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3. Correlating the Formation Protocols of Solid Electrolyte Interphases with Practical Performance Metrics in Lithium Metal Batteries

Author

Solomon T. Oyakhire, Wenbo Zhang, Zhiao Yu, Sarah E. Holmes, Philaphon Sayavong, Sang Cheol Kim, David T. Boyle, Mun Sek Kim, Zewen Zhang, Yi Cui, and Stacey F. Bent

Subjects
Fuel Technology, Renewable Energy, Sustainability and the Environment, Chemistry (miscellaneous), Materials Chemistry, Energy Engineering and Power Technology
Published
2023
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4. High Entropy Electrolytes for Practical Lithium Metal Batteries

Author

Sang Cheol Kim, Jingyang Wang, Rong Xu, Pu Zhang, Yuelang Chen, Zhuojun Huang, Yufei Yang, Zhiao Yu, Solomon Oyakhire, Wenbo Zhang, Louisa Greenburg, Mun Sek Kim, David Boyle, Philaphon Sayavong, Yusheng Ye, Jian Qin, Zhenan Bao, and Yi Cui

Abstract

Electrolyte engineering is crucial for improving battery performance, particularly for lithium metal batteries. Recent advances in electrolytes have greatly improved cyclability by enhancing electrochemical stability at the electrode interfaces, but concurrently achieving high ionic conductivity has remained challenging. Here we report an electrolyte design strategy for enhanced lithium metal batteries by increasing the molecular diversity in electrolytes, which essentially leads to high entropy electrolytes (HEEs). We find that in weakly solvating electrolytes, the entropy effect reduces ion clustering while preserving the characteristic anion-rich solvation structures, which is characterized by synchrotron-based X-ray scattering and molecular dynamics simulations. Electrolytes with smaller-sized clusters exhibit a 2-fold improvement in ionic conductivity compared to conventional weakly-solvating electrolytes, enabling stable cycling at high current densities up to 2C (6.2 mA cm-2) in anode-free LiNi0.6Mn0.2Co0.2 (NMC622) || Cu pouch cells. The efficacy of the design strategy is verified by performance improvements in three disparate weakly solvating electrolyte systems.

Published
2023
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10. Data-driven electrolyte design for lithium metal anodes

Author

Sang Cheol Kim, Solomon T. Oyakhire, Constantine Athanitis, Jingyang Wang, Zewen Zhang, Wenbo Zhang, David T. Boyle, Mun Sek Kim, Zhiao Yu, Xin Gao, Tomi Sogade, Esther Wu, Jian Qin, Zhenan Bao, Stacey F. Bent, and Yi Cui

Subjects
Multidisciplinary
Abstract

Improving Coulombic efficiency (CE) is key to the adoption of high energy density lithium metal batteries. Liquid electrolyte engineering has emerged as a promising strategy for improving the CE of lithium metal batteries, but its complexity renders the performance prediction and design of electrolytes challenging. Here, we develop machine learning (ML) models that assist and accelerate the design of high-performance electrolytes. Using the elemental composition of electrolytes as the features of our models, we apply linear regression, random forest, and bagging models to identify the critical features for predicting CE. Our models reveal that a reduction in the solvent oxygen content is critical for superior CE. We use the ML models to design electrolyte formulations with fluorine-free solvents that achieve a high CE of 99.70%. This work highlights the promise of data-driven approaches that can accelerate the design of high-performance electrolytes for lithium metal batteries.

Published
2023
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11. Suspension electrolyte with modified Li+ solvation environment for lithium metal batteries

Author

Mun Sek Kim, Zewen Zhang, Paul E. Rudnicki, Zhiao Yu, Jingyang Wang, Hansen Wang, Solomon T. Oyakhire, Yuelang Chen, Sang Cheol Kim, Wenbo Zhang, David T. Boyle, Xian Kong, Rong Xu, Zhuojun Huang, William Huang, Stacey F. Bent, Lin-Wang Wang, Jian Qin, Zhenan Bao, and Yi Cui

Subjects
Mechanics of Materials, Mechanical Engineering, General Materials Science, General Chemistry, Condensed Matter Physics
Published
2022
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12. Rational solvent molecule tuning for high-performance lithium metal battery electrolytes

Author

Zhiao Yu, Paul E. Rudnicki, Zewen Zhang, Zhuojun Huang, Hasan Celik, Solomon T. Oyakhire, Yuelang Chen, Xian Kong, Sang Cheol Kim, Xin Xiao, Hansen Wang, Yu Zheng, Gaurav A. Kamat, Mun Sek Kim, Stacey F. Bent, Jian Qin, Yi Cui, and Zhenan Bao

Subjects
Fuel Technology, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, Electronic, Optical and Magnetic Materials
Published
2022
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13. High Entropy Electrolytes for Practical Lithium Metal Batteries

Author

Sang Cheol Kim, Jingyang Wang, Rong Xu, Pu Zhang, Yuelang Chen, Zhuojun Huang, Yufei Yang, Zhiao Yu, Solomon Oyakhire, Wenbo Zhang, Mun Sek Kim, David Boyle, Philaphon Sayavong, Jian Qin, Zhenan Bao, and Yi Cui

Abstract

Electrolyte engineering is a critical approach to improve battery performance, particularly for lithium metal batteries. In this work, we introduce the concept of high entropy electrolytes (HEEs) that achieve improved ionic conductivity while maintaining excellent electrochemical stability. We find that increasing the molecular diversity and concomitantly the mixing entropy of weakly solvating electrolytes can reduce ion clustering while retaining anion-rich solvation structure, confirmed through synchrotron-based X-ray scattering and molecular dynamics simulations. Less clustered electrolytes exhibit higher diffusivity and ionic conductivity, enabling high current density cycling up to 2C (> 6 mA cm-2) for up to ~80 cycles in anode-free NMC-Cu pouch cells. We substantiate the generality of the concept by verifying performance improvement in three disparate electrolyte systems. This work highlights a large unexplored design space of HEEs that can improve electrolyte properties for lithium metal batteries.

