<p>Amorphous polymeric sulfur cathodes, such as sulfurized polyacrylonitrile (SPAN), enable high-energy lithium–sulfur batteries without cobalt or nickel, leveraging abundant sulfur. However, the limited in situ understanding of their synthesis and electrochemistry has impeded targeted optimization. Here we integrate operando high-energy total scattering with sulfur K-edge X-ray absorption spectroscopy to monitor SPAN’s formation and cycling in real time. Our results show that S–C bond formation halts further fusion of cyclized polyacrylonitrile, fostering π–π stacking and a transition from long-chain to short-chain sulfur—critical for reversible sulfur redox. These features synergistically minimize polysulfide dissolution and charge-transfer resistance, enabling optimized SPAN to achieve high capacity retention over 1,000 cycles. Operando X-ray absorption spectroscopy reveals that residual protons drive thiol–thione tautomerism, with lithium replacement during the first discharge causing ~20% irreversible capacity loss. To enhance performance, minimizing –NH groups and expanding pyridine networks are key. These findings transform SPAN optimization from empirical tuning to mechanism‑guided engineering and point the way towards sulfur loadings and energy densities competitive with state‑of‑the‑art Li‑ion cathodes.</p>

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Revealing key structures for reversible sulfur redox in amorphous polymeric sulfur

  • Nan Wang,
  • Shen Wang,
  • Yu Zheng,
  • Dacheng Kuai,
  • Seungmin Lee,
  • Sha Tan,
  • Dean Yen,
  • Hui Zhong,
  • Sanjit Ghose,
  • Yonghua Du,
  • Perla Balbuena,
  • Ping Liu,
  • Enyuan Hu

摘要

Amorphous polymeric sulfur cathodes, such as sulfurized polyacrylonitrile (SPAN), enable high-energy lithium–sulfur batteries without cobalt or nickel, leveraging abundant sulfur. However, the limited in situ understanding of their synthesis and electrochemistry has impeded targeted optimization. Here we integrate operando high-energy total scattering with sulfur K-edge X-ray absorption spectroscopy to monitor SPAN’s formation and cycling in real time. Our results show that S–C bond formation halts further fusion of cyclized polyacrylonitrile, fostering π–π stacking and a transition from long-chain to short-chain sulfur—critical for reversible sulfur redox. These features synergistically minimize polysulfide dissolution and charge-transfer resistance, enabling optimized SPAN to achieve high capacity retention over 1,000 cycles. Operando X-ray absorption spectroscopy reveals that residual protons drive thiol–thione tautomerism, with lithium replacement during the first discharge causing ~20% irreversible capacity loss. To enhance performance, minimizing –NH groups and expanding pyridine networks are key. These findings transform SPAN optimization from empirical tuning to mechanism‑guided engineering and point the way towards sulfur loadings and energy densities competitive with state‑of‑the‑art Li‑ion cathodes.