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1. Allegro-Legato: Scalable, Fast, and Robust Neural-Network Quantum Molecular Dynamics via Sharpness-Aware Minimization

Author

Ibayashi, Hikaru, Razakh, Taufeq Mohammed, Yang, Liqiu, Linker, Thomas, Olguin, Marco, Hattori, Shinnosuke, Luo, Ye, Kalia, Rajiv K., Nakano, Aiichiro, Nomura, Ken-ichi, and Vashishta, Priya

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Machine Learning, Physics - Computational Physics
Abstract

Neural-network quantum molecular dynamics (NNQMD) simulations based on machine learning are revolutionizing atomistic simulations of materials by providing quantum-mechanical accuracy but orders-of-magnitude faster, illustrated by ACM Gordon Bell prize (2020) and finalist (2021). State-of-the-art (SOTA) NNQMD model founded on group theory featuring rotational equivariance and local descriptors has provided much higher accuracy and speed than those models, thus named Allegro (meaning fast). On massively parallel supercomputers, however, it suffers a fidelity-scaling problem, where growing number of unphysical predictions of interatomic forces prohibits simulations involving larger numbers of atoms for longer times. Here, we solve this problem by combining the Allegro model with sharpness aware minimization (SAM) for enhancing the robustness of model through improved smoothness of the loss landscape. The resulting Allegro-Legato (meaning fast and "smooth") model was shown to elongate the time-to-failure $t_\textrm{failure}$, without sacrificing computational speed or accuracy. Specifically, Allegro-Legato exhibits much weaker dependence of timei-to-failure on the problem size, $t_{\textrm{failure}} \propto N^{-0.14}$ ($N$ is the number of atoms) compared to the SOTA Allegro model $\left(t_{\textrm{failure}} \propto N^{-0.29}\right)$, i.e., systematically delayed time-to-failure, thus allowing much larger and longer NNQMD simulations without failure. The model also exhibits excellent computational scalability and GPU acceleration on the Polaris supercomputer at Argonne Leadership Computing Facility. Such scalable, accurate, fast and robust NNQMD models will likely find broad applications in NNQMD simulations on emerging exaflop/s computers, with a specific example of accounting for nuclear quantum effects in the dynamics of ammonia., Comment: This paper is published at International Supercomputing Conference 2023

Published
2023

3. Enhanced oxygen evolution over dual corner-shared cobalt tetrahedra

Author

Chen, Yubo, Seo, Joon Kyo, Sun, Yuanmiao, Wynn, Thomas A, Olguin, Marco, Zhang, Minghao, Wang, Jingxian, Xi, Shibo, Du, Yonghua, Yuan, Kaidi, Chen, Wei, Fisher, Adrian C, Wang, Maoyu, Feng, Zhenxing, Gracia, Jose, Huang, Li, Du, Shixuan, Gao, Hong-Jun, Meng, Ying Shirley, and Xu, Zhichuan J

Abstract

Developing efficient catalysts is of paramount importance to oxygen evolution, a sluggish anodic reaction that provides essential electrons and protons for various electrochemical processes, such as hydrogen generation. Here, we report that the oxygen evolution reaction (OER) can be efficiently catalyzed by cobalt tetrahedra, which are stabilized over the surface of a Swedenborgite-type YBCo4O7 material. We reveal that the surface of YBaCo4O7 possesses strong resilience towards structural amorphization during OER, which originates from its distinctive structural evolution toward electrochemical oxidation. The bulk of YBaCo4O7 composes of corner-sharing only CoO4 tetrahedra, which can flexibly alter their positions to accommodate the insertion of interstitial oxygen ions and mediate the stress during the electrochemical oxidation. The density functional theory calculations demonstrate that the OER is efficiently catalyzed by a binuclear active site of dual corner-shared cobalt tetrahedra, which have a coordination number switching between 3 and 4 during the reaction. We expect that the reported active structural motif of dual corner-shared cobalt tetrahedra in this study could enable further development of compounds for catalyzing the OER.