Published
2022
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14. Monolithic optical microlithography of high-density elastic circuits

Author

Chenxin Zhu, Hung-Chin Wu, Helen Tran, Zhenan Bao, Donglai Zhong, Zhiao Yu, Jinxing Li, Jeffrey B.-H. Tok, Shuhan Liu, Yuxin Liu, Deyu Liu, Yu-Qing Zheng, and Shayla Nikzad

Subjects
Adder, Multidisciplinary, Materials science, business.industry, Stretchable electronics, Transistor, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Signal, 0104 chemical sciences, law.invention, Arithmetic logic unit, Nanolithography, law, Optoelectronics, 0210 nano-technology, business, XOR gate, Electronic circuit
Abstract

Direct optical polymer patterning As a platform for electronic devices, polymeric materials offer the advantages of intrinsic flexibility and stretchability relative to hard material devices. However, unlike materials such as silicon, there are few tools for large-scale patterning of monolithic devices. Zheng et al. developed an optical lithography technique for the high-throughput fabrication of transistor circuitry on stretchable substrates. In this method, ultraviolet light is used to control the local solubility of the polymer, which makes it possible to fabricate transistors on the micrometer scale. These devices can be made with high yield and excellent uniformity without compromising their electronic and mechanical characteristics. Science , abh3551, this issue p. 88

Published
2021
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15. A Stretchable and Highly Conductive Sulfonic Pendent Single-Ion Polymer Electrolyte Derived from Multifunctional Tri-Block Polyether

Author

Caixia Liu, Xudong Jia, Yifeng Cai, Zhiao Yu, Wen Yan, Haomin Wu, Qiuhong Zhang, and Wencan Ma

Subjects
chemistry.chemical_classification, Materials science, Polymers and Plastics, Single ion, Chemical engineering, chemistry, Process Chemistry and Technology, Block (telecommunications), Organic Chemistry, Electrolyte, Polymer, Electrical conductor
Published
2021
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16. Corrosion of lithium metal anodes during calendar ageing and its microscopic origins

Author

David T. Boyle, Hao Chen, Hansen Wang, Zhenan Bao, William Huang, Yuzhang Li, Zhiao Yu, Wenbo Zhang, and Yi Cui

Subjects
Materials science, Passivation, Renewable Energy, Sustainability and the Environment, Open-circuit voltage, Metallurgy, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, Corrosion, Anode, Metal, Fuel Technology, chemistry, Ageing, visual_art, visual_art.visual_art_medium, Lithium, 0210 nano-technology
Abstract

Rechargeable lithium (Li) metal batteries must have long cycle life and calendar life (retention of capacity during storage at open circuit). Particular emphasis has been placed on prolonging the cycle life of Li metal anodes, but calendar ageing is less understood. Here, we show that Li metal loses at least 2–3% of its capacity after only 24 hours of ageing, regardless of the electrolyte chemistry. These losses of capacity during calendar ageing also shorten the cycle life of Li metal batteries. Cryogenic transmission electron microscopy shows that chemical corrosion of Li and the continuous growth of the solid electrolyte interphase—a passivation film on Li—cause the loss of capacity. Electrolytes with long cycle life do not necessarily form a solid electrolyte interphase with more resistance to chemical corrosion, so functional electrolytes must simultaneously minimize the rate of solid electrolyte interphase growth and the surface area of electrodeposited Li metal. Batteries keep degrading even when they are not in operation, but their calendar life is rarely studied in advanced batteries that are still in the development stage. Here the authors quantify the calendar ageing of Li metal anodes and report its underlying mechanisms.

Published
2021
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17. Efficient Lithium Metal Cycling over a Wide Range of Pressures from an Anion-Derived Solid-Electrolyte Interphase Framework

Author

Rong Xu, Wenxiao Huang, Zewen Zhang, Yi Cui, Zhenan Bao, Hansen Wang, William Huang, and Zhiao Yu

Subjects
Range (particle radiation), Materials science, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Anode, Ion, Metal, Fuel Technology, chemistry, Chemical engineering, Chemistry (miscellaneous), visual_art, Materials Chemistry, visual_art.visual_art_medium, Interphase, Lithium, 0210 nano-technology, Cycling
Abstract

Advanced electrolytes were developed to improve the cyclability of lithium (Li) metal anodes, yet their working mechanisms remain unclear. Here, we study the Li cycling performance under different ...

Published
2021
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18. Multivalent Assembly of Flexible Polymer Chains into Supramolecular Nanofibers

Author

Shayla Nikzad, Zhiao Yu, Hung-Chin Wu, Yikai Yin, Christopher B. Cooper, Wei Cai, Yuto Ochiai, Hongping Yan, Zhenan Bao, and Jiheong Kang

Subjects
chemistry.chemical_classification, Supramolecular chemistry, Nanotechnology, General Chemistry, Polymer, 010402 general chemistry, 01 natural sciences, Biochemistry, Catalysis, 0104 chemical sciences, Molecular dynamics, Colloid and Surface Chemistry, chemistry, Nanofiber, Order of magnitude
Abstract

Polymeric materials in nature regularly employ ordered, hierarchical structures in order to perform unique and precise functions. Importantly, these structures are often formed and stabilized by the cooperative summation of many weak interactions as opposed to the independent association of a few strong bonds. Here, we show that synthetic, flexible polymer chains with periodically placed and directional dynamic bonds collectively assemble into supramolecular nanofibers when the overall molecular weight is below the polymer's critical entanglement molecular weight. This causes bulk films of long polymer chains to have faster dynamics than films of shorter polymer chains of identical chemical composition. The formation of nanofibers increases the bulk film modulus by over an order of magnitude and delays the onset of terminal flow by more than 100 °C, while still remaining solution processable. Systematic investigation of different polymer chain architectures and dynamic bonding moieties along with coarse-grained molecular dynamics simulations illuminate governing structure-function relationships that determine a polymer's capacity to form supramolecular nanofibers. This report of the cooperative assembly of multivalent polymer chains into hierarchical, supramolecular structures contributes to our fundamental understanding of designing biomimetic functional materials.

