Your search keyword '"Mikaela R. Dunkin"' showing total 23 results

1. Hybrid MoS2+x Nanosheet/Nanocarbon Heterostructures for Lithium-Ion Batteries

Author

Diana M. Lutz, Mikaela R. Dunkin, Steven T. King, Chavis A. Stackhouse, Jason Kuang, Yonghua Du, Seong-Min Bak, David C. Bock, Xiao Tong, Lu Ma, Steven N. Ehrlich, Esther S. Takeuchi, Kenneth J. Takeuchi, Amy C. Marschilok, and Lei Wang

Subjects

General Materials Science

Published

2022

2. Impact of Charge Voltage on Factors Influencing Capacity Fade in Layered NMC622: Multimodal X-ray and Electrochemical Characterization

Author

Lu Ma, Alison H. McCarthy, Calvin D. Quilty, Mikaela R. Dunkin, Xiao Tong, Esther S. Takeuchi, Lei Wang, Garrett P. Wheeler, Killian R. Tallman, Shan Yan, Kenneth J. Takeuchi, David C. Bock, Steven N. Ehrlich, and Amy C. Marschilok

Subjects

X-ray absorption spectroscopy, Scanning electrochemical microscopy, Materials science, Absorption spectroscopy, X-ray photoelectron spectroscopy, law, Electrode, Analytical chemistry, General Materials Science, Electrochemistry, Cathode, law.invention, Dielectric spectroscopy

Abstract

Ni-rich NMC is an attractive Li-ion battery cathode due to its combination of energy density, thermal stability, and reversibility. While higher delivered energy density can be achieved with a more positive charge voltage limit, this approach compromises sustained reversibility. Improved understanding of the local and bulk structural transformations as a function of charge voltage, and their associated impacts on capacity fade are critically needed. Through simultaneous operando synchrotron X-ray diffraction (XRD) and X-ray absorption spectroscopy (XAS) of cells cycled at 3-4.3 or 3-4.7 V, this study presents an in-depth investigation into the effects of voltage window on local coordination, bulk structure, and oxidation state. These measurements are complemented by ex situ X-ray fluorescence (XRF) mapping and scanning electrochemical microscopy mapping (SECM) of the negative electrode, X-ray photoelectron spectroscopy (XPS) of the positive electrode, and cell level electrochemical impedance spectroscopy (EIS). Initially, cycling between 3 and 4.7 V leads to greater delivered capacity due to greater lithium extraction, accompanied by increased structural distortion, moderately higher Ni oxidation, and substantially higher Co oxidation. Continued cycling at this high voltage results in suppressed Ni and Co redox, greater structural distortion, increased levels of transition metal dissolution, higher cell impedance, and 3× greater capacity fade.

Published

2021

3. Local and Bulk Probe of Vanadium-Substituted α-Manganese Oxide (α-KxVyMn8–yO16) Lithium Electrochemistry

Author

Mikaela R. Dunkin, Esther S. Takeuchi, Shize Yang, Lei Wang, Ping Liu, Bingjie Zhang, Yimei Zhu, David C. Bock, Diana M. Lutz, Amy C. Marschilok, Kenneth J. Takeuchi, Lisa M. Housel, and Killian R. Tallman

Subjects

X-ray absorption spectroscopy, Valence (chemistry), Absorption spectroscopy, Rietveld refinement, Analytical chemistry, Vanadium, chemistry.chemical_element, Inorganic Chemistry, symbols.namesake, Molecular geometry, chemistry, symbols, Crystallite, Physical and Theoretical Chemistry, Raman spectroscopy

