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3. Intrinsic chemical reactivity of solid-electrolyte interphase components in silicon–lithium alloy anode batteries probed by FTIR spectroscopy

Author

Kristin A. Persson, Brenda A. Smith, Baris Key, Eric Sivonxay, Ryan T. Pekarek, Nathan R. Neale, Jaclyn Coyle, Ting-Zheng Hou, Rebecca D. McAuliffe, Lauryn L. Baranowski, Christopher A. Apblett, Alec Affolter, and Gabriel M. Veith

Subjects
Battery (electricity), Chemical substance, Materials science, Renewable Energy, Sustainability and the Environment, chemistry.chemical_element, 02 engineering and technology, General Chemistry, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, Chemical reaction, 0104 chemical sciences, Anode, Chemical species, chemistry, Chemical engineering, General Materials Science, Lithium, 0210 nano-technology
Abstract

In this work we report the solid reaction products from the chemical reaction of aprotic battery electrolyte and three purported components of the Si-based anode SEI : SiO2 nanoparticles (NPs), lithium silicate (LixSiOy) powders, and Si NPs. We use FTIR and classical molecular dynamics/density functional perturbation theory to assess the solid products remaining with these model materials after exposure to electrolyte. The absence of electrochemical bias provides a view of the chemical speciation resulting from early-stage chemical reactivity during battery assembly as well as under open circuit storage conditions. We believe these species represent the initial stages of SEI growth and predict they likely drive subsequent chemical and electrochemical reactions by controlling molecular interactons at the Si active material interface. We find that nominally equivalent materials react differently even before any electrochemistry is performed (e.g., acidic SiO2 dissolves whereas alkaline SiO2 is relatively robust), and derive new understanding of the chemical species that could and could not form stable SEI components in Si-based anodes. These results can be used to inform how to passivate Si anode surfaces and potentially generate an artificially engineered SEI that would be stable and enable next-generation battery anodes.

Published
2020
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4. Solid Electrolyte Interphase on Native Oxide-Terminated Silicon Anodes for Li-Ion Batteries

Author

Thomas P. Devereaux, Eric Sivonxay, Brian Moritz, Iwnetim Abate, Badri Shyam, Kristin A. Persson, Hans-Georg Steinrück, Chuntian Cao, Chunjing Jia, and Michael F. Toney

Subjects
Materials science, Silicon, Oxide, chemistry.chemical_element, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Lithium-ion battery, 0104 chemical sciences, chemistry.chemical_compound, General Energy, X-ray photoelectron spectroscopy, chemistry, Chemical engineering, Linear sweep voltammetry, Wafer, 0210 nano-technology, Layer (electronics)
Abstract

Summary To shed light on the formation process and structure of the solid electrolyte interphase (SEI) layer on native oxide-terminated silicon wafer anodes from a carbonate-based electrolyte (LP30), we combined in situ synchrotron X-ray reflectivity, linear sweep voltammetry, ex situ X-ray photoelectron spectroscopy, and first principles calculations from the Materials Project. We present in situ sub-nanometer resolution structural insights and compositional information of the SEI, as well as predicted equilibrium phase stability. Combining these findings, we observe two well-defined inorganic SEI layers next to the Si anode—a bottom-SEI layer (adjacent to the electrode) formed via the lithiation of the native oxide, and a top-SEI layer mainly consisting of the electrolyte decomposition product LiF. Our study provides novel mechanistic insights into the SEI growth process on Si, and we discuss several important implications regarding ion and electron transport through the SEI layer.