Published
2020
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19. Molecular design for electrolyte solvents enabling energy-dense and long-cycling lithium metal batteries

Author

David G. Mackanic, Kecheng Wang, Jian Qin, Wenxiao Huang, Yuchi Tsao, Yi Cui, Samantha T. Hung, Yuting Ma, Hansen Wang, Eder G. Lomeli, Zhenan Bao, Xian Kong, Chibueze V. Amanchukwu, Yu Zheng, Xinchang Wang, Zhiao Yu, William Huang, and Snehashis Choudhury

Subjects
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, 01 natural sciences, Cathode, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, Anode, law.invention, Metal, Solvent, Fuel Technology, Chemical engineering, law, visual_art, visual_art.visual_art_medium, Lithium metal, 0210 nano-technology, Faraday efficiency
Abstract

Electrolyte engineering is critical for developing Li metal batteries. While recent works improved Li metal cyclability, a methodology for rational electrolyte design remains lacking. Herein, we propose a design strategy for electrolytes that enable anode-free Li metal batteries with single-solvent single-salt formations at standard concentrations. Rational incorporation of –CF2– units yields fluorinated 1,4-dimethoxylbutane as the electrolyte solvent. Paired with 1 M lithium bis(fluorosulfonyl)imide, this electrolyte possesses unique Li–F binding and high anion/solvent ratio in the solvation sheath, leading to excellent compatibility with both Li metal anodes (Coulombic efficiency ~ 99.52% and fast activation within five cycles) and high-voltage cathodes (~6 V stability). Fifty-μm-thick Li|NMC batteries retain 90% capacity after 420 cycles with an average Coulombic efficiency of 99.98%. Industrial anode-free pouch cells achieve ~325 Wh kg−1 single-cell energy density and 80% capacity retention after 100 cycles. Our design concept for electrolytes provides a promising path to high-energy, long-cycling Li metal batteries. The realization of the full potential of Li metal batteries requires high-performance electrolytes. Here Z. Bao and colleagues develop low-concentration electrolytes with a single-solvent and single-salt formulation, offering promise for high-energy and long-cycling batteries.

Published
2020
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20. Tuning the Mechanical Properties of a Polymer Semiconductor by Modulating Hydrogen Bonding Interactions

Author

Xiaodan Gu, Jaewan Mun, Zhenan Bao, Song Zhang, Hung-Chin Wu, Yu-Qing Zheng, Shayla Nikzad, Jiheong Kang, Jeffrey B.-H. Tok, Minoru Ashizawa, Zhiao Yu, Yuto Ochiai, Yu Zheng, and Helen Tran

Subjects
chemistry.chemical_classification, Materials science, Strain (chemistry), business.industry, General Chemical Engineering, Intermolecular force, Modulus, 02 engineering and technology, General Chemistry, Polymer, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Strain energy, Crystallinity, Semiconductor, chemistry, Materials Chemistry, Composite material, Thin film, 0210 nano-technology, business
Abstract

Conjugation breakers (CBs) with different H-bonding chemistries and linker flexibilities are designed and incorporated into a diketopyrrolopyrrole (DPP)-based conjugated polymer backbone. The effects of H-bonding interactions on polymer semiconductor morphology, mechanical properties, and electrical performance are systematically investigated. We observe that CBs with an H-bonding self-association constant >0.7 or a denser packing tendency are able to induce higher polymer chain aggregation and crystallinity in as-casted thin films, resulting in a higher modulus and crack on-set strain. Additionally, the rDoC (relative degree of crystallinity) of the stretched thin film with the highest crack on-set strain only suffers a small decrease, suggesting the main energy dissipation mechanism is the breakage of H-bonding interactions. By contrast, other less stretchable polymer films dissipate strain energy through the breakage of crystalline domains, indicated by a drastic decrease in rDoC. Furthermore, we evaluate their electrical performances under mechanical strain in fully stretchable field-effect transistors. The polymer with the highest crack on-set strain has the least degradation in mobility as a function of strain. Overall, these observations suggest that we can aptly tune the mechanical properties of a polymer semiconductor by modulating intermolecular interactions, such as H-bonding chemistry and linker flexibility. Such understanding provides molecular design guidelines for future stretchable semiconductors.

Published
2020
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21. Capturing the swelling of solid-electrolyte interphase in lithium metal batteries

Author

Zewen Zhang, Yuzhang Li, Rong Xu, Weijiang Zhou, Yanbin Li, Solomon T. Oyakhire, Yecun Wu, Jinwei Xu, Hansen Wang, Zhiao Yu, David T. Boyle, William Huang, Yusheng Ye, Hao Chen, Jiayu Wan, Zhenan Bao, Wah Chiu, and Yi Cui

Subjects
Multidisciplinary
Abstract

Preservation of cycling behavior Understanding the changes in interfaces between electrode and electrolyte during battery cycling, including the formation of the solid-electrolyte interphase (SEI), is key to the development of longer lasting batteries. Z. Zhang et al . adapt a thin-film vitrification method to ensure the preservation of liquid electrolyte so that the samples taken for analysis using microscopy and spectroscopy better reflect the state of the battery during operation. A key finding is that the SEI is in a swollen state, in contrast to current belief that it only contained solid inorganic species and polymers. The extent of swelling can affect transport through the SEI, which thickens with time, and thus might also decrease the amount of free electrolyte available for battery cycling. —MSL

Published
2022

22. Slidable and Highly Ionic Conductive Polymer Binder for High‐Performance Si Anodes in Lithium‐Ion Batteries

Author

Yifeng Cai, Caixia Liu, Zhiao Yu, Wencan Ma, Qi Jin, Ruichun Du, Bingyun Qian, Xinxin Jin, Haomin Wu, Qiuhong Zhang, and Xudong Jia

Subjects
General Chemical Engineering, General Engineering, General Physics and Astronomy, Medicine (miscellaneous), General Materials Science, Biochemistry, Genetics and Molecular Biology (miscellaneous)
Abstract

Silicon is expected to become the ideal anode material for the next generation of high energy density lithium battery because of its high theoretical capacity (4200 mAh g

Published
2022
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23. Steric Effect Tuned Ion Solvation Enabling Stable Cycling of High-Voltage Lithium Metal Battery

Author

Yi Cui, Jian-Cheng Lai, Zhiao Yu, Zhenan Bao, Sang Cheol Kim, Paul E. Rudnicki, Huaxin Gong, Zhuojun Huang, Yuelang Chen, Xian Kong, and Jian Qin

Subjects
Battery (electricity), Inorganic chemistry, Solvation, chemistry.chemical_element, General Chemistry, Electrolyte, Electrochemistry, Biochemistry, Catalysis, Cathode, law.invention, Anode, Colloid and Surface Chemistry, chemistry, law, Lithium, Faraday efficiency
Abstract