Published
2022

4. A Safer, Wide-Temperature Liquefied Gas Electrolyte Based on Difluoromethane

Author

Davies, Daniel M, Yang, Yangyuchen, Sablina, Ekaterina S, Yin, Yijie, Mayer, Matthew, Zhang, Yihui, Olguin, Marco, Lee, Jungwoo Z, Lu, Bingyu, Damien, Dijo, Borodin, Oleg, Rustomji, Cyrus S, and Meng, Y Shirley

Subjects
Safety, Liquefied Gas Electrolyte, Solvation Structure, Lithium Metal, Energy, Chemical Sciences, Engineering
Published
2021

6. Local structure adaptability through multi cations for oxygen redox accommodation in Li-Rich layered oxides

Author

Zhao, Enyue, Zhang, Minghao, Wang, Xuelong, Hu, Enyuan, Liu, Jue, Yu, Xiqian, Olguin, Marco, Wynn, Thomas A, Meng, Ying Shirley, Page, Katharine, Wang, Fangwei, Li, Hong, Yang, Xiao-Qing, Huang, Xuejie, and Chen, Liquan

Subjects
Affordable and Clean Energy, Lithium-ion battery, Lithium-rich cathode, Lattice oxygen redox, Pair distribution function, Local structure, Chemical Engineering, Electrical and Electronic Engineering
Abstract

Stable lattice oxygen redox (l-OR) is the key enabler for achieving attainable high energy density in Li-rich layered oxide cathode materials for Li-ion batteries. However, the unique local structure response to oxygen redox in these materials, resulting in energy inefficiency and hysteresis, still remains elusive, preventing their potential applications. By combining the state-of-the-art neutron pair distribution function with crystal orbital overlap analysis, we directly observe the distinct local structure adaption originated from the potential O–O chemical bonds. The structure adaptability is optimized based on the nature of multi transition metals in our model compound Li1.2Ni0.13Mn0.54Co0.13O2, which accommodates the oxygen redox and at the same time preserves the global layered structure. These findings not only advance the understanding of l-OR, but also provide new perspectives in the rational design of high-energy-density cathode materials with reversible and stable l-OR.

Published
2020

10. A carbonate-free, sulfone-based electrolyte for high-voltage Li-ion batteries

Author

Alvarado, Judith, Schroeder, Marshall A, Zhang, Minghao, Borodin, Oleg, Gobrogge, Eric, Olguin, Marco, Ding, Michael S, Gobet, Mallory, Greenbaum, Steve, Meng, Ying Shirley, and Xu, Kang

Subjects
Affordable and Clean Energy, Chemical Sciences, Engineering, Materials
Abstract

Practical implementation of next-generation Li-ion battery chemistries is to a large extent obstructed by the absence of an electrolyte that is capable of simultaneously supporting reversible electrochemical reactions at two extreme electrochemical potentials—above 4.5 V at the positive electrode and near 0 V vs. Li at the negative electrode. Electrolytes based on carbonate esters have been reliable in satisfying state-of-the-art Li-ion battery (LIB) chemistries below 4.4 V), releasing CO2. In this work, we explore a carbonate-free electrolyte system based on a single sulfone solvent, in which a newly discovered synergy between solvent and salt simultaneously addresses the interfacial requirements of both graphitic anode and high-voltage cathode (LiNi0.5Mn1.5O4 (LNMO)). Experimental measurements, quantum chemistry (QC) calculations, and molecular dynamics simulations reveal the system's fast ion conduction, stability over a wide temperature range, and non-flammability. At the anode, a LiF-rich interphase generated by early-onset reduction of the salt anion effectively suppresses solvent co-intercalation and subsequent graphite exfoliation, enabling unprecedented and highly reversible graphite cycling in a pure sulfone system. Under oxidative conditions, QC calculations predict that high salt concentration promotes complex/aggregate formation which slow the decomposition of sulfolane and leads to polymerizable rather than gaseous products—a fundamental improvement over carbonate solvents. These predictions are corroborated by X-ray photoelectron spectroscopy (XPS), cryogenic-transmission electron microscopy (TEM), and electron energy loss spectroscopy (EELS) experiments, which revealed the presence of a thin, conformal, sulfur-based cathode electrolyte interphase (CEI). Together, the functional interphases (SEI/CEI) generated by this electrolyte system supported long term operation of a high-voltage (4.85 V) LNMO/graphite full cell, which retained ∼70% of its original first-cycle discharge capacity after the 1000th cycle. Based on these results, this new carbonate-free electrolyte system, supported by the mechanistic understanding of its behavior, presents a promising new direction toward unlocking the potential of next generation Li-ion battery electrodes.

