sm²⁺ and Eu²⁺: A molecular dynamics study with polarizable AMOEBA force field

Application of a Novel Ultrasonic Technology to Improve Oil Recovery with an Environmental Viewpoint

Free Energy Calculations and Conformational Analysis of Dibenzo-30-crown-10 with Sm²⁺, Eu²⁺, and Three Halide Salts in THF Using the AMOEBA Force Field

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Hesam Arabzadeh

Studies of Functional Defects for Fast Na‐Ion Conduction in Na3−yPS4−xClx with a Combined Experimental and Computational Approach

Molecular Dynamics and Free Energy Calculations of Dicyclohexano-18-crown-6 Diastereoisomers with Sm2+, Eu2+, Dy2+, Yb2+, Cf2+, and Three Halide Salts in Tetrahydrofuran and Acetonitrile Using the AMOEBA Force Field

Hydration of divalent lanthanides, Sm2+ and Eu2+: A molecular dynamics study with polarizable AMOEBA force field

Application of a Novel Ultrasonic Technology to Improve Oil Recovery with an Environmental Viewpoint

Free Energy Calculations and Conformational Analysis of Dibenzo-30-crown-10 with Sm2+, Eu2+, and Three Halide Salts in THF Using the AMOEBA Force Field

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Product

Resources

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Studies of Functional Defects for Fast Na‐Ion Conduction in Na₃₋_yPS₄₋_xCl_x with a Combined Experimental and Computational Approach

Molecular Dynamics and Free Energy Calculations of Dicyclohexano-18-crown-6 Diastereoisomers with Sm²⁺, Eu²⁺, Dy²⁺, Yb²⁺, Cf²⁺, and Three Halide Salts in Tetrahydrofuran and Acetonitrile Using the AMOEBA Force Field

Hydration of divalent lanthanides, Sm²⁺ and Eu²⁺: A molecular dynamics study with polarizable AMOEBA force field

Free Energy Calculations and Conformational Analysis of Dibenzo-30-crown-10 with Sm²⁺, Eu²⁺, and Three Halide Salts in THF Using the AMOEBA Force Field