1,2-Dimethoxyethane (DME) is a common electrolyte solvent for lithium metal batteries. Various DME-based electrolyte designs have improved long-term cyclability of high-voltage full cells. However, insufficient Coulombic efficiency at the Li anode and poor high-voltage stability remain a challenge for DME electrolytes. Here, we report a molecular design principle that utilizes a steric hindrance effect to tune the solvation structures of Li+ ions. We hypothesized that by substituting the methoxy groups on DME with larger-sized ethoxy groups, the resulting 1,2-diethoxyethane (DEE) should have a weaker solvation ability and consequently more anion-rich inner solvation shells, both of which enhance interfacial stability at the cathode and anode. Experimental and computational evidence indicates such steric-effect-based design leads to an appreciable improvement in electrochemical stability of lithium bis(fluorosulfonyl)imide (LiFSI)/DEE electrolytes. Under stringent full-cell conditions of 4.8 mAh cm-2 NMC811, 50 μm thin Li, and high cutoff voltage at 4.4 V, 4 M LiFSI/DEE enabled 182 cycles until 80% capacity retention while 4 M LiFSI/DME only achieved 94 cycles. This work points out a promising path toward the molecular design of non-fluorinated ether-based electrolyte solvents for practical high-voltage Li metal batteries.

Published
2021

24. A molecular design approach towards elastic and multifunctional polymer electronics

Author

Zhitao Zhang, Jian-Cheng Lai, Shayla Nikzad, Wesley Michaels, Iain McCulloch, Yu Zheng, Zhenan Bao, Donglai Zhong, Weimin Zhang, Song Zhang, Christopher B. Cooper, Weichen Wang, Jiheong Kang, Nathaniel Prine, Deyu Liu, Xian Kong, Jaewan Mun, Gan Chen, Jian Qin, Zhiao Yu, Xiaodan Gu, and Jeffrey B.-H. Tok

Subjects
Electronic materials, Polymers, Science, General Physics and Astronomy, Nanotechnology, Dielectric, Article, General Biochemistry, Genetics and Molecular Biology, law.invention, Natural rubber, law, Electronic devices, Electronics, Elasticity (economics), chemistry.chemical_classification, Multidisciplinary, business.industry, Transistor, General Chemistry, Polymer, Semiconductor, chemistry, Covalent bond, visual_art, visual_art.visual_art_medium, business
Abstract

Next-generation wearable electronics require enhanced mechanical robustness and device complexity. Besides previously reported softness and stretchability, desired merits for practical use include elasticity, solvent resistance, facile patternability and high charge carrier mobility. Here, we show a molecular design concept that simultaneously achieves all these targeted properties in both polymeric semiconductors and dielectrics, without compromising electrical performance. This is enabled by covalently-embedded in-situ rubber matrix (iRUM) formation through good mixing of iRUM precursors with polymer electronic materials, and finely-controlled composite film morphology built on azide crosslinking chemistry which leverages different reactivities with C–H and C=C bonds. The high covalent crosslinking density results in both superior elasticity and solvent resistance. When applied in stretchable transistors, the iRUM-semiconductor film retained its mobility after stretching to 100% strain, and exhibited record-high mobility retention of 1 cm2 V−1 s−1 after 1000 stretching-releasing cycles at 50% strain. The cycling life was stably extended to 5000 cycles, five times longer than all reported semiconductors. Furthermore, we fabricated elastic transistors via consecutively photo-patterning of the dielectric and semiconducting layers, demonstrating the potential of solution-processed multilayer device manufacturing. The iRUM represents a molecule-level design approach towards robust skin-inspired electronics., Next-generation skin-inspired electronics require enhanced mechanical robustness and device complexity including elasticity, solvent resistance, and facile patternability. Here, the authors show a molecular design concept that simultaneously achieves all these requirements by covalently linking an in-situ formed rubber matrix with polymer electronic materials.

Published
2021
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25. High-brightness all-polymer stretchable LED with charge-trapping dilution

Author

Zhitao Zhang, Weichen Wang, Yuanwen Jiang, Yi-Xuan Wang, Yilei Wu, Jian-Cheng Lai, Simiao Niu, Chengyi Xu, Chien-Chung Shih, Cheng Wang, Hongping Yan, Luke Galuska, Nathaniel Prine, Hung-Chin Wu, Donglai Zhong, Gan Chen, Naoji Matsuhisa, Yu Zheng, Zhiao Yu, Yang Wang, Reinhold Dauskardt, Xiaodan Gu, Jeffrey B.-H. Tok, and Zhenan Bao

Subjects
Multidisciplinary
Abstract

Next-generation light-emitting displays on skin should be soft, stretchable and bright

Published
2021

26. Suspension electrolyte with modified Li

Author

Mun Sek, Kim, Zewen, Zhang, Paul E, Rudnicki, Zhiao, Yu, Jingyang, Wang, Hansen, Wang, Solomon T, Oyakhire, Yuelang, Chen, Sang Cheol, Kim, Wenbo, Zhang, David T, Boyle, Xian, Kong, Rong, Xu, Zhuojun, Huang, William, Huang, Stacey F, Bent, Lin-Wang, Wang, Jian, Qin, Zhenan, Bao, and Yi, Cui

Subjects
Electrolytes, Electric Power Supplies, Lithium, Electrodes
Abstract

Designing a stable solid-electrolyte interphase on a Li anode is imperative to developing reliable Li metal batteries. Herein, we report a suspension electrolyte design that modifies the Li

Published
2021

27. A Dynamic, Electrolyte-Blocking, and Single-Ion-Conductive Network for Stable Lithium-Metal Anodes

Author

Minah Lee, Jiheong Kang, Yuchi Tsao, Hansen Wang, Qiuhong Zhang, Zhenan Bao, Kai Liu, David G. Mackanic, Xuzhou Yan, Yi Cui, Wesley Michaels, Chibueze V. Amanchukwu, Allen Pei, Jian Qin, Zhiao Yu, Shucheng Chen, and Dawei Feng

Subjects
Materials science, 02 engineering and technology, Electrolyte, engineering.material, Conductivity, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Anode, General Energy, Coating, Chemical engineering, engineering, Interphase, 0210 nano-technology, Electrical conductor, Faraday efficiency, Ion transporter
Abstract