Abstract

A series of V-substituted α-MnO2 (KxMn8-yVyO16·nH2O, y = 0, 0.2, 0.34, 0.75) samples were successfully synthesized without crystalline or amorphous impurities, as evidenced by X-ray diffraction (XRD) and Raman spectroscopy. Transmission electron microscopy (TEM) revealed a morphological evolution from nanorods to nanoplatelets as V-substitution increased, while electron-energy loss spectroscopy (EELS) confirmed uniform distribution of vanadium within the materials. Rietveld refinement of synchrotron XRD showed an increase in bond lengths and a larger range of bond angles with increasing V-substitution. X-ray absorption spectroscopy (XAS) of the as-prepared materials revealed the V valence to be >4+ and the Mn valence to decrease with increasing V content. Upon electrochemical lithiation, increasing amounts of V were found to preserve the Mn-Mnedge relationship at higher depths of discharge, indicating enhanced structural stability. Electrochemical testing showed the y = 0.75 V-substituted sample to deliver the highest capacity and capacity retention after 50 cycles. The experimental findings were consistent with the predictions of density functional theory (DFT), where the V centers impart structural stability to the manganese oxide framework upon lithiation. The enhanced electrochemistry of the y = 0.75 V-substituted sample is also attributed to its smaller crystallite size in the form of a nanoplatelet morphology, which promotes facile ion access via reduced Li-ion diffusion path lengths.

Published

2021

4. Multimodal electrochemistry coupled microcalorimetric and X-ray probing of the capacity fade mechanisms of Nickel rich NMC - progress and outlook

Author

Calvin D. Quilty, Patrick J. West, Wenzao Li, Mikaela R. Dunkin, Garrett P. Wheeler, Steven Ehrlich, Lu Ma, Cherno Jaye, Daniel A. Fischer, Esther S. Takeuchi, Kenneth J. Takeuchi, David C. Bock, and Amy C. Marschilok

Subjects

General Physics and Astronomy, Physical and Theoretical Chemistry

Abstract

Lithium nickel manganese cobalt oxide (NMC) is a commercially successful Li-ion battery cathode due to its high energy density; however, its delivered capacity must be intentionally limited to achieve capacity retention over extended cycling. To design next-generation NMC batteries with longer life and higher capacity the origins of high potential capacity fade must be understood.

Published

2022

5. Lithium vanadium oxide (Li1.1V3O8) thick porous electrodes with high rate capacity: utilization and evolution upon extended cycling elucidatedvia operandoenergy dispersive X-ray diffraction and continuum simulation

Author

Jason Kuang, Lisa M. Housel, Steven T. King, Alan C. West, Mikaela R. Dunkin, Lei Wang, Karthik S. Mayilvahanan, Esther S. Takeuchi, Amy C. Marschilok, Calvin D. Quilty, Alison H. McCarthy, and Kenneth J. Takeuchi

Subjects

Diffraction, Phase transition, Materials science, Analytical chemistry, General Physics and Astronomy, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Synchrotron, Electrical contacts, Vanadium oxide, 0104 chemical sciences, law.invention, Ion, law, Electrode, Physical and Theoretical Chemistry, Energy-dispersive X-ray diffraction, 0210 nano-technology

Abstract

The phase distribution of lithiated LVO in thick (∼500 μm) porous electrodes (TPEs) designed to facilitate both ion and electron transport was determined using synchrotron-based operando energy dispersive X-ray diffraction (EDXRD). Probing 3 positions in the TPE while cycling at a 1C rate revealed a homogeneous phase transition across the thickness of the electrode at the 1st and 95th cycles. Continuum modelling indicated uniform lithiation across the TPE in agreement with the EDXRD results and ascribed decreasing accessible active material to be the cause of loss in delivered capacity between the 1st and 95th cycles. The model was supported by the observation of significant particle fracture by SEM consistent with loss of electrical contact. Overall, the combination of operando EDXRD, continuum modeling, and ex situ measurements enabled a deeper understanding of lithium vanadium oxide transport properties under high rate extended cycling within a thick highly porous electrode architecture.

