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1. Distilling nanoscale heterogeneity of amorphous silicon using tip-enhanced Raman spectroscopy (TERS) via multiresolution manifold learning

Author

Guang Yang, Xin Li, Yongqiang Cheng, Mingchao Wang, Dong Ma, Alexei P. Sokolov, Sergei V. Kalinin, Gabriel M. Veith, and Jagjit Nanda

Subjects
Science
Abstract

Short range atomic ordering quantification and nanoscale spatial resolution over a large area for amorphous materials is crucial for accelerating technology development but remain challenges. Here, the authors explore nanoscale heterogeneity of amorphous silicon by tip-enhanced Raman spectroscopy via multiresolution manifold learning.

Published
2021
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3. Silicon Surface Tethered Polymer as Artificial Solid Electrolyte Interface

Author

Brian H. Shen, Gabriel M. Veith, and Wyatt E. Tenhaeff

Subjects
Medicine, Science
Abstract

Abstract We have developed a proof of concept electrode design to covalently graft poly(methyl methacrylate) brushes directly to silicon thin film electrodes via surface-initiated atom transfer radical polymerization. This polymer layer acts as a stable artificial solid electrolyte interface that enables surface passivation despite large volume changes during cycling. Thin polymer layers (75 nm) improve average first cycle coulombic efficiency from 62.4% in bare silicon electrodes to 76.3%. Average first cycle reversible capacity was improved from 3157 to 3935 mAh g−1, and average irreversible capacity was reduced from 2011 to 1020 mAh g−1. Electrochemical impedance spectroscopy performed on silicon electrodes showed that resistance from solid electrolyte interface formation increased from 79 to 1508 Ω in untreated silicon thin films over 26 cycles, while resistance growth was lower – from 98 to 498 Ω – in silicon films functionalized with PMMA brushes. The lower increase suggests enhanced surface passivation and lower electrolyte degradation. This work provides a pathway to develop artificial solid electrolyte interfaces synthesized under controlled reaction conditions.

Published
2018
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4. Li2O-Based Cathode Additives Enabling Prelithiation of Si Anodes

Author

Yeyoung Ha, Maxwell C. Schulze, Sarah Frisco, Stephen E. Trask, Glenn Teeter, Nathan R. Neale, Gabriel M. Veith, and Christopher S. Johnson

Subjects
lithium-ion batteries, silicon anodes, prelithiation, cathode additives, lithium oxide, cobalt oxide, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999
Abstract

Low first-cycle Coulombic efficiency is especially poor for silicon (Si)-based anodes due to the high surface area of the Si-active material and extensive electrolyte decomposition during the initial cycles forming the solid electrolyte interphase (SEI). Therefore, developing successful prelithiation methods will greatly benefit the development of lithium-ion batteries (LiBs) utilizing Si anodes. In pursuit of this goal, in this study, lithium oxide (Li2O) was added to a LiNi0.6Mn0.2Co0.2O2 (NMC622) cathode using a scalable ball-milling approach to compensate for the initial Li loss at the anode. Different milling conditions were tested to evaluate the impact of particle morphology on the additive performance. In addition, Co3O4, a well-known oxygen evolution reaction catalyst, was introduced to facilitate the activation of Li2O. The Li2O + Co3O4 additives successfully delivered an additional capacity of 1116 mAh/gLi2O when charged up to 4.3 V in half cells and 1035 mAh/gLi2O when charged up to 4.1 V in full cells using Si anodes.

Published
2021
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5. Determination of the Solid Electrolyte Interphase Structure Grown on a Silicon Electrode Using a Fluoroethylene Carbonate Additive

Author

Gabriel M. Veith, Mathieu Doucet, Robert L. Sacci, Bogdan Vacaliuc, J. Kevin Baldwin, and James F. Browning

Subjects
Medicine, Science
Abstract

Abstract In this work we explore how an electrolyte additive (fluorinated ethylene carbonate – FEC) mediates the thickness and composition of the solid electrolyte interphase formed over a silicon anode in situ as a function of state-of-charge and cycle. We show the FEC condenses on the surface at open circuit voltage then is reduced to C-O containing polymeric species around 0.9 V (vs. Li/Li+). The resulting film is about 50 Å thick. Upon lithiation the SEI thickens to 70 Å and becomes more organic-like. With delithiation the SEI thins by 13 Å and becomes more inorganic in nature, consistent with the formation of LiF. This thickening/thinning is reversible with cycling and shows the SEI is a dynamic structure. We compare the SEI chemistry and thickness to 280 Å thick SEI layers produced without FEC and provide a mechanism for SEI formation using FEC additives.

Published
2017
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6. Taming interfacial electronic properties of platinum nanoparticles on vacancy-abundant boron nitride nanosheets for enhanced catalysis

Author

Wenshuai Zhu, Zili Wu, Guo Shiou Foo, Xiang Gao, Mingxia Zhou, Bin Liu, Gabriel M. Veith, Peiwen Wu, Katie L. Browning, Ho Nyung Lee, Huaming Li, Sheng Dai, and Huiyuan Zhu

Subjects
Science
Abstract

Tuning electronic properties of metallic catalysts is a useful way to improve their activity, however control over metal-support interactions is still challenging. Here the authors report a vacancy-induced interfacial electronic effect for Pt assembled on vacancy-abundanth-BN nanosheets leading to superior CO oxidation catalysis.

Published
2017
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12. Relative Kinetics of Solid-State Reactions: The Role of Architecture in Controlling Reactivity

Author

Gabrielle E. Kamm, Guanglong Huang, Simon M. Vornholt, Rebecca D. McAuliffe, Gabriel M. Veith, Katsuyo S. Thornton, and Karena W. Chapman

Subjects
Colloid and Surface Chemistry, General Chemistry, Biochemistry, Catalysis
Abstract

Countless inorganic materials are prepared via high temperature solid-state reaction of mixtures of reagents powders. Understanding and controlling the phenomena that limit these solid-state reactions is crucial to designing reactions for new materials synthesis. Here, focusing on topotactic ion-exchange between NaFeO

Published
2022
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13. Study of Chromium Migration in a Nickel-Based Alloy Using Polarized Neutron Reflectometry and Rutherford Backscattering Spectrometry

Author

Mathieu Doucet, James F. Browning, Barney L. Doyle, Timothy R. Charlton, Haile Ambaye, Joohyun Seo, Alessandro R. Mazza, John F. Wenzel, George R. Burns, Ryan R. Wixom, and Gabriel M. Veith

Subjects
General Energy, Physical and Theoretical Chemistry, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials
Published
2022
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14. Calendar aging of silicon-containing batteries

