Journal article 658 views
Mechanical Milling Assisted Synthesis and Electrochemical Performance of High Capacity LiFeBO3 for Lithium Batteries
Musa A. Cambaz,
M. Anji Reddy,
B. P. Vinayan,
Ralf Witte,
Alexander Pohl,
Xiaoke Mu,
Venkata Sai Kiran Chakravadhanula,
Christian Kübel,
Maximilian Fichtner,
Anji Munnangi 
ACS Applied Materials & Interfaces, Volume: 8, Issue: 3, Pages: 2166 - 2172
Swansea University Author:
Anji Munnangi
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DOI (Published version): 10.1021/acsami.5b10747
Abstract
Borate chemistry offers attractive features for iron based polyanionic compounds. For battery applications, lithium iron borate has been proposed as cathode material because it has the lightest polyanionic framework that offers a high theoretical capacity. Moreover, it shows promising characteristic...
| Published in: | ACS Applied Materials & Interfaces |
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| ISSN: | 1944-8244 1944-8252 |
| Published: |
2016
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| URI: | https://cronfa.swan.ac.uk/Record/cronfa51568 |
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<?xml version="1.0"?><rfc1807><datestamp>2019-09-04T11:59:51.2806947</datestamp><bib-version>v2</bib-version><id>51568</id><entry>2019-08-27</entry><title>Mechanical Milling Assisted Synthesis and Electrochemical Performance of High Capacity LiFeBO3 for Lithium Batteries</title><swanseaauthors><author><sid>3ed0b4f2ff4fb9e87c7a73e7a3c39da7</sid><ORCID>0000-0001-9101-0252</ORCID><firstname>Anji</firstname><surname>Munnangi</surname><name>Anji Munnangi</name><active>true</active><ethesisStudent>false</ethesisStudent></author></swanseaauthors><date>2019-08-27</date><deptcode>MTLS</deptcode><abstract>Borate chemistry offers attractive features for iron based polyanionic compounds. For battery applications, lithium iron borate has been proposed as cathode material because it has the lightest polyanionic framework that offers a high theoretical capacity. Moreover, it shows promising characteristics with an element combination that is favorable in terms of sustainability, toxicity, and costs. However, the system is also associated with a challenging chemistry, which is the major reason for the slow progress in its further development as a battery material. The two major challenges in the synthesis of LiFeBO3 are in obtaining phase purity and high electrochemical activity. Herein, we report a facile and scalable synthesis strategy for highly pure and electrochemically active LiFeBO3 by circumventing stability issues related to Fe2+ oxidation state by the right choice of the precursor and experimental conditions. Additionally, we carried out a Mössbauer spectroscopic study of electrochemical charged and charged–discharged LiFeBO3 and reported a lithium diffusion coefficient of 5.56 × 10–14 cm2 s–1 for the first time.</abstract><type>Journal Article</type><journal>ACS Applied Materials & Interfaces</journal><volume>8</volume><journalNumber>3</journalNumber><paginationStart>2166</paginationStart><paginationEnd>2172</paginationEnd><publisher/><issnPrint>1944-8244</issnPrint><issnElectronic>1944-8252</issnElectronic><keywords>LiFeBO3, polyanion, lithium diffusion coefficient, lithium batteries, Mössbauer study, cathode</keywords><publishedDay>27</publishedDay><publishedMonth>1</publishedMonth><publishedYear>2016</publishedYear><publishedDate>2016-01-27</publishedDate><doi>10.1021/acsami.5b10747</doi><url/><notes/><college>COLLEGE NANME</college><department>Materials Science and Engineering</department><CollegeCode>COLLEGE CODE</CollegeCode><DepartmentCode>MTLS</DepartmentCode><institution>Swansea University</institution><apcterm/><lastEdited>2019-09-04T11:59:51.2806947</lastEdited><Created>2019-08-27T12:16:46.2199817</Created><path><level id="1">Faculty of Science and Engineering</level><level id="2">School of Engineering and Applied Sciences - Materials Science and Engineering</level></path><authors><author><firstname>Musa A.</firstname><surname>Cambaz</surname><order>1</order></author><author><firstname>M.</firstname><surname>Anji Reddy</surname><order>2</order></author><author><firstname>B. P.</firstname><surname>Vinayan</surname><order>3</order></author><author><firstname>Ralf</firstname><surname>Witte</surname><order>4</order></author><author><firstname>Alexander</firstname><surname>Pohl</surname><order>5</order></author><author><firstname>Xiaoke</firstname><surname>Mu</surname><order>6</order></author><author><firstname>Venkata Sai Kiran</firstname><surname>Chakravadhanula</surname><order>7</order></author><author><firstname>Christian</firstname><surname>Kübel</surname><order>8</order></author><author><firstname>Maximilian</firstname><surname>Fichtner</surname><order>9</order></author><author><firstname>Anji</firstname><surname>Munnangi</surname><orcid>0000-0001-9101-0252</orcid><order>10</order></author></authors><documents/><OutputDurs/></rfc1807> |
| spelling |