Published

2021

6. Defect Control in the Synthesis of 2 D MoS 2 Nanosheets: Polysulfide Trapping in Composite Sulfur Cathodes for Li–S Batteries

Author

Alison H. McCarthy, Kenneth J. Takeuchi, Amy C. Marschilok, Mikaela R. Dunkin, Alyson Abraham, Esther S. Takeuchi, Lei Wang, Diana M. Lutz, Lisa M. Housel, Christopher R. Tang, and Calvin D. Quilty

Subjects

Battery (electricity), Materials science, General Chemical Engineering, Composite number, chemistry.chemical_element, Lithium–sulfur battery, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, Sulfur, Lithium battery, 0104 chemical sciences, chemistry.chemical_compound, General Energy, Chemical engineering, chemistry, Environmental Chemistry, General Materials Science, 0210 nano-technology, Polysulfide

Abstract

One of the inherent challenges with Li-S batteries is polysulfide dissolution, in which soluble polysulfide species can contribute to the active material loss from the cathode and undergo shuttling reactions inhibiting the ability to effectively charge the battery. Prior theoretical studies have proposed the possible benefit of defective 2 D MoS2 materials as polysulfide trapping agents. Herein the synthesis and thorough characterization of hydrothermally prepared MoS2 nanosheets that vary in layer number, morphology, lateral size, and defect content are reported. The materials were incorporated into composite sulfur-based cathodes and studied in Li-S batteries with environmentally benign ether-based electrolytes. Through directed synthesis of the MoS2 additive, the relationship between synthetically induced defects in 2 D MoS2 materials and resultant electrochemistry was elucidated and described.

Published

2019

7. Ex Situ and Operando XRD and XAS Analysis of MoS2: A Lithiation Study of Bulk and Nanosheet Materials

Author

Diana M. Lutz, Mikaela R. Dunkin, Lei Wang, Andrea M. Bruck, Alyson Abraham, Amy C. Marschilok, David C. Bock, Kenneth J. Takeuchi, Esther S. Takeuchi, Calvin D. Quilty, and Lisa M. Housel

Subjects

chemistry.chemical_classification, X-ray absorption spectroscopy, Materials science, Sulfide, Inorganic chemistry, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 7. Clean energy, Lithium battery, 0104 chemical sciences, chemistry, Molybdenum, Materials Chemistry, Electrochemistry, Chemical Engineering (miscellaneous), Electrical and Electronic Engineering, 0210 nano-technology, Nanosheet

Abstract

Molybdenum(IV) sulfide (MoS2) has generated significant interest as an electroactive material for Li-ion batteries because of its high theoretical capacity, good rate capability, and minimal volume...

Published

2019

8. Interface effects on self-forming rechargeable Li/I2-based solid state batteries

Author

Jianping Huang, Alyson Abraham, Kenneth J. Takeuchi, Mikaela R. Dunkin, Bingjie Zhang, Esther S. Takeuchi, and Amy C. Marschilok

Subjects

Self forming, Battery (electricity), Materials science, Interface (computing), Solid-state, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Electrochemical response, 0104 chemical sciences, Chemical engineering, Solid-state battery, General Materials Science, 0210 nano-technology, Interface design

Abstract

Solid state batteries are an emerging alternative to traditional liquid electrolyte cells that provide potential for safe and high-energy density power sources. This report describes a self-forming, solid state battery based on the Li/I2 couple using an LiI-rich LiI(3-hydroxypropionitrile)2 electrolyte (LiI–LiI(HPN)2). As the negative and positive active materials are generated in situ, the solid electrolyte–current collector interfaces play a critical role in determining the electrochemical response of the battery. Herein, we report the investigation of solid electrolyte–current collector interfaces with a self-forming LiI–LiI(HPN)2 solid electrolyte and the role of varying interface design in reducing resistance during cycling.

