用于Li-CO_(2)电池的阴极催化剂:发展及挑战

在能源危机与温室效应日益加剧的形势下,Li-CO_(2)电池作为一种兼具高效储能与CO_(2)气体利用的新型器件,具有重大的研究意义。鉴于电池涉及多相反应,电子传递与物质转移主要发生于阴极,因此,Li-CO_(2)电池阴极催化剂的设计与制备显得尤为重要。本文探讨了Li-CO_(2)电池作为新型储能器件的优势,基于Li-CO_(2)电池充放电反应机理的发展历程,深入探讨了目前其面临的关键挑战,如充放电电位差较大,容量衰减快和循环稳定性差等问题,将解决方案聚焦于阴极催化剂的研发,提出高效催化剂应该满足的核心条件。总结了近年来碳基非金属,贵金属和过渡金属等传统催化剂在Li-CO_(2)电池领域的应用情况,并深入分析了各类催化剂的优势与不足;本文重点介绍了新兴的单原子催化剂与氧化还原介质研究进展,通过结构表征和理论计算证明其在Li-CO_(2)电池领域展现出卓越的催化性能;本文深入剖析了Li-CO_(2)电池进一步发展所面临的关键问题与严峻挑战,并对单原子催化剂未来的研究方向进行了展望,旨在为推动Li-CO_(2)电池技术的不断进步提供有益的参考与借鉴。

高效Li-CO_(2)电池用富缺陷Co-N-C纳米片电极的制备

采用原位生长-模板保护-裂解组装策略,对双金属类沸石咪唑骨架材料(ZIFs)前驱体进行结构调控,成功制备Co-N_(x)、N-C活性位点及缺陷共存的二维钴-氮-碳纳米片(Co-N-C NFs)催化剂。Co-N-C NFs耦合了内在的Co-N-C的电子结构和外在的富缺陷的二维片层结构,为锂-二氧化碳电池(LCB)提供了有利的气-液-固三相反应界面;纳米薄片彼此交互,构建出有利于CO_(2)吸脱附、锂离子和电子迁移输运路径以及便于产物寄宿的空间结构。基于Co-N-C NFs催化剂正极构筑LCB电池,电池表现出优异的电化学性能,放电容量达到2880μAh/cm^(2),在100μA/cm^(2)的大电流密度下,放-充电平台维持在2.60 V和4.40 V,且能稳定工作超1480 h。

用于Li-CO_(2)电池的过渡金属及其合金催化剂研究进展

【目的】提升锂-二氧化碳(Li-CO_(2))电池的反应可逆性和动力学特性,概括Li-CO_(2)电池的简史、结构、工作原理以及关键科学问题,综述用于Li-CO_(2)电池的过渡金属及其合金催化剂的成分、形貌、微观结构等特性及其对Li-CO_(2)电池性能的影响,分析过渡金属及其合金催化剂在催化过程中的作用机制和演化行为。【研究现状】过渡金属对反应物吸附与活化、放电产物沉积及分解具有促进作用。基于过渡金属元素构筑的单金属和双金属正极催化剂,在Li-CO_(2)电池中的催化活性、作用机制及其自身在催化过程中的演化各不相同。金属间化合物具有显著区别于固溶合金、单分散双金属、单一金属的化学微环境,因此在促进反应物种吸附与活化、产物分解等方面表现出独特优势。【结论与展望】过渡金属及其合金催化剂的未来研究方向有:调控催化剂宏观形貌和表面微结构;监测催化过程中催化剂结构与成分演化、放电产物沉积与分解行为;建立适用于Li-CO_(2)电池的催化剂关键“描述符”;开发低成本催化剂量产工艺。

Sabatier principle guiding the design of cathode catalysts for Li-CO_(2) batteries

The Sabatier principle has been widely used for designing electrocatalysts for energy conversion applications,but it is rarely mentioned in the research of cathode catalyst of Li-CO_(2) batteries.In our work,the"volcanic"relationship between the catalytic activity and the adsorption energy of the catalyst to the intermediates is first demonstrated based on the first-principles calculation,which meets the Sabatier principle and can be used to design the cathode catalysts.The increases in the number of nitrogenvacancy in WN shift the d-band center and increase the interaction with the reactants.The catalytic activity increases first and then decreases with the increase of adsorption energy,which was proved in the experiment.The optimal catalyst for moderate adsorption of intermediate makes the thin LiaCO_(3) distribute evenly.It exhibits a median voltage difference of 0.68 V and an energy efficiency of 84.33%at20μA cm^(-2)with a limited capacity of 200μA h cm^(-2).

