Quantum Spin Exchange Interactions Trigger O p Band Broadening for Enhanced Aqueous Zinc-Ion Battery Performance

The pressing demand for large-scale energy storage solutions has propelled the development of advanced battery technologies, among which zinc-ion batteries (ZIBs) are prominent due to their resource abundance, high capacity, and safety in aqueous environments. However, the use of manganese oxide cat...

Full description

Saved in:

Bibliographic Details
Published in	Angewandte Chemie International Edition p. e202415997
Main Authors	Wang, Shiyu, Yao, Shuyun, Zhang, Feike, Ji, Kang, Ji, Yingjie, Li, Jingxian, Fu, Weijie, Liu, Yuanming, Yang, Jinghua, Liu, Ruilong, Xie, Jiangzhou, Yang, Zhiyu, Yan, Yi-Ming
Format	Journal Article
Language	English
Published	Germany 21.09.2024
Subjects	O p band, Quantum spin exchange interactions, Aqueous zinc ion batteries, Kinetics, Transition metal oxides
Online Access	Get full text

Cover

Loading…

Abstract	The pressing demand for large-scale energy storage solutions has propelled the development of advanced battery technologies, among which zinc-ion batteries (ZIBs) are prominent due to their resource abundance, high capacity, and safety in aqueous environments. However, the use of manganese oxide cathodes in ZIBs is challenged by their poor electrical conductivity and structural stability, stemming from the intrinsic properties of MnO2 and the destabilizing effects of ion intercalation. To overcome these limitations, our research delves into atomic-level engineering, emphasizing quantum spin exchange interactions (QSEI). These essential for modifying electronic characteristics, can significantly influence material efficiency and functionality. We demonstrate through density functional theory (DFT) calculations that enhanced QSEI in manganese oxides broadens the O p band, narrows the bandgap, and improves both proton adsorption and electron transport. Empirical evidence is provided through the synthesis of Ru-MnO2 nanosheets, which display a marked increase in energy storage capacity, achieving 314.4 mAh g-1 at 0.2 A g-1 and maintaining high capacity after 2000 cycles. Our findings underscore the potential of QSEI to enhance the performance of TMO cathodes in ZIBs, pointing to new avenues for advancing battery technology.
AbstractList	The pressing demand for large-scale energy storage solutions has propelled the development of advanced battery technologies, among which zinc-ion batteries (ZIBs) are prominent due to their resource abundance, high capacity, and safety in aqueous environments. However, the use of manganese oxide cathodes in ZIBs is challenged by their poor electrical conductivity and structural stability, stemming from the intrinsic properties of MnO2 and the destabilizing effects of ion intercalation. To overcome these limitations, our research delves into atomic-level engineering, emphasizing quantum spin exchange interactions (QSEI). These essential for modifying electronic characteristics, can significantly influence material efficiency and functionality. We demonstrate through density functional theory (DFT) calculations that enhanced QSEI in manganese oxides broadens the O p band, narrows the bandgap, and improves both proton adsorption and electron transport. Empirical evidence is provided through the synthesis of Ru-MnO2 nanosheets, which display a marked increase in energy storage capacity, achieving 314.4 mAh g-1 at 0.2 A g-1 and maintaining high capacity after 2000 cycles. Our findings underscore the potential of QSEI to enhance the performance of TMO cathodes in ZIBs, pointing to new avenues for advancing battery technology.The pressing demand for large-scale energy storage solutions has propelled the development of advanced battery technologies, among which zinc-ion batteries (ZIBs) are prominent due to their resource abundance, high capacity, and safety in aqueous environments. However, the use of manganese oxide cathodes in ZIBs is challenged by their poor electrical