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Highly Enforced Rate Capability of a Graphite Anode via Interphase Chemistry Tailoring Based on an Electrolyte Additive

Wenjin Xiang, Min Chen, Xianggui Zhou, Jiakun Chen, Haidong Huang, Zhaoyu Sun, Ying Lü, Gaige Zhang, Xinyang Wen, Weishan Li

2022The Journal of Physical Chemistry Letters25 citationsDOI

Abstract

The rate capability of lithium-ion batteries is highly dependent on the interphase chemistry of graphite anodes. Herein, we demonstrate an anode interphase tailoring based on a novel electrolyte additive, lithium dodecyl sulfate (LiDS), which greatly improves the rate capability and cyclic stability of graphite anodes. Upon application of 1% LiDS in a base electrolyte, the discharge capacity at 2 C is improved from 102 to 240 mAh g–1 and its capacity retention is enhanced from 51% to 94% after 200 cycles at 0.5 C. These excellent performances are attributed to the preferential absorption of LiDS and the as-constructed interphase chemistry that is mainly composed of organic long-chain polyether and inorganic lithium sulfite. The long-chain polyether possesses flexibility endowing the interphase with robustness, while its combination with inorganic lithium sulfite accelerates lithium intercalation/deintercalation kinetics via decreasing the resistance for charge transfer.

Topics & Concepts

ElectrolyteInterphaseAnodeGraphiteSulfiteChemical engineeringLithium (medication)ChemistryIntercalation (chemistry)Inorganic chemistrySodium sulfiteMaterials scienceElectrodeOrganic chemistrySodiumPhysical chemistryBiologyGeneticsEndocrinologyEngineeringMedicineAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesAdvanced Battery Technologies Research
Highly Enforced Rate Capability of a Graphite Anode via Interphase Chemistry Tailoring Based on an Electrolyte Additive | Litcius