Photo‑Energized MoS_(2)/CNT Cathode for High‑Performance Li–CO_(2)Batteries in a Wide‑Temperature Range

Li–CO_(2) batteries are considered promising energy storage systems in extreme environments such as Mars;however,severe performance degradation will occur at a subzero temperature owning to the sluggish reaction kinetics.Herein,a photo-energized strategy adopting sustainable solar energy in wide working temperature range Li–CO_(2) battery was achieved with a binder-free MoS_(2)/carbon nanotube(CNT)photo-electrode as cathode.The unique layered structure and excellent photoelectric properties of MoS_(2) facilitate the abundant generation and rapid transfer of photo-excited carriers,which accelerate the CO_(2) reduction and Li_(2)CO_(3) decomposition upon illumination.The illuminated battery at room temperature exhibited high discharge voltage of 2.95 V and mitigated charge voltage of 3.27 V,attaining superior energy efficiency of 90.2%and excellent cycling stability of over 120 cycles.Even at an extremely low temperature of−30℃,the battery with same electrolyte can still deliver a small polarization of 0.45 V by the photoelectric and photothermal synergistic mechanism of MoS_(2)/CNT cathode.This work demonstrates the promising potential of the photo-energized wide working temperature range Li–CO_(2) battery in addressing the obstacle of charge overpotential and energy efficiency.

基于氮掺杂碳纳米管负载超细Ir纳米颗粒的高性能Li-CO_(2)电池

随着能源需求的增长和环境问题的恶化,寻找一种新的环境友好型的储能转换装置已成必然。Li-CO_(2)电池由于具有能捕获CO_(2)并将其转化为电能的特性,成为了当前的研究热点之一。然而,Li-CO_(2)电池目前还存在过电位高、循环性能差等问题与挑战。因此,本工作首次通过简单的溶剂热法合成了一种超细Ir纳米颗粒并将其均匀负载到氮掺杂碳纳米管上(N-CNTs),作为Li-CO_(2)电池的高效催化阴极。得益于N-CNTs与超细Ir纳米颗粒的协同作用,N-CNTs交联而成的3D多孔道碳骨架结构保证了CO_(2)、离子和电子的传输,并且为放电产物的沉积和分解提供了空间;超细Ir纳米颗粒催化剂的均匀分布提高了催化活性并调节了放电产物的形貌。采用Ir/N-CNTs阴极催化剂提高了Li-CO_(2)电池的库仑效率(72%),延长了电池的循环寿命(160圈/1600 h),降低了过电势(1.2 V)。另外,设计了一个简单的放电产物形核机理示意图以深入探讨充放电过程中Li_(2)CO_(3)的形成与分解。本工作推动了催化剂设计的进一步研究,并为开发高性能Li-CO_(2)电池提供了新的思路。

Copper Indium Sulfide Enables Li-CO_(2)Batteries with Boosted Reaction Kinetics and Cycling Stability

High energy density Li-CO_(2)batteries have attracted much attention owing to the"two birds with one stone"feature in fixing greenhouse gas CO_(2)and providing renewable energy.However,poor reversibility of the discharge product Li_(2)CO_(3)is one of the main problems that limit its application,resulting in poor cycling stability and severe polarization.Herein,copper indium sulfide(CIS),a semiconducting non-precious metal sulfide,is fabricated as cathode catalysts for high-performance Li-CO_(2)batteries.Combined with the synergistic effect of bimetallic valence bonding and coordinated electron transfer,Li-CO_(2)batteries using CIS cathodes exhibit high full specific discharge capacity,excellent rate capability and cycle stability,namely it delivers a high specific full discharge capacity of 8878μAh cm^(-2),runs steadily from 10 to 100μA cm^(-2),and performs a stable long-term cycling behavior(>1050 h)under a high energy efficiency of 84%and a low charge voltage of approximately 3.4 V at 20μA cm^(-2)within 100μAh cm^(-2).In addition,a flexible Li-CO_(2)pouch cell is constructed to reveal the potential of employing CIS to fabricate flexible high energy storage devices in practical applications.This work shows a promising development pathway toward next-generation sustainable energy storage devices.

