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34 results on '"Croy, Jason R"'

1. Topotactic phase transformation of lithiated spinel to layered LiMn0.5Ni0.5O2: the interaction of 3-D and 2-D Li-ion diffusion.

Author

Shi, Boyu, Gim, Jihyeon, Li, Tianyi, Koirala, Krishna, Wang, Chongmin, Hou, Dewen, Liu, Yuzi, Jorne, Jacob, Croy, Jason R., Thackeray, Michael M., and Lee, Eungje

Abstract

This study investigates the structural evolution of LiMn0.5Ni0.5O2 cathode materials for Li-ion batteries as a function of synthesis temperature and its effect on electrochemical performance. It is demonstrated that, as the synthesis temperature increases from 400 to 900 °C, a gradual topotactic transformation occurs between a lithiated spinel structure, denoted herein as "lithium-excess spinel" LxS-LiMn0.5Ni0.5O2 (or LxS-LMNO), and the well-known layered LiMn0.5Ni0.5O2 structure prepared at high temperature, HT-LiMn0.5Ni0.5O2 (HT-LMNO). The electrochemical capacity of the LiMn0.5Ni0.5O2 electrodes follows a parabolic trend with increasing synthesis temperature, which is attributed primarily to the gradual transformation of 3-dimensional (3-D) to 2-dimensional (2-D) diffusion pathways for the Li ions. When synthesized at 400 °C, LxS-LiMn0.5Ni0.5O2 electrodes perform well, benefitting from the 3-D network of channels within the LxS structure. By contrast, when prepared at 500–700 °C, LiMn0.5Ni0.5O2 electrodes operate poorly, which is attributed to the formation of locally disordered structural arrangements that impede Li-ion diffusion. Such an increase in local disorder in the mid-temperature synthesis range is attributed to the structural frustration between the lithium-excess spinal and layered end-members. The transformation from the locally disordered to more ordered layered components between 700 °C and 900 °C enhances electrochemical performance. The study opens new avenues for designing next-generation Mn-rich cathode materials by fine-tuning the synthesis conditions as well as the composition and structure of LxS-LMNO electrodes. [ABSTRACT FROM AUTHOR]

Published
2025
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2. High‐Energy LiNiO2 Li Metal Batteries Enabled by Hybrid Electrolyte Consisting of Ionic Liquid and Weakly Solvating Fluorinated Ether.

Author

Liu, Qian, Xu, Jiayi, Jiang, Wei, Gim, Jihyeon, Tornheim, Adam P., Pathak, Rajesh, Zhu, Qijia, Zuo, Peng, Yang, Zhenzhen, Pupek, Krzysztof Z., Lee, Eungje, Wang, Chongmin, Liu, Cong, Croy, Jason R., Xu, Kang, and Zhang, Zhengcheng

Subjects
ENERGY density, DENSITY functional theory, RESEARCH personnel, ELECTROLYTES, DYNAMIC simulation, ELECTRIC batteries, LITHIUM cells
Abstract

In pursuit of the highest possible energy density, researchers shift their focus to the ultimate anode material, lithium metal (Li0), and high‐capacity cathode materials with high nickel content (Ni > 80%). The combination of these aggressive electrodes presents unprecedented challenges to the electrolyte. Here, we report a hybrid electrolyte consisting of a highly fluorinated ionic liquid and a weakly solvating fluorinated ether, whose hybridization structure enables the reversible operation of a battery chemistry based on Li0 and LiNiO2 (Ni = 100%), delivering nearly theoretical capacity of the latter (up to 249 mAh g−1) for >300 cycles with retention of 78.6% and in absence of unwanted morphological changes in both electrodes. Extensive characterization assisted by molecular dynamic simulation and density functional theory calculations reveals the function of the fluorinated ether to be far more profound than simple dilution and viscosity reduction. Instead, it induces drastic changes in Li+‐solvation environment, the consequence of which engenders simultaneous stabilization of electrode/electrolyte and interfacing via formation of respective interfacial chemistries. This study further unlocks fundamental knowledge underneath the prevailing "diluent strategy" that is extensively applied by the electrolyte researchers and opens more design space for the next‐generation electrolytes and interphases for these coveted battery chemistries. [ABSTRACT FROM AUTHOR]

Published
2024
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10. LT-LiMn0.5Ni0.5O2: a unique co-free cathode for high energy Li-ion cells.

