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In a galvanic cell, the electrical work is done by a redox system on its surroundings as electrons produced by the spontaneous redox reactions are transferred through an external circuit. Alternatively, an external circuit does work on a redox system by imposing a voltage sufficient to drive an otherwise nonspontaneous reaction in a process known as electrolysis. For instance, recharging a battery involves the use of an external power source to drive the spontaneous (discharge) cell reaction in...
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pH plays a critical role in maintaining normal cellular activities. It helps maintain the structure and function of various proteins, dictates the charge on cellular membranes, and is crucial for metabolic reactions inside the cell. Moreover, cells use the energy from the proton motive force to generate ATP.
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A concentration cell is a type of a  voltaic cell constructed by connecting two almost identical half-cells, both based on the same half-reaction and using the same electrode, differing only in the concentration of one redox species. A concentration cell's potential, therefore, is determined only by the concentration difference of the particular redox species.
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Substances that undergo either a physical or a chemical change in solution to yield ions that can conduct electricity are called electrolytes. If a substance yields ions in solution, that is, if the compound undergoes 100% dissociation, then the substance is a strong electrolyte. Complete dissociation is indicated by a single forward arrow. For example, water-soluble ionic compounds like sodium chloride dissociate into sodium cations and chloride anions in aqueous solution.
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In humans, electrolytes play a vital role in various physiological processes. Balancing electrolyte levels is essential for normal body functions; their imbalance can be life-threatening. The major electrolytes include sodium, potassium, chloride, calcium, phosphate, and bicarbonate. They are primarily involved in physiological processes, such as nerve signal transmission, membrane trafficking, muscle contraction, buffering body fluids, and balancing water levels in the body.
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在电解质中调节分子微异质性 控制宏观电池性能

Canfu Zhang1, Zhineng Ren1, Yuan Tu1

  • 1Department of Chemistry, Zhejiang University, Hangzhou 310027, China.

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|September 10, 2025
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概括

研究人员通过控制水分子的行为来调整水性电解质以获得更好的电池. 通过使用以太分子, 他们创造了较小的水, 提高了电化学稳定性, 扩大了更安全, 高密度的水电池的能量窗口.

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科学领域:

  • 电化学
  • 材料科学
  • 物理化学

背景情况:

  • 水性电池受到狭窄的电化学窗口和高反应性的限制.
  • 了解和控制电解质中的水分子反应性至关重要但具有挑战性.

研究的目的:

  • 研究以太分子如何影响水溶液的微观结构.
  • 确定电解质微观结构与水分子反应性之间的相关性.
  • 提高水性电解质的电化学稳定性和性能.

主要方法:

  • 采用了六种以太分子,结构和溶解能力各不相同.
  • 分析了微观结构参数,如溶解功率差异,Li+协调数和水集群大小.
  • 研究了LiMn2O4的电解质性能,其中包括Li4Ti5O12全细胞和1Ah的水性囊细胞.

主要成果:

  • 乙醇和水之间的阳性溶解功率差异促进了微异质性,减少了+协调数和水大小.
  • 小,孤立的水集群抑制长距离的水扩散,增强电化学稳定性.
  • 乙烯优化了电解质微结构,使得Li+扩散速度快,电化学窗口扩大.
  • 全电池在200个周期内保持了97.5%的容量;袋式电池提供了80.93Wh/kg的能量密度.

结论:

  • 通过以太分子进行微结构调节,有效地稳定水性电解质.
  • 控制水大小和+协调是提高电池性能的关键.
  • 这种方法为设计用于储能的高性能水性电池提供了途径.