Your search keyword '"Ji, Huiwen"' showing total 10 results

1. Publisher Correction: Unlocking Li superionic conductivity in face-centred cubic oxides via face-sharing configurations

Author

Chen, Yu, Lun, Zhengyan, Zhao, Xinye, Koirala, Krishna Prasad, Li, Linze, Sun, Yingzhi, O’Keefe, Christopher A, Yang, Xiaochen, Cai, Zijian, Wang, Chongmin, Ji, Huiwen, Grey, Clare P, Ouyang, Bin, and Ceder, Gerbrand

Subjects

Inorganic Chemistry, Chemical Sciences, Physical Sciences, Good Health and Well Being, Nanoscience & Nanotechnology

Abstract

Correction to: Nature Materialshttps://doi.org/10.1038/s41563-024-01800-8, published online 2 February 2024. In the version of the article initially published, the x axes in Figs. 2b,d and 5a,b originally read “T−1 (K−1)” and have now been amended to “1000 T−1 (K−1)” in the HTML and PDF versions of the article.

Published

2024

2. Unlocking Li superionic conductivity in face-centred cubic oxides via face-sharing configurations

Author

Chen, Yu, Lun, Zhengyan, Zhao, Xinye, Koirala, Krishna Prasad, Li, Linze, Sun, Yingzhi, O’Keefe, Christopher A, Yang, Xiaochen, Cai, Zijian, Wang, Chongmin, Ji, Huiwen, Grey, Clare P, Ouyang, Bin, and Ceder, Gerbrand

Subjects

Chemical Sciences, Physical Chemistry, Engineering, Physical Sciences, Materials Engineering, Nanoscience & Nanotechnology

Abstract

Oxides with a face-centred cubic (fcc) anion sublattice are generally not considered as solid-state electrolytes as the structural framework is thought to be unfavourable for lithium (Li) superionic conduction. Here we demonstrate Li superionic conductivity in fcc-type oxides in which face-sharing Li configurations have been created through cation over-stoichiometry in rocksalt-type lattices via excess Li. We find that the face-sharing Li configurations create a novel spinel with unconventional stoichiometry and raise the energy of Li, thereby promoting fast Li-ion conduction. The over-stoichiometric Li-In-Sn-O compound exhibits a total Li superionic conductivity of 3.38 × 10-4 S cm-1 at room temperature with a low migration barrier of 255 meV. Our work unlocks the potential of designing Li superionic conductors in a prototypical structural framework with vast chemical flexibility, providing fertile ground for discovering new solid-state electrolytes.

Published

2024

3. Solid-State Calcium-Ion Diffusion in Ca1.5Ba0.5Si5O3N6

Author

Chen, Yu, Bartel, Christopher J, Avdeev, Maxim, Zhang, Ya-Qian, Liu, Jue, Zhong, Peichen, Zeng, Guobo, Cai, Zijian, Kim, Haegyeom, Ji, Huiwen, and Ceder, Gerbrand

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, Materials, Chemical sciences

Abstract

Rechargeable batteries based on multivalent working ions are promising candidates for next-generation high-energy-density batteries. Development of these technologies, however, is largely limited by the low diffusion rate of multivalent ions in solid-state materials, thereby necessitating a better understanding of the design principles that control multivalent-ion mobility. Here, we report Ca1.5Ba0.5Si5O3N6 as a potential calcium solid-state conductor and investigate its Ca migration mechanism by means of ab initio computations and neutron diffraction. This compound contains partially occupied Ca sites in close proximity to each other, providing a unique mechanism for Ca migration. Nuclear density maps obtained with the maximum entropy method from neutron powder diffraction data provide strong evidence for low-energy percolating one-dimensional pathways for Ca-ion migration. Ab initio molecular dynamics simulations further support a low Ca-ion migration barrier of ∼400 meV when Ca vacancies are present and reveal a unique "vacancy-adjacent"concerted ion migration mechanism. This work provides a new understanding of solid-state Ca-ion diffusion and insights into the future design of novel cation configurations that utilize the interactions between mobile ions to enable fast multivalent-ion conduction in solid-state materials.