Author

Marco-Tulio F. Rodrigues, Nathan R. Neale, Shelley D. Minteer, Brian Cunningham, Christopher A. Apblett, Gerard M. Carroll, Gabriel M. Veith, Andrew M. Colclasure, Anthony K. Burrell, Maxwell C. Schulze, John T. Vaughey, Josefine McBrayer, Chen Fang, Daniel P. Abraham, Gao Liu, Christopher S. Johnson, Katharine L. Harrison, and Ira Bloom

Subjects
Battery (electricity), Engineering, Silicon, Renewable Energy, Sustainability and the Environment, business.industry, Automotive industry, Energy Engineering and Power Technology, chemistry.chemical_element, Electronic, Optical and Magnetic Materials, Fuel Technology, chemistry, Risk analysis (engineering), Hardware_GENERAL, business
Abstract

High-energy batteries for automotive applications require cells to endure well over a decade of constant use, making their long-term stability paramount. This is particularly challenging for emerging cell chemistries containing silicon, for which extended testing information is scarce. While much of the research on silicon anodes has focused on mitigating the consequences of volume changes during cycling, comparatively little is known about the time-dependent degradation of silicon-containing batteries. Here we discuss a series of studies on the reactivity of silicon that, collectively, paint a picture of how the chemistry of silicon exacerbates the calendar aging of lithium-ion cells. Assessing and mitigating this shortcoming should be the focus of future research to fully realize the benefits of this battery technology. Silicon-containing batteries are increasingly becoming a reality in the mass market, but their calendar aging behaviours have received comparatively little attention. Researchers from the Silicon Consortium Project discuss the issues surrounding the calendar lifetime of silicon anodes for lithium-ion batteries.

Published
2021
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15. Role of Pairwise Reactions on the Synthesis of Li0.3La0.57TiO3 and the Resulting Structure–Property Correlations

Author

Valentino R. Cooper, Thomas F. Malkowski, Gabriel M. Veith, Robert L. Sacci, Nancy J. Dudney, Shree Ram Acharya, and Rebecca D. McAuliffe

Subjects
Inorganic Chemistry, Tetragonal crystal system, chemistry, Chemical physics, Phase (matter), Thermal decomposition, chemistry.chemical_element, Lithium, Grain boundary, Crystal structure, Physical and Theoretical Chemistry, Stoichiometry, Perovskite (structure)
Abstract

The performance of single-ion conductors is highly sensitive to the material's defect chemistry. Tuning these defects is limited for solid-state reactions as they occur at particle-particle interfaces, which provide a complex evolving energy landscape for atomic rearrangement and product formation. In this report, we investigate the (1) order of addition and (2) lithium precursor decomposition temperature and their effect on the synthesis and grain boundary conductivity of the perovskite lithium lanthanum titanium oxide (LLTO). We use an intimately mixed sol-gel, a solid-state reaction of Li precursor + La2O3 + TiO2, and Li precursor + amorphous La0.57TiOx as different chemical routes to change the way in which the elements are brought together. The results show that the perovskite can accommodate a wide range of Li deficiencies (upward of 50%) while maintaining the tetragonal LLTO structure, indicating that X-ray diffraction (XRD) is insufficient to fully characterize the chemical nature of the product (i.e., Li-deficient LLTO may behave differently than stoichiometric LLTO). Variations in the relative intensities of different reflections in XRD suggest variations in the La ordering within the crystal structure between synthesis methods. Furthermore, the choice of the precursor and the order of addition of the reactants lower the time required to form a pure phase. Density functional theory calculations of the formation energy of possible reaction intermediates support the hypothesis that a greater thermodynamic driving force to form LLTO leads to a greater LLTO yield. The retention of lithium is correlated with the thermal decomposition temperature of the Li precursor and the starting material mixing strategy. Taking the results together suggests that cations that share a site with Li should be mixed early to avoid ordering. Such cation ordering inhibits Li motion, leading to higher Li ion resistance.

Published
2021
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16. La2Zr2O7 Nanoparticle-Mediated Synthesis of Porous Al-Doped Li7La3Zr2O12 Garnet

Author

Robert L. Sacci, Gabriel M. Veith, Beth L. Armstrong, Thomas F. Malkowski, Melanie J. Kirkham, X. Chelsea Chen, Luke L. Daemen, Nathan Kidder, Ashfia Huq, and Rebecca D. McAuliffe

Subjects
010405 organic chemistry, Chemistry, Doping, Mixing (process engineering), Nanoparticle, Ionic bonding, chemistry.chemical_element, 010402 general chemistry, 01 natural sciences, Decomposition, 0104 chemical sciences, Inorganic Chemistry, Chemical engineering, Phase (matter), Lithium, Physical and Theoretical Chemistry, Porosity
Abstract

In this work, we modified the reaction pathway to quickly (minutes) incorporate lithium and stabilize the ionic conducting garnet phase by decoupling the formation of a La-Zr-O network from the addition of lithium. To do this, we synthesized La2Zr2O7 (LZO) nanoparticles to which LiNO3 was added. This method is a departure from typical solid-state synthesis methods that require high-energy milling to promote mixing and intimate particle-particle contact and from sol-gel syntheses as a unique porous microstructure is obtained. We show that the reaction time is limited by the rate of nitrate decomposition and that this method produces a porous high-Li-ion-conducting cubic phase, within an hour, that may be used as a starting structure for a composite electrolyte.

Published
2021
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17. Role of Low Molecular Weight Polymers on the Dynamics of Silicon Anodes During Casting

Author

Stephen E. Trask, Ryan Murphy, Alexander M. Rogers, Beth L. Armstrong, Mary K. Burdette-Trofimov, Mathieu Doucet, Gabriel M. Veith, and Luke Heroux

Subjects
chemistry.chemical_classification, Materials science, Silicon, chemistry.chemical_element, 02 engineering and technology, Polymer, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Casting, Dispersant, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, Shear rate, chemistry.chemical_compound, chemistry, Chemical engineering, Agglomerate, Slurry, Physical and Theoretical Chemistry, 0210 nano-technology, Acrylic acid
Abstract

This work probes the slurry architecture of a high silicon content electrode slurry with and without low molecular weight polymeric dispersants as a function of shear rate to mimic electrode casting conditions for poly(acrylic acid) (PAA) and lithium neutralized poly(acrylic acid) (LiPAA) based electrodes. Rheology coupled ultra-small angle neutron scattering (rheo-USANS) was used to examine the aggregation and agglomeration behavior of each slurry as well as the overall shape of the aggregates. The addition of dispersant has opposing effects on slurries made with PAA or LiPAA binder. With a dispersant, there are fewer aggregates and agglomerates in the PAA based silicon slurries, while LiPAA based silicon slurries become orders of magnitude more aggregated and agglomerated at all shear rates. The reorganization of the PAA and LiPAA binder in the presence of dispersant leads to a more homogeneous slurry and a more heterogeneous slurry, respectively. This reorganization ripples through to the cast electrode architecture and is reflected in the electrochemical cycling of these electrodes.

