Chem. Commun. Semantic Scholar profile for Zhenan Bao, with 418 highly influential citations and 610 scientific research papers. Liang, X. et al. A commercial conducting polymer as both binder and conductive additive for silicon nanoparticle-based lithium-ion battery negative electrodes. Nat. Soc. Solid State Ion. (2021), Journal of Power Sources ACS Cent. Joule 2, 1548–1558 (2018). 160, A1611–A1617 (2013). Ma, L. et al. Improving the performance of lithium–sulfur batteries by conductive polymer coating. Cited by. 50, 4448–4450 (2014). Nature Reviews. J. Chem. Magasinski, A. et al. Polymeric peptide pigments with sequence-encoded properties. Nat. 25, 562–569 (1985). Lee Professor in Chemical Engineering, and with courtesy appointments in Chemistry and Material Science and Engineering. 17, 725–731 (2018). Energy 1, 16071 (2016). Silicon microparticle anodes with self-healing multiple network binder. She was named as one of Nature's 10 in 2015,[1] and was one of the laureates of the 2017 L'Oréal-UNESCO Awards for Women in Science. Kim, C. S. & Oh, S. M. Importance of donor number in determining solvating ability of polymers and transport properties in gel-type polymer electrolytes. Chen, Z. et al. ACS Appl. Macromolecules 24, 3725–3746 (1991). Chem. Pesko, D. M. et al. Energy Mater. 47, 2145–2164 (2018). 15, 65–84 (1991). 7, 749–756 (2012). Relationship between conductivity, ion diffusion, and transference number in perfluoropolyether electrolytes. Rev. J. We also discuss how polymer materials have been designed to create stable artificial interfaces and improve battery safety. Pan, Q., Smith, D. M., Qi, H., Wang, S. & Li, C. Y. Rational sulfur cathode design for lithium–sulfur batteries: sulfur-embedded benzoxazine polymers. (2021), Nature Reviews Materials Mater. Hoffmann, R., Janiak, C. & Kollmar, C. A chemical approach to the orbitals of organic polymers. Wang, Y. et al. Je, S. H. et al. Solid State Lett. Adv. [3] She was one of the early students of Luping Yu and did initial work on liquid-crystalline polymers.[4][5]. She was named one of MIT Technology Review's TR35[10] and C&EN 12 rising stars[3] for her work with organic semiconductors. Adv. Mater. Michan, A. L. et al. At the polymer electrolyte interfaces: the role of the polymer host in interphase layer formation in Li-batteries. Natl Acad. Am. Electrochem. Sci. Luo, J., Fang, C.-C. & Wu, N.-L. High polarity poly(vinylidene difluoride) thin coating for dendrite-free and high-performance lithium metal anodes. Acc. Angew. Chem. ACS Appl. Langmuir 33, 13973–13981 (2017). Mater. Ionically conductive self-healing binder for low cost Si microparticles anodes in Li-ion batteries. & Koch, D. L. Stabilizing electrodeposition in elastic solid electrolytes containing immobilized anions. Commun. Am. Zhenan Bao joined Stanford University in 2004. A pomegranate-inspired nanoscale design for large-volume-change lithium battery anodes. Hoffman, D. M. & McKinley, B. M. Crystallinity as a selection criterion for engineering properties of high density polyethylene. Commun. 7, 319–327 (1975). She is known for her work developing technologies with organic field-effect transistors and organic semiconductors. Sort by citations Sort by year Sort by title. DGE-114747. Shi, Y., Zhang, Q., Zhang, Y., Jia, L. & Xu, X. Lee Professor of Chemical Engineering, and by courtesy, a Professor of Chemistry and a Professor of Material Science and Engineering at Stanford University, has been selected to receive the 2020 Willard Gibbs Award. Bates, C. M., Chang, A. 46, 1125–1134 (2012). 