Regulating the nucleation of Li_(2)CO_(3) and C by anchoring Li-containing carbonaceous species towards high performance Li-CO_(2) batteries

Li-CO_(2) batteries provide an attractive and potential strategy for CO_(2) utilization as well as energy conversion and storage with high specific energy densities.However,the poor reversibility caused by the decomposition obstacles of Li_(2)CO_(3) and C products is still a challenge for Li-CO_(2) batteries,which seriously influences its electrochemical performances.Herein,a free-standing MnOOH arrays cathode has been prepared and employed in Li-CO_(2) battery,which realizes a great improvement of electrochemical performances by adjusting the discharge products distribution.Experiments coupled with theoretical calculations verifies that the formation of Li-containing carbonaceous species(LiCO_(2),LiCO and Li_(2) CO_(3))bonded with MnOOH through Li ion regulates the nucleation behavior of Li_(2)CO_(3) and C,making them grown on MnOOH uniformly.The fine Li_(2) CO_(3) grains(with a size about 5 nm)embedded into carbon matrix greatly enlarges the contact interface between them,facilitating the transmission of electrons through the discharge products and finally improves CO_(2) evolution activity.This ingenious design strategy of regulating discharge products distribution to improve electrochemical performances provides a promising way to develop advanced Li-CO_(2) batteries.

Li-CO_(2)电池碳基阴极研究进展

可充电Li-CO_(2)电池为碳捕获和储能提供了一种非常有前景的新途径。Li-CO_(2)电池通过Li阳极失去电子形成的Li+与CO_(2)、电子结合生成Li_(2)CO_(3)和C,从而实现碳捕获和能量释放。阴极催化剂对Li-CO_(2)电池至关重要,而碳基催化剂因其来源广泛、经济性好等原因成为了研究的热点。简要叙述了Li-CO_(2)电池的充放电机理和发展简史,归纳了Li-CO_(2)电池碳基阴极材料的研究进展,重点介绍了碳基材料及其改性对Li-CO_(2)电池性能的提升情况,并总结了Li-CO_(2)电池未来发展面临的挑战与问题。由于Li-CO_(2)电池在放电过程中形成的绝缘Li_(2)CO_(3)在充电过程中难以分解,容易产生积聚,最终导致电池性能快速衰减,探索具有独特结构和高催化活性的高效阴极催化剂以促进CO_(2)与Li反应以及Li-CO_(2)电池的充放电机理将成为未来研究的重点和难点。

富镍LiNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)正极材料改性研究进展

锂离子电池用富镍正极材料LiNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)具有高能量密度、高安全性等优点。受容量衰减、循环寿命和热稳定性等方面的限制,该材料进一步的改性成为当前研究的热点。针对LiNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)材料的改性研究主要集中在离子掺杂、表面包覆和结构设计等方面。离子掺杂能改善结构稳定性和电化学性能,特别是过渡金属离子的掺杂有助于延长循环寿命和提高结构稳定性;表面包覆改性可增强电化学稳定性和抗氧化性能,延长循环寿命和提高抗极化能力;结构设计可优化晶体结构、提高传导性能和缓解应力,提高循环稳定性、容量保持率和功率密度。

Li-CO_(2)电池金属基催化剂的研究进展

对Li-CO_(2)电池金属基催化剂进行文献综述,阐明目前贵金属基催化剂具有催化活性最高,但价格昂贵、储量较少等特点;过渡金属基催化剂具有价格相对便宜,但催化活性较低等特点。总结了不同金属基催化剂在Li-CO_(2)电池中的作用及其对电池性能的贡献,提出目前可通过结构设计和多元催化剂协同等手段提高催化剂的催化活性。

In situ observation of the electrochemical behavior of Li–CO_(2)/O_(2)batteries in an environmental transmission electron microscope