Published

2022

4. Realizing continuous cation order-to-disorder tuning in a class of high-energy spinel-type Li-ion cathodes

Author

Cai, Zijian, Ji, Huiwen, Ha, Yang, Liu, Jue, Kwon, Deok-Hwang, Zhang, Yaqian, Urban, Alexander, Foley, Emily E, Giovine, Raynald, Kim, Hyunchul, Lun, Zhengyan, Huang, Tzu-Yang, Zeng, Guobo, Chen, Yu, Wang, Jingyang, McCloskey, Bryan D, Balasubramanian, Mahalingam, Clément, Raphaële J, Yang, Wanli, and Ceder, Gerbrand

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, Macromolecular and materials chemistry, Materials engineering, Nanotechnology

Abstract

Conventional Li-ion cathode materials are dominated by well-ordered structures, in which Li and transition metals occupy distinct crystallographic sites. We show in this paper that profoundly new degrees of freedom for the optimization of electrochemical properties may be accessed if controllable cation disorder is introduced. In a class of high-capacity spinel-type cathode materials, we identify cation to anion ratio in synthesis as a key parameter for tuning the structure continuously from a well-ordered spinel, through a partially ordered spinel, to rocksalt. We find that the varying degree of cation disorder modifies the voltage profile, rate capability, and charge-compensation mechanism in a rational and predictable way. Our results indicate that spinel-type order is most beneficial for achieving high-rate performance as long as the cooperative 8a to 16c phase transition is suppressed, while more rocksalt-like disorder facilitates O redox, which can increase capacity. Our findings reveal an important tuning handle for achieving high energy and power in the vast space of partially ordered cathode materials.

Published

2021

5. Cation-disordered rocksalt-type high-entropy cathodes for Li-ion batteries

Author

Lun, Zhengyan, Ouyang, Bin, Kwon, Deok-Hwang, Ha, Yang, Foley, Emily E, Huang, Tzu-Yang, Cai, Zijian, Kim, Hyunchul, Balasubramanian, Mahalingam, Sun, Yingzhi, Huang, Jianping, Tian, Yaosen, Kim, Haegyeom, McCloskey, Bryan D, Yang, Wanli, Clément, Raphaële J, Ji, Huiwen, and Ceder, Gerbrand

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, Nanoscience & Nanotechnology

Abstract

High-entropy (HE) ceramics, by analogy with HE metallic alloys, are an emerging class of solid solutions composed of a large number of species. These materials offer the benefit of large compositional flexibility and can be used in a wide variety of applications, including thermoelectrics, catalysts, superionic conductors and battery electrodes. We show here that the HE concept can lead to very substantial improvements in performance in battery cathodes. Among lithium-ion cathodes, cation-disordered rocksalt (DRX)-type materials are an ideal platform within which to design HE materials because of their demonstrated chemical flexibility. By comparing a group of DRX cathodes containing two, four or six transition metal (TM) species, we show that short-range order systematically decreases, whereas energy density and rate capability systematically increase, as more TM cation species are mixed together, despite the total metal content remaining fixed. A DRX cathode with six TM species achieves 307 mAh g-1 (955 Wh kg-1) at a low rate (20 mA g-1), and retains more than 170 mAh g-1 when cycling at a high rate of 2,000 mA g-1. To facilitate further design in this HE DRX space, we also present a compatibility analysis of 23 different TM ions, and successfully synthesize a phase-pure HE DRX compound containing 12 TM species as a proof of concept.