6, 6152 (2015). Gadjourova, Z., Andreev, Y. G., Tunstall, D. P. & Bruce, P. G. Ionic conductivity in crystalline polymer electrolytes. Am. A major constituent of brown algae for use in high-capacity Li-ion batteries. J. Fan, X. et al. Zachman, M. 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The Zhenan Bao Research Group at Stanford University, Dept. Adv. Commun. Small (Weinheim An Der Bergstrasse, Germany). Lee Professor in Chemical Engineering, and with courtesy appointments in Chemistry and Material Science and Engineering. Self-healing chemistry enables the stable operation of silicon microparticle anodes for high-energy lithium-ion batteries. Rev. Soc. & Tarascon, J.-M. Li–O2 and Li–S batteries with high energy storage. Adv. researched data for the article and wrote the article. Phys. J. Crosslinked perfluoropolyether solid electrolytes for lithium ion transport. & Tarascon, J. M. Si electrodes for Li-ion batteries — a new way to look at an old problem. Phys. She is a member of the National Academy of Engineering and National Academy of Inventors. 26: 938-942. Chem. Am. 139, 14992–15004 (2017). Ding, F. et al. Funct. Zhu, X. et al. Power Sources 254, 168–182 (2014). https://doi.org/10.1038/s41578-019-0103-6, DOI: https://doi.org/10.1038/s41578-019-0103-6, Electrochimica Acta Nat. 4, 260–267 (2018). Materials. Interfaces 2, 3004–3010 (2010). Sci. 30, 2058–2066 (2018). J. Phys. J. Improving the cycling stability of silicon nanowire anodes with conducting polymer coatings. Chem. Lithium metal anodes for rechargeable batteries. 135, 16736–16743 (2013). Commun. Diederichsen, K. M., McShane, E. J. Wei, X. The effects of cross-linking in a supramolecular binder on cycle life in silicon microparticle anodes. Nat. 127, 4399–4403 (2015). Nano Lett. Zhenan Bao, a professor of chemical engineering at Stanford University, has pioneered a number of novel materials-design concepts for organic electronics. Liu, X. H. et al. Stanford University. J. Mod. Trigg, E. B. et al. Res. Zhang, J. et al. Mater. Macromolecules 32, 1541–1548 (1999). Proc. Liu, W.-R., Yang, M.-H., Wu, H.-C., Chiao, S. M. & Wu, N.-L. Li, N.-W. et al. Correspondence to Adv. J. Electrochem. Crosslinked poly(tetrahydrofuran) as a loosely coordinating polymer electrolyte. Electrochem. Zhou, W., Yu, Y., Chen, H., DiSalvo, F. J. The impact of elastic deformation on deposition kinetics at lithium/polymer interfaces. Mei, J. 1, 1500017 (2015). USA 114, 12138–12143 (2017). Sun, B. et al. 150, A1073–A1078 (2003). Adv. Chan, C. K. et al. Commun. Jeong, Y. K., Kwon, T., Lee, I., Kim, T. S. & Coskun, A. Millipede-inspired structural design principle for high performance polysaccharide binders in silicon anodes. Villaluenga, I. et al. She is currently a K.K. Designing high-energy lithium–sulfur batteries. Energy Environ. Vogel, H. The temperature dependence law of the viscosity of fluids. ACS Energy Lett. J. Chem. Mater. Energy Environ. Lee Professor in Chemical Engineering, and with courtesy appointments in Chemistry and Material Science and Engineering. High-efficiency lithium metal batteries with fire-retardant electrolytes. Nature Reviews Materials volume 4, ... Jeffrey Lopez, David G. Mackanic & Zhenan Bao. Christie, A. M., Lilley, S. J., Staunton, E., Andreev, Y. G. & Bruce, P. G. Increasing the conductivity of crystalline polymer electrolytes. Nat. Energy Mater. of Chemical Engineering, focuses on the synthesis of functional organic and polymer materials, organic electronic device design and fabrication, and applications for organic electronics. Chem. In situ formed Si nanoparticle network with micron-sized Si particles for lithium-ion battery anodes. Zhenan Bao joined Stanford University in 2004. Int. VAT will be added later in the checkout. Am. The human skin is capable