锂离子电池低温电解液的挑战及研究进展

近年来,锂离子电池(LIB)已广泛应用于便携式电子设备、电动汽车、储能领域,是目前最有前景的新能源应用技术之一。然而低温条件下,LIB仍面临循环寿命和能量/功率密度衰减过大等诸多挑战,严重限制了其在极端工况下的实际应用。其主要原因包括:Li+在电极材料中的扩散及其界面处的电荷传递和去溶剂化过程较为缓慢;电解液粘度增大,对材料和隔膜的润湿性变差;石墨负极嵌锂时容易形成锂枝晶等。基于多年来低温锂离子电池的开发经验和相关文献报道,从电解液的角度综述了提高低温锂离子电池的策略,重点介绍了低粘度、宽液程的共溶剂,高电导率、低去溶剂化能的新型锂盐以及形成薄且致密固体电解质中间相(solid electrolyte interphase,SEI)的成膜添加剂对低温性能的影响及其挑战,并对未来低温电解液的发展方向进行了展望。

凹凸棒石/g-C_3N_4-AgFeO_2复合材料制备及其光催化性能

以凹凸棒石(简称凹土,ATP)为基体,通过原位化学法一步直接合成g-C_3N_4薄层材料,并将其有效固载于凹土表面(ATP/gC_3N_4),再通过原位沉淀法引入不同比例AgFeO_2纳米颗粒,构筑系列兼具磁分离特性和高效光催化活性的ATP/g-C_3N_4-AgFeO_2-Y复合光催化剂(Y=wATP/g-C_3N_4/(wATP/g-C_3N_4+wAg FeO_2)×100%,表示ATP/g-C_3N_4在ATP/g-C_3N_4-AgFeO_2复合材料中所占的质量百分数)。采用XRD、SEM、BET、UV-Vis、PL和ICP表征其结构和物化性能,以酸性红G(ARG)为目标降解物,研究其光催化性能。研究发现:通过形成Si-O-C键,g-C_3N_4薄层被均匀固定在凹土表面;AgFeO_2纳米颗粒均匀沉积于ATP/g-C_3N_4表面并形成Z型异质结,ATP/gC_3N_4-AgFeO_2-Y具有比ATP/g-C_3N_4和AgFeO_2更优异的可见光光催化性能,且随着ATP/g-C_3N_4含量的增大呈先升高而后下降的趋势;当Y=57%时复合材料的性能最佳,ATP/g-C_3N_4-AgFeO_2-57%对20 mg·L-1酸性红G的降解率可达97.4%,循环4次使用后,降解率仍保持94.2%。通过自由基捕获实验研究了光催化反应机理,发现·O2-是光催化过程的主要活性物种。

电纺纤维在锌-空气电池中的应用研究进展

日益严重的环境污染与能源危机成为人类社会可持续发展进程中的最大阻碍。锌-空气电池作为一类很有发展潜力的电化学储能装置,因其高能量密度和环境友好等特点在能源领域引发了广泛关注,然而空气电极中的氧还原反应和析氧反应动力学缓慢,严重限制了它的商业化应用,因此当前迫切需要开发高效廉价的非贵金属双功能催化剂。静电纺丝制备的一维纳米纤维具有高孔隙率和大比表面积等优点,缩短了离子扩散距离并提供了更多的反应活性位点,有效改善了活性物质的嵌入/脱出反应动力学,在储能器件领域尤其是锌-空气电池中有广阔的应用前景。首先简要介绍了静电纺丝技术,然后探讨了电纺纤维及其自支撑结构的氧还原/析氧反应的催化反应活性,并通过经典的文献案例讨论了电纺纤维在液态和柔性固态锌-空气电池中的应用研究最新进展,最后,对基于电纺纤维催化剂的锌-空气电池应用面临的挑战和未来的发展方向进行了展望。

Multi-dimensional hierarchical CoS_(2)@MXene as trifunctional electrocatalysts for zinc-air batteries and overall water splitting

The demanding all-in-one electrocatalyst system for oxygen reduction reaction(ORR), oxygen evolution reaction(OER) and hydrogen evolution reaction(HER) in zinc-air batteries or water splitting requires elaborate material manufacturing, which is usually complicated and time-consuming.Efficient interface engineering between MXene and highly active electrocatalytic species(CoS_(2)) is, herein, achieved by an in situ hydrothermal growth and facile sulfurization process.The CoS_(2)@MXene electrocatalyst is composed by one-dimensional CoS_(2) nanowires and two-dimensional MXene nanosheets, which lead to a hierarchical structure(large specific surface area and abundant active sites), a spatial electron redistribution(high intrinsic activity), and high anchoring strength(superior performance stability). Therefore, the electrocatalyst achieves enhanced catalytic activity and longtime stability for ORR(a half-wave potential of 0.80 V), OER(an overpotential of 270 mV at 10 mA cm^(-2), i.e., η10= 270 mV)and HER(η10= 175 mV). Furthermore, the asymmetry water splitting system based on the CoS_(2)@MXene composites delivers a low overall voltage of 1.63 V at 10 mA cm^(-2). The solidstate zinc-air batteries using CoS_(2)@MXene as the air cathode display a small charge-discharge voltage gap(0.53 V at1 mA cm^(-2)) and superior stability(60 circles and 20-h continuous test). The energy interconversion between the chemical energy and electricity can be achieved by a self-powered system via integrating the water splitting system and quasisolid-state zinc-air batteries. Supported by in situ Raman analyses, the formation of cobalt oxyhydroxide species provides the active sites for water oxidation. This study paves apromising avenue for the design and application of multifunctional nanocatalysts.