Published

2021

6. Effect of Fluorination on Lithium Transport and Short‐Range Order in Disordered‐Rocksalt‐Type Lithium‐Ion Battery Cathodes

Author

Ouyang, Bin, Artrith, Nongnuch, Lun, Zhengyan, Jadidi, Zinab, Kitchaev, Daniil A, Ji, Huiwen, Urban, Alexander, and Ceder, Gerbrand

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, cluster expansion, lithium batteries, percolation theory, short-range order, transition metal oxides, Macromolecular and Materials Chemistry, Interdisciplinary Engineering, Macromolecular and materials chemistry, Materials engineering

Abstract

Fluorine substitution is a critical enabler for improving the cycle life and energy density of disordered rocksalt (DRX) Li-ion battery cathode materials which offer prospects for high energy density cathodes, without the reliance on limited mineral resources. Due to the strong Li–F interaction, fluorine also is expected to modify the short-range cation order in these materials which is critical for Li-ion transport. In this work, density functional theory and Monte Carlo simulations are combined to investigate the impact of Li–F short-range ordering on the formation of Li percolation and diffusion in DRX materials. The modeling reveals that F substitution is always beneficial at sufficiently high concentrations and can, surprisingly, even facilitate percolation in compounds without Li excess, giving them the ability to incorporate more transition metal redox capacity and thereby higher energy density. It is found that for F levels below 15%, its effect can be beneficial or disadvantageous depending on the intrinsic short-range order in the unfluorinated oxide, while for high fluorination levels the effects are always beneficial. Using extensive simulations, a map is also presented showing the trade-off between transition-metal capacity, Li-transport, and synthetic accessibility, and two of the more extreme predictions are experimentally confirmed.

Published

2020

7. Design Principles for High-Capacity Mn-Based Cation-Disordered Rocksalt Cathodes

Author

Lun, Zhengyan, Ouyang, Bin, Cai, Zijian, Clément, Raphaële J, Kwon, Deok-Hwang, Huang, Jianping, Papp, Joseph K, Balasubramanian, Mahalingam, Tian, Yaosen, McCloskey, Bryan D, Ji, Huiwen, Kim, Haegyeom, Kitchaev, Daniil A, and Ceder, Gerbrand

Subjects

Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, Macromolecular and Materials Chemistry, Chemical sciences

Abstract

Mn-based Li-excess cation-disordered rocksalt (DRX) oxyfluorides are promising candidates for next-generation rechargeable battery cathodes owing to their large energy densities, the earth abundance, and low cost of Mn. In this work, we synthesized and electrochemically tested four representative compositions in the Li-Mn-O-F DRX chemical space with various Li and F content. While all compositions achieve higher than 200 mAh g−1 initial capacity and good cyclability, we show that the Li-site distribution plays a more important role than the metal-redox capacity in determining the initial capacity, whereas the metal-redox capacity is more closely related to the cyclability of the materials. We apply these insights and generate a capacity map of the Li-Mn-O-F chemical space, LixMn2-xO2-yFy (1.167 ≤ x ≤ 1.333, 0 ≤ y ≤ 0.667), which predicts both accessible Li capacity and Mn-redox capacity. This map allows the design of compounds that balance high capacity with good cyclability.

Published

2020

8. Computational Investigation and Experimental Realization of Disordered High-Capacity Li-Ion Cathodes Based on Ni Redox

Author

Ji, Huiwen, Kitchaev, Daniil A, Lun, Zhengyan, Kim, Hyunchul, Foley, Emily, Kwon, Deok-Hwang, Tian, Yaosen, Balasubramanian, Mahalingam, Bianchini, Matteo, Cai, Zijian, Clément, Raphaële J, Kim, Jae Chul, and Ceder, Gerbrand

