Your search keyword '"Xu, Gui-Liang"' showing total 223 results

201. High‐Voltage and High‐Safety Practical Lithium Batteries with Ethylene Carbonate‐Free Electrolyte.

Author

Wu, Yu, Ren, Dongsheng, Liu, Xiang, Xu, Gui‐Liang, Feng, Xuning, Zheng, Yuejiu, Li, Yalun, Yang, Min, Peng, Yong, Han, Xuebing, Wang, Li, Chen, Zonghai, Ren, Yang, Lu, Languang, He, Xiangming, Chen, Jitao, Amine, Khalil, and Ouyang, Minggao

Subjects

*ELECTROLYTES, *HIGH voltages, *ETHYLENE carbonates, *ETHYLENE, *ALKENES, *ELECTRIC batteries, *LITHIUM cells, *LITHIUM-ion batteries

Abstract

Serious safety issues are impeding the widespread adoption of high‐energy lithium‐ion batteries for transportation electrification and large‐scale grid storage. Herein, a triple‐salt ethylene carbonate (EC) free electrolyte for high‐safety and high‐energy pouch‐type LiNi0.8Mn0.1Co0.1O2|graphite (NMC811|Gr) cells is reported. This EC‐free electrolyte can effectively stabilize the NMC811 surface under high potential (up to 4.5 V), as well as generate a stable interphase to achieve a superior compatibility with the Gr anode. The electrolyte strategy enables significantly enhanced intrinsic safety (trigger temperature of thermal runaway (TR) increased by 67.0 °C), excellent electrochemical properties (4.2V, ≈100% after 200 cycles), and superior high voltage stability (4.5 V, 82.1% after 200 cycles). The work opens up a new avenue for developing novel electrolyte systems to build safer high‐energy batteries for practical applications. [ABSTRACT FROM AUTHOR]

Published

2021

202. PtBi intermetallic and PtBi intermetallic with the Bi-rich surface supported on porous graphitic carbon towards HCOOH electro-oxidation.

Author

Zhang, Bin-Wei, Jiang, Yan-Xia, Ren, Jie, Qu, Xi-Ming, Xu, Gui-Liang, and Sun, Shi-Gang

Subjects

*PLATINUM compounds, *INTERMETALLIC compounds, *METALLIC surfaces, *ELECTROLYTIC oxidation, *POROUS materials synthesis

Abstract

Well-dispersed PtBi intermetallic and PtBi intermetallic with Bi-rich surface supported on the porous graphitic carbon have been synthesized by using hydrogen gas to reduce the Pt and Bi precursors. TEM images indicated that the simple and clean method can effectively synthesize those PtBi intermetallics with uniform dispersion and small size (below 3 nm) on the porous graphitic carbon. Electrochemical characterization revealed that PtBi intermetallic with Bi-rich surface showed extremely high mass activity and stability towards oxidizing of formic acid. Combining precursors’ melt-diffusion strategy with the following effective reduction by the hydrogen gas, the proposed method is easy to scale up and has promising potential for synthesizing anode electro-catalyst of direct formic acid fuel cells. [ABSTRACT FROM AUTHOR]

Published

2015

203. Correction to: Tuning working potential of silicon‑phosphorus anode via microstructure control for high‑energy lithium‑ion batteries.

Author

Daali, Amine, Zhao, Chen, Zhou, Xinwei, Yang, Zhenzhen, Amine, Rachid, Liu, Yuzi, Wilkistar, Otieno, Xu, Gui‑Liang, and Amine, Khalil

Subjects

*LITHIUM-ion batteries, *ANODES, *COPYRIGHT, *MICROSTRUCTURE, *PHOSPHORUS in water

Published

2022

204. Establishing substitution rules of functional groups for high-capacity organic anode materials in Na-ion batteries.

Author

Holguin, Kathryn, Qin, Kaiqiang, Kamphaus, Ethan Phillip, Chen, Fu, Cheng, Lei, Xu, Gui-Liang, Amine, Khalil, and Luo, Chao

Subjects

*FUNCTIONAL groups, *ANODES, *SODIUM dichromate, *ENERGY storage, *MOLECULAR structure, *POLYANILINES, *GRAPHENE oxide