Summary Implementation of lithium (Li)-metal anodes requires developments to solve the heterogeneity and instability issues of naturally formed solid-electrolyte interphase (SEI). The artificial SEI, as an alternative, enables an ideal interface by regulating critical features such as fast ion transport, conformal protection, and parasitic reaction mitigation. Herein, for the first time, we integrate all of these desired properties into a single matrix, the dynamic single-ion-conductive network (DSN), as a multifunctional artificial SEI. The DSN incorporates the tetrahedral Al(OR)4− (R = soft fluorinated linker) centers as both dynamic bonding motifs and counter anions, endowing it with flowability and Li+ single-ion conductivity. Simultaneously, the fluorinated linkers provide chain mobility and electrolyte-blocking capability. A solution-processed DSN coating was found to simultaneously hinder electrolyte penetration, mitigate side reactions between Li and electrolyte, maintain low interfacial impedance, and allow homogenous Li deposition. With this coating, long cycle life and high Coulombic efficiency are achieved for Li-metal battery in a commercial carbonate electrolyte.

Published
2019
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28. Dynamic Impedance Spectroscopy of Lithium Plating from Next Generation Electrolytes

Author

Robert L Sacci, Andrew S Westover, Zhiao Yu, and Zhenan Bao

Abstract

The anode-free cells have emerged due to the need to maximize Li metal batteries' energy density. However, anode-free Li batteries suffer from short cycle life because of the lack of Li inventory at the anode. Freshly deposited Li metal anodes usually take hundreds of cycles to reach initial SEI stabilization optimum coulombic efficiency (CE) due to initial SEI stabilization and electrode activation. The anode-free cell design requires high Li metal CE over the whole cycling life, particularly during the initial activation cycles. A holistic approach to electrolyte design, mechanism understanding, and battery engineering is needed to fulfill these requirements. Here, we present a mechanistic study on lithium plating and stripping from next generation electrolytes. We conducted dynamic impedance spectroscopy (dEIS) to probe the formation and evolution of the SEI during Li plating and stripping on copper current collectors. dEIS superimposes a multisine waveform atop the dc stimulus signal, as shown by the lightly shaded curves in Fig 1 (top left). We applied a sliding window FFT protocol that takes the complex ratio of the measured potential and current signals obtained from Fig 1 (top right) and transforms it into complex impedance. We will discuss two Li platting systems, Lipon (an amorphous ceramic) and a liquid electrolyte with stabilizing additives. We observed drastic changes in the cells' impedance during plating and stripping, Figure 1 (bottom plots). We will show how the passivation layer's impedance continues to evolve during Li cycling and accounts for a significant amount of the overall cell resistance. The US Department of Energy’s Energy Efficiency and Renewable Energy Vehicles Technologies Office provided funding for this work under the US-German Cooperation on Energy Storage: Lithium-Solid-Electrolyte Interfaces program. Figure 1

Published
2022
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29. High Energy Density Shape Memory Polymers Using Strain-Induced Supramolecular Nanostructures

Author

Jiheong Kang, Zhiao Yu, Shayla Nikzad, Hongping Yan, Zhenan Bao, Yuto Ochiai, Gan Chen, Christopher B. Cooper, and Jian-Cheng Lai

Subjects
chemistry.chemical_classification, Materials science, Nanostructure, Strain (chemistry), General Chemical Engineering, Supramolecular chemistry, General Chemistry, Polymer, Trapping, Chemistry, Shape-memory polymer, chemistry, Chemical physics, Energy density, QD1-999, Research Article
Abstract

Shape memory polymers are promising materials in many emerging applications due to their large extensibility and excellent shape recovery. However, practical application of these polymers is limited by their poor energy densities (up to ∼1 MJ/m3). Here, we report an approach to achieve a high energy density, one-way shape memory polymer based on the formation of strain-induced supramolecular nanostructures. As polymer chains align during strain, strong directional dynamic bonds form, creating stable supramolecular nanostructures and trapping stretched chains in a highly elongated state. Upon heating, the dynamic bonds break, and stretched chains contract to their initial disordered state. This mechanism stores large amounts of entropic energy (as high as 19.6 MJ/m3 or 17.9 J/g), almost six times higher than the best previously reported shape memory polymers while maintaining near 100% shape recovery and fixity. The reported phenomenon of strain-induced supramolecular structures offers a new approach toward achieving high energy density shape memory polymers., We report an approach to achieve a high energy density shape memory polymer based on the formation of strain-induced supramolecular nanostructures, which immobilize stretched chains to store entropic energy.

Published
2021

30. Potentiometric Measurement to Probe Solvation Energy and Its Correlation to Lithium Battery Cyclability

Author

Yuelang Chen, Xian Kong, Zhiao Yu, Yi Cui, Rafael A. Vilá, Zhenan Bao, Hansen Wang, Jian Qin, David T. Boyle, Sang Cheol Kim, and William Y. C. Huang

Subjects
Battery (electricity), Open-circuit voltage, Chemistry, Inorganic chemistry, Potentiometric titration, Solvation, General Chemistry, Electrolyte, 010402 general chemistry, 01 natural sciences, Biochemistry, Catalysis, Lithium battery, 0104 chemical sciences, Anode, Colloid and Surface Chemistry, Electrode
Abstract

The electrolyte plays a critical role in lithium-ion batteries, as it impacts almost every facet of a battery's performance. However, our understanding of the electrolyte, especially solvation of Li+, lags behind its significance. In this work, we introduce a potentiometric technique to probe the relative solvation energy of Li+ in battery electrolytes. By measuring open circuit potential in a cell with symmetric electrodes and asymmetric electrolytes, we quantitatively characterize the effects of concentration, anions, and solvents on solvation energy across varied electrolytes. Using the technique, we establish a correlation between cell potential (Ecell) and cyclability of high-performance electrolytes for lithium metal anodes, where we find that solvents with more negative cell potentials and positive solvation energies-those weakly binding to Li+-lead to improved cycling stability. Cryogenic electron microscopy reveals that weaker solvation leads to an anion-derived solid-electrolyte interphase that stabilizes cycling. Using the potentiometric measurement for characterizing electrolytes, we establish a correlation that can guide the engineering of effective electrolytes for the lithium metal anode.