Published
2018

12. Substituent-level Tuning of Frontier Orbital Energy Levels in Phthalocyanine/C60 Donor-Acceptor Charge Transfer Pairs

Author

Olguin, Marco, Basurto, Luis, Zope, Rajendra R., and Baruah, Tunna

Subjects
Condensed Matter - Materials Science
Abstract

We have calculated several low-lying Charge Transfer (CT) excited-state energies for four non-covalently bound dyads composed of a sulfonated-ZnPc coupled to C60. Our results show that the di- and tri-sulfonated systems yield a CT state as the lowest-energy excited state in the system. In contrast, an energy re-ordering for the tetra-sulfonated ZnPc system leads to local excitations lying lower in energy than the CT state, displaying a possible deactivation pathway obstructing charge separation. Since several different donor-acceptor relative orientations may co-exist at an organic heterojunction, we compare the energetics of a few low-lying CT states for the end-on geometry of a di-sulfonated system to its co-facial orientation counterpart. The calculated CT excitation energies are larger for the end-on orientation in comparison to the co-facial structure by ~1.5 eV, which results principally from a substantial decrease in exciton binding energy in going from the co-facial to the end-on orientation. Furthermore, changes in relative donor-acceptor orientation have a larger impact on the CT energies than changes in donor-acceptor distance. TDDFT calculations on the various sulfonated ZnPc donor molecules show a significant splitting of the Q-band for only one of the four donor systems. Our present calculations, in line with previous experimental studies, show that the systematic variation of chemical functional groups is a promising avenue for the substituent-level tuning of various physical properties of organic semiconductors.

Published
2013

13. The Effect of Structural Conformational Changes on Charge Transfer States in a Light-Harvesting Carotenoid-diaryl-Porphyrin-C60 Molecular Triad

Author

Olguin, Marco, Zope, Rajendra R., and Baruah, Tunna

Subjects
Condensed Matter - Materials Science, Physics - Chemical Physics
Abstract

We present a detailed study of charge transfer (CT) excited states for a large number of structural conformations in a light-harvesting Carotenoid-diaryl-Porphyrin-C60 (CPC60) molecular triad. The molecular triad undergoes a photoinduced charge transfer process exhibiting a large excited state dipole moment, making it suitable for application to molecular-scale opto-electronic devices. An important consideration is that the conformational flexibility of the CPC 60 triad impacts its dynamics in solvents. Since experimentally measured dipole moments for the triad of ~110 Debye (D) and ~160 Debye strongly indicate a range in conformational variability for the triad in the excited state, studying the effect of conformational changes on the CT excited state energetics furthers the understanding of its charge transfer states. We have calculated the lowest CT excited state energies for a series of 14 triad conformers, where the structural conformations were generated by incrementally scanning a 360 degree torsional (dihedral) twist at the C60-porhyrin linkage and the porphyrin-carotenoid linkage. Additionally, five different CPC60 conformations were studied to determine the effect of pi-conjugation and particle-hole Coulombic attraction on the CT excitation energies. Our calculations show that structural conformational changes in the triad show a variation of ~0.4 eV in CT excited state energies in the gas-phase. The corresponding calculated excited state dipoles show a range of 88 D - 188 D.