Abstract

Tailoring molecular structures of organic electrode materials (OEMs) can enhance their performance in Na-ion batteries, however, the substitution rules and the consequent effect on the specific capacity and working potential remain elusive. Herein, by examining three sodium carboxylates with selective N substitution or extended conjugation structure, we exploited the correlation between structure and performance to establish substitution rules for high-capacity OEMs. Our results show that substitution position and types of functional groups are essential to create active centers for uptake/removal of Na+ and thermodynamically stabilize organic structures. Furthermore, rational host design and electrolytes modulation were performed to extend the cycle life to 500 cycles. A full cell based on the optimal 2,2′-bipyridine-4,4′-dicarboxylic acid disodium salt anode and the polyaniline cathode is demonstrated to confirm the feasibility of achieving all-organic batteries. This work provides a valuable guideline for the design principle of high-capacity and stable OEMs for sustainable energy storage. [Display omitted] • N substituted carboxylates are exploited as anode materials in Na-ion batteries. • Impacts of N substitution and conjugation structure to performance are explored. • N-doped reduced graphene oxide is used to enhance the electrochemical performance. • All-organic Na-ion full cells have been demonstrated. • Substitution rules of functional groups in carboxylate anodes are discussed. [ABSTRACT FROM AUTHOR]

Published

2022

205. Tailoring-Orientated Deposition of Li 2 S for Extreme Fast-Charging Lithium-Sulfur Batteries.

Author

Yu JH, Lee BJ, Zhou S, Sung JH, Zhao C, Shin CH, Yu B, Xu GL, Amine K, and Yu JS

Abstract

Precipitation/dissolution of insulating Li 2 S has long been recognized as the rate-determining step in lithium-sulfur (Li-S) batteries, which dramatically undermines sulfur utilization at elevated charging rates. Herein, we present an orientated Li 2 S deposition strategy to achieve extreme fast charging (XFC, ≤15 min) through synergistic control of porosity, electronic conductivity, and anchoring sites of electrode substrate. Via magnesiothermic reduction of a zeolitic imidazolate framework, a nitrogen-doped and hierarchical porous carbon with highly graphitic phase was developed. This design effectively reduces interfacial resistance and ensures efficient sequestration of polysulfides during deposition, leading to (110)-preferred growth of Li 2 S nanocrystalline between (002)-dominated graphitic layers. Our approach directs an alternative Li 2 S deposition pathway to the commonly reported lateral growth and 3D thickening growth mode, ameliorating the electrode passivation. Therefore, a Li-S cell capable of charging/discharging at 5C (12 min) while maintaining excellent cycling stability (82% capacity retention) for 1000 cycles is demonstrated. Even under high S loading (8.3 mg cm -2 ) and low electrolyte/sulfur ratio (3.8 mL mg -1 ), the sulfur cathode still delivers a high areal capacity of >7 mAh cm -2 for 80 cycles.

Published

2024

206. Microstrain screening towards defect-less layered transition metal oxide cathodes.

Author

Zuo W, Gim J, Li T, Hou D, Gao Y, Zhou S, Zhao C, Jia X, Yang Z, Liu Y, Xu W, Xiao X, Xu GL, and Amine K

Abstract

Microstrain and the associated surface-to-bulk propagation of structural defects are known to be major roadblocks to developing high-energy and long-life batteries. However, the origin and effects of microstrain during the synthesis of battery materials remain largely unknown. Here we perform microstrain screening during real-time and realistic synthesis of sodium layered oxide cathodes. Evidence gathered from multiscale in situ synchrotron X-ray diffraction and microscopy characterization collectively reveals that the spatial distribution of transition metals within individual precursor particles strongly governs the nanoscale phase transformation, local charge heterogeneity and accumulation of microstrain during synthesis. This unexpected dominance of transition metals results in a counterintuitive outward propagation of defect nucleation and growth. These insights direct a more rational synthesis route to reduce the microstrain and crystallographic defects within the bulk lattice, leading to significantly improved structural stability. The present work on microstrain screening represents a critical step towards synthesis-by-design of defect-less battery materials., Competing Interests: Competing interests The authors declare no competing interests., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

207. Chemo-mechanical behaviour of Ni-rich layered cathodes: insights from operando monitoring.

Author

Zhou S, Xu GL, and Amine K

Published

2024

208. High-Energy Earth-Abundant Cathodes with Enhanced Cationic/Anionic Redox for Sustainable and Long-Lasting Na-Ion Batteries.

