Avoiding Fracture in a Conversion Battery Material through Reaction with Larger Ions

Conversion and alloying electrode materials offer high specific capacity for emerging sodium- and potassium-ion batteries, but the larger volume changes compared to reaction with lithium are thought to limit cyclability. The reaction mechanisms of many materials with Na+ and K+ are unknown, however,...

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Veröffentlicht in:	Joule 2018-09, Vol.2 (9), p.1783-1799
Hauptverfasser:	Boebinger, Matthew G., Yeh, David, Xu, Michael, Miles, B. Casey, Wang, Baolin, Papakyriakou, Marc, Lewis, John A., Kondekar, Neha P., Cortes, Francisco Javier Quintero, Hwang, Sooyeon, Sang, Xiahan, Su, Dong, Unocic, Raymond R., Xia, Shuman, Zhu, Ting, McDowell, Matthew T.
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Schlagworte:	batteries chemomechanics ENERGY STORAGE fracture in situ TEM phase transformations
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creator	Boebinger, Matthew G. Yeh, David Xu, Michael Miles, B. Casey Wang, Baolin Papakyriakou, Marc Lewis, John A. Kondekar, Neha P. Cortes, Francisco Javier Quintero Hwang, Sooyeon Sang, Xiahan Su, Dong Unocic, Raymond R. Xia, Shuman Zhu, Ting McDowell, Matthew T.
description	Conversion and alloying electrode materials offer high specific capacity for emerging sodium- and potassium-ion batteries, but the larger volume changes compared to reaction with lithium are thought to limit cyclability. The reaction mechanisms of many materials with Na+ and K+ are unknown, however, and this knowledge is key for engineering mechanically resilient materials. Here, in situ transmission electron microscopy is used to uncover the nanoscale transformations during the reaction of FeS2 electrode materials with Li+, Na+, and K+. Surprisingly, despite larger volume changes during the conversion reaction with Na+ and K+, the FeS2 crystals only fracture during lithiation. Modeling of reaction-induced deformation shows that the shape of the two-phase reaction front influences stress evolution, and unique behavior during lithiation causes stress concentrations and fracture. The larger volume changes in Na- and K-ion battery materials may therefore be managed through understanding and control of reaction mechanisms, ultimately leading to better alkali-ion batteries. [Display omitted] •In situ TEM reveals reaction mechanisms in FeS2 with various alkali ions•Only reaction with lithium causes fracture•Fracture process is driven by evolution of crystal shape and stress concentrations•Finite element modeling and nanoindentation provide insight into chemomechanics High-capacity electrode materials hold promise for next-generation batteries with high energy density. However, such materials often undergo large volume changes during charge and discharge, which can cause mechanical degradation and reduced cycle life. It is therefore critical to understand and control coupled reaction and degradation processes in high-capacity electrode materials. Here we find that FeS2, a battery electrode material that undergoes a conversion-type reaction, fractures during reaction with lithium, but not with larger alkali ions (sodium and potassium). This result is counterintuitive, since larger ions induce larger volume changes, which are generally associated with greater stresses and more significant mechanical degradation. These findings are important since they indicate that large-volume-change electrode materials can be mechanically resilient in emerging sodium- and potassium-ion battery systems, which is a key aspect of attaining long cycle life. Next-generation batteries with high energy density rely on high-capacity electrode materials, but large volume changes and mecha
doi_str_mv	10.1016/j.joule.2018.05.015
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Casey ; Wang, Baolin ; Papakyriakou, Marc ; Lewis, John A. ; Kondekar, Neha P. ; Cortes, Francisco Javier Quintero ; Hwang, Sooyeon ; Sang, Xiahan ; Su, Dong ; Unocic, Raymond R. ; Xia, Shuman ; Zhu, Ting ; McDowell, Matthew T.</creator><creatorcontrib>Boebinger, Matthew G. ; Yeh, David ; Xu, Michael ; Miles, B. Casey ; Wang, Baolin ; Papakyriakou, Marc ; Lewis, John A. ; Kondekar, Neha P. ; Cortes, Francisco Javier Quintero ; Hwang, Sooyeon ; Sang, Xiahan ; Su, Dong ; Unocic, Raymond R. ; Xia, Shuman ; Zhu, Ting ; McDowell, Matthew T. ; Oak Ridge National Lab. (ORNL), Oak Ridge, TN (United States)</creatorcontrib><description>Conversion and alloying electrode materials offer high specific capacity for emerging sodium- and potassium-ion batteries, but the larger volume changes compared to reaction with lithium are thought to limit cyclability. The reaction mechanisms of many materials with Na+ and K+ are unknown, however, and this knowledge is key for engineering mechanically resilient materials. Here, in situ transmission electron microscopy is used to uncover the nanoscale transformations during the reaction of FeS2 electrode materials with Li+, Na+, and K+. Surprisingly, despite larger volume changes during the conversion reaction with Na+ and K+, the FeS2 crystals only