Author

Shi, Boyu, Gim, Jihyeon, Li, Linze, Wang, Chongmin, Vu, Anh, Croy, Jason R., Thackeray, Michael M., and Lee, Eungje

Subjects
CATHODES, OXIDATION-reduction reaction, LOW temperatures, HIGH voltages
Abstract

A novel LiMn0.5Ni0.5O2 cathode with a predominant, partially-disordered lithiated-spinel structure has been prepared by a 'low temperature' (LT) synthesis. Li/LT-LiMn0.5Ni0.5O2 cells operate between 5.0 and 2.5 V with good cycling stability, yielding a capacity of 225 mA h g−1, principally by redox reactions on the nickel ions on distinct voltage plateaus at ∼3.6 V and ∼4.6 V. [ABSTRACT FROM AUTHOR]

Published
2021
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12. Strain-driven surface reconstruction and cation segregation in layered Li(Ni1−x−yMnxCoy)O2 (NMC) cathode materials.

Author

Garcia, Juan C., Bareño, Javier, Chen, Guoying, Croy, Jason R., and Iddir, Hakim

Abstract

The composition, structure and phase transformations occurring on cathode surfaces greatly affect the performance of Li-ion batteries. Li-Ion diffusion and surface–electrolyte interaction are two major phenomena that impact the capacity and cell impedance. The effects of surface reconstruction (SR) of cathode materials on the performance of Li-ion batteries are of current interest. However, the origin and evolution of the SR are still not well understood. In this work, density functional theory (DFT) calculations are used to investigate the processes taking place during surface segregation and reconstruction. Facet dependent segregation was found in Li(Ni1−x−yMnxCoy)O2 (NMC) cathodes. Specifically, Co tends to segregate to the (104) surface of the primary particles within the transition metal layer, while Ni ions tend to segregate to the (012) surface in the Li layer, forming a SR. Experimental evidence shows the SR to be epitaxial with the bulk of the as-synthesized material, and the new SR phase is pinned to the NMC unit cell leading to a strained SR. Here, we show that strain can stabilize a spinel structure of the SR layers. Understanding the effects of surface strain opens a new avenue for the design of cathode materials with enhanced surface properties. [ABSTRACT FROM AUTHOR]

Published
2020
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20. First-charge instabilities of layered-layered lithium-ion-battery materials.

Author

Croy, Jason R., Iddir, Hakim, Gallagher, Kevin, Johnson, Christopher S., Benedek, Roy, and Balasubramanian, Mahalingam

Abstract

Li- and Mn-rich layered oxides with composition xLi2MnO3·(1 −x)LiMO2 enable high capacity and energy density Li-ion batteries, but suffer from degradation with cycling. Evidence of atomic instabilities during the first charge are addressed in this work with X-ray absorption spectroscopy, first principles simulation at the GGA+U level, and existing literature. The pristine material of composition xLi2MnO3·(1 −x)LiMn0.5Ni0.5O2 is assumed in the simulations to have the form of LiMn2 stripes, alternating with NiMn stripes, in the metal layers. The charged state is simulated by removing Li from the Li layer, relaxing the resultant system by steepest descents, then allowing the structure to evolve by molecular dynamics at 1000 K, and finally relaxing the evolved system by steepest descents. The simulations show that about ¼ of the oxygen ions in the Li2MnO3 domains are displaced from their original lattice sites, and form oxygen–oxygen bonds, which significantly lowers the energy, relative to that of the starting structure in which the oxygen sublattice is intact. An important consequence of the displacement of the oxygen is that it enables about ⅓ of the (Li2MnO3 domain) Mn ions to migrate to the delithiated Li layers. The decrease in the coordination of the Mn ions is about twice that of the Ni ions. The approximate agreement of simulated coordination number deficits for Mn and Ni following the first charge with analysis of EXAFS measurements on 0.3Li2MnO3·0.7LiMn0.5Ni0.5O2 suggests that the simulation captures significant features of the real material. [ABSTRACT FROM AUTHOR]

Published
2015
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21. Pristine-state structure of lithium-ion-battery cathode material Li1.2Mn0.4Co0.4O2 derived from NMR bond pathway analysis.

Author

Iddir, Hakim, Key, Baris, Dogan, Fulya, Russell, John T., Long, Brandon R., Bareño, Javier, Croy, Jason R., and Benedek, Roy

Abstract

Layered lithium ion battery cathode materials have been extensively investigated, of which layered–layered composites xLi2MnO3·(1 −x)LiMO2 (M = Mn, Co, Ni) are of particular interest, owing to their high energy density. Before the structural transformations that occur in these materials with cycling can be understood, the structure of the pristine material must be established. In this work, NMR spectra are measured for the model layered–layered system xLi2MnO3·(1 −x)LiCoO2 and Bond-Pathway-model analysis is applied to elucidate the atomic arrangement and domain structure of this material in its pristine state, before electrochemical cycling. The simplest structural element of an Li2MnO3 domain consists of a stripe of composition LiMn2 parallel to a crystallographic axis in a metal layer of the composite. A simple model of the composite structure may be constructed by a superposition of such stripes in an LiCoO2 background. We show that such a model can account for most of the features of the observed NMR spectra. [ABSTRACT FROM AUTHOR]

Published
2015
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25. Next-generation lithium-ion batteries: The promise of near-term advancements.