of identifying compliance of touched materials using pressure and strain-sensing mechanoreceptors. Electrode–electrolyte interface in Li-ion batteries: current understanding and new insights. Mater. Am. Polym. J. Angew. Tammann, G. & Hesse, W. The dependancy of viscosity on temperature in hypothermic liquids. ISSN 2058-8437 (online). J. J. Interface layer formation in solid polymer electrolyte lithium batteries: an XPS study. Toward an ideal polymer binder design for high-capacity battery anodes. Devaux, D. et al. Seh, Z. W. et al. ACS Nano 5, 9187–9193 (2011). Xu, W. et al. Chem. Ryu, J. H., Kim, J. W., Sung, Y.-E. & Oh, S. M. Failure modes of silicon powder negative electrode in lithium secondary batteries. Solid State Ion. Effect of monomer structure on ionic conductivity in a systematic set of polyester electrolytes. Choudhury, S., Mangal, R., Agrawal, A. Solid electrolyte interphase growth and capacity loss in silicon electrodes. Verified email at stanford.edu. & Teller, H. A short review of failure mechanisms of lithium metal and lithiated graphite anodes in liquid electrolyte solutions. Chem. Fulcher, G. S. Analysis of recent measurements of the viscosity of glasses. Chem. Mater. Vogl, U. S. et al. Kinetic study of parasitic reactions in lithium-ion batteries: a case study on LiNi0.6Mn0.2Co0.2O2. Mater. Zhang, X.-Q., Cheng, X.-B., Chen, X., Yan, C. & Zhang, Q. Fluoroethylene carbonate additives to render uniform Li deposits in lithium metal batteries. Side chain engineering in solution-processable conjugated polymers. 5, 1400993 (2015). Am. Int. 12, 452–457 (2013). 7, 513–537 (2014). CAS  She is the Department Chair of Chemical Engineering from 2018. 4, eaas9820 (2018). 7, A93–A96 (2004). Am. Strong lithium polysulfide chemisorption on electroactive sites of nitrogen-doped carbon composites for high-performance lithium-sulfur battery cathodes. She serves as an advising Partner for Fusion Venture Capital. & Xu, J. Macromolecules 48, 4967–4973 (2015). Chem. J. Electrochem. Phys. Toward efficient binders for Li-ion battery Si-based anodes: polyacrylic acid. Wang, X. et al. 26, 7979–7985 (2014). J. Chem. Obrovac, M. N. & Krause, L. J. Reversible cycling of crystalline silicon powder. Our experimental results demonstrated that a well-known n-channel semiconductor, [6,6]-phenyl C61 butyric acid methyl ester (PCBM), can be effectively doped with N-DMBI by solution processing; the film conductivity is significantly increased by n-type doping. Materials. & Nazar, L. F. Advances in lithium–sulfur batteries based on multifunctional cathodes and electrolytes. J. & Cheng, J. DOI: 10.1002/adfm.201503756 0.88 148, 405–416 (2002). J. Electrochem. Seh, Z. W., Sun, Y., Zhang, Q. Chem. J. 2146: 2010: [9] She was named a Distinguished Member of Technical Staff. Sun, J., Stone, G. M., Balsara, N. P. & Zuckermann, R. N. Structure–conductivity relationship for peptoid-based PEO–mimetic polymer electrolytes. Transforming from planar to three-dimensional lithium with flowable interphase for solid lithium metal batteries. Sci. Mater. Rep. 5, 14458 (2015). RSC Adv. Rev. Bao is a member of the National Academy of Engineering and the National Academy of Inventors. 