fracture during lithiation. Modeling of reaction-induced deformation shows that the shape of the two-phase reaction front influences stress evolution, and unique behavior during lithiation causes stress concentrations and fracture. The larger volume changes in Na- and K-ion battery materials may therefore be managed through understanding and control of reaction mechanisms, ultimately leading to better alkali-ion batteries. [Display omitted] •In situ TEM reveals reaction mechanisms in FeS2 with various alkali ions•Only reaction with lithium causes fracture•Fracture process is driven by evolution of crystal shape and stress concentrations•Finite element modeling and nanoindentation provide insight into chemomechanics High-capacity electrode materials hold promise for next-generation batteries with high energy density. However, such materials often undergo large volume changes during charge and discharge, which can cause mechanical degradation and reduced cycle life. It is therefore critical to understand and control coupled reaction and degradation processes in high-capacity electrode materials. Here we find that FeS2, a battery electrode material that undergoes a conversion-type reaction, fractures during reaction with lithium, but not with larger alkali ions (sodium and potassium). This result is counterintuitive, since larger ions induce larger volume changes, which are generally associated with greater stresses and more significant mechanical degradation. These findings are important since they indicate that large-volume-change electrode materials can be mechanically resilient in emerging sodium- and potassium-ion battery systems, which is a key aspect of attaining long cycle life. Next-generation batteries with high energy density rely on high-capacity electrode materials, but large volume changes and mechanical fracture in these materials during charge and discharge limit cycle life. Here, we discover that FeS2 electrode materials are more mechanically resilient during reaction with larger alkali ions (sodium and potassium) compared with lithium, despite larger volume changes. 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(ORNL), Oak Ridge, TN (United States)</creatorcontrib><title>Avoiding Fracture in a Conversion Battery Material through Reaction with Larger Ions</title><title>Joule</title><description>Conversion and alloying electrode materials offer high specific capacity for emerging sodium- and potassium-ion batteries, but the larger volume changes compared to reaction with lithium are thought to limit cyclability. The reaction mechanisms of many materials with Na+ and K+ are unknown, however, and this knowledge is key for engineering mechanically resilient materials. Here, in situ transmission electron microscopy is used to uncover the nanoscale transformations during the reaction of FeS2 electrode materials with Li+, Na+, and K+. Surprisingly, despite larger volume changes during the conversion reaction with Na+ and K+, the FeS2 crystals only fracture during lithiation. Modeling of reaction-induced deformation shows that the shape of the two-phase reaction front influences stress evolution, and unique behavior during lithiation causes stress concentrations and fracture. The larger volume changes in Na- and K-ion battery materials may therefore be managed through understanding and control of reaction mechanisms, ultimately leading to better alkali-ion batteries. [Display omitted] •In situ TEM reveals reaction mechanisms in FeS2 with various alkali ions•Only reaction with lithium causes fracture•Fracture process is driven by evolution of crystal shape and stress concentrations•Finite element modeling and nanoindentation provide insight into chemomechanics High-capacity electrode materials hold promise for next-generation batteries with high energy density. However, such materials often undergo large volume changes during charge and discharge, which can cause mechanical degradation and reduced cycle life. It is therefore critical to understand and control coupled reaction and degradation processes in high-capacity electrode materials. Here we find that FeS2, a battery electrode material that undergoes a conversion-type reaction, fractures during reaction with lithium, but not with larger alkali ions (sodium and potassium). This result is counterintuitive, since larger ions induce larger volume changes, which are generally associated with greater stresses and more significant mechanical degradation. These findings are important since they indicate that large-volume-change electrode materials can be mechanically resilient in emerging sodium- and potassium-ion battery systems, which is a key aspect of attaining long cycle life. Next-generation batteries with high energy density rely on high-capacity electrode materials, but large volume changes and mechanical fracture in these materials during charge and discharge limit cycle life. Here, we discover that FeS2 electrode materials are more mechanically resilient during reaction with larger alkali ions (sodium and potassium) compared with lithium, despite larger volume changes. These findings are important since they suggest that various large-volume-change electrode materials could enable stable cycling performance in next-generation sodium- and potassium-ion batteries.