Published
2021
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18. Probing Clustering Dynamics between Silicon and PAA or LiPAA Slurries under Processing Conditions

Author

Gabriel M. Veith, Mary K. Burdette-Trofimov, Luke Heroux, Beth L. Armstrong, Ryan Murphy, Mathieu Doucet, and Alexander M. Rogers

Subjects
chemistry.chemical_compound, Materials science, Polymers and Plastics, Silicon, chemistry, Chemical engineering, Economies of agglomeration, Process Chemistry and Technology, Organic Chemistry, Slurry, chemistry.chemical_element, Cluster analysis, Acrylic acid
Abstract

This work explores the complex interplay between slurry aggregation, agglomeration, and conformation (i.e., shape) of poly(acrylic acid) (PAA)- and lithiated PAA-based silicon slurries as a functio...

Published
2021
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19. An anode-free Li metal cell with replenishable Li designed for long cycle life

Author

Haodong Liu, Zhaohui Wu, Yejing Li, Yoonjung Choi, John Holoubek, Hongyao Zhou, Sicen Yu, Ping Liu, Meng Hu, Gabriel M. Veith, and Xing Xing

Subjects
Battery (electricity), Long cycle, Materials science, Stripping (chemistry), Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Anode, Corrosion, Metal, Chemical engineering, visual_art, visual_art.visual_art_medium, Energy density, General Materials Science, 0210 nano-technology
Abstract

Pit corrosion of Li during stripping is an important factor responsible for poor Li cycling efficiency, a metric that determines its cycling life. When excess Li is present, it has been observed that Li tends to strip in a non-uniform fashion, forming pits that extend well past the theoretical Li depth that inevitably lead to the formation of electronically isolated “dead” Li particles. In this work, a novel cell with replenishable Li is shown to inherently mitigate the formation of this “dead” Li, as a direct result of a design in which the intrinsically more homogenous stripping behavior of anode-free cells are combined with a replenishable limited Li reservoir. These novel cells (Li|Cu||LiFePO4) exhibit 25% and 34% higher cumulative capacities than the conventional cells (Cu|Li||LiFePO4) in carbonate and ether electrolytes, respectively, enabling a significant increase in cycle life without impacting energy density. This improvement strategy represents a new direction in Li metal battery improvement, in which improved cycling can be achieved regardless of electrolyte chemistry.

Published
2021
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20. Quantification of the ion transport mechanism in protective polymer coatings on lithium metal anodes†

Author

Gabriel M. Veith, Haodong Liu, Ping Liu, Hongyao Zhou, Xing Xing, Sicen Yu, and Zijun Wang

Subjects
chemistry.chemical_classification, Materials science, chemistry.chemical_element, General Chemistry, Polymer, Electrolyte, Conductivity, Solvent, Hildebrand solubility parameter, Chemistry, chemistry, Chemical engineering, Phase (matter), Chemical Sciences, medicine, Lithium, Swelling, medicine.symptom
Abstract

Protective Polymer Coatings (PPCs) have been proposed to protect lithium metal anodes in rechargeable batteries to stabilize the Li/electrolyte interface and to extend the cycle life by reducing parasitic reactions and improving the lithium deposition morphology. However, the ion transport mechanism in PPCs remains unclear. Specifically, the degree of polymer swelling in the electrolyte and the influence of polymer/solvent/ion interactions are never quantified. Here we use poly(acrylonitrile-co-butadiene) (PAN–PBD) with controlled cross-link densities to quantify how the swelling ratio of the PPC affects conductivity, Li+ ion selectivity, activation energy, and rheological properties. The large difference in polarities between PAN (polar) and PBD (non-polar) segments allows the comparison of PPC properties when swollen in carbonate (high polarity) and ether (low polarity) electrolytes, which are the two most common classes of electrolytes. We find that a low swelling ratio of the PPC increases the transference number of Li+ ions while decreasing the conductivity. The activation energy only increases when the PPC is swollen in the carbonate electrolyte because of the strong ion–dipole interaction in the PAN phase, which is absent in the non-polar PBD phase. Theoretical models using Hansen solubility parameters and a percolation model have been shown to be effective in predicting the swelling behavior of PPCs in organic solvents and to estimate the conductivity. The trade-off between conductivity and the transference number is the primary challenge for PPCs. Our study provides general guidelines for PPC design, which favors the use of non-polar polymers with low polarity organic electrolytes., Protective Polymer Coatings (PPCs) protect lithium metal anodes in rechargeable batteries to stabilize the Li/electrolyte interface and to extend the cycle life by reducing parasitic reactions and improving the lithium deposition morphology.

Published
2021

21. XPCS Microrheology and Rheology of Sterically Stabilized Nanoparticle Dispersions in Aprotic Solvents

Author

Yugang Zhang, Surita R. Bhatia, Lutz Wiegart, Weiping Liu, Bingqian Zheng, Xuechen Yin, Gabriel M. Veith, Xiaoxi Yu, Andrei Fluerasu, and Beth L. Armstrong

Subjects
Microrheology, chemistry.chemical_classification, Materials science, Rheometry, 020209 energy, Nanoparticle, 02 engineering and technology, Polymer, 021001 nanoscience & nanotechnology, Rheology, Chemical engineering, chemistry, Dynamic light scattering, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Particle size, 0210 nano-technology, Complex fluid
Abstract

X-ray photon correlation spectroscopy (XPCS) microrheology and conventional bulk rheology were performed on silica nanoparticle dispersions associated with battery electrolyte applications to probe the properties of these specific complex materials and to explore the utility of XPCS microrheology in characterizing nanoparticle dispersions. Sterically stabilized shear-thickening electrolytes were synthesized by grafting poly(methyl methacrylate) chains onto silica nanoparticles. Coated silica dispersions containing 5-30 wt % nanoparticles dispersed in propylene carbonate were studied. In general, both XPCS microrheology and conventional rheology showed that coated silica dispersions were more viscous at higher concentrations, as expected. The complex viscosity of coated silica dispersions showed shear-thinning behavior over the frequency range probed by XPCS measurements. However, measurements using conventional mechanical rheometry yielded a shear viscosity with weak shear-thickening behavior for dispersions with the highest concentration of 30% particles. Our results indicate that there is a critical concentration needed for shear-thickening behavior, as well as appropriate particle size and surface polymer chain length, for this class of nanoparticle-based electrolytes. The results of this study can provide insights for comparing XPCS microrheology and bulk rheology for related complex fluids and whether XPCS microrheology can capture expected macroscopic rheological properties by probing small-scale particle dynamics.

