Dynamic Intercalation-Conversion Site Supported Ultrathin 2D Mesoporous SnO2/SnSe2 Hybrid as Bifunctional Polysulfide Immobilizer and Lithium Regulator for Lithium-Sulfur Chemistry

The practical application of lithium-sulfur batteries is impeded by the polysulfide shuttling and interfacial instability of the metallic lithium anode. In this work, a twinborn ultrathin two-dimensional graphene-based mesoporous SnO2/SnSe2 hybrid (denoted as G-mSnO(2)/SnSe2) is constructed as a polysulfide immobilizer and lithium regulator for Li-S chemistry. The as-designed G-mSnO(2)/SnSe2 hybrid possesses high conductivity, strong chemical affinity (SnO2), and a dynamic intercalation-conversion site (LixSnSe2), inhibits shuttle behavior, provides rapid Li-intercalative transport kinetics, accelerates LiPS conversion, and decreases the decomposition energy barrier for Li2S, which is evidenced by the ex situ XAS spectra, in situ Raman, in situ XRD, and DFT calculations. Moreover, the mesoporous G-mSnO(2)/SnSe2 with lithiophilic characteristics enables homogeneous Li-ion deposition and inhibits Li dendrite growth. Therefore, Li-S batteries with a G-mSnO(2)/SnSe2 separator achieve a favorable electrochemical performance, including high sulfur utilization (1544 mAh g(-1) at 0.2 C), high-rate capability (794 mAh g(-1) at 8 C), and long cycle life (extremely low attenuation rate of 0.0144% each cycle at 5 C over 2000 cycles). Encouragingly, a 1.6 g S/Ah-level pouch cell realizes a high energy density of up to 359 Wh kg(-1) under a lean E/S usage of 3.0 mu L mg(-1). This work sheds light on the design roadmap for tackling S-cathode and Li-anode challenges simultaneously toward long-durability Li-S chemistry.

Automated summary

In this work, a twinborn ultrathin two-dimensional G-mSnO(2)/SnSe2 hybrid is constructed as a polysulfide immobilizer and lithium regulator for Li-S chemistry. The hybrid possesses high conductivity, strong chemical affinity, and provides rapid Li-intercalative transport kinetics. It inhibits shuttle behavior and Li dendrite growth, resulting in favorable electrochemical performance and long cycle life in Li-S batteries.