Author

Zhang X, Zuo W, Liu S, Zhao C, Li Q, Gao Y, Liu X, Xiao D, Hwang I, Ren Y, Sun CJ, Chen Z, Wang B, Feng Y, Yang W, Xu GL, Amine K, and Yu H

Abstract

Layered iron/manganese-based oxides are a class of promising cathode materials for sustainable batteries due to their high energy densities and earth abundance. However, the stabilization of cationic and anionic redox reactions in these cathodes during cycling at high voltage remain elusive. Here, an electrochemically/thermally stable P2-Na 0.67 Fe 0.3 Mn 0.5 Mg 0.1 Ti 0.1 O 2 cathode material with zero critical elements is designed for sodium-ion batteries (NIBs) to realize a highly reversible capacity of ≈210 mAh g -1 at 20 mA g -1 and good cycling stability with a capacity retention of 74% after 300 cycles at 200 mA g -1 , even when operated with a high charge cut-off voltage of 4.5 V versus sodium metal. Combining a suite of cutting-edge characterizations and computational modeling, it is shown that Mg/Ti co-doping leads to stabilized surface/bulk structure at high voltage and high temperature, and more importantly, enhances cationic/anionic redox reaction reversibility over extended cycles with the suppression of other undesired oxygen activities. This work fundamentally deepens the failure mechanism of Fe/Mn-based layered cathodes and highlights the importance of dopant engineering to achieve high-energy and earth-abundant cathode material for sustainable and long-lasting NIBs., (© 2024 UChicago Argonne, LLC, Operator of Argonne National Laboratory and University of California, Operator of Lawrence Berkeley National Laboratory and The Author(s). Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

209. Protonation Stimulates the Layered to Rock Salt Phase Transition of Ni-Rich Sodium Cathodes.

Author

Xiao B, Zheng Y, Song M, Liu X, Lee GH, Omenya F, Yang X, Engelhard MH, Reed D, Yang W, Amine K, Xu GL, Balbuena PB, and Li X

Abstract

Protonation of oxide cathodes triggers surface transition metal dissolution and accelerates the performance degradation of Li-ion batteries. While strategies are developed to improve cathode material surface stability, little is known about the effects of protonation on bulk phase transitions in these cathode materials or their sodium-ion battery counterparts. Here, using NaNiO 2 in electrolytes with different proton-generating levels as model systems, a holistic picture of the effect of incorporated protons is presented. Protonation of lattice oxygens stimulate transition metal migration to the alkaline layer and accelerates layered-rock-salt phase transition, which leads to bulk structure disintegration and anisotropic surface reconstruction layers formation. A cathode that undergoes severe protonation reactions attains a porous architecture corresponding to its multifold performance fade. This work reveals that interactions between electrolyte and cathode that result in protonation can dominate the structural reversibility/stability of bulk cathodes, and the insight sheds light for the development of future batteries., (© 2023 Battelle Memorial Institute. Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

210. Regulating Li Nucleation and Growth Heterogeneities via Near-Surface Lithium-Ion Irrigation for Stable Anode-Less Lithium Metal Batteries.

Author

Xie C, Zhao C, Jeong H, Liu Q, Li T, Xu W, Cheng L, Xu GL, Amine K, and Chen G

Abstract

The inhomogeneous nucleation and growth of Li dendrite combined with the spontaneous side reactions with the electrolytes dramatically challenge the stability and safety of Li metal anode (LMA). Despite tremendous endeavors, current success relies on the use of significant excess of Li to compensate the loss of active Li during cycling. Herein, a near-surface Li + irrigation strategy is developed to regulate the inhomogeneous Li deposition behavior and suppress the consequent side reactions under limited Li excess condition. The conformal polypyrrole (PPy) coating layer on Cu surface via oxidative chemical vapor deposition technique can induce the migration of Li + to the interregional space between PPy and Cu, creating a near-surface Li + -rich region to smooth diffusion of ion flux and uniform the deposition. Moreover, as evidenced by multiscale characterizations including synchrotron high-energy X-ray diffraction scanning, a robust N-rich solid-electrolyte interface (SEI) is formed on the PPy skeleton to effectively suppress the undesired SEI formation/dissolution process. Strikingly, stable Li metal cycling performance under a high areal capacity of 10 mAh cm -2 at 2.0 mA cm -2 with merely 0.5 × Li excess is achieved. The findings not only resolve the long-standing poor LMA stability/safety issues, but also deepen the mechanism understanding of Li deposition process., (© 2023 UChicago Argonne, LLC and The Authors. Small published by Wiley‐VCH GmbH.)