Published
2013
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14. High Pressure Effect on Structural and Electrochemical Properties of Anionic Redox- Based Lithium Transition Metal Oxides

Author

Zhang, Minghao, Qiu, Bao, Gallardo-Amores, Jose Manuel, Olguin, Marco, Liu, Haodong, Li, Yixuan, Yin, Chong, Jiang, Sheng, Yao, Weiliang, Arroyo De Dompablo, María Elena, Liu, Zhaoping, Shirley Meng, Ying, Zhang, Minghao, Qiu, Bao, Gallardo-Amores, Jose Manuel, Olguin, Marco, Liu, Haodong, Li, Yixuan, Yin, Chong, Jiang, Sheng, Yao, Weiliang, Arroyo De Dompablo, María Elena, Liu, Zhaoping, and Shirley Meng, Ying

Abstract

Depto. de Química Inorgánica, CAI Ciencias de la Tierra y Arqueometría, TRUE, pub

Published
2023

20. Local structure adaptability through multi cations for oxygen redox accommodation in Li-Rich layered oxides

Author

Zhao, Enyue, primary, Zhang, Minghao, additional, Wang, Xuelong, additional, Hu, Enyuan, additional, Liu, Jue, additional, Yu, Xiqian, additional, Olguin, Marco, additional, Wynn, Thomas A., additional, Meng, Ying Shirley, additional, Page, Katharine, additional, Wang, Fangwei, additional, Li, Hong, additional, Yang, Xiao-Qing, additional, Huang, Xuejie, additional, and Chen, Liquan, additional

Published
2020
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21. Estrés hídrico en la producción, productividad y calidad nutracéutica de melón injertado

Author

Villegas Olguin, Marco Antonio, Cabrera De La Fuente, Marcelino, Benavides Mendoza, Adalberto, Sandoval Rangel, Alberto, and Feregrino Pérez, Ana Angélica

Subjects
antioxidantes, melón, CIENCIAS AGROPECUARIAS Y BIOTECNOLOGÍA, injerto
Abstract

"El melón es un cultivo caracterizado por su sabor y alto valor nutricional, con propiedades antioxidantes y antiinflamatorias. A nivel internacional el principal productor es China; a nivel nacional la región de La Comarca Lagunera se posiciona como la principal zona productora de este fruto. Las condiciones edafoclimáticas de esta incitan a emplear nuevas tecnologías para subsanar la falta – escasez del recurso hídrico, proponiendo el uso del injerto como una alternativa. Es por esto que la presente investigación tiene como objetivo evaluar el efecto del estrés hídrico en la producción, productividad, histología y calidad nutracéutica del cultivo de melón injertado. Se hicieron evaluaciones en variables agronómicas, histológicas y de calidad comercial y nutracéutica del fruto destacando que plantas cultivadas en condiciones óptimas de riego presentan una mayor altura, número de hojas y frutos en tanto que el injerto favorece el grosor del tallo. El injerto tiene influencia sobre el índice estomático en condiciones medias de estrés hídrico. En la raíz el número de haces vasculares de la variedad no difiere con la del patrón, los vasos del xilema son mayores en plantas sin entrés pero son más grandes (en área) en plantas con injerto. En el tallo el injerto y tensión hídrica modifican el número de los haces vasculares y el área de éstos la presentan las plantas con injerto. En las hojas de plantas sin injerto se mostraron mayor número de vasos del xilema y área de éstos. La calidad del fruto se ve beneficiada en presencia del injerto ya que presentan mayor firmeza, aunado a mayor actividad antioxidante enzimática (catalasa, glutatión peroxidasa) y no enzimática (vitamina C, actividad antioxidantes por DPPH y fenoles totales)" "The melon is a crop characterized by its flavor and high nutritional value, with antioxidant and anti-inflammatory properties. At the international level, the main producer is China; At a national level, the region of La Comarca Lagunera is positioned as the main producing area of this fruit. The edaphoclimatic conditions of this encourage the use of new technologies to correct the lack - shortage of water resources, proposing the use of the graft as an alternative. This is the reason why the present investigation aims to evaluate the effect of water stress on the production, productivity, histology and nutraceutical quality of the grafted melon crop. Evaluations were made in agronomic, histological and commercial quality variables and nutraceutical of the fruit highlighting that plants grown under optimal irrigation conditions have a higher height, number of leaves and fruits while the graft favors the stem thickness. The graft has influence on the stomatal index in medium conditions of water stress. In the root the number of vascular bundles of the variety does not differ with the one of the pattern, the vessels of the xylem are greater in plants without entrés but they are bigger (in area) in plants with graft. In the stem the graft and water stress modify the number of vascular bundles and the area of these are presented by the grafted plants. In the leaves of plants without grafting, a greater number of xylem vessels and their area were shown. The quality of the fruit is benefited in the presence of the graft since they present greater firmness, together with greater enzymatic antioxidant activity (catalase, Glutathione peroxidase) and nonenzymatic (Vitamin C, DPPH, total phenols)"

