{"title":"高能效卤化锌复合电池的阳离子驱动相变和阴离子增强动力学","authors":"Wei Zhong, Hao Cheng, Shichao Zhang, Laixi Li, Chaoqiang Tan, Wei Chen, Yingying Lu","doi":"10.1038/s41467-025-59894-w","DOIUrl":null,"url":null,"abstract":"<p>Aqueous Zn-halogen batteries, valued for high safety, large capacity, and low cost, suffer from the polyhalide shuttle effect and chaotic zinc electrodeposition, reducing energy efficiency and lifespan. Here we show a cation-driven positive electrode phase transition to suppress the shuttle effect and achieve uniform zinc electrodeposition, along with an anion kinetic enhancement strategy to improve energy efficiency and lifespan. Taking tetramethylammonium halide (TMAX, X = F, Cl, Br) as a subject, TMA<sup>+</sup> promotes oriented zinc (101) deposition on the negative electrode through electrostatic shielding, significantly extending cycling life. Concurrently, it captures I<sub>3</sub><sup>–</sup> on the positive electrode, forming a stable solid-phase interhalide complex that enhances coulombic efficiency. Compared to I<sub>3</sub><sup>–</sup> and TMAI<sub>3</sub>, X<sup>–</sup> anions lower the Gibbs free energy differences of I<sup>–</sup> → I<sub>2</sub>X<sup>–</sup> and I<sub>2</sub>X<sup>–</sup> → TMAI<sub>2</sub>X, accelerating I<sup>–</sup>/I<sub>2</sub>X<sup>–</sup>/TMAI<sub>2</sub>X conversions and improving voltage efficiency. In TMAF-modified electrolytes, zinc interhalide complex batteries achieve a high energy efficiency of 95.2% at 0.2 A g<sup>–1</sup> with good reversibility, showing only 0.1% capacity decay per cycle over 1000 cycles. At 1 A g<sup>–1</sup>, they show a low decay rate of 0.1‰ per cycle across 10,000 cycles. This study provides insights into enhancing energy efficiency and long-term stability for sustainable energy storage.</p>","PeriodicalId":19066,"journal":{"name":"Nature Communications","volume":"114 1","pages":""},"PeriodicalIF":14.7000,"publicationDate":"2025-05-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Cation-driven phase transition and anion-enhanced kinetics for high energy efficiency zinc-interhalide complex batteries\",\"authors\":\"Wei Zhong, Hao Cheng, Shichao Zhang, Laixi Li, Chaoqiang Tan, Wei Chen, Yingying Lu\",\"doi\":\"10.1038/s41467-025-59894-w\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Aqueous Zn-halogen batteries, valued for high safety, large capacity, and low cost, suffer from the polyhalide shuttle effect and chaotic zinc electrodeposition, reducing energy efficiency and lifespan. Here we show a cation-driven positive electrode phase transition to suppress the shuttle effect and achieve uniform zinc electrodeposition, along with an anion kinetic enhancement strategy to improve energy efficiency and lifespan. Taking tetramethylammonium halide (TMAX, X = F, Cl, Br) as a subject, TMA<sup>+</sup> promotes oriented zinc (101) deposition on the negative electrode through electrostatic shielding, significantly extending cycling life. Concurrently, it captures I<sub>3</sub><sup>–</sup> on the positive electrode, forming a stable solid-phase interhalide complex that enhances coulombic efficiency. Compared to I<sub>3</sub><sup>–</sup> and TMAI<sub>3</sub>, X<sup>–</sup> anions lower the Gibbs free energy differences of I<sup>–</sup> → I<sub>2</sub>X<sup>–</sup> and I<sub>2</sub>X<sup>–</sup> → TMAI<sub>2</sub>X, accelerating I<sup>–</sup>/I<sub>2</sub>X<sup>–</sup>/TMAI<sub>2</sub>X conversions and improving voltage efficiency. In TMAF-modified electrolytes, zinc interhalide complex batteries achieve a high energy efficiency of 95.2% at 0.2 A g<sup>–1</sup> with good reversibility, showing only 0.1% capacity decay per cycle over 1000 cycles. At 1 A g<sup>–1</sup>, they show a low decay rate of 0.1‰ per cycle across 10,000 cycles. 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引用次数: 0
摘要
卤水锌电池具有高安全性、大容量、低成本等优点,但存在多卤化物穿梭效应和锌电沉积混乱等问题,降低了电池的能效和寿命。在这里,我们展示了一个阳离子驱动的正极相变来抑制穿梭效应并实现均匀的锌电沉积,以及一个阴离子动力学增强策略来提高能源效率和寿命。以四甲基卤化铵(TMAX, X = F, Cl, Br)为研究对象,TMA+通过静电屏蔽促进负极取向锌(101)沉积,显著延长循环寿命。同时,它捕获了正极上的I3 -,形成了稳定的固相卤化物配合物,提高了库仑效率。与I3 -和TMAI3相比,X -阴离子降低了I -→I2X -和I2X -→TMAI2X的吉布斯自由能差,加速了I - /I2X - /TMAI2X的转换,提高了电压效率。在tmaf修饰的电解质中,在0.2 a g-1下,卤化锌复合电池的能量效率达到95.2%,具有良好的可逆性,在1000次循环中,每循环仅显示0.1%的容量衰减。在1 A g-1时,它们表现出低的衰减率,在10,000个循环中每循环0.1‰。该研究为提高能源效率和可持续能源储存的长期稳定性提供了见解。
Cation-driven phase transition and anion-enhanced kinetics for high energy efficiency zinc-interhalide complex batteries
Aqueous Zn-halogen batteries, valued for high safety, large capacity, and low cost, suffer from the polyhalide shuttle effect and chaotic zinc electrodeposition, reducing energy efficiency and lifespan. Here we show a cation-driven positive electrode phase transition to suppress the shuttle effect and achieve uniform zinc electrodeposition, along with an anion kinetic enhancement strategy to improve energy efficiency and lifespan. Taking tetramethylammonium halide (TMAX, X = F, Cl, Br) as a subject, TMA+ promotes oriented zinc (101) deposition on the negative electrode through electrostatic shielding, significantly extending cycling life. Concurrently, it captures I3– on the positive electrode, forming a stable solid-phase interhalide complex that enhances coulombic efficiency. Compared to I3– and TMAI3, X– anions lower the Gibbs free energy differences of I– → I2X– and I2X– → TMAI2X, accelerating I–/I2X–/TMAI2X conversions and improving voltage efficiency. In TMAF-modified electrolytes, zinc interhalide complex batteries achieve a high energy efficiency of 95.2% at 0.2 A g–1 with good reversibility, showing only 0.1% capacity decay per cycle over 1000 cycles. At 1 A g–1, they show a low decay rate of 0.1‰ per cycle across 10,000 cycles. This study provides insights into enhancing energy efficiency and long-term stability for sustainable energy storage.
期刊介绍:
Nature Communications, an open-access journal, publishes high-quality research spanning all areas of the natural sciences. Papers featured in the journal showcase significant advances relevant to specialists in each respective field. With a 2-year impact factor of 16.6 (2022) and a median time of 8 days from submission to the first editorial decision, Nature Communications is committed to rapid dissemination of research findings. As a multidisciplinary journal, it welcomes contributions from biological, health, physical, chemical, Earth, social, mathematical, applied, and engineering sciences, aiming to highlight important breakthroughs within each domain.
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