Author

Croy, Jason R., Abouimrane, Ali, and Zhang, Zhengcheng

Subjects
LITHIUM-ion batteries, TECHNOLOGICAL innovations, HYBRID electric vehicles, ENERGY density, PRODUCT safety, PRODUCT costing
Abstract

The commercialization of lithium-ion batteries has intimately changed our lives and enabled portable electronic devices, which has revolutionized communications, entertainment, medicine, and more. After three decades of commercial development, researchers around the world are now pursuing major advances that would allow this technology to power the next generation of light-duty, electric, and hybrid-electric vehicles. If this goal is to be met, concerted advances in safety and cost, as well as cycle-life and energy densities, must be realized through advances in the properties of the highly correlated, but separate, components of lithium-ion energy-storage systems. [ABSTRACT FROM AUTHOR]

Published
2014
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26. Oxidation state of cross-over manganese species on the graphite electrode of lithium-ion cells.

Author

Gowda, Sanketh R., Gallagher, Kevin G., Croy, Jason R., Bettge, Martin, Thackeray, Michael M., and Balasubramanian, Mahalingam

Abstract

It is well known that Li-ion cells containing manganese oxide-based positive electrodes and graphite-based negative electrodes suffer accelerated capacity fade, which has been attributed to the deposition of dissolved manganese on the graphite electrodes during electrochemical cell cycling. However, the reasons for the accelerated capacity fade are still unclear. This stems, in part, from conflicting reports of the oxidation state of the manganese species in the negative electrode. In this communication, the oxidation state of manganese deposited on graphite electrodes has been probed by X-ray absorption near edge spectroscopy (XANES). The XANES features confirm, unequivocally, the presence of fully reduced manganese (Mn0) on the surface of graphite particles. The deposition of Mn0 on the graphite negative electrode acts as a starting point to understand the consequent electrochemical behavior of these electrodes; possible reasons for the degradation of cell performance are proposed and discussed. [ABSTRACT FROM AUTHOR]

Published
2014
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32. Size-selected Pt Nanoparticles Synthesized via Micelle Encapsulation: Effect of Pretreatment and Oxidation State on the Activity for Methanol Decomposition and Oxidation.

Author

Croy, Jason R., Mostafa, S., Heinrich, H., and Cuenya, B. Roldan

Subjects
NANOPARTICLES, MICELLES, MICROENCAPSULATION, METHANOL, OXIDATION, CATALYSIS
Abstract

The effect of pretreatment conditions on the oxidation state and activity of micelle-synthesized Pt nanoparticles supported on ZrO2 was studied for methanol decomposition and oxidation reactions. An O2-pretreatment is observed to be effective for producing clean, stable, and active nanoparticles. Pt-oxide species formed during such pretreatments were found to have little influence in methanol decomposition reactions due to their tendency to reduce. However, these same species are stable during methanol oxidation and appear to take part in a Mars-van Krevelen-type of process, in which bound-oxygen (nanoparticle shell) may be replenished with oxygen from the gas phase. [ABSTRACT FROM AUTHOR]

Published
2009
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33. Support Dependence of MeOH Decomposition Over Size-Selected Pt Nanoparticles.

Author

Croy, Jason R., Mostafa, Simon, Jing Liu, Yongho Sohn, Heinrich, Helge, and Cuenya, Beatriz Roldan

Subjects
CHEMICAL decomposition, NANOPARTICLES, CRYSTALS, METHANOL, BULK solids, NANOSTRUCTURED materials, SCISSION (Chemistry)
Abstract

We present here the decomposition of methanol over Pt nanoparticles supported on a series of oxide powders. The samples tested may be roughly grouped in two categories consisting of large (∼15–18 nm) and small (∼8–9 nm) Pt particles deposited on reducible (CeO2, TiO2) and non-reducible (SiO2, ZrO2, Al2O3) supports. The smallest particles (∼8 nm), deposited on ZrO2, were found to be cationic and the most active for the decomposition of methanol. Furthermore, the stability of metallic Pt and its oxides was observed to be dependent on the choice of support. In all Pt containing samples the reaction proceeds via he direct decomposition of methanol, as no significant amounts of by-products were detected in the experimental range of 100–300 °C. [ABSTRACT FROM AUTHOR]

Published
2007
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