Published
2018

24. The effect of structural changes on charge transfer states in a light-harvesting carotenoid-diaryl-porphyrin-C60 molecular triad.

Author

Olguin, Marco, Basurto, Luis, Zope, Rajendra R., and Baruah, Tunna

Subjects
*CHARGE transfer, *ION exchange (Chemistry), *CAROTENOIDS, *DIARYL compounds, *DIPOLE moments
Abstract

We present a detailed study of charge transfer (CT) excited states for a large number of configurations in a light-harvesting Carotenoid-diaryl-Porphyrin-C60 (CPC60) molecular triad. The chain-like molecular triad undergoes photoinduced charge transfer process exhibiting a large excited state dipole moment, making it suitable for application to molecular-scale opto-electronic devices. An important consideration is that the structural flexibility of the CPC60 triad impacts its dynamics in solvents. Since experimentally measured dipole moments for the triad of ∼110 D and ∼160 D strongly indicate a range in structural variability in the excited state, studying the effect of structural changes on the CT excited state energetics furthers the understanding of its charge transfer states. We have calculated the variation in the lowest CT excited state energies by performing a scan of possible variation in the structure of the triad. Some of these configurations were generated by incrementally scanning a 360° torsional (dihedral) twist at the C60-porhyrin linkage and the porphyrin-carotenoid linkage. Additionally, five different CPC60 conformations were studied to determine the effect of pi-conjugation and particle-hole Coulombic attraction on the CT excitation energies. Our calculations show that configurational changes in the triad induces a variation of ∼0.6 eV in CT excited state energies in the gas-phase. The corresponding calculated excited state dipoles show a range of 47 D-188 D. The absorption spectra and density of states of these structures show little variation except for the structures where the porphyrin and aryl conjugation is changed. [ABSTRACT FROM AUTHOR]

Published
2014
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26. Ion Conductivities: Protons Enhance Conductivities in Lithium Halide Hydroxide/Lithium Oxyhalide Solid Electrolytes by Forming Rotating Hydroxy Groups (Adv. Energy Mater. 3/2018)

Author

Song, Ah-Young, primary, Xiao, Yiran, additional, Turcheniuk, Kostiantyn, additional, Upadhya, Punith, additional, Ramanujapuram, Anirudh, additional, Benson, Jim, additional, Magasinski, Alexandre, additional, Olguin, Marco, additional, Meda, Lamartine, additional, Borodin, Oleg, additional, and Yushin, Gleb, additional

Published
2018
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28. Charge transfer excitations in cofacial fullerene-porphyrin complexes.