Published
2021

31. A flexible and highly conductive quasi-solid single-ion polymer electrolyte for high performance Li-metal batteries

Author

Yifeng Cai, Caixia Liu, Zhiao Yu, Haomin Wu, Yaoda Wang, Wencan Ma, Qiuhong Zhang, and Xudong Jia

Subjects
History, Polymers and Plastics, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, Business and International Management, Electrical and Electronic Engineering, Physical and Theoretical Chemistry, Industrial and Manufacturing Engineering
Published
2022
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32. A Solution‐Processable High‐Modulus Crystalline Artificial Solid Electrolyte Interphase for Practical Lithium Metal Batteries

Author

Zhiao Yu, Samuel Seo, Jongchan Song, Zewen Zhang, Solomon T. Oyakhire, Yang Wang, Rong Xu, Huaxin Gong, Song Zhang, Yu Zheng, Yuchi Tsao, Luca Mondonico, Eder G. Lomeli, Xinchang Wang, Wonkeun Kim, Kyounghan Ryu, and Zhenan Bao

Subjects
Renewable Energy, Sustainability and the Environment, General Materials Science
Published
2022
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33. Dynamic spatial progression of isolated lithium during battery operations

Author

Fang Liu, Rong Xu, Yecun Wu, David Thomas Boyle, Ankun Yang, Jinwei Xu, Yangying Zhu, Yusheng Ye, Zhiao Yu, Zewen Zhang, Xin Xiao, Wenxiao Huang, Hansen Wang, Hao Chen, and Yi Cui

Subjects
Multidisciplinary
Abstract

The increasing demand for next-generation energy storage systems necessitates the development of high-performance lithium batteries

Published
2020

34. Onboard early detection and mitigation of lithium plating in fast-charging batteries

Author

Wenxiao Huang, Yusheng Ye, Hao Chen, Rafael A. Vilá, Andrew Xiang, Hongxia Wang, Fang Liu, Zhiao Yu, Jinwei Xu, Zewen Zhang, Rong Xu, Yecun Wu, Lien-Yang Chou, Hansen Wang, Junwei Xu, David Tomas Boyle, Yuzhang Li, and Yi Cui

Subjects
Multidisciplinary, Affordable and Clean Energy, General Physics and Astronomy, General Chemistry, General Biochemistry, Genetics and Molecular Biology
Abstract

Fast-charging is considered as one of the most desired features needed for lithium-ion batteries to accelerate the mainstream adoption of electric vehicles. However, current battery charging protocols mainly consist of conservative rate steps to avoid potential hazardous lithium plating and its associated parasitic reactions. A highly sensitive onboard detection method could enable battery fast-charging without reaching the lithium plating regime. Here, we demonstrate a novel differential pressure sensing method to precisely detect the lithium plating event. By measuring the real-time change of cell pressure per unit of charge (dP/dQ) and comparing it with the threshold defined by the maximum of dP/dQ during lithium-ion intercalation into the negative electrode, the onset of lithium plating before its extensive growth can be detected with high precision. In addition, we show that by integrating this differential pressure sensing into the battery management system (BMS), a dynamic self-regulated charging protocol can be realized to effectively extinguish the lithium plating triggered by low temperature (0 °C) while the conventional static charging protocol leads to catastrophic lithium plating at the same condition. We propose that differential pressure sensing could serve as an early nondestructive diagnosis method to guide the development of fast-charging battery technologies.

Published
2020

35. A New Class of Ionically Conducting Fluorinated Ether Electrolytes with High Electrochemical Stability

Author

Xian Kong, Yi Cui, Chibueze V. Amanchukwu, Jian Qin, Zhenan Bao, and Zhiao Yu

Subjects
Battery energy, Colloid and Surface Chemistry, Chemical engineering, Chemistry, Fluorinated ether, General Chemistry, Electrolyte, Electronics, Electrochemistry, Biochemistry, Catalysis
Abstract

Increasing battery energy density is greatly desired for applications such as portable electronics and transportation. However, many next-generation batteries are limited by electrolyte selection because high ionic conductivity and poor electrochemical stability are typically observed in most electrolytes. For example, ether-based electrolytes have high ionic conductivity but are oxidatively unstable above 4 V, which prevents the use of high-voltage cathodes that promise higher energy densities. In contrast, hydrofluoroethers (HFEs) have high oxidative stability but do not dissolve lithium salt. In this work, we synthesize a new class of fluorinated ether electrolytes that combine the oxidative stability of HFEs with the ionic conductivity of ethers in a single compound. We show that conductivities of up to 2.7 × 10

Published
2020

36. Tuning Fluorination of Linear Carbonate for Lithium-Ion Batteries

Author

Zhiao Yu, Weilai Yu, Yuelang Chen, Luca Mondonico, Xin Xiao, Yu Zheng, Fang Liu, Samantha T. Hung, Yi Cui, and Zhenan Bao

Subjects
Renewable Energy, Sustainability and the Environment, Materials Chemistry, Electrochemistry, Condensed Matter Physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials
Abstract

Liquid electrolyte engineering plays a critical role in modern lithium-ion batteries. However, the existing electrolytes fall short when used with some trending battery chemistries such as high-voltage and high-energy-density electrodes. Fluorination of electrolyte solvents has been identified as an effective approach for improved cyclability, but few works systematically studied the effects of fluorination extent of carbonate solvents on battery performance. Here we design and synthesize a family of fluorinated ethyl methyl carbonates. Different numbers of F atoms are finely tuned to yield monofluoroethyl methyl carbonate (F1EMC), difluoroethyl methyl carbonate (F2EMC) and trifluoroethyl methyl carbonate (F3EMC). The cycling behavior of several types of lithium-ion pouch cells, including graphite (Gr)/single-crystalline LiNi0.8Mn0.1Co0.1O2 (SC-NMC811), Gr-SiOx/LiNi0.6Mn0.2Co0.2O2 (NMC622), high-voltage Gr/LiNi0.5Mn1.5O4 (LNMO), Gr/layered Li-rich Mn-based oxide (LLMO) and fast-charging Gr/NMC622, were systematically investigated to understand the impact of fluorination degree. Compared to the commercially available F3EMC, we found that the partially-fluorinated F1EMC and F2EMC in some cases showed improved cycling stability, which we attribute to their locally-polar –CH2F and –CHF2 groups and thus fast ion conduction than –CF3. This work suggests that highly or fully fluorinated solvents are not necessarily desirable; instead, fluorination degree needs to be rationally and finely tuned for optimized lithium-ion cell performance.

