Your search keyword '"Hau, Han‐Ming"' showing total 11 results

1. Earth-abundant Li-ion cathode materials with nanoengineered microstructures.

Author

Hau, Han-Ming, Mishra, Tara, Ophus, Colin, Huang, Tzu-Yang, Bustilo, Karen, Sun, Yingzhi, Yang, Xiaochen, Holstun, Tucker, Zhao, Xinye, Wang, Shilong, Ha, Yang, Lee, Gihyeok, Song, Chengyu, Turner, John, Bai, Jianming, Ma, Lu, Chen, Ke, Wang, Feng, Yang, Wanli, Mccloskey, Bryan, Cai, Zijian, and Ceder, Gerbrand

Abstract

Manganese-based materials have tremendous potential to become the next-generation lithium-ion cathode as they are Earth abundant, low cost and stable. Here we show how the mobility of manganese cations can be used to obtain a unique nanosized microstructure in large-particle-sized cathode materials with enhanced electrochemical properties. By combining atomic-resolution scanning transmission electron microscopy, four-dimensional scanning electron nanodiffraction and in situ X-ray diffraction, we show that when a partially delithiated, high-manganese-content, disordered rocksalt cathode is slightly heated, it forms a nanomosaic of partially ordered spinel domains of 3-7 nm in size, which impinge on each other at antiphase boundaries. The short coherence length of these domains removes the detrimental two-phase lithiation reaction present near 3 V in a regular spinel and turns it into a solid solution. This nanodomain structure enables good rate performance and delivers 200 mAh g-1 discharge capacity in a (partially) disordered material with an average primary particle size of ∼5 µm. The work not only expands the synthesis strategies available for developing high-performance Earth-abundant manganese-based cathodes but also offers structural insights into the ability to nanoengineer spinel-like phases.

Published

2024

2. In situ formed partially disordered phases as earth-abundant Mn-rich cathode materials

Author

Cai, Zijian, Ouyang, Bin, Hau, Han-Ming, Chen, Tina, Giovine, Raynald, Koirala, Krishna Prasad, Li, Linze, Ji, Huiwen, Ha, Yang, Sun, Yingzhi, Huang, Jianping, Chen, Yu, Wu, Vincent, Yang, Wanli, Wang, Chongmin, Clément, Raphaële J., Lun, Zhengyan, and Ceder, Gerbrand

Published

2024

3. Thermodynamically Driven Synthetic Optimization for Cation‐Disordered Rock Salt Cathodes

Author

Cai, Zijian, Zhang, Ya‐Qian, Lun, Zhengyan, Ouyang, Bin, Gallington, Leighanne C, Sun, Yingzhi, Hau, Han‐Ming, Chen, Yu, Scott, Mary C, and Ceder, Gerbrand

Subjects

Affordable and Clean Energy, disordered rock salts, Li-ion batteries, short-range order, synthesis science, Macromolecular and Materials Chemistry, Materials Engineering, Interdisciplinary Engineering

Abstract

Relating the synthesis conditions of materials to their functional performance has long been an experience-based trial-and-error process. However, this methodology is not always efficient in identifying an appropriate protocol and can lead to overlooked opportunities for the performance optimization of materials through simple modifications of the synthesis process. In this work, the authors systematically track the structural evolution in the synthesis of a representative disordered rock salt (a promising next-generation Li-ion cathode material) at the scale of both the long-range crystal structure and the short-range atomic structure using various in situ and ex situ techniques, including transmission electron microscopy, X-ray diffraction, and pair distribution function analysis. An optimization strategy is proposed for the synthesis protocol, leading to a remarkably enhanced capacity (specific energy) of 313 mAh g−1 (987 Wh kg−1) at a low rate (20 mA g−1), with a capacity of more than 140 mAh g−1 retained even at a very high cycling rate of 2000 mA g−1. This strategy is further rationalized using ab initio calculations, and important opportunities for synthetic optimization demonstrated in this study are highlighted.