Published
2019
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5. Evaluation of Amorphous Oxide Coatings for High-Voltage Li-Ion Battery Applications Using a First-Principles Framework

Author

Eric Sivonxay, Kristin A. Persson, and Jianli Cheng

Subjects
Battery (electricity), Materials science, Diffusion, High voltage, 02 engineering and technology, engineering.material, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, Cathode, 0104 chemical sciences, law.invention, Amorphous solid, Coating, Chemical engineering, law, engineering, General Materials Science, Chemical stability, 0210 nano-technology
Abstract

Cathode surface coatings are widely used industrially as a means to suppress degradation and improve electrochemical performance of lithium-ion batteries. However, developing an optimal coating is challenging, as different coating materials may enhance one aspect of performance while hindering another. To elucidate the fundamental thermodynamic and transport properties of amorphous cathode coating materials, here, we present a framework for calculating and analyzing the Li+ and O2- transport and the stability against delithiation in such materials. Our framework includes systematic workflows of ab-initio molecular dynamics calculations to obtain amorphous structures and diffusion trajectories coupled with an analysis of critical changes of the active-ion local environment during diffusion. Based on these data, we provide an estimate of room-temperature diffusivities, including statistical error bars, and the evaluation of the coating suitability in terms of its ability to facilitate Li+ transport while blocking O2- transport. Finally, we add the thermodynamic stability analysis of the coating chemistry within the operating voltage of common Li-ion cathodes. We apply this framework to two commonly used amorphous coating materials, Al2O3 and ZnO. We find that (1) in general, a higher Li+ content increases both Li+ and O2- diffusivities in both Al2O3 and ZnO. Also, Li+ and O2- diffuse much faster in ZnO than in Al2O3. (2) However, neither Al2O3 nor ZnO is expected to retain a significant concentration of Li+ at high charge. (3) ZnO performs much more poorly in terms of O2- blocking, and hence, Al2O3 is preferred for high-voltage cathode applications. These results will help to quantitatively evaluate amorphous materials, such as metal oxides and fluorides, for different performance metrics and facilitate the development of optimal cathode coatings.

Published
2020

6. Mechanical Properties and Chemical Reactivity of LixSiOy Thin Films

Author

Svitlana Pylypenko, Glenn Teeter, Caleb Stetson, Kevin N. Wood, Yun Xu, Sang-Don Han, Eric Sivonxay, Anthony K. Burrell, Andriy Zakutayev, Chun-Sheng Jiang, and Kristin A. Persson

Subjects
Materials science, Silicon, Oxide, chemistry.chemical_element, 02 engineering and technology, Sputter deposition, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Anode, chemistry.chemical_compound, chemistry, Chemical engineering, Sputtering, General Materials Science, Lithium, Reactivity (chemistry), Thin film, 0210 nano-technology
Abstract

Silicon (Si) is a commonly studied candidate material for next-generation anodes in Li-ion batteries. A native oxide SiO2 on Si is often inevitable. However, it is not clear if this layer has a positive or negative effect on the battery performance. This understanding is complicated by the lack of knowledge about the physical properties of the SiO2 lithiation products and by the convolution of chemical and electrochemical effects during the anode lithiation process. In this study, Li xSiO y thin films as model materials for lithiated SiO2 were deposited by magnetron sputtering at ambient temperature, with the goal of (1) decoupling chemical reactivity from electrochemical reactivity and (2) evaluating the physical and electrochemical properties of Li xSiO y. X-ray photoemission spectroscopy analysis of the deposited thin films demonstrate that a composition close to previous experimental reports of lithiated native SiO2 can be achieved through sputtering. Our density functional theory calculations also confirm that the possible phases formed by lithiating SiO2 are very close to the measured film compositions. Scanning probe microscopy measurements show that the mechanical properties of the film are strongly dependent on lithium concentration, with a ductile behavior at a higher Li content and a brittle behavior at a lower Li content. The chemical reactivity of the thin films was investigated by measuring the AC impedance evolution, suggesting that Li xSiO y continuously reacts with the electrolyte, in part because of the high electronic conductivity of the film determined from solid-state impedance measurements. The electrochemical cycling data of the sputter-deposited Li xSiO y/Si films also suggest that Li xSiO y is not beneficial in stabilizing the Si anode surface during battery operation, despite its favorable mechanical properties.

