TY - JOUR
T1 - Spatially coupled adsorption and catalysis for sustainable lithium–sulfur batteries
AU - Bi, Ruyi
AU - Wang, Jiangyan
AU - Wan, Jiawei
AU - Zhang, Lijuan
AU - Sun, Mingzi
AU - Huang, Bolong
AU - Li, Boquan
AU - Liang, Zheng
AU - Zhao, Yasong
AU - Li, Liang
AU - Yu, Ranbo
AU - Wang, Dan
N1 - Publisher Copyright:
© The Author(s), under exclusive licence to Springer Nature Limited 2026.
PY - 2026/5
Y1 - 2026/5
N2 - Lithium–sulfur batteries have been considered a promising energy storage technology for maximizing sustainability, owing to their ultrahigh theoretical energy density and the abundant supply of low-cost sulfur. However, their high-energy advantage is often compromised in practice by the heavy, voluminous host materials and catalysts required to mitigate the polysulfide shuttle effect and sluggish redox kinetics. Here we address this dilemma by spatially coupling adsorption and catalytic sites within an sp-nitrogen-doped graphdiyne multishelled architecture. This design enables an exceptional sulfur loading of 93.9%, achieving a close-to-theoretical capacity of 1,462 mAh g(S+host)−1 and a pouch-cell energy density of ~457 Wh kg−1. Even at a high rate of 10C, the system maintains an energy density of 1,384.5 Wh kg(S+host)−1 over 600 cycles. In situ spectroscopic characterizations and theoretical calculations reveal that the favourable orbital overlapping between sp-nitrogen and neighbouring carbon facilitates rapid electron transfer and optimized charge redistribution, thus simultaneously promoting the adsorption and redox reaction of polysulfides. By minimizing inactive mass, this work provides a scalable blueprint for high-performance, resource-efficient battery chemistries.
AB - Lithium–sulfur batteries have been considered a promising energy storage technology for maximizing sustainability, owing to their ultrahigh theoretical energy density and the abundant supply of low-cost sulfur. However, their high-energy advantage is often compromised in practice by the heavy, voluminous host materials and catalysts required to mitigate the polysulfide shuttle effect and sluggish redox kinetics. Here we address this dilemma by spatially coupling adsorption and catalytic sites within an sp-nitrogen-doped graphdiyne multishelled architecture. This design enables an exceptional sulfur loading of 93.9%, achieving a close-to-theoretical capacity of 1,462 mAh g(S+host)−1 and a pouch-cell energy density of ~457 Wh kg−1. Even at a high rate of 10C, the system maintains an energy density of 1,384.5 Wh kg(S+host)−1 over 600 cycles. In situ spectroscopic characterizations and theoretical calculations reveal that the favourable orbital overlapping between sp-nitrogen and neighbouring carbon facilitates rapid electron transfer and optimized charge redistribution, thus simultaneously promoting the adsorption and redox reaction of polysulfides. By minimizing inactive mass, this work provides a scalable blueprint for high-performance, resource-efficient battery chemistries.
UR - https://www.scopus.com/pages/publications/105034395482
U2 - 10.1038/s41893-026-01794-y
DO - 10.1038/s41893-026-01794-y
M3 - Article
AN - SCOPUS:105034395482
SN - 2398-9629
VL - 9
SP - 763
EP - 773
JO - Nature Sustainability
JF - Nature Sustainability
IS - 5
ER -