Tuning of Band Gap of Cathode Li 2 NiPO 4 F by Replacing P to Nb and Forming Li 2 NiNbO 4 F for Application as 5 V Cathode in Lithium Ion Battery: A Density Functional Theory Study

Electrochemical properties of Li 2 NiPO 4 F were studied using density functional theory. The obtained voltage, electronic band gap, capacity (∼ for 2 Li + extraction) and energy density are achieved as 5.33 V, 4.0 eV, 287.3 mAh g −1 and 1531.31 Wh kg −1 , respectively. Although, the electrochemical...

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Veröffentlicht in:	Journal of the Electrochemical Society 2024-08, Vol.171 (8), p.80508
Hauptverfasser:	Chakrabarti, Shamik, Thakur, A. K.
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description	Electrochemical properties of Li 2 NiPO 4 F were studied using density functional theory. The obtained voltage, electronic band gap, capacity (∼ for 2 Li + extraction) and energy density are achieved as 5.33 V, 4.0 eV, 287.3 mAh g −1 and 1531.31 Wh kg −1 , respectively. Although, the electrochemical properties of Li 2 NiPO 4 F are promising, large electronic band gap would certainly pose a limitation for its commercial application. Nb is a transition metal and its electronegativity is 1.6 which is less than the electronegativity of 2.19 for P. This implies, less operating voltage would be obtained if we replace P in Li 2 NiPO 4 F by Nb to form Li 2 NiNbO 4 F. However, electronic configuration of Nb is [Kr] 4d 4 5 s 1 and the valance state of Nb in Li 2 NiNbO 4 F is +5, which in turn specify that, localized Nb d states will reside in conduction band of Li 2 NiNbO 4 F and hence the electronic band-gap would be less owing to this localized Nb-d states. Our speculation gets verified by the calculated properties of Li 2 NiNbO 4 F obtained through DFT as follows; Voltage, electronic band gap, capacity (∼ for 2 Li + extraction) and energy density achieved, respectively, are 5.01 V, 3.64 eV (less than LiFePO 4 ), 215.71 mAh g −1 , 1080.71 Wh kg −1 . Lower electronic band gap of Li 2 NiNbO 4 F makes it an alternative to Li 2 NiPO 4 F.
doi_str_mv	10.1149/1945-7111/ad69c8
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K.</creator><creatorcontrib>Chakrabarti, Shamik ; Thakur, A. K.</creatorcontrib><description>Electrochemical properties of Li 2 NiPO 4 F were studied using density functional theory. The obtained voltage, electronic band gap, capacity (∼ for 2 Li + extraction) and energy density are achieved as 5.33 V, 4.0 eV, 287.3 mAh g −1 and 1531.31 Wh kg −1 , respectively. Although, the electrochemical properties of Li 2 NiPO 4 F are promising, large electronic band gap would certainly pose a limitation for its commercial application. Nb is a transition metal and its electronegativity is 1.6 which is less than the electronegativity of 2.19 for P. This implies, less operating voltage would be obtained if we replace P in Li 2 NiPO 4 F by Nb to form Li 2 NiNbO 4 F. However, electronic configuration of Nb is [Kr] 4d 4 5 s 1 and the valance state of Nb in Li 2 NiNbO 4 F is +5, which in turn specify that, localized Nb d states will reside in conduction band of Li 2 NiNbO 4 F and hence the electronic band-gap would be less owing to this localized Nb-d states. Our speculation gets verified by the calculated properties of Li 2 NiNbO 4 F obtained through DFT as follows; Voltage, electronic band gap, capacity (∼ for 2 Li + extraction) and energy density achieved, respectively, are 5.01 V, 3.64 eV (less than LiFePO 4 ), 215.71 mAh g −1 , 1080.71 Wh kg −1 . 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K.