Published
2022
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38. Influence of solution-state aggregation on conjugated polymer crystallization in thin films and microwire crystals

Author

Yu-Qing Zheng, Shayla Nikzad, Lin Zou, Wen-Bin Zhang, Zhiao Yu, Yilin Wang, Jin-Hu Dou, Jie-Yu Wang, Jian Pei, Qi-Yi Li, Ze-Hao Sun, Ze-Fan Yao, and Wei Ma

Subjects
Polymer nanowire, chemistry.chemical_classification, Electron mobility, Science (General), Materials science, Polymers and Plastics, Crystallization of polymers, Intermolecular force, Self-assembly, General Chemistry, Polymer, Conjugated polymers, Conjugated system, Side chain effect, Surfaces, Coatings and Films, law.invention, Q1-390, Chemical engineering, chemistry, Field-effect transistor, law, Materials Chemistry, Side chain, Crystallization, Alkyl
Abstract

Highly ordered nanostructures assembled from conjugated polymers have great potential for probing fundamental structure-property relationships, as well as boosting the charge transport performance. To date, the effect of solution-state aggregation on crystallization and charge transport in conjugated polymers is still unclear and in need of precise description at the molecular level. In this work, we report a systematic study of solution-state aggregation on crystallization and charge transport in BDOPV-based conjugated polymers through side chain engineering. Detailed analysis of crystal packing structures of conjugated polymers reveals that intermolecular displacements are substantially modified in order to minimize steric hindrance caused by the alkyl side chains. Moreover, subtle differences in side chain chemical structures play a vital role in regulating solution-state aggregation, and thus crystalline domain sizes in both microwires and thin films. Farther branched side chain leads to larger polymer aggregates in solution and therefore larger crystalline domains in solid films. Subsequently, an increase in electron mobility is obtained with the highest mobility values surpassing 10 cm2 V−1 s−1. This work unravels that the modification of the side chains is an efficient strategy for fine-tuning the interchain organization of conjugated polymers from solution to solid state.

Published
2021
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39. Decoupling of mechanical properties and ionic conductivity in supramolecular lithium ion conductors

Author

Naoji Matsuhisa, Zhenan Bao, Xuzhou Yan, Xiaodong Chen, Kai Liu, David G. Mackanic, Jeffrey Lopez, Yi Cui, Tuheen Manika, Yuanwen Jiang, Qiuhong Zhang, Hongping Yan, and Zhiao Yu

Subjects
Materials science, Science, Supramolecular chemistry, General Physics and Astronomy, Ionic bonding, Mechanical properties, Nanotechnology, 02 engineering and technology, Electrolyte, 010402 general chemistry, Supramolecular polymers, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, Batteries, Ionic conductivity, lcsh:Science, Electrical conductor, chemistry.chemical_classification, Conductive polymer, Multidisciplinary, Polymer characterization, General Chemistry, Polymer, 021001 nanoscience & nanotechnology, 0104 chemical sciences, chemistry, lcsh:Q, 0210 nano-technology, Decoupling (electronics)
Abstract

The emergence of wearable electronics puts batteries closer to the human skin, exacerbating the need for battery materials that are robust, highly ionically conductive, and stretchable. Herein, we introduce a supramolecular design as an effective strategy to overcome the canonical tradeoff between mechanical robustness and ionic conductivity in polymer electrolytes. The supramolecular lithium ion conductor utilizes orthogonally functional H-bonding domains and ion-conducting domains to create a polymer electrolyte with unprecedented toughness (29.3 MJ m−3) and high ionic conductivity (1.2 × 10−4 S cm−1 at 25 °C). Implementation of the supramolecular ion conductor as a binder material allows for the creation of stretchable lithium-ion battery electrodes with strain capability of over 900% via a conventional slurry process. The supramolecular nature of these battery components enables intimate bonding at the electrode-electrolyte interface. Combination of these stretchable components leads to a stretchable battery with a capacity of 1.1 mAh cm−2 that functions even when stretched to 70% strain. The method reported here of decoupling ionic conductivity from mechanical properties opens a promising route to create high-toughness ion transport materials for energy storage applications., Typically, ion conducting polymers exhibit a trade-off between mechanical robustness and ionic conducting performance. Here, the authors utilize supramolecular chemistry obtaining extremely tough electrolytes with high ionic conductivity and enabling stretchable lithium-ion batteries.

Published
2019
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40. Organic Semiconducting Alloys with Tunable Energy Levels

Author

Jian Pei, Jin-Hu Dou, Yi Qin Gao, Junliang Sun, Yu-Qing Zheng, Ze-Fan Yao, Jie-Yu Wang, Xinchang Wang, Shiliang Huang, Xiao-Yu Cao, Chengwen Liu, Zhiao Yu, Jun Zhang, Zeyi Tu, and Yuanping Yi

Subjects
Dopant, Chemistry, Doping, Intermolecular force, Stacking, General Chemistry, Orbital overlap, 010402 general chemistry, 01 natural sciences, Biochemistry, Catalysis, 0104 chemical sciences, Organic semiconductor, Condensed Matter::Materials Science, Colloid and Surface Chemistry, Chemical physics, Intramolecular force, Single crystal
Abstract

Continuous band structure tuning, e.g., doping with different atoms, is one of the most important features of inorganic semiconductors. However, this can hardly be realized in organic semicondutors. Here, we report the first example of fine-tuning organic semiconductor band structures by alloying structurally similar derivatives into one single phase. By incorporating halogen atoms on different positions of the backbone, BDOPV derivatives with complementary intramolecular or intermolecular charge distributions were obtained. To maximize the Coloumbic attractive interactions and minimize repulsive interactions, they form antiparallel cofacial stacking in monocomponent or in alloy single crystals, resulting in efficient π orbital overlap. Benefiting from self-assembly induced solid state "olefin metathesis" reaction, it was observed, for the first time, that three BDOPV derivatives cocrystallized in one single crystal. Molecules with different energy levels serve like the dopants in inorganic semiconductors. Consequently, as the total number of halogen atoms increased, highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO) levels of the alloy single crystals decreased monotonously in the range from -5.94 to -6.96 eV and -4.19 to -4.48 eV, respectively.

