Dimolybdenum Paddlewheel Complexes with Cation Binding Sites as Electrolyte Additives to Manipulate the Solid-Electrolyte Interphase at Lithium Metal Anodes

Dimolybdenum Paddlewheel Complexes with Cation Binding Sites as Electrolyte Additives to Manipulate the Solid-Electrolyte Interphase at Lithium Metal Anodes

The use of electrolyte additives at millimolar loadings to control the surface chemistry of lithium metal anodes (LMAs) is a leading strategy to improve lithium metal batteries and promote electrosynthetic reactions. Whereas previous studies employed either inorganic or organic additives, in this st...

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Bibliographic Details
Main Author: Simon G. Gersib (21432741) (author)
Other Authors: Erik J. Askins (10182245) (author), Matthew Li (743636) (author), S. M. Supundrika Subasinghe (15197638) (author), Biki Kumar Behera (21432744) (author), Dan McElheny (249371) (author), Seoung-Bum Son (1586413) (author), Khalil Amine (1329924) (author), Ksenija D. Glusac (1633834) (author), Neal P. Mankad (1474654) (author)
Published: 2025
Subjects:
Biophysics
Biochemistry
Space Science
Biological Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
sup >+</ sup
promote electrosynthetic reactions
parasitic side reactions
lithium metal anodes
g ., overpotential
dimolybdenum paddlewheel complexes
dimolybdenum paddlewheel complex
coulombic efficiency ),
cationically charged aggregates
calendar aging tests
2 -( 2
promote reversible li
li plating properties
li plating conditions
second coordination sphere
first organometallic additive
cation binding sites
4 </ sub
1 </ b
solid electrolyte interphase
electrolyte interphase
organometallic synthesis
additive protects
electrolyte additives
surface structure
surface chemistry
products thereof
produce modest
organic additives
notable benefit
modified sei
millimolar loadings
measurable improvements
leading strategy
induces immobilization
data disclose
acetate ],
[< b
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Summary:The use of electrolyte additives at millimolar loadings to control the surface chemistry of lithium metal anodes (LMAs) is a leading strategy to improve lithium metal batteries and promote electrosynthetic reactions. Whereas previous studies employed either inorganic or organic additives, in this study, we report the first organometallic additive, Mo<sub>2</sub>(mea)<sub>4</sub> [<b>1</b>, mea = 2-(2-methoxyethoxy)acetate], a dimolybdenum paddlewheel complex that is stable under Li plating conditions and features cation binding sites in the second coordination sphere that promote reversible Li<sup>+</sup> coordination. Binding of Li<sup>+</sup> ions to <b>1</b> induces immobilization of cationically charged aggregates (or products thereof) into the solid electrolyte interphase (SEI), imparting multiple beneficial functions. The modified SEI was found to protect the LMA against parasitic side reactions, produce modest but measurable improvements to Li plating properties (e.g., overpotential, surface structure, and Coulombic efficiency), and improve interfacial charge transport properties. The most notable benefit to battery cycling performance appears in calendar aging tests, which show that the presence of the additive protects the LMA from parasitic side reactions that would otherwise decrease overall cell cycling efficiency over time. Collectively, these data disclose a tactic for designing electrolyte additives using principles of organometallic synthesis.

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