Published

2024

211. Implanting Transition Metal into Li 2 O-Based Cathode Prelithiation Agent for High-Energy-Density and Long-Life Li-Ion Batteries.

Author

Chen Y, Zhu Y, Zuo W, Kuai X, Yao J, Zhang B, Sun Z, Yin J, Wu X, Zhang H, Yan Y, Huang H, Zheng L, Xu J, Yin W, Qiu Y, Zhang Q, Hwang I, Sun CJ, Amine K, Xu GL, Qiao Y, and Sun SG

Abstract

Compensating the irreversible loss of limited active lithium (Li) is essentially important for improving the energy-density and cycle-life of practical Li-ion battery full-cell, especially after employing high-capacity but low initial coulombic efficiency anode candidates. Introducing prelithiation agent can provide additional Li source for such compensation. Herein, we precisely implant trace Co (extracted from transition metal oxide) into the Li site of Li 2 O, obtaining (Li 0.66 Co 0.11 □ 0.23 ) 2 O (CLO) cathode prelithiation agent. The synergistic formation of Li vacancies and Co-derived catalysis efficiently enhance the inherent conductivity and weaken the Li-O interaction of Li 2 O, which facilitates its anionic oxidation to peroxo/superoxo species and gaseous O 2 , achieving 1642.7 mAh/g ~Li2O prelithiation capacity (≈980 mAh/g for prelithiation agent). Coupled 6.5 wt % CLO-based prelithiation agent with LiCoO 2 cathode, substantial additional Li source stored within CLO is efficiently released to compensate the Li consumption on the SiO/C anode, achieving 270 Wh/kg pouch-type full-cell with 92 % capacity retention after 1000 cycles., (© 2023 Wiley-VCH GmbH.)

Published

2024

212. Nontraditional Approaches To Enable High-Energy and Long-Life Lithium-Sulfur Batteries.

Author

Zhao C, Amine K, and Xu GL

Abstract

ConspectusLithium-sulfur (Li-S) batteries are promising for automotive applications due to their high theoretical energy density (2600 Wh/kg). In addition, the natural abundance of sulfur could mitigate the global raw material supply chain challenge of commercial lithium-ion batteries that use critical elements, such as nickel and cobalt. However, due to persistent polysulfide shuttling and uncontrolled lithium dendrite growth, Li-S batteries using nonencapsulated sulfur cathodes and conventional ether-based electrolytes suffer from rapid cell degradation upon cycling. Despite significant improvements in recent decades, there is still a big gap between lab research and commercialization of the technology. To date, the reported cell energy densities and cycling life of practical Li-S pouch cells remain largely unsatisfactory.Traditional approaches to improving Li-S performance are primarily focused on confining polysulfides using electronically conductive hosts. However, these micro- and mesoporous hosts suffer from limited pore volume to accommodate high sulfur loading and the associated volume change during cycling. Moreover, they fail to balance adsorption-conversion of polysulfides during charge-discharge, leading to the formation of massive dead sulfur. Such hosts are themselves electrochemically inactive, which decreases the practical energy density. In contrast, a series of nontraditional approaches, paired with advances in multiscale mechanistic understanding, have recently demonstrated exciting performance outcomes not only in conventional coin cells but also in practical pouch cells.In this Account, we first introduce our novel cathode design strategies to overcome polysulfide shuttling and sluggish redox kinetics in thick S cathodes via selenium-sulfur chemistry and cathode host engineering. Next, we gain a mechanistic understanding of Li-S batteries in various types of electrolytes via a series of spectroscopic, nuclear magnetic resonance, and electrochemical methods. Meanwhile, a novel cathode solid electrolyte interphase encapsulation strategy via nonviscous highly fluorinated ether-based electrolyte is introduced. The established selection rule by investigating how solvating power retards the shuttle effect and induces robust cathode/solid-electrolyte interphase formation is also included. We then discuss how the synergistic interactions between rational cathode structures and electrolytes can be exploited to tailor the reaction pathways and kinetics of S cathodes under high mass loading and lean electrolyte conditions. In addition, a novel interlayer design to simultaneously overcome degradation processes (polysulfide shuttling and lithium dendrite formation) and accelerate redox reaction kinetics is presented. Finally, this Account concludes with an overview of the challenges and strategies to develop Li-S pouch cells with high practical energy density, long cycle life, and fast-charging capability.