conductivity and structural stability, stemming from the intrinsic properties of MnO2 and the destabilizing effects of ion intercalation. To overcome these limitations, our research delves into atomic-level engineering, emphasizing quantum spin exchange interactions (QSEI). These essential for modifying electronic characteristics, can significantly influence material efficiency and functionality. We demonstrate through density functional theory (DFT) calculations that enhanced QSEI in manganese oxides broadens the O p band, narrows the bandgap, and improves both proton adsorption and electron transport. Empirical evidence is provided through the synthesis of Ru-MnO2 nanosheets, which display a marked increase in energy storage capacity, achieving 314.4 mAh g-1 at 0.2 A g-1 and maintaining high capacity after 2000 cycles. Our findings underscore the potential of QSEI to enhance the performance of TMO cathodes in ZIBs, pointing to new avenues for advancing battery technology. The pressing demand for large‐scale energy storage solutions has propelled the development of advanced battery technologies, among which zinc‐ion batteries (ZIBs) are prominent due to their resource abundance, high capacity, and safety in aqueous environments. However, the use of manganese oxide cathodes in ZIBs is challenged by their poor electrical conductivity and structural stability, stemming from the intrinsic properties of MnO2 and the destabilizing effects of ion intercalation. To overcome these limitations, our research delves into atomic‐level engineering, emphasizing quantum spin exchange interactions (QSEI). These essential for modifying electronic characteristics, can significantly influence material efficiency and functionality. We demonstrate through density functional theory (DFT) calculations that enhanced QSEI in manganese oxides broadens the O p band, narrows the bandgap, and improves both proton adsorption and electron transport. Empirical evidence is provided through the synthesis of Ru‐MnO2 nanosheets, which display a marked increase in energy storage capacity, achieving 314.4 mAh g‐1 at 0.2 A g‐1 and maintaining high capacity after 2000 cycles. Our findings underscore the potential of QSEI to enhance the performance of TMO cathodes in ZIBs, pointing to new avenues for advancing battery technology The pressing demand for large-scale energy storage solutions has propelled the development of advanced battery technologies, among which zinc-ion batteries (ZIBs) are prominent due to their resource abundance, high capacity, and safety in aqueous environments. However, the use of manganese oxide cathodes in ZIBs is challenged by their poor electrical conductivity and structural stability, stemming from the intrinsic properties of MnO2 and the destabilizing effects of ion intercalation. To overcome these limitations, our research delves into atomic-level engineering, emphasizing quantum spin exchange interactions (QSEI). These essential for modifying electronic characteristics, can significantly influence material efficiency and functionality. We demonstrate through density functional theory (DFT) calculations that enhanced QSEI in manganese oxides broadens the O p band, narrows the bandgap, and improves both proton adsorption and electron transport. Empirical evidence is provided through the synthesis of Ru-MnO2 nanosheets, which display a marked increase in energy storage capacity, achieving 314.4 mAh g-1 at 0.2 A g-1 and maintaining high capacity after 2000 cycles. Our findings underscore the potential of QSEI to enhance the performance of TMO cathodes in ZIBs, pointing to new avenues for advancing battery technology.
Author	Xie, Jiangzhou Ji, Kang Fu, Weijie Wang, Shiyu Yang, Jinghua Yang, Zhiyu Zhang, Feike Yan, Yi-Ming Li, Jingxian Liu, Ruilong Ji, Yingjie Liu, Yuanming Yao, Shuyun
