In situ soft XAS study on nickel-based layered cathode material at elevated temperatures: A novel approach to study thermal stability

Won Sub Yoon; Otto Haas; Shoaib Muhammad; Hyunchul Kim; Wontae Lee; Donghwi Kim; Daniel A. Fischer; Cherno Jaye; Xiao Qing Yang; Mahalingam Balasubramanian; Kyung Wan Nam

doi:10.1038/srep06827

In situ soft XAS study on nickel-based layered cathode material at elevated temperatures: A novel approach to study thermal stability

Won Sub Yoon, Otto Haas, Shoaib Muhammad, Hyunchul Kim, Wontae Lee, Donghwi Kim, Daniel A. Fischer, Cherno Jaye, Xiao Qing Yang, Mahalingam Balasubramanian, Kyung Wan Nam

Emerging and Solid-State Batteries

Research output: Contribution to journal › Article › peer-review

66 Scopus citations

Abstract

Tracking thermally induced reactions has always been challenging for electrode materials of electrochemical battery systems. Traditionally, a variety of calorimetric techniques andin situ XRD at elevated temperatures has been used to evaluate the thermal stability of electrode materials. These techniques are capable of providing variations in heat capacity, mass and average bulk composition of materials only. Herein, we report investigation of thermal characteristics of Li_0.33Ni_0.8Co_0.15Al_0.05O₂ by using in situ soft XAS measurements in combination with XRD. Fluorescence yield and partial electron yield measurements are used simultaneously to obtain element selective surface and bulk information. Fluorescence yield measurements reveal no energy change of the absorption peak and thus no valence state change in the bulk. However, electron yield measurements indicate that NiO-type rock salt structure is formed at the surface at temperatures above 200°C while no evidence for a surface reaction near Co sites in investigated temperature range is found. These results clearly show that in situ soft XAS can give a unique understanding of the role of each element in the structural transformation under thermal abuse offering a useful guidance in developing new battery system with improved safety performance.

Original language	English
Article number	6827
Journal	Scientific Reports
Volume	4
DOIs	https://doi.org/10.1038/srep06827
State	Published - Oct 29 2014

Funding

This work was supported by the Human Resources Development program (No. 20124010203270) of the KETEP and the IT R&D program (10041856) of the KEIT funded by the Korea government Ministry of Knowledge Economy. The work at BNL was supported by the U.S. Department of Energy, the Assistant Secretary for Energy Efficiency and Renewable Energy, Office of Vehicle Technologies under Contract Number DEAC02-98CH10886.

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title = "In situ soft XAS study on nickel-based layered cathode material at elevated temperatures: A novel approach to study thermal stability",

abstract = "Tracking thermally induced reactions has always been challenging for electrode materials of electrochemical battery systems. Traditionally, a variety of calorimetric techniques andin situ XRD at elevated temperatures has been used to evaluate the thermal stability of electrode materials. These techniques are capable of providing variations in heat capacity, mass and average bulk composition of materials only. Herein, we report investigation of thermal characteristics of Li0.33Ni0.8Co0.15Al0.05O2 by using in situ soft XAS measurements in combination with XRD. Fluorescence yield and partial electron yield measurements are used simultaneously to obtain element selective surface and bulk information. Fluorescence yield measurements reveal no energy change of the absorption peak and thus no valence state change in the bulk. However, electron yield measurements indicate that NiO-type rock salt structure is formed at the surface at temperatures above 200°C while no evidence for a surface reaction near Co sites in investigated temperature range is found. These results clearly show that in situ soft XAS can give a unique understanding of the role of each element in the structural transformation under thermal abuse offering a useful guidance in developing new battery system with improved safety performance.",

author = "Yoon, \{Won Sub\} and Otto Haas and Shoaib Muhammad and Hyunchul Kim and Wontae Lee and Donghwi Kim and Fischer, \{Daniel A.\} and Cherno Jaye and Yang, \{Xiao Qing\} and Mahalingam Balasubramanian and Nam, \{Kyung Wan\}",

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AU - Yoon, Won Sub

AU - Haas, Otto

AU - Muhammad, Shoaib

AU - Kim, Hyunchul

AU - Lee, Wontae

AU - Kim, Donghwi

AU - Fischer, Daniel A.

AU - Jaye, Cherno

AU - Yang, Xiao Qing

AU - Balasubramanian, Mahalingam

AU - Nam, Kyung Wan

PY - 2014/10/29

Y1 - 2014/10/29

N2 - Tracking thermally induced reactions has always been challenging for electrode materials of electrochemical battery systems. Traditionally, a variety of calorimetric techniques andin situ XRD at elevated temperatures has been used to evaluate the thermal stability of electrode materials. These techniques are capable of providing variations in heat capacity, mass and average bulk composition of materials only. Herein, we report investigation of thermal characteristics of Li0.33Ni0.8Co0.15Al0.05O2 by using in situ soft XAS measurements in combination with XRD. Fluorescence yield and partial electron yield measurements are used simultaneously to obtain element selective surface and bulk information. Fluorescence yield measurements reveal no energy change of the absorption peak and thus no valence state change in the bulk. However, electron yield measurements indicate that NiO-type rock salt structure is formed at the surface at temperatures above 200°C while no evidence for a surface reaction near Co sites in investigated temperature range is found. These results clearly show that in situ soft XAS can give a unique understanding of the role of each element in the structural transformation under thermal abuse offering a useful guidance in developing new battery system with improved safety performance.

AB - Tracking thermally induced reactions has always been challenging for electrode materials of electrochemical battery systems. Traditionally, a variety of calorimetric techniques andin situ XRD at elevated temperatures has been used to evaluate the thermal stability of electrode materials. These techniques are capable of providing variations in heat capacity, mass and average bulk composition of materials only. Herein, we report investigation of thermal characteristics of Li0.33Ni0.8Co0.15Al0.05O2 by using in situ soft XAS measurements in combination with XRD. Fluorescence yield and partial electron yield measurements are used simultaneously to obtain element selective surface and bulk information. Fluorescence yield measurements reveal no energy change of the absorption peak and thus no valence state change in the bulk. However, electron yield measurements indicate that NiO-type rock salt structure is formed at the surface at temperatures above 200°C while no evidence for a surface reaction near Co sites in investigated temperature range is found. These results clearly show that in situ soft XAS can give a unique understanding of the role of each element in the structural transformation under thermal abuse offering a useful guidance in developing new battery system with improved safety performance.

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VL - 4

JO - Scientific Reports

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M1 - 6827

ER -

In situ soft XAS study on nickel-based layered cathode material at elevated temperatures: A novel approach to study thermal stability

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