Published
2021
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22. Solid-State Synthesis of Conjugated Nanoporous Polycarbazoles

Author

Tian Jin, Sheng Dai, Gabriel M. Veith, Xiang Zhu, Katie L. Browning, Robert L. Sacci, and Chengcheng Tian

Subjects
chemistry.chemical_classification, Materials science, Polymers and Plastics, Nanoporous, Organic Chemistry, Solid-state, Rational design, Nanotechnology, 02 engineering and technology, Polymer, Conjugated system, Co2 storage, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Inorganic Chemistry, chemistry, Polymerization, Materials Chemistry, Oxidative coupling of methane, 0210 nano-technology
Abstract

A novel solid-state synthetic approach has been developed for the generation of conjugated nanoporous polymer networks. Using mechanochemical-assisted oxidative coupling polymerization, we demonstrated a rapid and solvent-free synthesis of conjugated polycarbazoles with high porosities and promising CO2 storage abilities. This innovative approach constitutes a new direction for the development of novel nanoporous polymer frameworks through sustainable solid-state assembly pathways, and may open up new possibilities for the rational design and synthesis of nanoporous materials for carbon capture.

Published
2022

23. Understanding the Solution Dynamics and Binding of a PVDF Binder with Silicon, Graphite, and NMC Materials and the Influence on Cycling Performance

Author

Mary K. Burdette-Trofimov, Beth L. Armstrong, Rachel J. Korkosz, J. Landon Tyler, Rebecca D. McAuliffe, Luke Heroux, Mathieu Doucet, David T. Hoelzer, Nihal Kanbargi, Amit K. Naskar, and Gabriel M. Veith

Subjects
General Materials Science
Abstract

The impact of the binding, solution structure, and solution dynamics of poly(vinylidene fluoride) (PVDF) with silicon on its performance as compared to traditional graphite and Li

Published
2022

24. Elucidating Interfacial Stability between Lithium Metal Anode and Li Phosphorus Oxynitride via In Situ Electron Microscopy

Author

Xi Chen, Nancy J. Dudney, Robert L. Sacci, Miaofang Chi, Gabriel M. Veith, Junjie Niu, Yifei Mo, Zachary D. Hood, and Xiaoming Liu

Subjects
Materials science, Passivation, Mechanical Engineering, Bioengineering, Biasing, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Electrochemistry, Anode, Chemical engineering, Fast ion conductor, General Materials Science, 0210 nano-technology, Layer (electronics), Faraday efficiency, Electrochemical window
Abstract

Li phosphorus oxynitride (LiPON) is one of a very few solid electrolytes that have demonstrated high stability against Li metal and extended cyclability with high Coulombic efficiency for all solid-state batteries (ASSBs). However, theoretical calculations show that LiPON reacts with Li metal. Here, we utilize in situ electron microscopy to observe the dynamic evolutions at the LiPON-Li interface upon contacting and under biasing. We reveal that a thin interface layer (∼60 nm) develops at the LiPON-Li interface upon contact. This layer is composed of conductive binary compounds that show a unique spatial distribution that warrants an electrochemical stability of the interface, serving as an effective passivation layer. Our results explicate the excellent cyclability of LiPON and reconcile the existing debates regarding the stability of the LiPON-Li interface, demonstrating that, though glassy solid electrolytes may not have a perfect initial electrochemical window with Li metal, they may excel in future applications for ASSBs.

Published
2020
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25. Ru supported on micro and mesoporous carbons as catalysts for biomass-derived molecules hydrogenation

Author

Gabriel M. Veith, Marta Stucchi, Laura Prati, Di Wang, Alberto Villa, Wu Wang, and Stefano Cattaneo

Subjects
Chemistry, Nanoparticle, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Catalysis, 0104 chemical sciences, Ruthenium, chemistry.chemical_compound, Chemical engineering, Catalytic cycle, Levulinic acid, Leaching (metallurgy), 0210 nano-technology, Selectivity, Mesoporous material
Abstract

Supported ruthenium based materials are active for the catalytic hydrogenation of biomass-derived molecules. However, such catalysts still have problems regarding deactivation coming from Ru leaching and particles aggregation. In this work we demonstrate that spatial restriction on metal nanoparticles limits aggregation and eliminates performance losses upon subsequent testing. We synthesized and compared Ru supported on activated (Ru/AC) or mesoporous carbon (Ru/MC). Electron tomography characterization showed preferential Ru location depending on the material porosity; Ru nanoparticles were located inside mesoporous carbon pores and showed narrower size distribution. In catalytic reactions, Ru/MC reached the complete conversion of levulinic acid with the 96% selectivity to γ-valerolactone while it converted 74% of glycerol compared to the 34% showed by Ru/AC. The Ru/AC materials deactivated after 1 catalytic cycle, however the Ru/MC maintained constant activity for multiple catalytic cycles.

Published
2020
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27. Ambient Temperature Graphitization Based on Mechanochemical Synthesis

Author

Hao Chen, Tao Wang, Zhenzhen Yang, Yating Yuan, Shannon M. Mahurin, Sheng Dai, Huimin Luo, and Gabriel M. Veith

Subjects
Materials science, 010405 organic chemistry, General Medicine, General Chemistry, Thermal treatment, 010402 general chemistry, 01 natural sciences, Catalysis, Lithium-ion battery, 0104 chemical sciences, Crystallinity, chemistry.chemical_compound, Chemical engineering, chemistry, Mechanochemistry, Graphite, Carbon nitride, Acheson process, Nanosheet
Abstract

Graphite has become a critical material because of its high supply risk and essential applications in energy industries. Its present synthesis still relies on an energy-intensive thermal treatment pathway (Acheson process) at about 3000 °C. Herein, a mechanochemical approach is demonstrated to afford highly crystalline graphite nanosheets at ambient temperature. The key to the success of our methodology lies in the successive decomposition and rearrangement of a carbon nitride framework driven by a denitriding reaction in the presence of magnesium. The afforded graphite features high crystallinity, a high degree of graphitization, a thin nanosheet architecture, and a small flake size, which endow it with superior efficiency in lithium-ion batteries as an anode material in terms of rate capacity and cycle stability. The mild and cost-effective pathway used in this study could be a promising alternative for graphite production.

