Advanced search

Filter By:

Journal Check one or more journals to show results from those journals only.

Choose more journals

Article type Check one or more article types to show results from those article types only.
Subject Check one or more subjects to show results from those subjects only.
Date Choose a date option to show results from those dates only.

Custom date range

Clear all filters
Sort by:
Showing 1–9 of 9 results
Advanced filters: Author: Quanquan Pang Clear advanced filters

  • Despite promises of Li-S batteries as high energy storage systems, a cohesive design framework, systematic performance analysis, and benchmarks remain absent. Here, authors map recent advancements in the literature to identify general patterns that apply universally across all cell formats and materials chemistry, outlining key areas for optimization and future development towards practical Li-S batteries.

    • Saeed Yari
    • Albin Conde Reis
    • Mohammadhosein Safari
    ReviewsOpen Access
    Nature Communications
    Volume: 16, P: 1-15

  • Lithium–sulfur batteries are a promising electrochemical energy storage technology; however, they are limited by the dissolution of polysulfide intermediates. Now, it has been shown that sparingly solvating electrolytes containing a phase mediator can avoid polysulfide dissolution and accelerate surface-localized solution-phase sulfur reaction to improve battery performances.

    • Yatao Liu
    • Yun An
    • Quanquan Pang
    Research
    Nature Chemistry
    Volume: 17, P: 614-623

  • By using lithium thioborophosphate iodide glass-phase solid electrolytes in all-solid-state lithium–sulfur batteries, fast solid–solid sulfur redox reaction is demonstrated, leading to cells with ultrafast charging capability, superior cycling stability and high capacity.

    • Huimin Song
    • Konrad Münch
    • Quanquan Pang
    Research
    Nature
    Volume: 637, P: 846-853

  • A system integrating CO2 conversion and energy storage holds great promise, but faces a major challenge due to degraded catalysts on charge. Here, the authors present a highly efficient energy storage and CO2 reduction method in an aqueous battery, achieved through oxidation of reducing molecules.

    • Yumei Liu
    • Yun An
    • Quanquan Pang
    ResearchOpen Access
    Nature Communications
    Volume: 15, P: 1-12

  • Molten salt aluminium-sulfur batteries exhibit high-rate capability and moderate energy density, but suffer from high operating temperature. Here the authors demonstrate a rapidly charging aluminum-sulfur battery operating at 85 °C enabled by a quaternary alkali chloroaluminate electrolyte.

    • Jiashen Meng
    • Xufeng Hong
    • Quanquan Pang
    ResearchOpen Access
    Nature Communications
    Volume: 15, P: 1-10

  • Cation intercalation is an effective method to optimise the electronic structures of metal oxides. Here authors present a visual intercalation chemical synthesis strategy to control intercalated structures of metal oxides and synthesise flexible conductive metal oxide films in one minute at room temperature.

    • Yuanyuan Zhang
    • Xiaohua Zhang
    • Jianhua Yan
    ResearchOpen Access
    Nature Communications
    Volume: 14, P: 1-11

  • Conventional solid-to-solid conversion cathodes in rechargeable aluminium batteries suffer from sluggish reaction kinetics and cumulative structural degradation. Here the authors disclose a solution-to-solid conversion chemistry using molten salt electrolytes to achieve fast-charging capability and good cycling stability.

    • Jiashen Meng
    • Xuhui Yao
    • Quanquan Pang
    ResearchOpen Access
    Nature Communications
    Volume: 14, P: 1-9

  • An aluminium–chalcogen battery operating with a molten-salt electrolyte composed of NaCl–KCl–AlCl3 is presented, which allows rapid charging at up to 200C for hundreds of cycles, and is scalable, fire-resistant and low cost.

    • Quanquan Pang
    • Jiashen Meng
    • Donald R. Sadoway
    Research
    Nature
    Volume: 608, P: 704-711