4.8 Article

Synergetic LaPO4 and Al2O3 hybrid coating strengthens the interfacial stability of LiCoO2 at 4.6 V

JOURNAL OF POWER SOURCES (2023)

Related references

Note: Only part of the references are listed.
Article Chemistry, Multidisciplinary

Outside-In Nanostructure Fabricated on LiCoO2 Surface for High-Voltage Lithium-Ion Batteries

Shulan Mao et al.

Summary: The energy density of batteries with lithium cobalt oxide (LCO) can be maximized by creating an outside-in oriented nanostructure on LiCoO2 crystals. This structure provides physical protection for the cathodes and electrolytes, while promoting lithium ion diffusion and stabilizing lattice oxygen. As a result, the battery exhibits high energy density retention even after multiple cycles.

ADVANCED SCIENCE (2022)

Add to Collection
Article Nanoscience & Nanotechnology

Ultralong Lifespan for High-Voltage LiCoO2 Enabled by In Situ Reconstruction of an Atomic Layer Deposition Coating Layer

Rui Wu et al.

Summary: This paper presents a study on surface reconstruction of lithium cobalt oxide (LCO) using atomic layer deposition (ALD) method. An ultrathin Al2O3 layer is initially coated on the LCO surface, but it undergoes reconstruction after reacting with electrolyte decomposition products during cycling. The in situ formed Li3AlF6 layer shows better binding to the LCO surface, as well as good Li+ conductivity and electrochemical stability. The ALD technology allows for ultrathin and conformal coating, which benefits electronic conductivity and cycling stability.

ACS APPLIED MATERIALS & INTERFACES (2022)

Add to Collection
Article Chemistry, Physical

Improving interfacial stability of high voltage LiCoO2-based cells with 4-methylmorpholine-2,6-dione additive

Yue Zou et al.

Summary: A novel electrolyte additive, MMD, is proposed to improve the cycling stability of lithium-ion batteries at high temperature and high voltage by constructing a stable cathode-electrolyte-interface film. The addition of trace amounts of MMD significantly increases both the capacity retention rate and the retained capacity of the batteries.

JOURNAL OF POWER SOURCES (2022)

Add to Collection
Article Chemistry, Physical

Synergistical Stabilization of Li Metal Anodesand LiCoO2 Cathodes in High-VoltageLi∥LiCoO2 Batteries by Potassium Selenocyanate (KSeCN) Additive

Ang Fu et al.

Summary: In this study, a dual-functional electrolyte additive KSeCN is introduced to construct stable and dense SEI/CEI films by synergistic effects with -Se and -Cxe0c9;N groups, resulting in improved stability and cycling performance of the Li parallel to LCO battery.

ACS ENERGY LETTERS (2022)

Add to Collection
Article Chemistry, Physical

Highly stable operation of LiCoO2 at cut-off ≥ 4.6 V enabled by synergistic structural and interfacial manipulation

Ang Fu et al.

Summary: In this work, a synergistic strategy of Mg doping and Se coating is proposed to enhance the high-voltage electrochemical performance and cycling life of LiCoO2 as a cathode material for high energy density batteries.

ENERGY STORAGE MATERIALS (2022)

Add to Collection
Article Engineering, Electrical & Electronic

Improvement of electrochemical properties of LiCoO2 at 4.6 V by a LiPAA coating

Hongfu Gao et al.

Summary: In this study, a coating of lithium polyacrylate (LiPAA) was applied on the surface of LiCoO2 to improve its electrochemical performance at high voltages. The coating effectively blocked the side reactions between LiCoO2 and the electrolyte, resulting in enhanced discharge capacity and capacity retention rate of the electrode.

JOURNAL OF MATERIALS SCIENCE-MATERIALS IN ELECTRONICS (2022)

Add to Collection
Article Chemistry, Multidisciplinary

Simultaneously Constructing a TiO2-LiF Composite Coating Enhancing the Cycling Stability of LiCoO2 at 4.6 V High Voltage

Zhengfeng Wang et al.

Summary: In this paper, a TiO2-LiF composite coating layer with very stable chemical properties on the LiCoO2 surface is prepared in one step. The coating effectively stabilizes the LCO surface composition and structure, resulting in improved electrochemical performance, including enhanced cycling stability and capacity retention.

ACS SUSTAINABLE CHEMISTRY & ENGINEERING (2022)

Add to Collection
Article Electrochemistry

Functionalized nano-SiO2 for improving the cycling stability of 4.6V high voltage LiCoO2 cathodes

Pan He et al.

Summary: The functionalization of nano SiO2 was achieved by using dopamine self polymerization coating, and it was uniformly coated onto LiCoO2 cathode through rotary steaming. The functional nanocoating showed a homogeneous distribution on the surface of LiCoO2 particles. The interaction between nano SiO2 coating and LiCoO2 particles enhanced the function of solid superacid formed by fumed SiO2, leading to improved interface stability and ionic conductivity of LiCoO2 cathodes at high voltage. The modified LiCoO2 cathode with functionalized nano-SiO2 exhibited a reversible capacity of around 190 mAh g(-1) with good capacity retention after cycles at room temperature and elevated temperature.