Published

2019

9. Deliberate Modification of Fe3O4 Anode Surface Chemistry: Impact on Electrochemistry

Author

David C. Bock, Alison H. McCarthy, Lisa M. Housel, Mikaela R. Dunkin, Lei Wang, Qiyuan Wu, Alyson Abraham, Esther S. Takeuchi, Kenneth J. Takeuchi, Amy C. Marschilok, Andrew M. Kiss, and Juergen Thieme

Subjects

Materials science, 02 engineering and technology, Conjugated system, Surface engineering, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, 0104 chemical sciences, Anode, chemistry.chemical_compound, chemistry, Chemical engineering, Electrode, Surface modification, General Materials Science, 0210 nano-technology, Dispersion (chemistry), Benzoic acid

Abstract

Fe3O4 nanoparticles (NPs) with an average size of 8-10 nm have been successfully functionalized with various surface-treatment agents to serve as model systems for probing surface chemistry-dependent electrochemistry of the resulting electrodes. The surface-treatment agents used for the functionalization of Fe3O4 anode materials were systematically varied to include aromatic or aliphatic structures: 4-mercaptobenzoic acid, benzoic acid (BA), 3-mercaptopropionic acid, and propionic acid (PA). Both structural and electrochemical characterizations have been used to systematically correlate the electrode functionality with the corresponding surface chemistry. Surface treatment with ligands led to better Fe3O4 dispersion, especially with the aromatic ligands. Electrochemistry was impacted where the PA- and BA-treated Fe3O4 systems without the -SH group demonstrated a higher rate capability than their thiol-containing counterparts and the pristine Fe3O4. Specifically, the PA system delivered the highest capacity and cycling stability among all samples tested. Notably, the aromatic BA system outperformed the aliphatic PA counterpart during extended cycling under high current density, due to the improved charge transfer and ion transport kinetics as well as better dispersion of Fe3O4 NPs, induced by the conjugated system. Our surface engineering of the Fe3O4 electrode presented herein, highlights the importance of modifying the structure and chemistry of surface-treatment agents as a plausible means of enhancing the interfacial charge transfer within metal oxide composite electrodes without hampering the resulting tap density of the resulting electrode.

Published

2019

10. K-Edge and L-Edge Spectroscopy of Ni0.8Mn0.1Co0.1O2 Cathodes Under Expanded Voltage Conditions Via Soft X-Ray Absorption Spectroscopy

Author

Patrick J West, Cavlin Quilty, Wenzao Li, Mikaela R. Dunkin, Garrett Wheeler, Christopher Kern, Killian Tallman, Lisa M. Housel, Esther S. Takeuchi, Kenneth J. Takeuchi, David C Bock, and Amy C. Marschilok

Abstract

Mixed transition metal oxides, such as Ni0.8Mn0.1Co0.1O2 (NMC811), are intended to combine the high capacity of nickel oxides, the rate capability of cobalt oxides, and the structural stability of manganese oxides to meet the capacity and power demands of electric vehicles and commercial portable electronics. However, the capacity fade mechanisms in Ni-rich chemistries (x >y+z in NixMnyCozO2) can be elusive due to factors at the crystallographic, particle, or electrode level. In this study, bulk and surface x-ray spectroscopy characterization of NMC cathodes was used to explore cathode degradation mechanisms as influenced by cycling protocol, namely current rate and upper voltage limits. Soft x-ray absorption spectroscopy (sXAS) was used to probe the surface of recovered NMC electrodes via transition metal L-edge and O K-edge spectroscopy. The effect of rate and upper voltage potential under charge will be discussed to illustrate the versatility of sXAS for NMC cathode electrode characterization.

Published

2022

11. Unveiling Charge Transport and Degradation Mechanisms of Aqueous Zn|α‐MoO 3 Batteries in Conventional Concentration and Water‐in‐Salt Electrolytes: A Multi‐Modal In Situ and Operando Study

Author

Mikaela R. Dunkin, Jason Kuang, Shan Yan, Steven T. King, Lisa M. Housel, Lu Ma, Steven N. Ehrlich, John S. Okasinski, Kenneth J. Takeuchi, Esther S. Takeuchi, Amy C. Marschilok, and Lei Wang

Subjects

Mechanics of Materials, Mechanical Engineering

Published

2022

12. Local and Bulk Probe of Vanadium-Substituted α-Manganese Oxide (α-K

Author

Diana M, Lutz, Mikaela R, Dunkin, Killian R, Tallman, Lei, Wang, Lisa M, Housel, Shize, Yang, Bingjie, Zhang, Ping, Liu, David C, Bock, Yimei, Zhu, Amy C, Marschilok, Esther S, Takeuchi, and Kenneth J, Takeuchi