Published

2023

213. Visualizing interfacial collective reaction behaviour of Li-S batteries.

Author

Zhou S, Shi J, Liu S, Li G, Pei F, Chen Y, Deng J, Zheng Q, Li J, Zhao C, Hwang I, Sun CJ, Liu Y, Deng Y, Huang L, Qiao Y, Xu GL, Chen JF, Amine K, Sun SG, and Liao HG

Abstract

Benefiting from high energy density (2,600 Wh kg -1 ) and low cost, lithium-sulfur (Li-S) batteries are considered promising candidates for advanced energy-storage systems 1-4 . Despite tremendous efforts in suppressing the long-standing shuttle effect of lithium polysulfides 5-7 , understanding of the interfacial reactions of lithium polysulfides at the nanoscale remains elusive. This is mainly because of the limitations of in situ characterization tools in tracing the liquid-solid conversion of unstable lithium polysulfides at high temporal-spatial resolution 8-10 . There is an urgent need to understand the coupled phenomena inside Li-S batteries, specifically, the dynamic distribution, aggregation, deposition and dissolution of lithium polysulfides. Here, by using in situ liquid-cell electrochemical transmission electron microscopy, we directly visualized the transformation of lithium polysulfides over electrode surfaces at the atomic scale. Notably, an unexpected gathering-induced collective charge transfer of lithium polysulfides was captured on the nanocluster active-centre-immobilized surface. It further induced an instantaneous deposition of nonequilibrium Li 2 S nanocrystals from the dense liquid phase of lithium polysulfides. Without mediation of active centres, the reactions followed a classical single-molecule pathway, lithium polysulfides transforming into Li 2 S 2 and Li 2 S step by step. Molecular dynamics simulations indicated that the long-range electrostatic interaction between active centres and lithium polysulfides promoted the formation of a dense phase consisting of Li + and S n 2- (2 < n ≤ 6), and the collective charge transfer in the dense phase was further verified by ab initio molecular dynamics simulations. The collective interfacial reaction pathway unveils a new transformation mechanism and deepens the fundamental understanding of Li-S batteries., (© 2023. UChicago Argonne, LLC, Operator of Argonne National Laboratory.)

Published

2023

214. Development of high-energy non-aqueous lithium-sulfur batteries via redox-active interlayer strategy.

Author

Lee BJ, Zhao C, Yu JH, Kang TH, Park HY, Kang J, Jung Y, Liu X, Li T, Xu W, Zuo XB, Xu GL, Amine K, and Yu JS

Abstract

Lithium-sulfur batteries have theoretical specific energy higher than state-of-the-art lithium-ion batteries. However, from a practical perspective, these batteries exhibit poor cycle life and low energy content owing to the polysulfides shuttling during cycling. To tackle these issues, researchers proposed the use of redox-inactive protective layers between the sulfur-containing cathode and lithium metal anode. However, these interlayers provide additional weight to the cell, thus, decreasing the practical specific energy. Here, we report the development and testing of redox-active interlayers consisting of sulfur-impregnated polar ordered mesoporous silica. Differently from redox-inactive interlayers, these redox-active interlayers enable the electrochemical reactivation of the soluble polysulfides, protect the lithium metal electrode from detrimental reactions via silica-polysulfide polar-polar interactions and increase the cell capacity. Indeed, when tested in a non-aqueous Li-S coin cell configuration, the use of the interlayer enables an initial discharge capacity of about 8.5 mAh cm -2 (for a total sulfur mass loading of 10 mg cm -2 ) and a discharge capacity retention of about 64 % after 700 cycles at 335 mA g -1 and 25 °C., (© 2022. UChicago Argonne, LLC, Operator of Argonne National Laboratory.)