Published
2020
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29. Defect-Accommodating Intermediates Yield Selective Low-Temperature Synthesis of YMnO3 Polymorphs

Author

Paul K. Todd, James R. Neilson, Gabriel M. Veith, Gia Thinh Tran, Karena W. Chapman, Brennan C. McBride, Matthew J. McDermott, Shyam Dwaraknath, Simon J. L. Billinge, Rebecca D. McAuliffe, Ethan D. Boeding, Kristin A. Persson, Daniel O'Nolan, Allison Wustrow, Ashfia Huq, and Chia-Hao Liu

Subjects
Chemistry, Spinel, Neutron diffraction, Disproportionation, engineering.material, Metathesis, Inorganic Chemistry, Tetragonal crystal system, Crystallography, Yield (chemistry), engineering, Orthorhombic crystal system, Physical and Theoretical Chemistry, Ternary operation
Abstract

In the synthesis of complex oxides, solid-state metathesis provides low-temperature reactions where product selectivity can be achieved through simple changes in precursor composition. The influence of precursor structure, however, is less understood in solid-state synthesis. Here we present the ternary metathesis reaction (LiMnO2 + YOCl → YMnO3 + LiCl) to target two yttrium manganese oxide products, hexagonal and orthorhombic YMnO3, when starting from three different LiMnO2 precursors. Using temperature-dependent synchrotron X-ray and neutron diffraction, we identify the relevant intermediates and temperature regimes of reactions along the pathway to YMnO3. Manganese-containing intermediates undergo a charge disproportionation into a reduced Mn(II,III) tetragonal spinel and oxidized Mn(III,IV) cubic spinel, which lead to hexagonal and orthorhombic YMnO3, respectively. Density functional theory calculations confirm that the presence of Mn(IV) caused by a small concentration of cation vacancies (∼2.2%) in YMnO3 stabilizes the orthorhombic polymorph over the hexagonal. Reactions over the course of 2 weeks yield o-YMnO3 as the majority product at temperatures below 600 °C, which supports an equilibration of cation defects over time. Controlling the composition and structure of these defect-accommodating intermediates provides new strategies for selective synthesis of complex oxides at low temperatures.

Published
2020
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30. Electrochemical Reactivity and Passivation of Silicon Thin-Film Electrodes in Organic Carbonate Electrolytes

Author

Liang Zhang, Gabriel M. Veith, Jinghua Guo, Wan-Yu Tsai, Philip N. Ross, Ivana Hasa, Atetegeb Meazah Haregewoin, and Robert Kostecki

Subjects
Amorphous silicon, Materials science, Silicon, Passivation, thin film, 020209 energy, chemistry.chemical_element, lithium-ion battery, 02 engineering and technology, Electrolyte, lithium ethylene decarbonate, Lithium-ion battery, chemistry.chemical_compound, Engineering, solid electrolyte interphase, SEI breathing, silicon anode, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, passivation, Dicarbonate, Nanoscience & Nanotechnology, Thin film, interfacial reactivity, 021001 nanoscience & nanotechnology, chemistry, Chemical engineering, Attenuated total reflection, Chemical Sciences, 0210 nano-technology
Abstract

This work focuses on the mechanisms of interfacial processes at the surface of amorphous silicon thin-film electrodes in organic carbonate electrolytes to unveil the origins of the inherent nonpassivating behavior of silicon anodes in Li-ion batteries. Attenuated total reflection Fourier-transform infrared spectroscopy, X-ray absorption spectroscopy, and infrared near-field scanning optical microscopy were used to investigate the formation, evolution, and chemical composition of the surface layer formed on Si upon cycling. We found that the chemical composition and thickness of the solid/electrolyte interphase (SEI) layer continuously change during the charging/discharging cycles. This SEI layer "breathing" effect is directly related to the formation of lithium ethylene dicarbonate (LiEDC) and LiPF6 salt decomposition products during silicon lithiation and their subsequent disappearance upon delithiation. The detected appearance and disappearance of LiEDC and LiPF6 decomposition compounds in the SEI layer are directly linked with the observed interfacial instability and poor passivating behavior of the silicon anode.

Published
2020
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31. Goldilocks and the three glymes: How Na+ solvation controls Na–O2 battery cycling

Author

Gabriel M. Veith, I. Ruiz de Larramendi, Javier Carrasco, N. Ortiz Vitoriano, Oier Arcelus, Teófilo Rojo, Marina Enterría, Robert L. Sacci, Craig A. Bridges, and Iñigo Lozano

Subjects
Battery (electricity), Materials science, Renewable Energy, Sustainability and the Environment, Solvation, Energy Engineering and Power Technology, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, 0104 chemical sciences, Solvent, Tetraethylene glycol dimethyl ether, chemistry.chemical_compound, chemistry, Chemical engineering, General Materials Science, Dimethyl ether, 0210 nano-technology, Ethylene glycol
Abstract

In this work we report a framework to understand the role of solvent-salt interactions and how they mediate the performance of sodium-air/O2 batteries. The utilization of suitable electrolyte materials remains a point of major concern within the research community, as their stability and decomposition pathways during cycling are intimately connected with capacity and cycle life. Glyme based solvents have been widely utilized in Na–O2 batteries, however, to date no clear correlation between solvent/electrolyte properties and battery performance has been given. Herein, we have examined the effect of glyme chain length (ethylene glycol dimethyl ether DME; diethylene glycol dimethyl ether, DEGDME; and tetraethylene glycol dimethyl ether, TEGME) on the cycling behaviour of Na–O2 batteries and conclude that overall cell performance is highly dependent on solvent selection, salt concentration and rate of discharge/charge. We demonstrate how solvent selection helps define cell chemistry and performance by linking salt-solvent interactions to enthalpy of dissolution - and subsequently to sodium battery electrolyte properties - through the combination of both experimental and theoretical methodologies. The approaches detailed in this study could be used to predictively prepare electrolytes for Li-air batteries, other glyme-based electrochemical systems and low temperature applications.

Published
2020
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32. Investigating the Chemical Reactivity of Lithium Silicate Model SEI Layers

Author

Gabriel M. Veith, Christopher A. Apblett, Michael T. Brumbach, and Jaclyn Coyle

Subjects
Materials science, Silicon, chemistry.chemical_element, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Silicate, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Anode, chemistry.chemical_compound, General Energy, chemistry, Chemical engineering, Interphase, Lithium, Physical and Theoretical Chemistry, Fade, 0210 nano-technology, Layer (electronics)
Abstract

Silicon anodes suffer from an unstable solid electrolyte interphase (SEI) layer that contributes to undesirable capacity fade with cycling. A key part to addressing this unstable SEI formation is t...

Published
2020
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33. Intrinsic Chemical Reactivity of Silicon Electrode Materials: Gas Evolution

Author

Kevin A. Hays, Robert L. Sacci, Ryan R. Armstrong, Christopher A. Apblett, Tyler H. Bennet, Beth L. Armstrong, Nathan R. Neale, Claire L. Seitzinger, Gabriel M. Veith, Jaclyn Coyle, and Alexander M. Rogers

Subjects
chemistry.chemical_classification, Work (thermodynamics), Materials science, Silicon, General Chemical Engineering, Gas evolution reaction, Battery electrolyte, Salt (chemistry), chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, chemistry, Chemical engineering, Materials Chemistry, Lithium, sense organs, skin and connective tissue diseases, 0210 nano-technology, Silicon electrode
Abstract

In this work, we explore how the chemical reactivity toward an aprotic battery electrolyte changes as a function of lithium salt and silicon surface termination chemistry. The reactions are highly ...