Abstract

A series of V-substituted α-MnO

Published

2021

13. Lithium vanadium oxide (Li

Author

Alison H, McCarthy, Karthik, Mayilvahanan, Mikaela R, Dunkin, Steven T, King, Calvin D, Quilty, Lisa M, Housel, Jason, Kuang, Kenneth J, Takeuchi, Esther S, Takeuchi, Alan C, West, Lei, Wang, and Amy C, Marschilok

Abstract

The phase distribution of lithiated LVO in thick (∼500 μm) porous electrodes (TPEs) designed to facilitate both ion and electron transport was determined using synchrotron-based operando energy dispersive X-ray diffraction (EDXRD). Probing 3 positions in the TPE while cycling at a 1C rate revealed a homogeneous phase transition across the thickness of the electrode at the 1st and 95th cycles. Continuum modelling indicated uniform lithiation across the TPE in agreement with the EDXRD results and ascribed decreasing accessible active material to be the cause of loss in delivered capacity between the 1st and 95th cycles. The model was supported by the observation of significant particle fracture by SEM consistent with loss of electrical contact. Overall, the combination of operando EDXRD, continuum modeling, and ex situ measurements enabled a deeper understanding of lithium vanadium oxide transport properties under high rate extended cycling within a thick highly porous electrode architecture.

Published

2020

14. Electrochemically Induced Phase Evolution of Lithium Vanadium Oxide: Complementary Insights Gained via Ex-Situ, In-Situ, and Operando Experiments and Density Functional Theory

Author

Wenzao Li, Esther S. Takeuchi, Kenneth J. Takeuchi, Amy C. Marschilok, Mikaela R. Dunkin, and Jiefu Yin

Subjects

Diffraction, In situ, Materials science, 020209 energy, Mechanical Engineering, chemistry.chemical_element, 02 engineering and technology, Condensed Matter Physics, Electrochemistry, Lithium-ion battery, Vanadium oxide, Chemical engineering, chemistry, Mechanics of Materials, Electrode, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Density functional theory, Lithium

Abstract

Understanding the structural evolution of electrode material during electrochemical activity is important to elucidate the mechanism of (de)lithiation, and improve the electrochemical function based on the material properties. In this study, lithium vanadium oxide (LVO, LiV3O8) was investigated using ex-situ, in-situ, and operando experiments. Via a combination of in-situ X-ray diffraction (XRD) and density functional theory results, a reversible structural evolution during lithiation was revealed: from Li poor α phase (LiV3O8) to Li rich α phase (Li2.5V3O8) and finally β phase (Li4V3O8). In-situ and operando energy dispersive X-ray diffraction (EDXRD) provided tomographic information to visualize the spatial location of the phase evolution within the LVO electrode while inside a sealed lithium ion battery.

Published

2018

15. Capacity Retention for (De)lithiation of Silver Containing α-MnO2: Impact of Structural Distortion and Transition Metal Dissolution

Author

Bingjie Zhang, Mikaela R. Dunkin, Kenneth J. Takeuchi, Calvin D. Quilty, Alexander B. Brady, Diana M. Lutz, Amy C. Marschilok, Esther S. Takeuchi, Paul F. Smith, Lisa M. Housel, Alyson Abraham, and Jianping Huang

Subjects

Materials science, Renewable Energy, Sustainability and the Environment, 020209 energy, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Transition metal, Distortion, 0202 electrical engineering, electronic engineering, information engineering, Materials Chemistry, Electrochemistry, Composite material, 0210 nano-technology, Dissolution

Published

2018

16. Improved ionic conductivity and battery function in a lithium iodide solid electrolyte via particle size modification

Author

Steven T. King, Esther S. Takeuchi, Mikaela R. Dunkin, Kenneth J. Takeuchi, Lei Wang, and Amy C. Marschilok