Published

2022

215. Entropy and crystal-facet modulation of P2-type layered cathodes for long-lasting sodium-based batteries.

Author

Fu F, Liu X, Fu X, Chen H, Huang L, Fan J, Le J, Wang Q, Yang W, Ren Y, Amine K, Sun SG, and Xu GL

Abstract

P2-type sodium manganese-rich layered oxides are promising cathode candidates for sodium-based batteries because of their appealing cost-effective and capacity features. However, the structural distortion and cationic rearrangement induced by irreversible phase transition and anionic redox reaction at high cell voltage (i.e., >4.0 V) cause sluggish Na-ion kinetics and severe capacity decay. To circumvent these issues, here, we report a strategy to develop P2-type layered cathodes via configurational entropy and ion-diffusion structural tuning. In situ synchrotron X-ray diffraction combined with electrochemical kinetic tests and microstructural characterizations reveal that the entropy-tuned Na 0.62 Mn 0.67 Ni 0.23 Cu 0.05 Mg 0.07 Ti 0.01 O 2 (CuMgTi-571) cathode possesses more {010} active facet, improved structural and thermal stability and faster anionic redox kinetics compared to Na 0.62 Mn 0.67 Ni 0.37 O 2 . When tested in combination with a Na metal anode and a non-aqueous NaClO 4 -based electrolyte solution in coin cell configuration, the CuMgTi-571-based positive electrode enables an 87% capacity retention after 500 cycles at 120 mA g -1 and about 75% capacity retention after 2000 cycles at 1.2 A g -1 ., (© 2022. UChicago Argonne, LLC, Operator of Argonne National Laboratory.)

Published

2022

216. Native lattice strain induced structural earthquake in sodium layered oxide cathodes.

Author

Xu GL, Liu X, Zhou X, Zhao C, Hwang I, Daali A, Yang Z, Ren Y, Sun CJ, Chen Z, Liu Y, and Amine K

Abstract

High-voltage operation is essential for the energy and power densities of battery cathode materials, but its stabilization remains a universal challenge. To date, the degradation origin has been mostly attributed to cycling-initiated structural deformation while the effect of native crystallographic defects induced during the sophisticated synthesis process has been significantly overlooked. Here, using in situ synchrotron X-ray probes and advanced transmission electron microscopy to probe the solid-state synthesis and charge/discharge process of sodium layered oxide cathodes, we reveal that quenching-induced native lattice strain plays an overwhelming role in the catastrophic capacity degradation of sodium layered cathodes, which runs counter to conventional perception-phase transition and cathode interfacial reactions. We observe that the spontaneous relaxation of native lattice strain is responsible for the structural earthquake (e.g., dislocation, stacking faults and fragmentation) of sodium layered cathodes during cycling, which is unexpectedly not regulated by the voltage window but is strongly coupled with charge/discharge temperature and rate. Our findings resolve the controversial understanding on the degradation origin of cathode materials and highlight the importance of eliminating intrinsic crystallographic defects to guarantee superior cycling stability at high voltages., (© 2022. UChicago Argonne, LLC, Operator of Argonne National Laboratory.)

Published

2022

217. Suppressing electrolyte-lithium metal reactivity via Li + -desolvation in uniform nano-porous separator.

Author

Sheng L, Wang Q, Liu X, Cui H, Wang X, Xu Y, Li Z, Wang L, Chen Z, Xu GL, Wang J, Tang Y, Amine K, Xu H, and He X

Abstract

Lithium reactivity with electrolytes leads to their continuous consumption and dendrite growth, which constitute major obstacles to harnessing the tremendous energy of lithium-metal anode in a reversible manner. Considerable attention has been focused on inhibiting dendrite via interface and electrolyte engineering, while admitting electrolyte-lithium metal reactivity as a thermodynamic inevitability. Here, we report the effective suppression of such reactivity through a nano-porous separator. Calculation assisted by diversified characterizations reveals that the separator partially desolvates Li + in confinement created by its uniform nanopores, and deactivates solvents for electrochemical reduction before Li 0 -deposition occurs. The consequence of such deactivation is realizing dendrite-free lithium-metal electrode, which even retaining its metallic lustre after long-term cycling in both Li-symmetric cell and high-voltage Li-metal battery with LiNi 0.6 Mn 0.2 Co 0.2 O 2 as cathode. The discovery that a nano-structured separator alters both bulk and interfacial behaviors of electrolytes points us toward a new direction to harness lithium-metal as the most promising anode., (© 2022. The Author(s).)