Author

Zope, Rajendra R., Olguin, Marco, and Baruah, Tunna

Subjects
*CHARGE transfer, *ELECTRONIC excitation, *FULLERENES, *PORPHYRINS, *COMPLEX compounds, *ELECTRON donor-acceptor complexes, *ELECTRONIC structure
Abstract

Porphyrin and fullerene donor-acceptor complexes have been extensively studied for their photo-induced charge transfer characteristics. We present the electronic structure of ground states and a few charge transfer excited states of four cofacial porphyrin-fullerene molecular constructs studied using density functional theory at the all-electron level using large polarized basis sets. The donors are base and Zn-tetraphenyl porphyrins and the acceptor molecules are C60 and C70. The complexes reported here are non-bonded with a face-to-face distance between the porphyrin and the fullerene of 2.7 to 3.0 Å. The energies of the low lying excited states including charge transfer states calculated using our recent excited state method are in good agreement with available experimental values. We find that replacing C60 by C70 in a given dyad may increase the lowest charge transfer excitation energy by about 0.27 eV. Variation of donor in these complexes has marginal effect on the lowest charge transfer excitation energy. The interfacial dipole moments and lowest charge transfer states are studied as a function of face-to-face distance. [ABSTRACT FROM AUTHOR]

Published
2012
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29. Charge transfer excited state energies by perturbative delta self consistent field method.

Author

Baruah, Tunna, Olguin, Marco, and Zope, Rajendra R.

Subjects
*CHARGE transfer, *SELF-consistent field theory, *PERTURBATION theory, *ELECTRONIC excitation, *HYDROCARBONS, *COMPLEX compounds, *PORPHYRINS, *FORCE & energy
Abstract

We use our recently outlined perturbative approach to compute the lowest charge transfer excitation energies for a set of tetracynoehylene (TCNE)-hydrocarbon complexes, C2H4-C2F4, NH3-F2, pentacene-C60, and tetraphenyl porphyrin-C60 complexes. Results show that the method can provide a reliable description of charge transfer excitation energies, which are comparable to that obtained by time-dependent density functional theory using specially optimized range-corrected functionals. As the calculation cost of excited state is comparable to the ground state and the calculation of each excited state is independent of others, the method can be easily used to describe the charge transfer excited states of large donor-acceptor complexes containing 200 or more atoms. [ABSTRACT FROM AUTHOR]

Published
2012
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30. Protons Enhance Conductivities in Lithium Halide Hydroxide/Lithium Oxyhalide Solid Electrolytes by Forming Rotating Hydroxy Groups

Author

Song, Ah‐Young, primary, Xiao, Yiran, additional, Turcheniuk, Kostiantyn, additional, Upadhya, Punith, additional, Ramanujapuram, Anirudh, additional, Benson, Jim, additional, Magasinski, Alexandre, additional, Olguin, Marco, additional, Meda, Lamartine, additional, Borodin, Oleg, additional, and Yushin, Gleb, additional

Published
2017
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31. Liquid Structure with Nano-Heterogeneity Promotes Cationic Transport in Concentrated Electrolytes

Author

Borodin, Oleg, primary, Suo, Liumin, additional, Gobet, Mallory, additional, Ren, Xiaoming, additional, Wang, Fei, additional, Faraone, Antonio, additional, Peng, Jing, additional, Olguin, Marco, additional, Schroeder, Marshall, additional, Ding, Michael S., additional, Gobrogge, Eric, additional, von Wald Cresce, Arthur, additional, Munoz, Stephen, additional, Dura, Joseph A., additional, Greenbaum, Steve, additional, Wang, Chunsheng, additional, and Xu, Kang, additional

Published
2017
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36. Rendimiento agronómico en melón injertado y cultivado con diferentes tensiones hídricas.