2019-09-04T11:59:51.2806947 v2 51568 2019-08-27 Mechanical Milling Assisted Synthesis and Electrochemical Performance of High Capacity LiFeBO3 for Lithium Batteries 3ed0b4f2ff4fb9e87c7a73e7a3c39da7 0000-0001-9101-0252 Anji Munnangi Anji Munnangi true false 2019-08-27 MTLS Borate chemistry offers attractive features for iron based polyanionic compounds. For battery applications, lithium iron borate has been proposed as cathode material because it has the lightest polyanionic framework that offers a high theoretical capacity. Moreover, it shows promising characteristics with an element combination that is favorable in terms of sustainability, toxicity, and costs. However, the system is also associated with a challenging chemistry, which is the major reason for the slow progress in its further development as a battery material. The two major challenges in the synthesis of LiFeBO3 are in obtaining phase purity and high electrochemical activity. Herein, we report a facile and scalable synthesis strategy for highly pure and electrochemically active LiFeBO3 by circumventing stability issues related to Fe2+ oxidation state by the right choice of the precursor and experimental conditions. Additionally, we carried out a Mössbauer spectroscopic study of electrochemical charged and charged–discharged LiFeBO3 and reported a lithium diffusion coefficient of 5.56 × 10–14 cm2 s–1 for the first time. Journal Article ACS Applied Materials & Interfaces 8 3 2166 2172 1944-8244 1944-8252 LiFeBO3, polyanion, lithium diffusion coefficient, lithium batteries, Mössbauer study, cathode 27 1 2016 2016-01-27 10.1021/acsami.5b10747 COLLEGE NANME Materials Science and Engineering COLLEGE CODE MTLS Swansea University 2019-09-04T11:59:51.2806947 2019-08-27T12:16:46.2199817 Faculty of Science and Engineering School of Engineering and Applied Sciences - Materials Science and Engineering Musa A. Cambaz 1 M. Anji Reddy 2 B. P. Vinayan 3 Ralf Witte 4 Alexander Pohl 5 Xiaoke Mu 6 Venkata Sai Kiran Chakravadhanula 7 Christian Kübel 8 Maximilian Fichtner 9 Anji Munnangi 0000-0001-9101-0252 10 |
| title |
Mechanical Milling Assisted Synthesis and Electrochemical Performance of High Capacity LiFeBO3 for Lithium Batteries |
| spellingShingle |
Mechanical Milling Assisted Synthesis and Electrochemical Performance of High Capacity LiFeBO3 for Lithium Batteries Anji Munnangi |
| title_short |
Mechanical Milling Assisted Synthesis and Electrochemical Performance of High Capacity LiFeBO3 for Lithium Batteries |
| title_full |
Mechanical Milling Assisted Synthesis and Electrochemical Performance of High Capacity LiFeBO3 for Lithium Batteries |
| title_fullStr |
Mechanical Milling Assisted Synthesis and Electrochemical Performance of High Capacity LiFeBO3 for Lithium Batteries |
| title_full_unstemmed |
Mechanical Milling Assisted Synthesis and Electrochemical Performance of High Capacity LiFeBO3 for Lithium Batteries |
| title_sort |
Mechanical Milling Assisted Synthesis and Electrochemical Performance of High Capacity LiFeBO3 for Lithium Batteries |
| author_id_str_mv |
3ed0b4f2ff4fb9e87c7a73e7a3c39da7 |
| author_id_fullname_str_mv |
3ed0b4f2ff4fb9e87c7a73e7a3c39da7_***_Anji Munnangi |
| author |
Anji Munnangi |
| author2 |
Musa A. Cambaz M. Anji Reddy B. P. Vinayan Ralf Witte Alexander Pohl Xiaoke Mu Venkata Sai Kiran Chakravadhanula Christian Kübel Maximilian Fichtner Anji Munnangi |
| format |
Journal article |
| container_title |
ACS Applied Materials & Interfaces |
| container_volume |
8 |
| container_issue |
3 |
| container_start_page |
2166 |
| publishDate |
2016 |
| institution |
Swansea University |
| issn |
1944-8244 1944-8252 |
| doi_str_mv |
10.1021/acsami.5b10747 |
| college_str |
Faculty of Science and Engineering |
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facultyofscienceandengineering |
| hierarchy_top_title |
Faculty of Science and Engineering |
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facultyofscienceandengineering |
| hierarchy_parent_title |
Faculty of Science and Engineering |
| department_str |
School of Engineering and Applied Sciences - Materials Science and Engineering{{{_:::_}}}Faculty of Science and Engineering{{{_:::_}}}School of Engineering and Applied Sciences - Materials Science and Engineering |
| document_store_str |
0 |
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| description |
Borate chemistry offers attractive features for iron based polyanionic compounds. For battery applications, lithium iron borate has been proposed as cathode material because it has the lightest polyanionic framework that offers a high theoretical capacity. Moreover, it shows promising characteristics with an element combination that is favorable in terms of sustainability, toxicity, and costs. However, the system is also associated with a challenging chemistry, which is the major reason for the slow progress in its further development as a battery material. The two major challenges in the synthesis of LiFeBO3 are in obtaining phase purity and high electrochemical activity. Herein, we report a facile and scalable synthesis strategy for highly pure and electrochemically active LiFeBO3 by circumventing stability issues related to Fe2+ oxidation state by the right choice of the precursor and experimental conditions. Additionally, we carried out a Mössbauer spectroscopic study of electrochemical charged and charged–discharged LiFeBO3 and reported a lithium diffusion coefficient of 5.56 × 10–14 cm2 s–1 for the first time. |
| published_date |
2016-01-27T04:03:30Z |
| _version_ |
1763753287057670144 |
| score |
11.013575 |