</description><subject>batteries</subject><subject>chemomechanics</subject><subject>ENERGY STORAGE</subject><subject>fracture</subject><subject>in situ TEM</subject><subject>phase transformations</subject><issn>2542-4351</issn><issn>2542-4351</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><recordid>eNp9kLFOwzAURS0EEhX0C1gs9oRnO06cgaFUFCoVIaEyW47tNo5KjGy3qH9PQhmYmO4b7rl6OgjdEMgJkPKuyzu_39mcAhE58BwIP0MTyguaFYyT8z_3JZrG2AEAqamgJZug9ezgnXH9Fi-C0mkfLHY9Vnju-4MN0fkeP6iUbDjiFzWEUzuc2uD32xa_2YEYG18utXilwtYGvPR9vEYXG7WLdvqbV-h98bieP2er16flfLbKNKt4yiotjACtSi2EKYipOSWbCoRgjWK01DVlprKNsAyg4RpAVEzUFIShpKRNw67Q7WnXx-Rk1C5Z3Wrf91YnSYqa14INJXYq6eBjDHYjP4P7UOEoCchRoOzkj0A5CpTA5SBwoO5PlB3-Pzgbxnnba2tcGNeNd__y33KyeYs</recordid><startdate>20180919</startdate><enddate>20180919</enddate><creator>Boebinger, Matthew G.</creator><creator>Yeh, David</creator><creator>Xu, Michael</creator><creator>Miles, B. 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(ORNL), Oak Ridge, TN (United States)</aucorp><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Avoiding Fracture in a Conversion Battery Material through Reaction with Larger Ions</atitle><jtitle>Joule</jtitle><date>2018-09-19</date><risdate>2018</risdate><volume>2</volume><issue>9</issue><spage>1783</spage><epage>1799</epage><pages>1783-1799</pages><issn>2542-4351</issn><eissn>2542-4351</eissn><abstract>Conversion and alloying electrode materials offer high specific capacity for emerging sodium- and potassium-ion batteries, but the larger volume changes compared to reaction with lithium are thought to limit cyclability. The reaction mechanisms of many materials with Na+ and K+ are unknown, however, and this knowledge is key for engineering mechanically resilient materials. Here, in situ transmission electron microscopy is used to uncover the nanoscale transformations during the reaction of FeS2 electrode materials with Li+, Na+, and K+. Surprisingly, despite larger volume changes during the conversion reaction with Na+ and K+, the FeS2 crystals only fracture during lithiation. Modeling of reaction-induced deformation shows that the shape of the two-phase reaction front influences stress evolution, and unique behavior during lithiation causes stress concentrations and fracture. The larger volume changes in Na- and K-ion battery materials may therefore be managed through understanding and control of reaction mechanisms, ultimately leading to better alkali-ion batteries. [Display omitted] •In situ TEM reveals reaction mechanisms in FeS2 with various alkali ions•Only reaction with lithium causes fracture•Fracture process is driven by evolution of crystal shape and stress concentrations•Finite element modeling and nanoindentation provide insight into chemomechanics High-capacity electrode materials hold promise for next-generation batteries with high energy density. However, such materials often undergo large volume changes during charge and discharge, which can cause mechanical degradation and reduced cycle life. It is therefore critical to understand and control coupled reaction and degradation processes in high-capacity electrode materials. Here we find that FeS2, a battery electrode material that undergoes a conversion-type reaction, fractures during reaction with lithium, but not with larger alkali ions (sodium and potassium). This result is counterintuitive, since larger ions induce larger volume changes, which are generally associated with greater stresses and more significant mechanical degradation. These findings are important since they indicate that large-volume-change electrode materials can be mechanically resilient in emerging sodium- and potassium-ion battery systems, which is a key aspect of attaining long cycle life. Next-generation batteries with high energy density rely on high-capacity electrode materials, but large volume changes and mechanical fracture in these materials during charge and discharge limit cycle life. Here, we discover that FeS2 electrode materials are more mechanically resilient during reaction with larger alkali ions (sodium and potassium) compared with lithium, despite larger volume changes. These findings are important since they suggest that various large-volume-change electrode materials could enable stable cycling performance in next-generation sodium- and potassium-ion batteries.</abstract><cop>United States</cop><pub>Elsevier Inc</pub><doi>10.1016/j.joule.2018.05.015</doi><tpages>17</tpages><orcidid>https://orcid.org/0000-0001-5552-3456</orcidid><orcidid>https://orcid.org/0000000155523456</orcidid><oa>free_for_read</oa></addata></record>
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source	Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals; Alma/SFX Local Collection
subjects	batteries chemomechanics ENERGY STORAGE fracture in situ TEM phase transformations
title	Avoiding Fracture in a Conversion Battery Material through Reaction with Larger Ions
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