Subjects

Affordable and Clean Energy, Chemical Sciences, Engineering, Materials

Abstract

In cation-disordered rocksalt Li-ion cathode materials, an excess of Li with respect to the transition metal content is necessary for the creation of percolating pathways for Li transport. Because of the lower amount of redox-active transition metal, a substantial part of the charge transfer must occur via less reversible oxygen redox. Fluorination can be used to minimize this dependence on oxygen redox by increasing the amount of low-valent transition metal in the compound, but it adds complexity to materials design. Here, we investigate the feasibility of using computationally constructed phase diagrams to facilitate the search for optimal oxyfluorides. We use the phase diagram of LiF-Li3NbO4-NiO to identify Li1.13Ni0.57Nb0.3O1.75F0.25 and Li1.19Ni0.59Nb0.22O1.46F0.54 as two promising compositions and demonstrate that they can be successfully synthesized. These compounds exhibit significantly reduced hysteresis and higher energy density than the previously reported Li1.3Ni0.27Nb0.43O2 compound in this space. Although we generally attribute the improved performance to the increased Ni content enabled by fluorination, a more nuanced relation between fluorination and the cycling behavior is revealed through electrochemical tests, X-ray absorption spectroscopy, solid-state nuclear magnetic resonance spectroscopy, and density functional theory. We find that fluorination increases the voltage, improves cycle life, but reduces the accessibility of Ni redox. Consideration of these effects will facilitate the future design of optimized disordered-rocksalt oxyfluoride cathodes.

Published

2019

9. Hidden structural and chemical order controls lithium transport in cation-disordered oxides for rechargeable batteries

Author

Ji, Huiwen, Urban, Alexander, Kitchaev, Daniil A, Kwon, Deok-Hwang, Artrith, Nongnuch, Ophus, Colin, Huang, Wenxuan, Cai, Zijian, Shi, Tan, Kim, Jae Chul, Kim, Haegyeom, and Ceder, Gerbrand

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Generic health relevance, cond-mat.mtrl-sci

Abstract

Structure plays a vital role in determining materials properties. In lithium ion cathode materials, the crystal structure defines the dimensionality and connectivity of interstitial sites, thus determining lithium ion diffusion kinetics. In most conventional cathode materials that are well-ordered, the average structure as seen in diffraction dictates the lithium ion diffusion pathways. Here, we show that this is not the case in a class of recently discovered high-capacity lithium-excess rocksalts. An average structure picture is no longer satisfactory to understand the performance of such disordered materials. Cation short-range order, hidden in diffraction, is not only ubiquitous in these long-range disordered materials, but fully controls the local and macroscopic environments for lithium ion transport. Our discovery identifies a crucial property that has previously been overlooked and provides guidelines for designing and engineering cation-disordered cathode materials.

Published

2019

10. Design principles for high transition metal capacity in disordered rocksalt Li-ion cathodes

Author

Kitchaev, Daniil A, Lun, Zhengyan, Richards, William D, Ji, Huiwen, Clément, Raphaële J, Balasubramanian, Mahalingam, Kwon, Deok-Hwang, Dai, Kehua, Papp, Joseph K, Lei, Teng, McCloskey, Bryan D, Yang, Wanli, Lee, Jinhyuk, and Ceder, Gerbrand

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, Energy

Abstract

The discovery of facile Li transport in disordered, Li-excess rocksalt materials has opened a vast new chemical space for the development of high energy density, low cost Li-ion cathodes. We develop a strategy for obtaining optimized compositions within this class of materials, exhibiting high capacity and energy density as well as good reversibility, by using a combination of low-valence transition metal redox and a high-valence redox active charge compensator, as well as fluorine substitution for oxygen. Furthermore, we identify a new constraint on high-performance compositions by demonstrating the necessity of excess Li capacity as a means of counteracting high-voltage tetrahedral Li formation, Li-binding by fluorine and the associated irreversibility. Specifically, we demonstrate that 10-12% of Li capacity is lost due to tetrahedral Li formation, and 0.4-0.8 Li per F dopant is made inaccessible at moderate voltages due to Li-F binding. We demonstrate the success of this strategy by realizing a series of high-performance disordered oxyfluoride cathode materials based on Mn2+/4+ and V4+/5+ redox.

Published

2018