ELECTROCHIMICA ACTA (2022)

Add to Collection
Review Chemistry, Applied

Progress and perspective of high-voltage lithium cobalt oxide in lithium-ion batteries

Qian Wua et al.

Summary: This review summarizes the degradation mechanisms and modification strategies of lithium cobalt oxide (LCO) batteries under high voltage conditions, focusing on structural modification, interface design, and electrolyte optimization. The review also highlights advanced characterization and monitoring techniques used to understand the structural and interfacial evolution of LCO during the charge/discharge process.

JOURNAL OF ENERGY CHEMISTRY (2022)

Add to Collection
Article Chemistry, Multidisciplinary

Highly Stable 4.6 V LiCoO2 Cathodes for Rechargeable Li Batteries by Rubidium-Based Surface Modifications

Tianju Fan et al.

Summary: LiCoO2 (LCO) is a widely studied cathode material for Li-ion batteries, but its charging to high potentials leads to rapid degradation. In this study, the authors propose a surface coating method using RbAlF4 modified LCO particles. The coated LCO cathodes demonstrate enhanced capacity and impressive retention, and the main reason for the degradation of high voltage cells is found to be the instability of the anode side rather than the failure of the coated cathodes.

ADVANCED SCIENCE (2022)

Add to Collection
Article Chemistry, Physical

A novel trimethylsilyl 2-(fluorosulfonyl)difluoroacetate additive for stabilizing the Ni-rich LiNi0.9Co0.05Mn0.05O2/electrolyte interface

Tianpeng Jiao et al.

Summary: The research reveals that a stable CEI layer formed on the LiNi0.9Co0.05Mn0.05O2 cathode material through the addition of TMSFS multifunctional additive can significantly improve the cycling performance and electrochemical performance of lithium-ion batteries.

JOURNAL OF POWER SOURCES (2021)

Add to Collection
Article Chemistry, Applied

Revealing the correlation between structure evolution and electrochemical performance of high-voltage lithium cobalt oxide

Jiajia Wan et al.

Summary: The introduction of La and Al ions can delay the appearance of the H1-3 phase, induce various local environments, adapt better to volume changes at the atomic level, improve reversibility of the H1-3 phase and reduce lattice strain, resulting in significantly enhanced cycle performance.

JOURNAL OF ENERGY CHEMISTRY (2021)

Add to Collection
Article Nanoscience & Nanotechnology

Enhanced Cycle Life and Rate Capability of Single-Crystal, Ni-Rich LiNi0.9Co0.05Mn0.05O2 Enabled by 1,2,4-1H-Triazole Additive

Yue Zou et al.

Summary: A novel electrolyte additive, 1,2,4-1H-triazole (HTZ), was introduced to enhance the interfacial stability and cycle life of LiNi0.9Co0.05Mn0.05O2 (NCM90). HTZ inhibits thermal decomposition of LiPF6 salt and suppresses HF acidic species, leading to the formation of a compact and dense CEI layer. The NCM90 cells with 0.3% HTZ-added electrolyte retain 86.6% of their original capacity after 150 cycles at 30 degrees C.

ACS APPLIED MATERIALS & INTERFACES (2021)

Add to Collection
Article Chemistry, Multidisciplinary

Stabilizing the LiCoO2 Interface at High Voltage with an Electrolyte Additive 2,4,6-Tris(4-fluorophenyl)boroxin

Yue Zou et al.

Summary: A novel electrolyte additive TFPB is proposed to enhance the interfacial stability of LCO, leading to substantially improved capacity retention of the cathode and reduced parasitic side reactions.

ACS SUSTAINABLE CHEMISTRY & ENGINEERING (2021)

Add to Collection
Article Chemistry, Multidisciplinary

Enabling Stable High-Voltage LiCoO2Operation by Using Synergetic Interfacial Modification Strategy

Xuerui Yang et al.

ADVANCED FUNCTIONAL MATERIALS (2020)

Add to Collection
Review Chemistry, Physical

Recent advances and historical developments of high voltage lithium cobalt oxide materials for rechargeable Li-ion batteries

Kai Wang et al.

JOURNAL OF POWER SOURCES (2020)

Add to Collection
Article Chemistry, Physical

An In Situ Formed Surface Coating Layer Enabling LiCoO2with Stable 4.6 V High-Voltage Cycle Performances

Yi Wang et al.

ADVANCED ENERGY MATERIALS (2020)

Add to Collection
Article Chemistry, Multidisciplinary

A Surface Se-Substituted LiCo[O2-δSeδ] Cathode with Ultrastable High-Voltage Cycling in Pouch Full-Cells

Zhi Zhu et al.

ADVANCED MATERIALS (2020)

Add to Collection
Article Chemistry, Multidisciplinary

Gradient-morph LiCoO2single crystals with stabilized energy density above 3400 W h L-1

Zhi Zhu et al.

ENERGY & ENVIRONMENTAL SCIENCE (2020)

Add to Collection
Article Nanoscience & Nanotechnology

Stabilizing LiCoO2/Graphite at High Voltages with an Electrolyte Additive

Suping Wu et al.