Published

2022

4. Oxygen Dimerization-Driven Cation Migration Induces Voltage Hysteresis in Disordered Rocksalt Cathodes.

Author

Kim, Byunghoon, Zhong, Peichen, Choi, Yunyeong, Anand, Shashwat, Hau, Han-Ming, Deng, Bowen, and Ceder, Gerbrand

Published

2025

5. Fast Room‐Temperature Mg‐Ion Conduction in Clay‐Like Halide Glassy Electrolytes.

Author

Yang, Xiaochen, Gupta, Sunny, Chen, Yu, Sari, Dogancan, Hau, Han‐Ming, Cai, Zijian, Dun, Chaochao, Qi, Miao, Ma, Lu, Liu, Yi, Urban, Jeffrey J., and Ceder, Gerbrand

Subjects

IONIC conductivity, MAGNESIUM ions, ELECTROLYTES, GALLIUM compounds, HALIDES, MAGNESIUM

Abstract

The discovery of mechanically soft solid‐state materials with fast Mg‐ion conduction is crucial for the development of solid‐state magnesium batteries. In this paper, novel magnesium gallium halide compounds are reported that achieve high ionic conductivity of 0.47 mS cm−1 at room temperature. These Mg‐ion conductors obtained by ball milling Mg and Ga salts exhibit clay‐like mechanical properties, enabling intimate contact at the electrode–electrolyte interface during battery cycling. With a combination of experimental and computational analysis, this study identifies that the soft‐clay formation is induced by partial anion exchange during milling. This partial anion exchange creates undercoordinated magnesium ions in a chlorine‐rich environment, yielding fast Mg‐ion conduction. This work demonstrates the potential of clay‐like halide electrolytes for all‐solid‐state magnesium batteries, with possible further extension to other multivalent battery systems. [ABSTRACT FROM AUTHOR]

Published

2024

6. In situ formed partially disordered phases as earth-abundant Mn-rich cathode materials

Author

Cai, Zijian, primary, Ouyang, Bin, additional, Hau, Han-Ming, additional, Chen, Tina, additional, Giovine, Raynald, additional, Koirala, Krishna Prasad, additional, Li, Linze, additional, Ji, Huiwen, additional, Ha, Yang, additional, Sun, Yingzhi, additional, Huang, Jianping, additional, Chen, Yu, additional, Wu, Vincent, additional, Yang, Wanli, additional, Wang, Chongmin, additional, Clément, Raphaële J., additional, Lun, Zhengyan, additional, and Ceder, Gerbrand, additional

Published

2023

7. Chemical Origin of in Situ Carbon Dioxide Outgassing from a Cation-Disordered Rock Salt Cathode

Author

Huang, Tzu-Yang, Cai, Zijian, Crafton, Matthew J., Giovine, Raynald, Patterson, Ashlea, Hau, Han-Ming, Rastinejad, Justin, Rinkel, Bernardine L. D., Clément, Raphaële J., Ceder, Gerbrand, and McCloskey, Bryan D.

Abstract

In situ carbon dioxide (CO2) outgassing is a common phenomenon in lithium-ion batteries (LiBs), primarily due to parasitic side reactions at the cathode–electrolyte interface. However, little is known about the chemical origins of the in situ CO2released from emerging Li-excess cation-disordered rock salt (DRX) cathodes. In this study, we selectively labeled various carbon sources with 13C in cathodes containing a representative DRX material, Li1.2Mn0.4Ti0.4O2(LMTO), and performed differential electrochemical mass spectrometry (DEMS) during galvanostatic cycling in a carbonate-based electrolyte. When charging LMTO cathodes, electrolyte solvent (EC) decomposition is the dominant source of the CO2outgassing. The amount of EC-originated CO2is strongly correlated with the total surface area of carbon black in the electrode, revealing the critical role of electron-conducting carbon additives in the electrolyte degradation mechanisms. In addition, unusual bimodal CO2evolution during the first cycle is found to originate from carbon black oxidation. Overall, the underlying chemical origin of in situ CO2release during battery cycling is highly voltage- and cycle-dependent. This work further provides insights into improving the stability of DRX cathodes in LiBs and is envisioned to help guide future relevant material design to mitigate parasitic reactions in DRX-based batteries.