5, 1042–1048 (2013). A nitrogen and sulfur dual-doped carbon derived from polyrhodanine@cellulose for advanced lithium-sulfur batteries. All authors contributed to the discussion of content and edited the manuscript before submission. She is a fellow of the American Association for the Advancement of Science, American Chemical Society and SPIE and serves on the advisory board for ACS Nano, Advanced Functional Materials, Advanced Energy Materials, Chemical Communications, Chemistry of Materials, Materials Today, Nanoscale, and NPG Asia Materials and the board of directors for the Materials Research Society and the Polymers Materials Science and Engineering division of the American Chemical Society. Zheng, G. et al. Nano Lett. Yu, X. et al. 138, 11044–11050 (2016). Chem. Acc. Adv. 5, 919–923 (2003). & Tominaga, Y. Ratner, M. A. Zhang, L., Zhang, L., Chai, L., Xue, P. & Hao, W. A coordinatively cross-linked polymeric network as a functional binder for high-performance silicon submicro-particle anodes in lithium-ion batteries. Sci. 30, 1704347 (2018). Mater. 39, 2354–2371 (2010). IEEE 100, 1518–1534 (2012). 22, 1229–1241 (2010). The ability to spontaneously repair damage, which is termed as self-healing, is an important survival feature in nature because it increases the lifetime of … Kwon, T.-W., Choi, J. W. & Coskun, A. B., Momčilović, N., Jones, S. C. & Grubbs, R. H. ABA triblock brush polymers: synthesis, self-assembly, conductivity, and rheological properties. Natural fibrous materials with a high refractive index such as cellulose 47 and silk 48 have been actively investigated as optical waveguides owing … Science 359, 72–76 (2018). Identifying the structural basis for the increased stability of the solid electrolyte interphase formed on silicon with the additive fluoroethylene carbonate. Proc. Resolution of the modulus versus adhesion dilemma in solid polymer electrolytes for rechargeable lithium metal batteries. Chem. Interfaces 7, 15961–15967 (2015). Zhenan Bao is part of Stanford Profiles, official site for faculty, postdocs, students and staff information (Expertise, Bio, Research, Publications, and more). J. Zhu, B. et al. 4, 1600377 (2016). Dr. Simiao Niu is a postdoctoral research fellow in Chemical Engineering, Stanford University, under the supervision of Dr. Zhenan Bao. Nature Mater. Nanocomposites of titanium dioxide and polystyrene-poly(ethylene oxide) block copolymer as solid-state electrolytes for lithium metal batteries. Soc. Effect of polyimide binder on electrochemical characteristics of surface-modified silicon anode for lithium ion batteries. (2020) Effects of Water and Different Solutes on Carbon-Nanotube Low-Voltage Field-Effect Transistors. Zhenan Bao joined Stanford University in 2004. Energy 1, 16132 (2016). Res. Single-ion conducting polymer electrolytes for lithium metal polymer batteries that operate at ambient temperature. Doeff, M. M., Edman, L., Sloop, S. E., Kerr, J. Wu, M. et al. Lithium metal anodes with an adaptive ‘solid-liquid’ interfacial protective layer. Chem. Stalin, S., Choudhury, S., Zhang, K. & Archer, L. A. Multifunctional cross-linked polymeric membranes for safe, high-performance lithium batteries. Nat. & Wang, S. Lithium battery chemistries enabled by solid-state electrolytes. 135, 12048–12056 (2013). Song, J. et al. Ryu, S.-W. et al. Decoupling of ionic transport from segmental relaxation in polymer electrolytes. 8, 1701482 (2017). Zeng, X. et al. Funct. Solid State Ion. Zhenan Bao . Sengodu, P. & Deshmukh, A. D. Conducting polymers and their inorganic composites for advanced Li-ion batteries: a review. You are using a browser version with limited support for CSS. Critical roles of binders and formulation at multiscales of silicon-based composite electrodes. 