Published
2019

41. Polymers in Lithium‐Ion and Lithium Metal Batteries

Author

Qiuhong Zhang, Yifeng Cai, Haomin Wu, Xudong Jia, Zhenan Bao, Theodore Z. Gao, Junheng Li, Zhiao Yu, Kai Liu, and Xuzhou Yan

Subjects
chemistry.chemical_classification, Materials science, chemistry, Chemical engineering, Renewable Energy, Sustainability and the Environment, Polymer electrolytes, chemistry.chemical_element, General Materials Science, Lithium, Polymer, Lithium metal, Ion
Published
2021
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42. Design Principles of Artificial Solid Electrolyte Interphases for Lithium-Metal Anodes

Author

Yi Cui, Zhiao Yu, and Zhenan Bao

Subjects
Materials science, Passivation, General Engineering, General Physics and Astronomy, Design elements and principles, General Chemistry, Electrolyte, Conductivity, Thermal conduction, Engineering physics, lcsh:QC1-999, Anode, General Energy, Electrode, General Materials Science, Lithium metal, lcsh:Physics
Abstract

Lithium metal is a promising anode to provide high energy density for next-generation batteries. However, it has not been implemented due to its low cycling efficiency, which results from the formation of an unstable solid electrolyte interphase (SEI). The SEIs formed with traditional liquid electrolytes are heterogeneous and easy to crack during cycling, thus resulting in the formation of dendritic and dead Li, and further devastating the electrode performance. To solve these issues, efforts have been made to replace natural SEIs with artificial SEIs (ASEIs). Here, we discuss critical design principles of ASEIs based on the understanding of SEI failure mechanisms. Three key principles for a successful ASEI are identified: (1) mechanical stability, which can be either high strength or adaptivity, (2) spatially uniform Li+ transport with moderate conductivity and even single-ion conduction, and (3) chemical passivation to mitigate Li-electrolyte parasitic reactions. Selected examples of recently developed ASEIs are categorized and elaborated. Finally, future directions are given for ASEI designs.

Published
2020
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43. A Cofacially Stacked Electron-Deficient Small Molecule with a High Electron Mobility of over 10 cm2V−1s−1in Air

Author

Ting Lei, Shi-Ding Zhang, Guangchao Han, Jie-Yu Wang, Ze-Fan Yao, Jian Pei, Yu-Qing Zheng, Zhi Wang, Xingxing Shen, Zhiao Yu, Yuanping Yi, Xuyi Luo, and Jin-Hu Dou

Subjects
Models, Molecular, Electron mobility, Materials science, Transistors, Electronic, Air, Mechanical Engineering, Molecular Conformation, Electrons, Electron, Molecular physics, Electron transport chain, Small molecule, Molecular conformation, Electron Transport, Mechanics of Materials, Polyvinyls, General Materials Science, Field-effect transistor, Atomic physics, HOMO/LUMO
Abstract

A strong, electron-deficient small molecule, F4 -BDOPV, has a lowest unoccupied molecular orbital (LUMO) level down to -4.44 eV and exhibits cofacial packing in single crystals. These features provide F4 -BDOPV with good ambient stability and large charge-transfer integrals for electrons, leading to a high electron mobility of up to 12.6 cm(2) V(-1) s(-1) in air.

Published
2015
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44. Fine-Tuning of Crystal Packing and Charge Transport Properties of BDOPV Derivatives through Fluorine Substitution

Author

Ze-Fan Yao, Jin-Hu Dou, Ting Lei, Junliang Sun, Guangchao Han, Yu-Qing Zheng, Yuanping Yi, Shi-Ding Zhang, Xuyi Luo, Yi-Fan Ding, Xingxing Shen, Zhiao Yu, Jie-Yu Wang, and Jian Pei

Subjects
Stereochemistry, Intermolecular force, Substituent, Stacking, Charge density, chemistry.chemical_element, General Chemistry, Biochemistry, Catalysis, Crystal, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Chemical physics, Fluorine, Molecule, Density functional theory
Abstract

Molecular packing in organic single crystals greatly influences their charge transport properties but can hardly be predicted and designed because of the complex intermolecular interactions. In this work, we have realized systematic fine-tuning of the single-crystal molecular packing of five benzodifurandione-based oligo(p-phenylenevinylene) (BDOPV)-based small molecules through incorporation of electronegative fluorine atoms on the BDOPV backbone. While these molecules all exhibit similar column stacking configurations in their single crystals, the intermolecular displacements and distances can be substantially modified by tuning of the amounts and/or the positions of the substituent fluorine atoms. Density functional theory calculations showed that the subtle differences in charge distribution or electrostatic potential induced by different fluorine substitutions play an important role in regulating the molecular packing of the BDOPV compounds. Consequently, the electronic couplings for electron transfer can vary from 71 meV in a slipped stack to 201 meV in a nearly cofacial antiparallel stack, leading to an increase in the electron mobility of the BDOPV derivatives from 2.6 to 12.6 cm(2) V(-1) s(-1). The electron mobility of the five molecules did not show a good correlation with the LUMO levels, indicating that the distinct difference in charge transport properties is a result of the molecular packing. Our work not only provides a series of high-electron-mobility organic semiconductors but also demonstrates that fluorination is an effective approach for fine-tuning of single-crystal packing modes beyond simply lowering the molecular energy levels.

Published
2015

45. Field-Effect Transistors: A Cofacially Stacked Electron-Deficient Small Molecule with a High Electron Mobility of over 10 cm2V−1s−1in Air (Adv. Mater. 48/2015)

Author

Jian Pei, Ze-Fan Yao, Yuanping Yi, Jie-Yu Wang, Ting Lei, Yu-Qing Zheng, Guangchao Han, Zhi Wang, Xingxing Shen, Zhiao Yu, Xuyi Luo, Shi-Ding Zhang, and Jin-Hu Dou

Subjects
Electron mobility, Materials science, Mechanics of Materials, business.industry, Mechanical Engineering, Optoelectronics, General Materials Science, Nanotechnology, Field-effect transistor, Electron, business, Small molecule
Published
2015
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