Published
2020
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35. Digestion processes and elemental analysis of oxide and sulfide solid electrolytes

Author

Thomas F. Malkowski, Ethan D. Boeding, Dina Fattakhova-Rohlfing, Nadine Wettengl, Martin Finsterbusch, and Gabriel M. Veith

Subjects
General Chemical Engineering, General Engineering, General Physics and Astronomy, General Materials Science, ddc:530, Physik (inkl. Astronomie)
Abstract

Detailed elemental analysis is essential for a successful development and optimization of material systems and synthesis methods. This is especially relevant for Li- and Na-containing compounds, found in state-of-the-art and next-generation battery systems. Their materials’ properties and thus the final device performance strongly depend on the crystal structure, the stoichiometry, and defect chemistry, e.g., influencing charge carrier concentration and activation energies for vacancy transport. However, a detailed quantitative analysis of light elements in a heavy matrix, featuring a broad range of solubilities and vapor pressures, is often difficult and associated with large uncertainties and thus neglected in favor of just reporting the stoichiometry as “weighed in.” In this work, we report several approaches to digest and dissolve various oxide and sulfide-based materials, used in next-generation Li batteries, for elemental analysis via optical emission spectroscopy. These include the most common solid electrolytes Li-La-Ti–O, a perovskite material (LLTO), and Li-La-Zr-O which has garnet structure (LLZO). Additionally, a facile thermal digestion process is reported for a surrogate sulfide solid electrolyte (Na2S). The digestion procedures reported here are suitable for almost any laboratory environment and, when applied, will improve understanding of the synthesis-structure–property correlations needed to advanced batteries with all solid-state configurations.

Published
2022
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36. A high temperature cell for investigating interfacial structure on the molecular scale in molten salt/alloy systems

Author

James F. Browning, Joohyun Seo, John F. Wenzel, Gabriel M. Veith, Mathieu Doucet, Alexander S. Ivanov, Phillip Halstenberg, Gary Lynn, and Sheng Dai

Subjects
Instrumentation
Abstract

In this work, we describe the design and development of an in situ neutron reflectometry cell for high temperature investigations of structural changes occurring at the interface between inorganic salts, in their molten state up to 800 °C, and corrosion resistant alloys or other surfaces. In the cell, a molten salt is confined by an annular ring of single crystal sapphire constrained between the sample substrate and a sapphire plate using two gold O-rings, enclosing a liquid salt volume of 20 ml, along with a dynamic cell volume to accommodate expansion of the liquid with heating. As a test case for the cell, we report on an in situ neutron reflectometry measurement of the interface between a eutectic salt mixture of MgCl

Published
2022

37. Stable SEI Formation on Al-Si-Mn Metallic Glass Li-Ion Anode

Author

Terri C. Lin, Xin He, Manuel Schnabel, Insun Yoon, Gabriel M. Veith, Elisabetta Arca, and Robert Kostecki

Subjects
Amorphous metal, Materials science, Energy, Silicon, Passivation, Renewable Energy, Sustainability and the Environment, chemistry.chemical_element, Splat quenching, Electrolyte, Materials Engineering, Condensed Matter Physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Anode, Amorphous solid, Macromolecular and Materials Chemistry, chemistry, Chemical engineering, Materials Chemistry, Electrochemistry, Lithium, Physical Chemistry (incl. Structural)
Abstract

Alloying anodes such as silicon are of great interest for lithium-ion batteries due to their high lithium-ion storage capacities, but have only seen minimal commercial deployment due to their limited calendar life. This has been attributed to an intrinsically unstable solid electrolyte interphase (SEI) that is aggravated by mechanical failure. An amorphous structure can mitigate lithiation strains, and amorphous alloys, or metallic glasses, often exhibit exceptional fracture toughness. Additional elements can be added to metallic glasses to improve passivation. Splat quenching was utilized to prepare an amorphous Al64Si25Mn11 Li-ion anode with a specific capacity >900 mAh g-1 that remains amorphous upon cycling. On this metallic glass electrode, parasitic electrolyte reduction is found to be much reduced in comparison to pure Si or Al, and comparable to that on Cu. The SEI is much thinner, more stable, and richer in fluorinated inorganic phases than the SEI formed on Si, while organic carbonate compounds such as lithium ethylene decarbonate (LiEDC) are notably absent. This study indicates that metallic glasses can become a viable new class of Li-ion anode materials with improved surface passivity.

Published
2021

38. Role of Pairwise Reactions on the Synthesis of Li

Author

Thomas F, Malkowski, Robert L, Sacci, Rebecca D, McAuliffe, Shree Ram, Acharya, Valentino R, Cooper, Nancy J, Dudney, and Gabriel M, Veith

Abstract

The performance of single-ion conductors is highly sensitive to the material's defect chemistry. Tuning these defects is limited for solid-state reactions as they occur at particle-particle interfaces, which provide a complex evolving energy landscape for atomic rearrangement and product formation. In this report, we investigate the (1) order of addition and (2) lithium precursor decomposition temperature and their effect on the synthesis and grain boundary conductivity of the perovskite lithium lanthanum titanium oxide (LLTO). We use an intimately mixed sol-gel, a solid-state reaction of Li precursor + La

Published
2021

39. Structure and dynamics of small polyimide oligomers with silicon as a function of aging

Author

Luke Heroux, Gabriel M. Veith, Mathieu Doucet, Beth L. Armstrong, Mary K. Burdette-Trofimov, and Robert L. Sacci

Subjects
Materials science, Silicon, chemistry.chemical_element, General Chemistry, Condensed Matter Physics, Casting, Dispersant, Anode, stomatognathic diseases, Chemical engineering, chemistry, Agglomerate, Electrode, UV curing, Polyimide
Abstract

The effect of UV curing and shearing on the structure and behavior of a polyimide (PI) binder as it disperses silicon particles in a battery electrode slurry was investigated. PI dispersant effectiveness increases with UV curing time, which controls the overall binder molecular weight. The shear force during electrode casting causes higher molecular weight PI to agglomerate, resulting in battery anodes with poorly dispersed Si particles that do not cycle well. It is hypothesized that when PI binder is added above a critical amount, it conformally coats the silicon particles and greatly impedes Li ion transport. There is an “interzonal region” for binder loading where it disperses silicon well and provides a coverage that facilitates Li transport through the anode material and into the silicon particles. These results have implications in ensuring reproducible electrode manufacturing and increasing cell performance by optimizing the PI structure and coordination with the silicon precursor.

