Litcius/Paper detail

Sulfonic Acid-Functionalized Graphdiyne for Effective Li–S Battery Separators

Yang Kong, Xuming Qiu, Yurui Xue, Guoxing Li, Lu Qi, Wenlong Yang, Taifeng Liu, Yuliang Li

2024Journal of the American Chemical Society103 citationsDOI

Abstract

Lithium–sulfur (Li–S) batteries enable a promising high-energy-storage system while facing practical challenges regarding lithium dendrites and lithium polysulfides (LiPSs) shuttling. Herein, a fascinating SO 3 H-functionalized graphdiyne (SOGDY) was developed by grafting SO 3 H onto GDY to modify the separator in Li–S batteries. It realizes structure-retained material transformation, that is, SOGDY retains the crystalline all-carbon network and uniform subnanopores from the initial GDY. The abundant SO 3 H and uniform pores create a rapid Li + transport relay station, benefit rapid Li + transport and even lithium deposition, and prevent lithium dendrite growth. The spatial obstruction and strong polar adsorption sites from SO 3 H effectively inhibit LiPS shuttling. Additionally, SOGDY establishes a fast electron-transfer pathway to facilitate the LiPS conversion. The SOGDY/PP separator exhibited steady cycling at 1 mA cm –2 over 3500 h in the Li∥Li symmetric battery and achieved outstanding low-temperature and high-rate performance in the Li–S battery with a high initial specific capacity of 804.5 mA h g –1 and a final capacity of 504.9 mA h g –1 after 500 cycles at 3 C and −10 °C. This work demonstrates that introducing a stable all-carbon network and uniform functionalized nanopores is an effective strategy to modify the Li–S battery separator.

Topics & Concepts

ChemistryLithium (medication)Battery (electricity)Sulfonic acidLithium–sulfur batteryEnergy storageLead–acid batterySulfurNanotechnologyChemical engineeringOrganic chemistryElectrochemistryElectrodePhysical chemistryQuantum mechanicsEndocrinologyEngineeringMaterials sciencePhysicsMedicinePower (physics)Advanced Battery Materials and TechnologiesAdvancements in Battery MaterialsAdvanced battery technologies research