Author

Villegas Olguin, Marco Antonio, Feregrino Pérez, Ana Angélica, Benavides Mendoza, Adalberto, Sandoval Rangel, Alberto, and De La Fuente, Marcelino Cabrera

Abstract

Copyright of Congreso Internacional de Investigacion Academia Journals is the property of PDHTech, LLC and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2017

38. Protons Enhance Conductivities in Lithium Halide Hydroxide/Lithium Oxyhalide Solid Electrolytes by Forming Rotating Hydroxy Groups.

Author

Song, Ah‐Young, Xiao, Yiran, Turcheniuk, Kostiantyn, Upadhya, Punith, Ramanujapuram, Anirudh, Benson, Jim, Magasinski, Alexandre, Yushin, Gleb, Olguin, Marco, Borodin, Oleg, and Meda, Lamartine

Subjects
LITHIUM-ion batteries, MOLECULAR dynamics, SOLID state physics, ELECTROLYTES, X-ray diffraction
Abstract

Abstract: Li‐halide hydroxides (Li2OHX) and Li‐oxyhalides (Li3OX) have emerged as new classes of low‐cost, lightweight solid state electrolytes (SSE) showing promising Li‐ion conductivities. The similarity in the lattice parameters between them, careless synthesis, and insufficient rigor in characterization often lead to erroneous interpretations of their compositions. Finally, moisture remaining in the synthesis or cell assembling environment and variability in the equivalent circuit models additionally contribute to significant errors in their properties. Thus, there remains a controversy about the real values of Li‐ion conductivities in such SSEs. Here an ultra‐fast synthesis and comprehensive material characterization is utilized to report on the ionic conductivities of contaminant‐free Li2+xOH1−xCl (x=0‐0.7), and Li2OHBr not exceeding 10‐4 S cm‐1 at 110 °C. Using powerful combination of experimental and numerical approaches, it is demonstrated that the presence of H in these SSEs yields significantly higher Li+ ‐ionic conductivity. Born‐Oppenheimer molecular dynamics simulations show excellent agreement with experimental results and reveal an unexpected mechanism for faster Li+ transport. It involves rotation of a short OH‐group in SSEs, which opens lower‐energy pathways for the formation of Frenkel defects and highly‐correlated Li+ jumps. These findings will reduce the existing confusions and show new avenues for tuning SSE compositions for further improved Li‐ion conductivities. [ABSTRACT FROM AUTHOR]

Published
2018
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41. Poly(aryl-ether-ether-ketone) as a Possible Metalized Film Capacitor Dielectric: Accurate Description of the Band Gap Through Ab Initio Calculation

Author

ARMY RESEARCH LAB ADELPHI MD SENSORS AND ELECTRON DEVICES DIRECTORATE, Ho, Janet, Olguin, Marco, Diaz, Carlos, ARMY RESEARCH LAB ADELPHI MD SENSORS AND ELECTRON DEVICES DIRECTORATE, Ho, Janet, Olguin, Marco, and Diaz, Carlos

Abstract

Poly(aryl-ether-ether-ketone) (PEEK) is a primary candidate for a high temperature capacitor dielectric due to its outstanding mechanical strength and thermal stability. However, its breakdown strength is unsatisfactory (400 MV/m) and its volumetric resistivity drops significantly at electric fields above 100 MV/m. Our main objective is to study the effect of chemical impurities, such as water molecules and chain ends, on impurity states in the band gap of PEEK using density functional theory (DFT) to gain insight on the factors impacting electrical resistivity under a high field, which may correlate to low breakdown strength. Our focus is to determine the correct geometry of the unit cell and develop a methodology for computing the band gap of PEEK accurately. We used dispersion-corrected DFT to optimize various starting geometries and determined the correct one based on a comparison with experimental crystallographic data. The band gap was determined from the projected density of states, which is calculated using the HSE06 hybrid exchange-correlation functional. The original HSE06 formulation overestimates the band gap of PEEK by 33% compared to the experimental value. So, to obtain a more accurate functional form, we conducted a systematic study on the parameter space of the functional by varying the exchange-correlation mixing and screening coefficients., The original document contains color images. Prepared in collaboration with the University of Texas at El Paso, TX.