Li–CO_(2)/O_(2)batteries,a promising energy storage technology,not only provide ultrahigh discharge capacity but also capture CO_(2)and turn it into renewable energy.Their electrochemical reaction pathways'ambiguity,however,creates a hurdle for their practical application.This study used copper selenide(CuSe)nanosheets as the air cathode medium in an environmental transmission electron microscope to in situ study Li–CO_(2)/O_(2)(mix CO_(2)as well as O_(2)at a volume ratio of 1:1)and Li–O_(2)batteries as well as Li–CO_(2)batteries.Primary discharge reactions take place successively in the Li–CO_(2)/O_(2)–CuSe nanobattery:(I)4Li^(+)+O_(2)+4e^(−)→2Li_(2)O;(II)Li_(2)O+CO_(2)→Li_(2)CO_(3).The charge reaction proceeded via(III)2Li_(2)CO_(3)→4Li^(+)+2CO_(2)+O_(2)+4e^(−).However,Li–O_(2)and Li–CO_(2)nanobatteries showed poor cycling stability,suggesting the difficulty in the direct decomposition of the discharge product.The fluctuations of the Li–CO_(2)/O_(2)battery's electrochemistry were also shown to depend heavily on O_(2).The CuSe‐based Li–CO_(2)/O_(2)battery showed exceptional electrochemical performance.The Li^–CO_(2)/O_(2)battery offered a discharge capacity apex of 15,492 mAh g^(−1) and stable cycling 60 times at 100 mA g^(−1).Our research offers crucial insight into the electrochemical behavior of Li–CO_(2)/O_(2),Li–O_(2),and Li–CO_(2)nanobatteries,which may help the creation of high‐performance Li–CO_(2)/O_(2)batteries for energy storage applications.

Li(Ni_(x)Co_(y)Mn_(z))O_(2)正极材料对溶胶-凝胶法制备KAlSi_(2)O_(6)的侵蚀研究

将不加和添加CaF_(2)的KAlSi_(2)O_(6)(KAS_(4))溶胶于800~1300℃煅烧得到的KAS_(4)以及原料CaF_(2)粉,分别与Li(Ni_(x)Co_(y)Mn_(z))O_(2)(LNCM)按照质量比70∶30混合均匀,然后在1100℃保温6 h进行侵蚀试验。对比分析了不加和添加CaF_(2)的KAS_(4)的物相组成以及侵蚀试验后几种材料的物相组成和显微结构。结果表明:1)添加1.88%(w)CaF_(2)可以使KAS_(4)纯相的生成温度下降约100℃;2)不加CaF_(2)的KAS_(4)比添加CaF_(2)的具有更好的抗LNCM侵蚀性能;3)CaF_(2)与LNCM在高温下容易发生反应。

锂离子电池正极材料LiCoO_(2)的性能优化研究

以锂过渡金属层状氧化物LiCoO_(2)为研究体系,通过体相掺杂的方法对其进行改性,主要研究了Al掺杂对LiCoO_(2)体系材料结构性能的影响。采用高温固相法合成Li(Co_(1-z)Al_(z))O_(2),对样品XRD图谱与标准PDF卡片进行对比分析,研究了不同的铝掺杂对合成样品结构(杂相)的影响,计算了晶粒大小和晶格参数,并得出最佳掺杂量为0.002 mol/L。

LiNi_(x)Co_(y)Al_(z)O_(2)锂离子电池SOC估算及衰减特性

以LiNi_(x)Co_(y)Al_(z)O_(2)(NCA)体系锂离子电池为研究对象,建立具有多工况下普适性的开路电压(OCV)-荷电状态(SOC)曲线,估算电池在不同工况下的SOC。研究电池在变工况(1.00 C倍率循环、1.50 C转1.00 C倍率循环、2.00 C转1.00 C倍率循环等)下,正极活性材料容量(Qp)、负极活性材料容量(Qn)及活性锂容量(QLi)的变化趋势。在变工况条件下,相同低倍率工况(1.00 C倍率)的Qn和QLi衰减趋势相对一致。

Mg^(2+)掺杂对富锂锰基正极材料性能影响

富锂锰基正极材料Li[Li_(0.2)Ni_(0.13)Co_(0.13)Mn_(0.54)]O_2通过采用高温固相合成法制备,通过X射线衍射、扫描电镜、激光粒度分析、充放电测试、循环伏安和交流阻抗分析该合成材料的晶体结构、形貌特征、粒径大小和电化学性能。经过Mg^(2+)掺杂改性后的富锂锰基正极材料晶体结构更稳定、颗粒表面更光滑和电化学性能更好,其中Li[Li_(0.2)Ni_(0.13)Co_(0.13)Mn_(0.54)]_(1-x)Mg_xO_2(x=0.07)的结晶程度较高,充放电比容量更高,循环稳定性更好。随着Mg^(2+)掺杂量的增加,Rs电阻值逐渐减小,说明掺杂Mg^(2+)后材料Li[Li_(0.2)Ni_(0.13)Co_(0.13)Mn_(0.54)]O_2表现出降低其交流阻抗的能力,促进电路中电荷的移动使得充放电比容量增大,导电性能更强。