Published
2021

40. The Study of the Binder Poly(acrylic acid) and Its Role in Concomitant Solid–Electrolyte Interphase Formation on Si Anodes

Author

Gabriel M. Veith, Katie L. Browning, James F. Browning, Mathieu Doucet, Joshua R. Kim, and Robert L. Sacci

Subjects
In situ, Materials science, education, technology, industry, and agriculture, 02 engineering and technology, Electrolyte, Quartz crystal microbalance, biochemical phenomena, metabolism, and nutrition, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Anode, chemistry.chemical_compound, chemistry, Chemical engineering, General Materials Science, Interphase, Neutron reflectometry, 0210 nano-technology, Chemical composition, Acrylic acid
Abstract

We use neutron reflectometry to study how the polymeric binder, poly(acrylic acid) (PAA), affects the in situ formation and chemical composition of the solid-electrolyte interphase (SEI) formation on a silicon anode at various states of charge. The reflectivity is correlated with electrochemical quartz crystal microbalance to better understand the viscoelastic effects of the polymer during cycling. The use of model thin films allows for a well-controlled interface between the amorphous Si surface and the PAA layer. If the PAA perfectly coats the Si surface and standard processing conditions are used, the binder will prevent the lithiation of the anode. The PAA suppresses the growth of a new layer formed at early states of discharge (open circuit voltage to 0.8 V vs Li/Li

Published
2020
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41. Structural Degradation of High Voltage Lithium Nickel Manganese Cobalt Oxide (NMC) Cathodes in Solid-State Batteries and Implications for Next Generation Energy Storage

Author

Claus Daniel, Andrew S. Westover, Gabriel M. Veith, and Nathan D. Phillip

Subjects
Materials science, Energy Engineering and Power Technology, chemistry.chemical_element, High voltage, Electrolyte, Cathode, Energy storage, law.invention, Nickel, chemistry, Chemical engineering, law, Materials Chemistry, Electrochemistry, Chemical Engineering (miscellaneous), Solid-state battery, Lithium, Electrical and Electronic Engineering, Cobalt oxide
Abstract

In this study, we report the stability of the layered high voltage cathode NMC622 with respect to a standard liquid electrolyte and in an all solid-state configuration. NMC622 cathodes with a (104)...

Published
2020
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42. 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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43. Dynamic Lithium Distribution upon Dendrite Growth and Shorting Revealed by Operando Neutron Imaging

Author

Gabriel M. Veith, Jue Liu, John C. Carothers, Ashfia Huq, Indu Dhiman, Hassina Z. Bilheux, and Bohang Song

Subjects
Materials science, Renewable Energy, Sustainability and the Environment, Neutron imaging, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Energy storage, 0104 chemical sciences, Dendrite (crystal), Fuel Technology, chemistry, Chemistry (miscellaneous), Chemical physics, Materials Chemistry, Lithium, 0210 nano-technology
Abstract

Lithium (Li) metal has the highest theoretical capacity and is essential for energy storage technologies beyond conventional Li chemistries. However, its utilization inevitably leads to dendrite gr...

Published
2019
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44. High‐Voltage Performance of Ni‐Rich NCA Cathodes: Linking Operating Voltage with Cathode Degradation

Author

Rose E. Ruther, David L. Wood, Lamuel David, Hsin Wang, Linxiao Geng, Harry M. Meyer, Debasish Mohanty, Ercan Cakmak, Gabriel M. Veith, and Athena S. Sefat

Subjects
Materials science, business.industry, High voltage, Electrochemistry, Magnetic susceptibility, Catalysis, Cathode, law.invention, Cathode degradation, law, Optoelectronics, Operating voltage, business
Published
2019
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45. Unraveling the Nanoscale Heterogeneity of Solid Electrolyte Interphase Using Tip-Enhanced Raman Spectroscopy

Author

Michael Naguib, Guang Yang, Xin Li, Rose E. Ruther, Dmitry Voylov, Gabriel M. Veith, Alexei P. Sokolov, Ting-Zheng Hou, Jagjit Nanda, and Kristin A. Persson

Subjects
Amorphous silicon, Materials science, Silicon, chemistry.chemical_element, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, 0104 chemical sciences, Anode, chemistry.chemical_compound, symbols.namesake, General Energy, Chemical engineering, chemistry, symbols, Lithium, Thin film, 0210 nano-technology, Raman spectroscopy
Abstract

Summary We employ tip-enhanced Raman spectroscopy (TERS) to study model amorphous silicon (a-Si) thin film anodes galvanostatically cycled for different numbers. For the 1× cycled a-Si, TERS shows good correlation between solid electrolyte interphase (SEI) topography and chemical mapping, corresponding to distribution of lithium ethylene dicarbonate (LEDC) and poly (ethylene oxide) (PEO)-like oligomer species. Subsequent electrochemical cycling makes the SEI relatively thick and rough with the chemical composition heavily dominated by LEDC monomer-dimer for 5× cycled a-Si. For 20× cycled a-Si, the TERS signal is dominated by carboxylate (RCO2Li) compounds of various conformations and fluorinated species (LixPOyFz). A nanomosaic-multilayer hybrid SEI model on top of the a-Si anode is proposed. The significance of this work is applicable not only to silicon, where SEI plays a dominant role in determining the cycle life performance and reversibility, but also for a number of other relevant battery chemistries such as Na-ion and multivalent redox systems.

Published
2019
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46. Understanding the Low-Voltage Hysteresis of Anionic Redox in Na2Mn3O7

Author

Jagjit Nanda, Zulipiya Shadike, Miaofang Chi, Kamila M. Wiaderek, Olaf J. Borkiewicz, Xiao-Qing Yang, Yan-Yan Hu, Katharine Page, Xiaoming Liu, Enyuan Hu, Bohang Song, Cheng Li, Likai Song, Ashfia Huq, Nathan D. Phillip, Mingxue Tang, Yiman Zhang, Gabriel M. Veith, and Jue Liu

Subjects
Materials science, General Chemical Engineering, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Redox, Cathode, 0104 chemical sciences, law.invention, Physics::Plasma Physics, Chemical physics, law, Lattice (order), Materials Chemistry, Energy density, 0210 nano-technology, Low voltage
Abstract

The large-voltage hysteresis remains one of the biggest barriers to optimizing Li/Na-ion cathodes using lattice anionic redox reaction, despite their very high energy density and relative low cost....