Published
2014

42. Charge storage at the nanoscale: understanding the trends from the molecular scale perspective.

Author

Borodin, Oleg, Olguin, Marco, Vatamanu, Jenel, Bedrov, Dmitry, and Yushin, Gleb

Abstract

Supercapacitors or electrical double layer (EDL) capacitors store charge via rearrangement of ions in electrolytes and their adsorption on electrode surfaces. They are actively researched for multiple applications requiring longer cycling life, broader operational temperature ranges, and higher power density compared to batteries. Recent developments in nanostructured carbon-based electrodes with a high specific surface area have demonstrated the potential to significantly increase the energy density of supercapacitors. Molecular modeling of electrolytes near charged electrode surfaces has provided key insights into the fundamental aspects of charge storage at the nanoscale, including an understanding of the mechanisms of ion adsorption and dynamics at flat surfaces and inside nanopores, and the influence of curvature, roughness, and electronic structure of electrode surfaces. Here we review these molecular modeling findings for EDL capacitors, dual ion batteries and pseudo-capacitors together with available experimental observations and put this analysis into the perspective of future developments in this field. Current research trends and future directions are discussed. [ABSTRACT FROM AUTHOR]

Published
2017
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46. Calcium coated B80 fullerene: A study on various coating configurations of B80

Author

Olguin, Marco, Baruah, Tunna, and Zope, Rajendra R.

Subjects
*CALCIUM, *SURFACE coatings, *FULLERENES, *ADSORPTION (Chemistry), *BORON compounds, *ELECTRON distribution, *DENSITY functionals, *GENERALIZATION
Abstract

Abstract: We investigate the adsorption of calcium atoms on the surface of novel boron fullerenes and the α-boron sheet using an all electron density functional method within the generalized gradient approximation. Recent theoretical works show that the B80 fullerene coated with one Ca atom on each pentagonal ring is capable of storing up to 60 H2 molecules, yielding a gravimetric density of 8.2wt.%. We have performed a detailed investigation of Ca adsorption on the B80 fullerene. At variance with recent results, our calculations show that a single Ca atom prefers to occupy a hexagonal site rather than a pentagonal site. The calculations on Ca12B80, Ca20B80 and Ca32B80 indicate that Ca atoms prefer to uniformly coat the whole surface over selectively occupying the pentagonal or hexagonal sites. [Copyright &y& Elsevier]

Published
2011
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47. "Water-in-salt" electrolyte enables high-voltage aqueous lithium-ion chemistries.

Author

Liumin Suo, Borodin, Oleg, Tao Gao, Olguin, Marco, Janet Ho, Xiulin Fan, Chao Luo, Chunsheng Wang, and Kang Xu

Subjects
*LITHIUM-ion batteries, *LITHIUM-ion batteries -- Fires & fire prevention, *NONAQUEOUS electrolytes, *ELECTRIC battery design & construction, *ELECTROLYTES, *AQUEOUS electrolytes
Abstract

Lithium-ion batteries raise safety, environmental, and cost concerns, which mostly arise from their nonaqueous electrolytes. The use of aqueous alternatives is limited by their narrow electrochemical stability window (1.23 volts), which sets an intrinsic limit on the practical voltage and energy output.We report a highly concentrated aqueous electrolyte whose window was expanded to ~3.0 volts with the formation of an electrode-electrolyte interphase. A full lithium-ion battery of 2.3 volts using such an aqueous electrolyte was demonstrated to cycle up to 1000 times, with nearly 100% coulombic efficiency at both low (0.15 coulomb) and high (4.5 coulombs) discharge and charge rates. [ABSTRACT FROM AUTHOR]

Published
2015
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