Published

2022

218. In situ observation of thermal-driven degradation and safety concerns of lithiated graphite anode.

Author

Liu X, Yin L, Ren D, Wang L, Ren Y, Xu W, Lapidus S, Wang H, He X, Chen Z, Xu GL, Ouyang M, and Amine K

Abstract

Graphite, a robust host for reversible lithium storage, enabled the first commercially viable lithium-ion batteries. However, the thermal degradation pathway and the safety hazards of lithiated graphite remain elusive. Here, solid-electrolyte interphase (SEI) decomposition, lithium leaching, and gas release of the lithiated graphite anode during heating were examined by in situ synchrotron X-ray techniques and in situ mass spectroscopy. The source of flammable gas such as H 2 was identified and quantitively analyzed. Also, the existence of highly reactive residual lithium on the graphite surface was identified at high temperatures. Our results emphasized the critical role of the SEI in anode thermal stability and uncovered the potential safety hazards of the flammable gases and leached lithium. The anode thermal degradation mechanism revealed in the present work will stimulate more efforts in the rational design of anodes to enable safe energy storage., (© 2021. This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply.)

Published

2021

219. A high-energy and long-cycling lithium-sulfur pouch cell via a macroporous catalytic cathode with double-end binding sites.

Author

Zhao C, Xu GL, Yu Z, Zhang L, Hwang I, Mo YX, Ren Y, Cheng L, Sun CJ, Ren Y, Zuo X, Li JT, Sun SG, Amine K, and Zhao T

Abstract

Lithium-sulfur batteries are attractive alternatives to lithium-ion batteries because of their high theoretical specific energy and natural abundance of sulfur. However, the practical specific energy and cycle life of Li-S pouch cells are significantly limited by the use of thin sulfur electrodes, flooded electrolytes and Li metal degradation. Here we propose a cathode design concept to achieve good Li-S pouch cell performances. The cathode is composed of uniformly embedded ZnS nanoparticles and Co-N-C single-atom catalyst to form double-end binding sites inside a highly oriented macroporous host, which can effectively immobilize and catalytically convert polysulfide intermediates during cycling, thus eliminating the shuttle effect and lithium metal corrosion. The ordered macropores enhance ionic transport under high sulfur loading by forming sufficient triple-phase boundaries between catalyst, conductive support and electrolyte. This design prevents the formation of inactive sulfur (dead sulfur). Our cathode structure shows improved performances in a pouch cell configuration under high sulfur loading and lean electrolyte operation. A 1-A-h-level pouch cell with only 100% lithium excess can deliver a cell specific energy of >300 W h kg -1 with a Coulombic efficiency >95% for 80 cycles.

Published

2021

220. Beyond the Polysulfide Shuttle and Lithium Dendrite Formation: Addressing the Sluggish Sulfur Redox Kinetics for Practical High-Energy Li-S Batteries.

Author

Zhao C, Xu GL, Zhao T, and Amine K

Abstract

Electrolyte modulation simultaneously suppresses polysulfide the shuttle effect and lithium dendrite formation of lithium-sulfur (Li-S) batteries. However, the sluggish S redox kinetics, especially under high S loading and lean electrolyte operation, has been ignored, which dramatically limits the cycle life and energy density of practical Li-S pouch cells. Herein, we demonstrate that a rational combination of selenium doping, core-shell hollow host structure, and fluorinated ether electrolytes enables ultrastable Li stripping/plating and essentially no polysulfide shuttle as well as fast redox kinetics. Thus, high areal capacity (>4 mAh cm -2 ) with excellent cycle stability and Coulombic efficiency were both demonstrated in Li metal anode and thick S cathode (4.5 mg cm -2 ) with a low electrolyte/sulfur ratio (10 μL mg -1 ). This research further demonstrates a durable Li-Se/S pouch cell with high specific capacity, validating the potential practical applications., (© 2020 Wiley-VCH GmbH.)