Subjects

Battery (electricity), Materials science, General Chemical Engineering, Analytical chemistry, 02 engineering and technology, Electrolyte, Overpotential, Conductivity, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Lithium iodide, chemistry.chemical_compound, chemistry, Electrochemistry, Fast ion conductor, Ionic conductivity, Particle size, 0210 nano-technology

Abstract

Solid electrolytes (SEs) are a promising, safe alternative to liquid electrolytes in high energy density batteries, but challenges, including low ionic conductivity and dendrite formation, remain. In a recent work, it was determined that dendrite formation within representative SEs, Li7La3Zr2O12 and Li3PS4, is due to their non-negligible electronic conductivity.[1] Notably, LiI has negligible electronic conductivity and thus the formation of lithium dendrites may be lessened, making LiI a good candidate for SE development. Our previous work on LiI SE, utilized 1:2 lithium iodide:3-hydroxypropionitrile (LiI(HPN)2) as a conductive additive, creating an 80/20 LiI/LiI(HPN)2 composite as a self-forming, rechargeable battery.[3] Additional work has demonstrated interfacial modification can effectively lower the cell impedance and improve coulombic efficiency (CE).[2, 4] In this work, a LiI SE was improved by reducing particle size via several processing methods; grinding (G), sonicating (C-S), and grinding with sonicating (G-S), and compared to a control (C) sample of LiI which underwent no processing. Partial hydration of LiI results in increased conductivity via increased defect density, and thus this parameter was controlled to ca. 34 mol% LiI monohydrate between samples. With further processing, particle size was reduced from 5 ± 1 µm to 2.0 ± 0.2 µm for the C and G-S samples. Utilized in 80/20 LiI/LiI(HPN)2 composites, reducing particle size resulted in an order of magnitude increase in ionic conductivity, from 7.7 x 10-8 to 6.1 x 10-7 S cm-1, at room temperature. Improved conductivity is attributed to an increased number of grain boundaries and defects, enabling ion transport and better mixing with the electrolyte additive, LiI(HPN)2. 3D confocal Raman spectroscopy in conjunction with non-negative matrix factorization (NMF) analysis determined the degree of HPN aggregation was lessened in the sample with smallest particle size. This LiI SE was utilized in a self-forming Li/I2 battery, where reduced particle size (improved conductivity) led to significantly reduced overpotential, allowing the coulombic efficiency to reach 100% in the first cycle. The G-S cells also exhibited improved electrochemical function when cycling at higher rates compared with the other electrolyte types. This work demonstrates the effect of particle size on solid electrolyte in a self-forming, self-healing, all solid state battery with a lithium metal negative electrode. References [1] F. Han, A.S. Westover, J. Yue, X. Fan, F. Wang, M. Chi, D.N. Leonard, N.J. Dudney, H. Wang, C. Wang, High electronic conductivity as the origin of lithium dendrite formation within solid electrolytes, Nature Energy, 4 (2019) 187-196. [2] C.A. Stackhouse, A. Abraham, S. Yan, L. Wang, N. Sadique, G. Singh, A.C. Marschilok, E.S. Takeuchi, K.J. Takeuchi, Self-Healing, Improved Efficiency Solid State Rechargeable Li/I2 Based Battery, Journal of The Electrochemical Society, 168 (2021). [3] A. Abraham, J. Huang, P.F. Smith, A.C. Marschilok, K.J. Takeuchi, E.S. Takeuchi, Communication—Demonstration and Electrochemistry of a Self-Forming Solid State Rechargeable LiI(HPN)2Based Li/I2Battery, Journal of The Electrochemical Society, 165 (2018) A2115-A2118. [4] A. Abraham, M.R. Dunkin, J. Huang, B. Zhang, K.J. Takeuchi, E.S. Takeuchi, A.C. Marschilok, Interface effects on self-forming rechargeable Li/I2-based solid state batteries, MRS Communications, 9 (2019) 657-662.