Published
2018
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8. Mechanical Properties and Chemical Reactivity of Li

Author

Yun, Xu, Caleb, Stetson, Kevin, Wood, Eric, Sivonxay, Chunsheng, Jiang, Glenn, Teeter, Svitlana, Pylypenko, Sang-Don, Han, Kristin A, Persson, Anthony, Burrell, and Andriy, Zakutayev

Abstract

Silicon (Si) is a commonly studied candidate material for next-generation anodes in Li-ion batteries. A native oxide SiO

Published
2018

9. The lithiation process and Li diffusion in amorphous SiO2 and Si from first-principles

Author

Muratahan Aykol, Eric Sivonxay, and Kristin A. Persson

Subjects
Materials science, Silicon, General Chemical Engineering, Oxide, Analytical chemistry, Ionic bonding, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Thermal diffusivity, 01 natural sciences, 0104 chemical sciences, Anode, Amorphous solid, chemistry.chemical_compound, chemistry, Electrochemistry, Surface layer, 0210 nano-technology, Order of magnitude
Abstract

Silicon is considered the next-generation, high-capacity anode for Li-ion energy storage applications, however, despite significant effort, there are still uncertainties regarding the bulk Si and surface SiO 2 structural and chemical evolution as it undergoes lithiation and amorphization. In this paper, we present first-principles calculations of the evolution of the amorphous Si anode, including its oxide surface layer, as a function of Li concentration. We benchmark our methodology by comparing the results for the Si bulk to existing experimental evidence of local structure evolution, ionic diffusivity as well as electrochemical activity. Recognizing the important role of the surface Si oxide (either native or artificially grown), we undertake the same calculations for amorphous SiO 2 , analyzing its potential impact on the activity of Si anode materials. Derived voltage curves for the amorphous phases compare well to experimental results, highlighting that SiO 2 lithiates at approximately 0.7 V higher than Si in the low Li concentration regime, which provides an important electrochemical fingerprint. The combined evidence suggests that i) the inherent diffusivity of amorphous Si is high (in the order 10 − 9 cm 2 s − 1 - 10 − 7 cm 2 s − 1 ), ii) SiO 2 is thermodynamically driven to lithiate, such that Li–O local environments are increasingly favored as compared to Si–O bonding, iii) the ionic diffusivity of Li in Li y SiO 2 is initially two orders of magnitude lower than that of Li y Si at low Li concentrations but increases rapidly with increasing Li content and iv) the final lithiation product of SiO 2 is Li 2 O and highly lithiated silicides. Hence, this work suggests that - excluding explicit interactions with the electrolyte - the SiO 2 surface layer presents a kinetic impediment for the lithiation of Si and a sink for Li inventory, resulting in non-reversible capacity loss through strong local Li–O bond formation.

Published
2020
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10. Hydrothermal synthesis and characterization of the eulytite phase of bismuth germanium oxide powders

Author

James J. M. Griego, Mark A. Rodriguez, Patrick Doty, Nelson S. Bell, Andrew T. Velazquez, Bernadette A. Hernandez-Sanchez, Pin Yang, Bryan Kaehr, Timothy J. Boyle, Marlene Bencomo, and Eric Sivonxay

Subjects
Photoluminescence, Materials science, Scanning electron microscope, Mechanical Engineering, Inorganic chemistry, Analytical chemistry, chemistry.chemical_element, Condensed Matter Physics, Hydrothermal circulation, Bismuth, chemistry, Mechanics of Materials, Hydrothermal synthesis, General Materials Science, Luminescence, Single crystal, Germanium oxide
Abstract

A simple hydrothermal route to the eulytite phase of bismuth germanium oxide (E-BGO: Bi4(GeO4)3) that required no post-processing has been developed. The E-BGO material was isolated from a mixture of bismuth nitrate pentahydrate and a slight excess of germanium oxide in water under hydrothermal conditions (185 °C for 24 h). The resultant materials were characterized by powder x-ray diffraction, scanning electron microscopy, transmission electron microscopy, and luminescence measurements to verify the particle’s phase (eulytite), morphology, size, and response to a variety of excitation energy sources, respectively. Photoluminescence spectroscopic response from E-BGO pellets indicated that the samples exhibited a strong emission peak consistent with an x-ray induced luminescence of a E-BGO single crystal (500 nm excited at 285 nm). Cathodoluminescent properties of the E-BGO displayed a broadband spectrum with a maximum at 487 nm. The growth process was consistent with a standard Oswald ripening and LaMer growth processes.

Published
2014
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