Journal
ADVANCED FUNCTIONAL MATERIALS
Volume 32, Issue 17, Pages -Publisher
WILEY-V C H VERLAG GMBH
DOI: 10.1002/adfm.202112399
Keywords
atomic force microscopy; deformation energy; dendrite growth; electric field; low concentration
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Funding
- General Research Fund (GRF) scheme of the Hong Kong Research Grants Council [15301220]
- Hong Kong Polytechnic University
- Guangdong-Hong Kong-Macau Joint Laboratory [2019B121205001]
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The mechanical stability of the solid electrolyte interphase (SEI) plays a crucial role in achieving exceptional cycling performance of K-metal batteries in low concentration carbonate electrolytes. Higher concentration electrolytes lead to increased inorganic content in SEI, which results in higher Young's modulus and ionic conductivity but lower elastic strain limit. SEI with low mechanical properties can trigger dendrite growth, highlighting the importance of optimizing SEI mechanical stability.
The mechanical properties of the solid electrolyte interphase (SEI) have attracted increasing attention, but their importance in guiding electrolyte design remains ambiguous. Here it is revealed that, despite a decrease in ionic conductivity for both electrolyte and SEI, exceptional cycling performance of K-metal batteries is achieved in a low concentration carbonate electrolyte by optimizing the mechanical stability of the SEI. The SEI formed in the studied carbonate electrolytes is predominantly organic. Its inorganic content increases with increasing electrolyte concentration and corresponds to an increase in Young's modulus (E) and ionic conductivity of SEI and a decrease in elastic strain limit (epsilon(Y)). The maximum elastic deformation energy combines effects of E and epsilon(Y), achieving a maximum in 0.5 m electrolyte. Finite element simulations indicate that SEI with low either E or epsilon(Y) inevitably triggers dendrite growth. These findings foreshadow an increased focus on the mechanical properties of the SEI, where low concentrations of carbonate electrolytes display merit.
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