Published

2021

17. Carboxylated Poly(thiophene) Binders for High-Performance Magnetite Anodes: Impact of Cation Structure

Author

Krysten Minnici, Yo-Han Kwon, Johnathan O’Neil, Elsa Reichmanis, Lei Wang, Mark V. de Simon, Mikaela R. Dunkin, Matthew M. Huie, Miguel A. González, Esther S. Takeuchi, Amy C. Marschilok, and Kenneth J. Takeuchi

Subjects

Materials science, Ion exchange, 020209 energy, Active particles, 02 engineering and technology, 021001 nanoscience & nanotechnology, Anode, chemistry.chemical_compound, chemistry, Chemical engineering, 0202 electrical engineering, electronic engineering, information engineering, Thiophene, General Materials Science, 0210 nano-technology, Magnetite

Abstract

While the focus of research related to the design of robust, high-performance Li-ion batteries relates primarily to the synthesis of active particles, the binder plays a crucial role in stability and ensures electrode integrity during volume changes that occur with cycling. Conventional polymeric binders such as poly(vinylidene difluoride) generally do not interact with active particle surfaces and fail to accommodate large changes in particle spacing during cycling. Thus, attention is now turning toward the exploration of interfacial interactions between composite electrode constituents as a key element in ensuring electrode stability. Recently, a poly[3-(potassium-4-butanoate)thiophene] (PPBT) binder component, coupled with a polyethylene glycol (PEG) surface coating for the active material was demonstrated to enhance both electron and ion transport in magnetite-based anodes, and it was established that the PEG/PPBT approach aids in overall battery electrode performance. Herein, the PEG/PPBT system is used as a model polymeric binder for understanding cation effects in anode systems. As such, the potassium ion was replaced with sodium, lithium, hydrogen, and ammonium through ion exchange. The potassium salt exhibited the most stable electrochemical performance, which is attributed to the cation size and resultant electrode morphology that facilitates ion transport. The lithium analogue demonstrated an initial increase in capacity but was unable to maintain this performance over 100 cycles; while the sodium-based system exhibited initially lower capacity as a result of slow reaction kinetics, which increased as cycling progressed. The parent carboxylic acid polymer and its ammonium salt were notably inferior. The results exploring the effect of ion exchange creates a framework for understanding how cations associated directly with the polymer impact electrochemical performance and aid in the overall design of binders for composite Li-ion battery anodes.

Published

2019

18. Defect Control in the Synthesis of 2 D MoS

Author

Alyson, Abraham, Lei, Wang, Calvin D, Quilty, Diana M, Lutz, Alison H, McCarthy, Christopher R, Tang, Mikaela R, Dunkin, Lisa M, Housel, Esther S, Takeuchi, Amy C, Marschilok, and Kenneth J, Takeuchi

Abstract

One of the inherent challenges with Li-S batteries is polysulfide dissolution, in which soluble polysulfide species can contribute to the active material loss from the cathode and undergo shuttling reactions inhibiting the ability to effectively charge the battery. Prior theoretical studies have proposed the possible benefit of defective 2 D MoS

Published

2019

19. Deliberate Modification of Fe

Author

Lei, Wang, Lisa M, Housel, David C, Bock, Alyson, Abraham, Mikaela R, Dunkin, Alison H, McCarthy, Qiyuan, Wu, Andrew, Kiss, Juergen, Thieme, Esther S, Takeuchi, Amy C, Marschilok, and Kenneth J, Takeuchi

Abstract

Fe

Published

2019

20. Full Utilization of Lithium Trivandate (Li1.1V3O8) in Thick Porous Electrodes with High Rate Capacity upon Extended Cycling Elucidated Via Operando Energy Dispersive X-Ray Diffraction

Author

Jason Kuang, Kenneth J Takeuchi, Steven T. King, Lisa M. Housel, Esther S Takeuchi, Alison H. McCarthy, Lei Wang, Karthik S. Mayilvahanan, Mikaela R. Dunkin, Amy C Marschilok, Calvin D. Quilty, and Alan C. West