ACS APPLIED MATERIALS & INTERFACES (2019)

Add to Collection
Article Chemistry, Multidisciplinary

Anti-Oxygen Leaking LiCoO2

Soroosh Sharifi-Asl et al.

ADVANCED FUNCTIONAL MATERIALS (2019)

Add to Collection
Article Chemistry, Physical

Al2O3 coated Na0.44MnO2 as high-voltage cathode for sodium ion batteries

Yue Zhang et al.

APPLIED SURFACE SCIENCE (2019)

Add to Collection
Article Energy & Fuels

Trace doping of multiple elements enables stable battery cycling of LiCoO2 at 4.6V

Jie-Nan Zhang et al.

NATURE ENERGY (2019)

Add to Collection
Article Chemistry, Physical

Improvement of the Cycling Stability of Li-Rich Layered Mn-Based Oxide Cathodes Modified by Nanoscale LaPO4 Coating

Xiaohui Zhang et al.

ACS APPLIED ENERGY MATERIALS (2019)

Add to Collection
Article Electrochemistry

Combustion combined with ball milling to produce nanoscale La2O3 coated on LiMn2O4 for optimized Li-ion storage performance at high temperature

Yannan Zhang et al.

JOURNAL OF APPLIED ELECTROCHEMISTRY (2018)

Add to Collection
Article Chemistry, Physical

Cathode material LiNi0.8Co0.1Mn0.1O2/LaPO4 with high electrochemical performance for lithium-ion batteries

Hui Tong et al.

JOURNAL OF ALLOYS AND COMPOUNDS (2018)

Add to Collection
Article Chemistry, Physical

Surface-protected LiCoO2 with ultrathin solid oxide electrolyte film for high-voltage lithium ion batteries and lithium polymer batteries

Qi Yang et al.

JOURNAL OF POWER SOURCES (2018)

Add to Collection
Article Energy & Fuels

Approaching the capacity limit of lithium cobalt oxide in lithium ion batteries via lanthanum and aluminium doping

Qi Liu et al.

NATURE ENERGY (2018)

Add to Collection
Article Energy & Fuels

Tailoring grain boundary structures and chemistry of Ni-rich layered cathodes for enhanced cycle stability of lithium-ion batteries

Pengfei Yan et al.

NATURE ENERGY (2018)

Add to Collection
Article Multidisciplinary Sciences

Electrochemical surface passivation of LiCoO2 particles at ultrahigh voltage and its applications in lithium-based batteries

Jiawei Qian et al.

NATURE COMMUNICATIONS (2018)

Add to Collection
Article Chemistry, Physical

Surface Engineering Strategies of Layered LiCoO2 Cathode Material to Realize High-Energy and High-Voltage Li-Ion Cells

Sujith Kalluri et al.

ADVANCED ENERGY MATERIALS (2017)

Add to Collection
Article Chemistry, Physical

Suppressed oxygen extraction and degradation of LiNi x Mn y Co z O2 cathodes at high charge cut-off voltages

Jianming Zheng et al.

NANO RESEARCH (2017)

Add to Collection
Article Chemistry, Physical

Al2O3 surface coating on LiCoO2 through a facile and scalable wet-chemical method towards high-energy cathode materials withstanding high cutoff voltages

Aijun Zhou et al.

JOURNAL OF MATERIALS CHEMISTRY A (2017)

Add to Collection
Article Chemistry, Physical

Improved high-voltage and high-temperature electrochemical performances of LiCoO2 cathode by electrode sputter-coating with Li3PO4

Aijun Zhou et al.

JOURNAL OF POWER SOURCES (2016)

Add to Collection
Article Chemistry, Physical

Highly Stable Operation of Lithium Metal Batteries Enabled by the Formation of a Transient High-Concentration Electrolyte Layer

Jianming Zheng et al.

ADVANCED ENERGY MATERIALS (2016)

Add to Collection
Article Chemistry, Multidisciplinary

Origin of Surface Coating Effect for MgO on LiCoO2 to Improve the Interfacial Reaction between Electrode and Electrolyte

Yuki Orikasa et al.

ADVANCED MATERIALS INTERFACES (2014)

Add to Collection
Article Chemistry, Physical

Comparison of Al2O3- and AlPO4-coated LiCoO2 cathode materials for a Li-ion cell

J Cho et al.

JOURNAL OF POWER SOURCES (2005)

Add to Collection
Article Chemistry, Physical

Mechanism of electrochemical activity in Li2MnO3

AD Robertson et al.

CHEMISTRY OF MATERIALS (2003)

Add to Collection
Article Materials Science, Ceramics

Properties and microstructure of machinable Al2O3/LaPO4 ceramic composites

RG Wang et al.

CERAMICS INTERNATIONAL (2003)

Add to Collection
Webinars Posters Questions Hubs Funding Journals Papers Connect Collections Reviewers About Us FAQs Mobile App Privacy Policy Terms of Use
© Peeref 2019-2024. All rights reserved.