石墨烯的制备及其复合导电浆料对LiNi_(0.5)Co_(0.2)Mn_(0.3)O_(2)锂离子电池性能的影响

通过化学氧化⁃热还原法制备了高柔韧性、片层少的石墨烯粉体,将其与碳纳米管、炭黑制备出石墨烯复合导电浆料,并分析对比了不同片径的石墨烯复合导电浆料和常规复合导电浆料对LiNi_(0.5)Co_(0.2)Mn_(0.3)O_(2)锂离子电池性能的影响。结果表明,石墨烯含有丰富的含氧官能团,复配后的石墨烯复合导电浆料在正极材料LiNi_(0.5)Co_(0.2)Mn_(0.3)O_(2)中可以构建高效的点⁃线⁃面结构的三维空间导电网络,其中,D_(50)片径为11.581μm的石墨烯复合导电浆料电化学性能较为优异,在8C(20 A)大倍率放电条件下容量保持率为104.45%,1C/8C倍率循环200周后电池仍有2121 mAh的容量,容量保持率为87.90%。

MgF_(2)包覆对锂离子电池正极材料LiNi_(0.4)Co_(0.2)Mn_(0.4)O_(2)的性能影响

通过流变相法合成LiNi_(0.4)Co_(0.2)Mn_(0.4)O_(2)材料,用MgF_(2)包覆对其进行表面修饰改性,来改善高温、高倍率下的循环稳定性。利用X射线衍射仪、扫描电子显微镜和充放电测试技术研究MgF_(2)包覆对正极材料的晶体结构、微观形貌和电化学性能的影响。电化学性能测试结果表明,当MgF_(2)的包覆量为1%时,材料的充放电性能和循环性能最好,初始放电比容量为176.2mAh/g;50次循环后,放电比容量仅降到162.9mAh/g,容量保持率最高,为92.4%,表现出良好的电化学稳定性。这些结果表明,通过对LiNi_(0.4)Co_(0.2)Mn_(0.4)O_(2)表面进行MgF_(2)包覆处理,可以提高材料的电子导电率,减少电极材料与电解液的副反应。MgF_(2)包覆改性使三元正极材料的电化学性能有一定程度的提高。

掺杂改性锂基材料吸附CO_(2)的研究进展

锂基吸附剂因稳定性强、理论吸附量大、吸附温度较高等优点,成为近年来捕获烟道气中CO_(2)的研究热点。主要论述了熔融盐掺杂、金属阳离子掺杂和其他元素掺杂的锂基材料对CO_(2)的捕获效果,并比较了它们的相关性能,对开发锂基吸附材料的研究和发展方向进行了展望。

陶瓷隔膜对LiNi_(0.8)Co_(0.15)Al_(0.05)O_(2)/C电池性能的影响

以聚丙烯(PP)/聚乙烯(PE)/PP复合隔膜为基膜,研究单面涂覆陶瓷层(12μm干法基膜+4μm单面陶瓷层)和双面涂覆陶瓷层(12μm干法基膜+2μm双面陶瓷层)制作的陶瓷隔膜对LiNi_(0.8)Co_(0.15)Al_(0.05)O_(2)/C体系锂离子电池性能的影响。用SEM、电化学阻抗谱(EIS)测试分析隔膜的微孔形貌、透气度和离子电导率。复合隔膜、单面涂覆和双面涂覆隔膜的透气度分别为501 s/100 ml、220 s/100 ml和175 s/100 ml;离子电导率分别为0.115 mS/cm^(2)、0.312 mS/cm^(2)和0.385 mS/cm^(2)。用3种隔膜制作锂离子电池,评估内阻、倍率性能、循环性能及贮存性能。涂覆陶瓷隔膜具有更高的吸液率、更低的内阻和更高的离子电导率,因此电池具有更好的倍率性能和循环性能,且双面涂覆陶瓷隔膜的性能更佳。