Published

2020

221. Highly Reversible Sodiation/Desodiation from a Carbon-Sandwiched SnS 2 Nanosheet Anode for Sodium Ion Batteries.

Author

Liu Z, Daali A, Xu GL, Zhuang M, Zuo X, Sun CJ, Liu Y, Cai Y, Hossain MD, Liu H, Amine K, and Luo Z

Abstract

The further improvement of sodium ion batteries requires the elucidation of the mechanisms pertaining to reversibility, which allows the novel design of the electrode structure. Here, through a hydrogel-embedding method, we are able to confine the growth of few-layer SnS 2 nanosheets between a nitrogen- and sulfur-doped carbon nanotube (NS-CNT) and amorphous carbon. The obtained carbon-sandwiched SnS 2 nanosheets demonstrate excellent sodium storage properties. In operando small-angle X-ray scattering combined with the ex situ X-ray absorption near edge spectra reveal that the redox reactions between SnS 2 /NS-CNT and the sodium ion are highly reversible. On the contrary, the nanostructure evolution is found to be irreversible, in which the SnS 2 nanosheets collapse, followed by the regeneration of SnS 2 nanoparticles. This work provides operando insights into the chemical environment evolution and structure change of SnS 2 -based anodes, elucidating its reversible reaction mechanism, and illustrates the significance of engineered carbon support in ensuring the electrode structure stability.

Published

2020

222. Methacrylated gelatin-embedded fabrication of 3D graphene-supported Co 3 O 4 nanoparticles for water splitting.

Author

Zhuang M, Liu Z, Ding Y, Xu GL, Li Y, Tyagi A, Zhang X, Sun CJ, Ren Y, Ou X, Wong H, Cai Y, Wu R, Abidi IH, Zhang Q, Xu F, Amine K, and Luo Z

Abstract

We developed a general platform for the fabrication of transition metal oxide nanoparticles supported by a graphene foam (GF) by first coating it with a methacrylated gelatin (GelMA) hydrogel, which served as a 3D matrix for nanoparticle dispersion. The engineered GelMA/GF matrix was hydrophilic with good mechanical strength and high conductivity, therefore providing a good platform for the dispersion of a variety of metal/oxide precursors. Due to this platform, well-dispersed Co3O4 nanoparticles with the smallest size of 3 nm assembled on the nitrogen-doped graphene foam (Co3O4/NGF). The crystalline transformation from a CoCl2[H2O]2 precursor to Co3O4 was revealed by in operando X-ray diffraction and absorption techniques. After applying Co3O4/NGF as a free-standing electrocatalyst for water splitting, the nanoparticles of size 3 nm exhibited optimal catalytic activity in alkaline media; the corresponding cell could promote water splitting at a current density of 10 mA cm-2 with only 1.63 V and exhibited excellent stability in a 25 h long-term operation. Our results demonstrate that the GelMA hydrogel-coated 3D graphene foam can be a promising platform for the design and fabrication of graphene-based multifunctional materials.

Published

2019

223. Electrostatic Self-Assembly Enabling Integrated Bulk and Interfacial Sodium Storage in 3D Titania-Graphene Hybrid.

Author

Xu GL, Xiao L, Sheng T, Liu J, Hu YX, Ma T, Amine R, Xie Y, Zhang X, Liu Y, Ren Y, Sun CJ, Heald SM, Kovacevic J, Sehlleier YH, Schulz C, Mattis WL, Sun SG, Wiggers H, Chen Z, and Amine K

Abstract

Room-temperature sodium-ion batteries have attracted increased attention for energy storage due to the natural abundance of sodium. However, it remains a huge challenge to develop versatile electrode materials with favorable properties, which requires smart structure design and good mechanistic understanding. Herein, we reported a general and scalable approach to synthesize three-dimensional (3D) titania-graphene hybrid via electrostatic-interaction-induced self-assembly. Synchrotron X-ray probe, transmission electron microscopy, and computational modeling revealed that the strong interaction between titania and graphene through comparably strong van der Waals forces not only facilitates bulk Na + intercalation but also enhances the interfacial sodium storage. As a result, the titania-graphene hybrid exhibits exceptional long-term cycle stability up to 5000 cycles, and ultrahigh rate capability up to 20 C for sodium storage. Furthermore, density function theory calculation indicated that the interfacial Li + , K + , Mg 2+, and Al 3+ storage can be enhanced as well. The proposed general strategy opens up new avenues to create versatile materials for advanced battery systems.

Published

2018