156, 245–257 (1926). Macromolecules 29, 3831–3838 (1996). Yang, H., Leow, W. R. & Chen, X. Thermal-responsive polymers for enhancing safety of electrochemical storage devices. Dendrite-free lithium deposition via self-healing electrostatic shield mechanism. She is known for her work developing technologies with organic field-effect transistors and organic semiconductors. Chem. Mater. A 5, 22156–22162 (2017). Zhenan Bao is K.K. 13, 5534–5540 (2013). Universal relationship between conductivity and solvation-site connectivity in ether-based polymer electrolytes. Soc. Specifically, we discuss the design of polymeric materials for desired mechanical properties, increased ionic and electronic conductivity and specific chemical interactions. & McCloskey, B. D. Promising routes to a high Li+ transference number electrolyte for lithium ion batteries. High rate and stable cycling of lithium metal anode. J. Mater. Macromolecules 50, 1998–2005 (2017). Xu, K. Electrolytes and interphases in Li-ion batteries and beyond. Cohen, M. H. & Turnbull, D. Molecular transport in liquids and glasses. Ceram. She is the Department Chair of Chemical Engineering from 2018. Ranger, M. & Leclerc, M. New base-doped polyfluorene derivatives. Acta 57, 201–206 (2011). Soc. J. Chem. Electrochim. Narrowing the mechanical mismatch between tissue and implantable microelectronics is essential for reducing immune responses and for accommodating … et al. & Kourkoutis, L. F. Cryo-STEM mapping of solid–liquid interfaces and dendrites in lithium-metal batteries. The Zhenan Bao Research Group at Stanford University, Dept. [6][7][8] It was also during this time when Jan Schön produced a series of papers, two of which with Bao as one of the coauthors. Mater. Title. Electrochemical energy storage devices are becoming increasingly important to our global society, and polymer materials are key components of these devices. Chang. Am. She is a member of the National Academy of Engineering and National Academy of Inventors. Wu Y, Xia C, Zhang W, Yang X, Bao ZY, Li JJ, Zhu B. Soc. Adv. Chem. Understanding the role of different conductive polymers in improving the nanostructured sulfur cathode performance. Liu, Y. et al. & West, A. C. Effect of electrolyte composition on lithium dendrite growth. J.L. Nat. Erk, C., Brezesinski, T., Sommer, H., Schneider, R. & Janek, J. [13], She was awarded the Beilby Medal and Prize in 2009. Angew. Molecularly imprinted polymer enables high-efficiency recognition and trapping lithium polysulfides for stable lithium sulfur battery. Chem 4, 174–185 (2018). 3, 31–35 (2008). Chem. 81, 114–143 (2018). Peljo, P. & Girault, H. H. Electrochemical potential window of battery electrolytes: the HOMO–LUMO misconception. Lett. Power Sources 280, 533–549 (2015). Promising and reversible electrolyte with thermal switching behavior for safer electrochemical storage devices. Zhang, X. et al. Hu, W. The melting point of chain polymers. J. 28, 1705015 (2018). ACS Energy Lett. Electron. Solid State Lett. A 4, 10038–10069 (2016). Heeger, A. J., Kivelson, S., Schrieffer, J. R. & Su, W. P. Solitons in conducting polymers. She is currently a K.K. Hallinan, D. T. Jr & Balsara, N. P. Polymer electrolytes. Confining electrodeposition of metals in structured electrolytes. Chem. 6, 6924 (2015). Mater. Beaulieu, L. Y., Eberman, K. W., Turner, R. L., Krause, L. J. Sperling, L. H. Introduction to Physical Polymer Science 427–505 (John Wiley & Sons, 2005). Gauthier, M. et al. Z. Polymer 55, 4067–4076 (2014). The focus is on these design principles applied to advanced silicon, lithium-metal and sulfur battery chemistries. & Su, Y.-S. USA 115, 1156–1161 (2018). Vashishta, P., Mundy, J. N. & Shenoy, G. K. (eds) Fast Ion Transport in Solids 87–107 (North-Holland, 1979). Adv. 27, 6021–6028 (2015). USA 111, 3327–3331 (2014). A 3, 19218–19253 (2015). Chem. Size-dependent fracture of silicon nanoparticles during lithiation. Her innovations include the first all-carbon solar cell, and skin-inspired materials for medical devices, energy storage and environmental applications. 