Subjects

High rate, Materials science, Porous electrode, chemistry, Analytical chemistry, chemistry.chemical_element, Lithium, Energy-dispersive X-ray diffraction, Cycling

Abstract

Newer, more demanding energy storage systems require high energy density along with high power and fast charge rates. Conventional battery electrode fabrication techniques are often limited by how much active material they can hold in the case of slurry-cast electrodes and how much of the electrode can be utilized in the case of dense pelletized electrodes. Thick porous electrode fabrication techniques have been developed as a way to obtain a higher active mass loading and an architecture which enables ionic and electronic transport. The homogeneity of the phase distribution of lithiated LVO in thick (∼500 μm) porous electrodes (TPEs) designed to facilitate both ion and electron transport was determined using synchrotron-based operando energy dispersive X-ray diffraction (EDXRD). Probing 3 positions in the TPE while cycling at a fast rate of 1C revealed a homogeneous phase transition across the thickness of the electrode at the 1st and 95th cycles. Continuum modelling indicated homogenous lithiation across the electrode upon discharge at 1C consistent with the EDXRD results and ascribed decreasing accessible active material to be the cause of loss in delivered capacity between the 1st and 95th cycles. The model was supported by the observation of significant particle fracture by SEM consistent with loss of electrical contact. The absence of the beta phase peaks in the EDXRD over extended cycling are consistent with electrochemical accessibility of only part of the active material. Overall, the combination of operando EDXRD, continuum modeling, and ex situ measurements enabled a deeper understanding of lithium vanadium oxide transport properties under high rate extended cycling within a thick highly porous electrode architecture.

Published

2021

21. Stable Molybdenum Oxide Cathodes: Achieving Stable Molybdenum Oxide Cathodes for Aqueous Zinc‐Ion Batteries in Water‐in‐Salt Electrolyte (Adv. Mater. Interfaces 9/2021)

Author

Calvin D. Quilty, Steven N. Ehrlich, Jason Kuang, Lu Ma, Mikaela R. Dunkin, Esther S. Takeuchi, Shan Yan, Lei Wang, Amy C. Marschilok, and Kenneth J. Takeuchi

Subjects

chemistry.chemical_classification, Materials science, Aqueous solution, Mechanical Engineering, Zinc ion, Inorganic chemistry, Molybdenum oxide, Salt (chemistry), Electrolyte, Cathode, law.invention, chemistry, Mechanics of Materials, law, Dissolution

Published

2021

22. Achieving Stable Molybdenum Oxide Cathodes for Aqueous Zinc‐Ion Batteries in Water‐in‐Salt Electrolyte

Author

Esther S. Takeuchi, Mikaela R. Dunkin, Lei Wang, Steven N. Ehrlich, Kenneth J. Takeuchi, Amy C. Marschilok, Shan Yan, Lu Ma, Jason Kuang, and Calvin D. Quilty

Subjects

chemistry.chemical_classification, Materials science, Aqueous solution, Mechanical Engineering, Zinc ion, Molybdenum oxide, Inorganic chemistry, Salt (chemistry), Electrolyte, Cathode, law.invention, chemistry, Mechanics of Materials, law, Dissolution

Published

2021

23. Cover Feature: Defect Control in the Synthesis of 2 D MoS 2 Nanosheets: Polysulfide Trapping in Composite Sulfur Cathodes for Li–S Batteries (ChemSusChem 6/2020)

Author

Diana M. Lutz, Alyson Abraham, Alison H. McCarthy, Kenneth J. Takeuchi, Lisa M. Housel, Esther S. Takeuchi, Christopher R. Tang, Amy C. Marschilok, Lei Wang, Calvin D. Quilty, and Mikaela R. Dunkin

Subjects

Materials science, General Chemical Engineering, Composite number, chemistry.chemical_element, Trapping, Sulfur, Cathode, law.invention, chemistry.chemical_compound, General Energy, Molybdenum sulfide, Chemical engineering, chemistry, law, Environmental Chemistry, General Materials Science, Polysulfide

Published

2020