</creatorcontrib><title>Tuning of Band Gap of Cathode Li 2 NiPO 4 F by Replacing P to Nb and Forming Li 2 NiNbO 4 F for Application as 5 V Cathode in Lithium Ion Battery: A Density Functional Theory Study</title><title>Journal of the Electrochemical Society</title><description>Electrochemical properties of Li 2 NiPO 4 F were studied using density functional theory. The obtained voltage, electronic band gap, capacity (∼ for 2 Li + extraction) and energy density are achieved as 5.33 V, 4.0 eV, 287.3 mAh g −1 and 1531.31 Wh kg −1 , respectively. Although, the electrochemical properties of Li 2 NiPO 4 F are promising, large electronic band gap would certainly pose a limitation for its commercial application. Nb is a transition metal and its electronegativity is 1.6 which is less than the electronegativity of 2.19 for P. This implies, less operating voltage would be obtained if we replace P in Li 2 NiPO 4 F by Nb to form Li 2 NiNbO 4 F. However, electronic configuration of Nb is [Kr] 4d 4 5 s 1 and the valance state of Nb in Li 2 NiNbO 4 F is +5, which in turn specify that, localized Nb d states will reside in conduction band of Li 2 NiNbO 4 F and hence the electronic band-gap would be less owing to this localized Nb-d states. Our speculation gets verified by the calculated properties of Li 2 NiNbO 4 F obtained through DFT as follows; Voltage, electronic band gap, capacity (∼ for 2 Li + extraction) and energy density achieved, respectively, are 5.01 V, 3.64 eV (less than LiFePO 4 ), 215.71 mAh g −1 , 1080.71 Wh kg −1 . 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K.</creatorcontrib><collection>CrossRef</collection><jtitle>Journal of the Electrochemical Society</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Chakrabarti, Shamik</au><au>Thakur, A. K.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Tuning of Band Gap of Cathode Li 2 NiPO 4 F by Replacing P to Nb and Forming Li 2 NiNbO 4 F for Application as 5 V Cathode in Lithium Ion Battery: A Density Functional Theory Study</atitle><jtitle>Journal of the Electrochemical Society</jtitle><date>2024-08-01</date><risdate>2024</risdate><volume>171</volume><issue>8</issue><spage>80508</spage><pages>80508-</pages><issn>0013-4651</issn><eissn>1945-7111</eissn><abstract>Electrochemical properties of Li 2 NiPO 4 F were studied using density functional theory. The obtained voltage, electronic band gap, capacity (∼ for 2 Li + extraction) and energy density are achieved as 5.33 V, 4.0 eV, 287.3 mAh g −1 and 1531.31 Wh kg −1 , respectively. Although, the electrochemical properties of Li 2 NiPO 4 F are promising, large electronic band gap would certainly pose a limitation for its commercial application. Nb is a transition metal and its electronegativity is 1.6 which is less than the electronegativity of 2.19 for P. This implies, less operating voltage would be obtained if we replace P in Li 2 NiPO 4 F by Nb to form Li 2 NiNbO 4 F. However, electronic configuration of Nb is [Kr] 4d 4 5 s 1 and the valance state of Nb in Li 2 NiNbO 4 F is +5, which in turn specify that, localized Nb d states will reside in conduction band of Li 2 NiNbO 4 F and hence the electronic band-gap would be less owing to this localized Nb-d states. Our speculation gets verified by the calculated properties of Li 2 NiNbO 4 F obtained through DFT as follows; Voltage, electronic band gap, capacity (∼ for 2 Li + extraction) and energy density achieved, respectively, are 5.01 V, 3.64 eV (less than LiFePO 4 ), 215.71 mAh g −1 , 1080.71 Wh kg −1 . Lower electronic band gap of Li 2 NiNbO 4 F makes it an alternative to Li 2 NiPO 4 F.</abstract><doi>10.1149/1945-7111/ad69c8</doi><orcidid>https://orcid.org/0000-0003-4915-1945</orcidid></addata></record>
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title	Tuning of Band Gap of Cathode Li 2 NiPO 4 F by Replacing P to Nb and Forming Li 2 NiNbO 4 F for Application as 5 V Cathode in Lithium Ion Battery: A Density Functional Theory Study
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