1, 198–205 (2015). Dynamic cross-linking of polymeric binders based on host-guest interactions for silicon anodes in lithium ion batteries. (2021), Chemical Engineering Journal Mater. Rev. Sci. A 2, 7256–7264 (2014). Adv. Kimura, K., Motomatsu, J. Energy Mater. Chem. 414, 1703138 (2018). Sci. Park, K. et al. Mater. Li, Y. et al. A 4, 11203–11206 (2016). Sun, Y., Liu, N. & Cui, Y. 13, 5397–5402 (2013). 5: 149-165: Foudeh AM, Pfattner R, Lu S, et al. Natl Acad. R. Rep. 121, 1–29 (2017). Chem. ACS Nano 6, 1522–1531 (2012). Nitrogen-doped mesoporous carbon promoted chemical adsorption of sulfur and fabrication of high-areal-capacity sulfur cathode with exceptional cycling stability for lithium-sulfur batteries. ACS Cent. Adv. 140, 11735–11744 (2018). She is currently a K.K. Nat. ACS Appl. Zhao, H. et al. 6, 6362 (2015). Sci. Adv. & Lita, A. J. Electrochem. Rev. Sort. Sustainable, heat-resistant and flame-retardant cellulose-based composite separator for high-performance lithium ion battery. Nat Rev Mater 4, 312–330 (2019). 1, 16013 (2016). 15, 937 ... Zhenan Bao is in the Department of Chemical Engineering at Stanford University, California, USA. ACS Energy Lett. Member of Board of Directors, Materials … Mater. Interfaces 10, 7171–7179 (2018). Commun. Jeong, Y. K. et al. Choi, J. W. & Aurbach, D. Promise and reality of post-lithium-ion batteries with high energy densities. Mater. Interfaces 5, 7299–7307 (2013). & De Jonghe, L. C. Transport properties of binary salt polymer electrolytes. Phys. 6, 10101 (2015). Mater. Solid State Lett. Lampel, A. et al. Clim. A flexible solid electrolyte interphase layer for long-life lithium metal anodes. Koo, B. et al. Pang, Q. et al. Nat. The emerging era of supramolecular polymeric binders in silicon anodes. Mater. Nanotechnol. Xue, Z., He, D. & Xie, X. Poly (ethylene oxide)-based electrolytes for lithium-ion batteries. Soc. Adv. Mater. A review of lithium deposition in lithium-ion and lithium metal secondary batteries. Am. https://doi.org/10.1038/s41578-019-0103-6, Taming polysulfides and facilitating lithium-ion migration: Novel electrospinning MOFs@PVDF-based composite separator with spiderweb-like structure for Li-S batteries, Recent advances in high performance conducting solid polymer electrolytes for lithium-ion batteries, Macromolecular Design of Lithium Conductive Polymer as Electrolyte for Solid‐State Lithium Batteries, Structural evolution of β-iPP with different supermolecular structures during the simultaneous biaxial stretching process, A flexible, ion-conducting solid electrolyte with vertically bicontinuous transfer channels toward high performance all-solid-state lithium batteries. Sci. Shi, Y., Zhou, X. Nat. Sci. Adv. [2], She was enrolled in chemistry major at Nanjing University in 1987, and later transferred directly into the Ph.D. program in chemistry at The University of Chicago in 1990. Song, J., Lee, H., Choo, M.-J., Park, J.-K. & Kim, H.-T. Ionomer-liquid electrolyte hybrid ionic conductor for high cycling stability of lithium metal electrodes. 4, 3673–3677 (2013). Qian, J. et al. Mater. 77, 3701–3707 (1955). Nishimoto, A., Agehara, K., Furuya, N., Watanabe, T. & Watanabe, M. High ionic conductivity of polyether-based network polymer electrolytes with hyperbranched side chains. Wu, M. et al. Proc. Mindemark, J., Lacey, M. J., Bowden, T. & Brandell, D. Beyond PEO—alternative host materials for Li+-conducting solid polymer electrolytes. Choi, S., Kwon, T.-W., Coskun, A. Nat. Manipulating the polarity of conductive polymer binders for Si-based anodes in lithium-ion batteries. 