Author_xml	– sequence: 1 givenname: Shiyu surname: Wang fullname: Wang, Shiyu organization: Beijing University of Chemical Technology, School of Chemical Engineering, CHINA – sequence: 2 givenname: Shuyun surname: Yao fullname: Yao, Shuyun organization: Beijing University of Chemical Technology, School of Chemical Engineering, CHINA – sequence: 3 givenname: Feike surname: Zhang fullname: Zhang, Feike organization: Beijing University of Chemical Technology, School of Chemical Engineering, CHINA – sequence: 4 givenname: Kang surname: Ji fullname: Ji, Kang organization: Beijing University of Chemical Technology, School of Chemical Engineering, CHINA – sequence: 5 givenname: Yingjie surname: Ji fullname: Ji, Yingjie organization: Beijing University of Chemical Technology, School of Chemical Engineering, CHINA – sequence: 6 givenname: Jingxian surname: Li fullname: Li, Jingxian organization: Beijing University of Chemical Technology, School of Chemical Engineering, CHINA – sequence: 7 givenname: Weijie surname: Fu fullname: Fu, Weijie organization: Beijing University of Chemical Technology, School of Chemical Engineering, CHINA – sequence: 8 givenname: Yuanming surname: Liu fullname: Liu, Yuanming organization: Beijing University of Chemical Technology, School of Chemical Engineering, CHINA – sequence: 9 givenname: Jinghua surname: Yang fullname: Yang, Jinghua organization: Beijing University of Chemical Technology, School of Chemical Engineering, CHINA – sequence: 10 givenname: Ruilong surname: Liu fullname: Liu, Ruilong organization: Beijing University of Chemical Technology, School of Chemical Engineering, CHINA – sequence: 11 givenname: Jiangzhou surname: Xie fullname: Xie, Jiangzhou organization: University of New South Wales, School of Mechanical and Manufacturing Engineering, AUSTRALIA – sequence: 12 givenname: Zhiyu surname: Yang fullname: Yang, Zhiyu organization: Beijing University of Chemical Technology, School of Chemical Engineering, CHINA – sequence: 13 givenname: Yi-Ming surname: Yan fullname: Yan, Yi-Ming organization: Beijing University of Chemical Technology, No.15, North Third Ring East Road, Chaoyang District, Beijing, Beijing, CHINA
BackLink	https://www.ncbi.nlm.nih.gov/pubmed/39305188$$D View this record in MEDLINE/PubMed
BookMark	eNo9kDtPwzAUhS1URB-wMiKPLCl23CTO2FYFKlUqiE4skR_XJahxgp1I9N_jqKXTvcN3jo6-MRrY2gJC95RMKSHxk7AlTGMSz2iS59kVGtEkphHLMjYI_4yxKOMJHaKx99-B55ykN2jIckYSyvkINe-dsG1X4Y-mtHj1q76E3QNe2xacUG1ZW493rtzvweEtbvBCWI0XrhYabGn32NQOr2wIKdB4_tNB3Xn8WVoVrWsb6Db0HPEbuABWPXWLro04eLg73wnaPa92y9dos31ZL-ebSOUJj4BTUAnhMleKktRInnE9M1Tm2oiUSmN0akiuUyqkoFJLnuQ60VIAB6Yzxibo8VTbuDqs8m1RlV7B4SBsP7FglGTBDE97dHpClau9d2CKxpWVcMeCkqKXXPSSi4vkEHg4d3eyAn3B_62yPyx9e-Y
ContentType	Journal Article
Copyright	2024 Wiley‐VCH GmbH.
Copyright_xml	– notice: 2024 Wiley‐VCH GmbH.
DBID	NPM AAYXX CITATION 7X8
DOI	10.1002/anie.202415997
DatabaseName	PubMed CrossRef MEDLINE - Academic
DatabaseTitle	PubMed CrossRef MEDLINE - Academic
DatabaseTitleList	MEDLINE - Academic CrossRef PubMed
Database_xml	– sequence: 1 dbid: NPM name: PubMed url: https://proxy.k.utb.cz/login?url=http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed sourceTypes: Index Database
DeliveryMethod	fulltext_linktorsrc
Discipline	Chemistry
EISSN	1521-3773
ExternalDocumentID	10_1002_anie_202415997 39305188
Genre	Journal Article
GroupedDBID	--- -DZ -~X .3N .GA 05W 0R~ 10A 1L6 1OB 1OC 1ZS 23M 33P 3SF 3WU 4.4 4ZD 50Y 50Z 51W 51X 52M 52N 52O 52P 52S 52T 52U 52W 52X 53G 5GY 5RE 5VS 66C 6TJ 702 7PT 8-0 8-1 8-3 8-4 8-5 8UM 930 A03 AAESR AAEVG AAHHS AANLZ AAONW AAXRX AAZKR ABCQN ABCUV ABEML ABIJN ABLJU ABPPZ ABPVW ACAHQ ACCFJ ACCZN ACFBH ACGFS ACIWK ACNCT ACPOU ACPRK ACSCC ACXBN ACXQS ADBBV ADEOM ADIZJ ADKYN ADMGS ADOZA ADXAS ADZMN ADZOD AEEZP AEIGN AEIMD AEQDE AEUQT AEUYR AFBPY AFFNX AFFPM AFGKR AFPWT AFRAH AFZJQ AHBTC AHMBA AITYG AIURR AIWBW AJBDE AJXKR ALAGY ALMA_UNASSIGNED_HOLDINGS ALUQN AMBMR AMYDB ATUGU AUFTA AZBYB AZVAB B-7 BAFTC BDRZF BFHJK BHBCM BMNLL BMXJE BNHUX BROTX BRXPI BTSUX BY8 CS3 D-E D-F D0L DCZOG DPXWK DR1 DR2 DRFUL DRSTM EBS F00 F01 F04 F5P G-S G.N GNP GODZA H.T H.X HBH HGLYW HHY HHZ HZ~ IX1 J0M JPC KQQ LATKE LAW LC2 LC3 LEEKS LH4 LITHE LOXES LP6 LP7 LUTES LYRES MEWTI MK4 MRFUL MRSTM MSFUL MSSTM MXFUL MXSTM N04 N05 N9A NF~ NNB NPM O66 O9- OIG P2P P2W P2X P4D PQQKQ Q.N Q11 QB0 QRW R.K RNS ROL RWI RX1 RYL SUPJJ TN5 UB1 UPT UQL V2E VQA W8V W99 WBFHL WBKPD WH7 WIB WIH WIK WJL WOHZO WQJ WRC WXSBR WYISQ XG1 XPP XSW XV2 YZZ ZZTAW ~IA ~KM ~WT AAYXX CITATION 7X8