Published

2024

8. Optimizing Li‐Excess Cation‐Disordered Rocksalt Cathode Design Through Partial Li Deficiency

Author

Huang, Liliang, primary, Zhong, Peichen, additional, Ha, Yang, additional, Cai, Zijian, additional, Byeon, Young‐Woon, additional, Huang, Tzu‐Yang, additional, Sun, Yingzhi, additional, Xie, Fengyu, additional, Hau, Han‐Ming, additional, Kim, Haegyeom, additional, Balasubramanian, Mahalingam, additional, McCloskey, Bryan D., additional, Yang, Wanli, additional, and Ceder, Gerbrand, additional

Published

2022

9. Optimizing Li‐Excess Cation‐Disordered Rocksalt Cathode Design Through Partial Li Deficiency.

Author

Huang, Liliang, Zhong, Peichen, Ha, Yang, Cai, Zijian, Byeon, Young‐Woon, Huang, Tzu‐Yang, Sun, Yingzhi, Xie, Fengyu, Hau, Han‐Ming, Kim, Haegyeom, Balasubramanian, Mahalingam, McCloskey, Bryan D., Yang, Wanli, and Ceder, Gerbrand

Subjects

CATHODES, MONTE Carlo method, DENSITY functional theory, LITHIUM-ion batteries, TRANSITION metals, ELECTROCHEMICAL electrodes

Abstract

Li‐excess disordered rocksalts (DRXs) are emerging as promising cathode materials for Li‐ion batteries due to their ability to use earth‐abundant transition metals. In this work, a new strategy based on partial Li deficiency engineering is introduced to optimize the overall electrochemical performance of DRX cathodes. Specifically, by using Mn‐based DRX as a proof‐of‐concept, it is demonstrated that the introduction of cation vacancies during synthesis (e.g., Li1.3‐xMn2+0.4‐xMn3+xNb0.3O1.6F0.4, x = 0, 0.2, and 0.4) improves both the discharge capacity and rate performance due to the more favored short‐range order in the presence of Mn3+. Density functional theory calculations and Monte Carlo simulations, in combination with spectroscopic tools, reveal that introducing 10% vacancies (Li1.1Mn2+0.2Mn3+0.2Nb0.3O1.6F0.4) enables both Mn2+/Mn3+ redox and excellent Li percolation. However, a more aggressive vacancy doping (e.g., 20% vacancies in Li0.9Mn3+0.4Nb0.3O1.6F0.4) impairs performance because it induces phase separation between an Mn‐rich and a Li‐rich phase. [ABSTRACT FROM AUTHOR]

Published

2023

10. Tuning State Energies for Narrow Blue Emission in Tetradentate Pyridyl-Carbazole Platinum Complexes.

Author

Fleetham, Tyler, Golden, Jessica H., Idris, Muazzam, Hau, Han-Ming, Muthiah Ravinson, Daniel Sylvinson, Djurovich, Peter I., and Thompson, Mark E.

Published

2019

11. Accelerating the Electrochemical Formation of the δ Phase in Manganese-Rich Rocksalt Cathodes.

Author

Holstun T, Mishra TP, Huang L, Hau HM, Anand S, Yang X, Ophus C, Bustillo K, Ma L, Ehrlich S, and Ceder G

Abstract

Mn-rich disordered rocksalt materials with Li-excess (DRX) materials have emerged as a promising class of earth-abundant and energy-dense next-generation cathode materials for lithium-ion batteries. Recently, an electrochemical transformation to a spinel-like "δ" phase has been reported in Mn-rich DRX materials, with improved capacity, rate capability, and cycling stability compared with previous DRX compositions. However, this transformation unfolds slowly over the course of cycling, complicating the development and understanding of these materials. In this work, it is reported that the transformation of Mn-rich DRX materials to the promising δ phase can be promoted to occur much more rapidly by electrochemical pulsing at elevated temperature, rate, and voltage. To extend this concept, micron-sized single-crystal DRX particles are also transformed to the δ phase by the same method, possessing greatly improved cycling stability in the first demonstration of cycling for large, single-crystal DRX particles. To shed light on the formation and specific structure of the δ phase, X-ray diffraction, scanning electron nanodiffraction (SEND) and atomic resolution STEM-HAADF are used to reveal a nanodomain spinel structure with minimal remnant disorder., (© 2024 The Author(s). Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024