22, 645–646 (1921). The Zhenan Bao Research Group at Stanford University, Dept. Aurbach, D. & Cohen, Y. Morphological studies of Li deposition processes in LiAsF6/PC solutions by in situ atomic force microscopy. Chen, S. et al. Chem. Science 334, 75–79 (2011). 16, 25628–25635 (2014). Nano Lett. 114, 11503–11618 (2014). Nano Lett. Lee Professor in Chemical Engineering, and with courtesy appointments in Chemistry and Material Science and Engineering. et al. Adv. J. Electrochem. Chen, Z., Christensen, L. & Dahn, J. R. Comparison of PVDF and PVDF-TFE-P as binders for electrode materials showing large volume changes in lithium-ion batteries. Huang, J.-Q. 60, 119–123 (1993). Nanostructured single-ion-conducting hybrid electrolytes based on salty nanoparticles and block copolymers. Adv. Sci. Nanotechnol. Rev. [3] She is married and has two children. Chem. 136, 7395–7402 (2014). J. Mater. of Chemical Engineering, focuses on the synthesis of functional organic and polymer materials, organic electronic device design and fabrication, and applications for organic electronics. Lu, Q. et al. Magasinski, A. et al. J. She is a member of the National Academy of Engineering and National Academy of Inventors. Garcia, J. M. et al. A 2, 19036–19045 (2014). 2, 2563–2575 (2017). Nature 433, 50–53 (2005). Bao was selected as Nature’s Ten people who mattered in 2015 as a “Master of Materials” for her work on artificial electronic skin. Energy Mater. J. Electrochem. Interfaces 8, 2318–2324 (2016). Energy Environ. Rev. Mater. Mussel-inspired adhesive binders for high-performance silicon nanoparticle anodes in lithium-ion batteries. Commun. Nat. Tung, S.-O., Ho, S., Yang, M., Zhang, R. & Kotov, N. A. Chem. Effects of polymer coatings on electrodeposited lithium metal. & Dahn, J. R. Sodium carboxymethyl cellulose a potential binder for Si negative electrodes for Li-ion batteries. USA 115, 6620–6625 (2018). Long, L., Wang, S., Xiao, M. & Meng, Y. Polymer electrolytes for lithium polymer batteries. A layer-by-layer supramolecular structure for a sulfur cathode. We present here the development of a new solution-processable n-type dopant, N-DMBI. Ceder’s Materials Genome Project (but larger & for molecular materials) • automated infrastructure for unprecedented scale • divide-and-conquer calculation hierarchy: from 6, 1800703 (2018). A 3, 13994–14000 (2015). Rev. and JavaScript. 2, 2454–2462 (2017). Reviving the lithium metal anode for high-energy batteries. Lee Professor in Chemical Engineering, and with courtesy appointments in Chemistry and Material Science and Engineering. Tethered molecular sorbents: enabling metal-sulfur battery cathodes. ACS Appl. Electrochem. Fluoroethylene carbonate and vinylene carbonate reduction: understanding lithium-ion battery electrolyte additives and solid electrolyte interphase formation. Effective approaches to improve the electrical conductivity of PEDOT:PSS: a review. Systematic computational and experimental investigation of lithium-ion transport mechanisms in polyester-based polymer electrolytes. Fluorine-donating electrolytes enable highly reversible 5-V-class Li metal batteries. Adam, G. & Gibbs, J. H. On the temperature dependence of cooperative relaxation properties in glass-forming liquids. Soc. Solid state ionics. She is currently a K.K. Bruce, P. G., Freunberger, S. A., Hardwick, L. J. Mater. Wang, C. et al. Natl Acad. thank the National Science Foundation Graduate Research Fellowship Program for support under grant no. Chintapalli, M. et al. & Coates, G. W. Suppression of lithium dendrite growth using cross-linked polyethylene/poly(ethylene oxide) electrolytes: a new approach for practical lithium-metal polymer batteries.
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