Published
2019
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47. Interpreting Electrochemical and Chemical Sodiation Mechanisms and Kinetics in Tin Antimony Battery Anodes Using in Situ Transmission Electron Microscopy and Computational Methods

Author

Raymond R. Unocic, Jacob S. Gutiérrez-Kolar, Gabriel M. Veith, Reza Shahbazian-Yassar, Dongwon Shin, Farzad Mashayek, Xiahan Sang, Vitaliy Yurkiv, and Loïc Baggetto

Subjects
Materials science, Diffusion, Intermetallic, Energy Engineering and Power Technology, chemistry.chemical_element, Electrochemistry, Nanocrystalline material, Anode, Chemical engineering, Electron diffraction, chemistry, Materials Chemistry, Chemical Engineering (miscellaneous), Electrical and Electronic Engineering, Thin film, Tin
Abstract

Intermetallic compounds such as SnSb are promising anode materials for sodium ion batteries; however, their nanoscale sodiation mechanisms are not well understood. Here, we used a combination of in situ transmission electron microscopy (TEM), first-principles electronic structure calculations, computational thermodynamic modeling, and phase-field simulations to reveal the sodiation mechanisms and to quantify microstructural effects contributing to the underlying reaction kinetics in SnSb electrodes. During in situ sodiation experiments, the nanocrystalline SnSb thin films underwent a rapid amorphous phase transformation upon sodiation, as determined by in situ TEM and electron diffraction experiments. The Na+ diffusion coefficients were measured with and without an external electrical bias, and the data showed that an applied potential increased Na+ diffusion by an order of magnitude compared to solid-state diffusion. Furthermore, there was a distinct decrease in sodium diffusion upon the formation of the...

Published
2019
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48. (Invited) How Does One Enable High Energy Li Metal Batteries a Case Study with Lipon

Author

Andrew S Westover, Sergiy Kalnaus, Nancy Dudney, Katie Browning, Gabriel M. Veith, and Robert L Sacci

Abstract

The next generation of high energy batteries using Li metal as an anode and utilizing a solid electrolyte requires good interfacial stability, reasonable ionic conductivity, and most importantly the ability to eliminate dendrites.i While most solid-state electrolytes suffer from both interfacial instability and Li penetration resulting in cell shorting,ii,iii The solid electrolyte Lipon has a remarkable ability to suppress dendrites, and enable solid state batteries that can cycle for more than 1000 cycles and support current densities as high as 10 mA/cm2.iii,iv Recent efforts have started to illuminate the origin of Lipon’s ability to enable high-energy solid-state Li metal batteries. This presentation will highlight the unique structure of Lipon and Lipon like materials, the interfacial structure of Lipon with Li metal, and the mechanics that enable high quality performance in Lipon based solid-state batteries.v,vi,vii Finally, the presentation will connect these findings from Lipon to outline key underlying principles that answer the question, how do we enable high energy Li metal batteries? Acknowledgements: Work for this presentation was funded by ARPA-E under contract #DE-AR0000775, and the US Department of Energy Office of Energy Efficiency and Renewable Energy for the Vehicle Technologies Office’s US-German Cooperation on Energy Storage: Interfaces and Interphases In Rechargeable Li-metal based Batteries Program and the Battery Materials Research Program under program managers Tien Duong and Simon Thompson. P. Albertus et al., “Challenges for and pathways toward Li-metal-based all-solid-state batteries”, ACS Energy Letters, 6, 4, 1399-1404, Mar. 2021. Fudong Han, Andrew S Westover, Jie Yue, Xiulin Fan, Fei Wang, Miaofang Chi, Donovan N Leonard, Nancy J Dudney, Howard Wang, Chunsheng Wang, “High electronic conductivity as the origin of lithium dendrite formation within solid electrolytes”, Nature Energy, 1, Jan. 2019. Andrew S Westover, Nancy J Dudney, Robert L Sacci, Sergiy Kalnaus, “Deposition and Confinement of Li Metal along an Artificial Lipon–Lipon Interface”, ACS Energy Letters, 4, 651-655, Feb. 2019. Juchuan Li, Cheng Ma, Miaofang Chi, Chengdu Liang, and Nancy J. Dudney. "Solid electrolyte: the key for high‐voltage lithium batteries." Advanced Energy Materials5, 4, 1401408, 2015. Andrew S Westover* Valentina Lacivita,* , Andrew Kercher, Nathan D Phillip, Guang Yang, Gabriel Veith, Gerbrand Ceder, Nancy J Dudney, “Resolving the amorphous structure of lithium phosphorus oxynitride (Lipon)”, Journal of the American Chemical Society 140 (35), 11029-11038, July 2018. Andrew S Westover, Robert L Sacci, Nancy Dudney, “Electroanalytical measurement of interphase formation at a Li metal–solid electrolyte interface”, ACS Energy Letters, 5, 12, 3860-3867, Nov. 2020. Sergiy Kalnaus, Andrew S Westover, Mordechai Kornbluth, Erik Herbert, Nancy J Dudney, “Resistance to fracture in the glassy solid electrolyte Lipon”, Journal of Materials Research, 36, 4, 787-796, Feb. 2021.

Published
2022
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49. Covalent Surface Functionalization of Silicon for Enhanced Cycling Performance

Author

Khryslyn G. Arano, Beth L. Armstrong, Ethan D. Boeding, Rachel J. Korkosz, Thomas F. Malkowski, and Gabriel M. Veith

Abstract

Silicon (Si)-based negative electrodes often have these two prerequisites for improved performance: submicron or nanoscale dimension and additives (generally for electrolytes). In this work, a single approach was implemented to achieve the beneficial effects of both. Functionalized Si particles with an average diameter of less than 300 nm and with good polydispersity indices (0.2 to 0.3) were successfully generated by ball-milling the Si with vinylene carbonate (VC) and polyethylene oxide (PEO). Surface characterization using x-ray photoelectron spectroscopy (XPS) confirms the modification of the Si surface and the presence of the additives even after the electrode fabrication processes. We demonstrate through half-cell cycling that the addition of small amounts of VC result in increased specific capacities compared to the neat Si, i.e., ~370 mAh.g-1 higher for Si-VC electrode after the formation cycles. On the other hand, the presence of PEO introduces a passivating film on the surface of Si that hinders Li+ transport to the electrode as indicated by electrochemical impedance spectroscopy (EIS), resulting in reduced specific capacities, i.e., ~325 mAh.g-1 less relative to the neat Siafter formation. Nevertheless, the Si-PEO system exhibited the most promising cycling stability compared to the neat Si and Si-VC electrodes after extended cycling. Similar observations were drawn from full cell studies using high voltage NMC 811 cathodes, confirming the viability of our approach for the improvement of Si-based next generation lithium-ion batteries.

Published
2022
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50. Moving Beyond Heat and Beat

Author

Gabriel M. Veith, Thomas F. Malkowski, Matthew Chambers, and Robert L Sacci

Abstract

The synthesis of solid electrolytes is often described as the mixing of simple precursors (e.g. Li2CO3, La2O3, etc.), followed by extensive heating and regrinding to yield a single phase solid ion conductor. In this presentation we move beyond the traditional "heat and beat" approach to synthesis to a more nuanced approach more analogous to classic organic synthesis with the controlled and stepwise addition of reagents. We will show this approach produces a 500 fold increase in grain boundary conductivity of perovskite solid electrolytes and the complete synthesis of others in under 15 minutes and 200oC lower reaction temperatures. Through control of reaction energetics reaction selectivity can be enhanced offering unique opportunities to facilitate the properties of solid ion conductors.

Published
2022
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