ID	FETCH-LOGICAL-c958-e81ec508b9cc106fb878d4f1b9dfa61bffd6f09d61aba1bdb859d5dbae8e3d733
ISSN	1433-7851 1521-3773
IngestDate	Sat Oct 26 03:54:58 EDT 2024 Wed Sep 25 14:12:35 EDT 2024 Tue Oct 29 09:16:17 EDT 2024
IsPeerReviewed	true
IsScholarly	true
Keywords	O p band, Quantum spin exchange interactions, Aqueous zinc ion batteries, Kinetics, Transition metal oxides
Language	English
License	2024 Wiley‐VCH GmbH.
LinkModel	OpenURL
MergedId	FETCHMERGED-LOGICAL-c958-e81ec508b9cc106fb878d4f1b9dfa61bffd6f09d61aba1bdb859d5dbae8e3d733
Notes	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23
PMID	39305188
PQID	3107785863
PQPubID	23479
ParticipantIDs	proquest_miscellaneous_3107785863 crossref_primary_10_1002_anie_202415997 pubmed_primary_39305188
PublicationCentury	2000
PublicationDate	2024-Sep-21 2024-09-21 20240921
PublicationDateYYYYMMDD	2024-09-21
PublicationDate_xml	– month: 09 year: 2024 text: 2024-Sep-21 day: 21
PublicationDecade	2020
PublicationPlace	Germany
PublicationPlace_xml	– name: Germany
PublicationTitle	Angewandte Chemie International Edition
PublicationTitleAlternate	Angew Chem Int Ed Engl
PublicationYear	2024
SSID	ssj0028806
Score	2.5091138
Snippet	The pressing demand for large-scale energy storage solutions has propelled the development of advanced battery technologies, among which zinc-ion batteries... The pressing demand for large‐scale energy storage solutions has propelled the development of advanced battery technologies, among which zinc‐ion batteries...
SourceID	proquest crossref pubmed
SourceType	Aggregation Database Index Database
StartPage	e202415997
Title	Quantum Spin Exchange Interactions Trigger O p Band Broadening for Enhanced Aqueous Zinc-Ion Battery Performance
URI	https://www.ncbi.nlm.nih.gov/pubmed/39305188 https://www.proquest.com/docview/3107785863
hasFullText	1
inHoldings	1
isFullTextHit
isPrint
link	http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwnV1Lb9QwELagSNALKq926UOuhMQhyrKO83CO23ar0kMrYBGIS2THthpVTSPYCJZfzzi20_QlAZdo5XgTZb5P45nxzBihN2DFa-BKGgpYq8JYSB7ymJUhrNWgLuNMUd1l-Z6kR5_j46_JYKO9qy5ZiHH5-866kv9BFcYAV1Ml-w_I9g-FAfgN-MIVEIbrX2H8oQW5tBfBp6aqg9kvW8Rrg3y2XuFHMAfv2xT2ngZNsGeC5OB3c9A1PoFyVp_ZHIApLBAmHfZbVZfhe-CE7by5NDnyvrRgaMlO4VU_uSkGCLqmA-pGcHEmq-Ee_xcflz6rlm2vavilHWuXbT-zD2Efquq8p92xzTrgbqF1cYooNkkVtvh5rJxujQjos4wO9KUyM8Gisjm6t9S5bQ9rau3Hd04EOJqLDlyag-Ii9oTAGw20_a2H6FEE2sjk_R187HuMRaDAUt_NcxK9u_6yVfTY__264XKPN9JZJfM19NS5E3hqufEMPVD1c_Rk35_i9wI1jiPYcAR7juAhR7DjCD7FDTYcwVccwQA99hzBjiPYcwQ7juABR16i-eFsvn8UulM2wjJPWKgYUSVY6SIvSzJJtWAZk7EmIpeap0RoLVM9yWVKuOBESMGSXCZScMUUlRmlr9BKfVmrDYR1npRgwDI-kWA0JvAkktE44ZqCTxwJNkJvvQSLxvZSKWzX7KgwYi96sY_QrhdwAfIye1i8Nh9YgDeSZSxhKR2hdSv5_lkeqdf33tlEq1fU3EIri--t2gajciF2OlL8ARW4eAU
link.rule.ids	315,783,787,27938,27939
linkProvider	Wiley-Blackwell
openUrl	ctx_ver=Z39.88-2004&ctx_enc=info%3Aofi%2Fenc%3AUTF-8&rfr_id=info%3Asid%2Fsummon.serialssolutions.com&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.genre=article&rft.atitle=Quantum+Spin+Exchange+Interactions+Trigger+O+p+Band+Broadening+for+Enhanced+Aqueous+Zinc-Ion+Battery+Performance&rft.jtitle=Angewandte+Chemie+International+Edition&rft.au=Wang%2C+Shiyu&rft.au=Yao%2C+Shuyun&rft.au=Zhang%2C+Feike&rft.au=Ji%2C+Kang&rft.date=2024-09-21&rft.eissn=1521-3773&rft.spage=e202415997&rft_id=info:doi/10.1002%2Fanie.202415997&rft_id=info%3Apmid%2F39305188&rft.externalDocID=39305188
thumbnail_l	http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/lc.gif&issn=1433-7851&client=summon
thumbnail_m	http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/mc.gif&issn=1433-7851&client=summon
thumbnail_s	http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/sc.gif&issn=1433-7851&client=summon