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A-π-A type quasi-macromolecular acceptors with molecular conjugation length control strategy for high-performance organic solar cells 采用分子共轭长度控制策略的 A-π-A 型准大分子受体用于高性能有机太阳能电池
IF 11.9 2区 材料科学 Q1 CHEMISTRY, PHYSICAL Pub Date : 2024-10-15 DOI: 10.1039/d4ta05543h
Siqing He, Changhao Xiang, Wei Liu, Songting Liang, Rui Zhang, Weikun Chen, Bin Zhao, Jun Yuan, Yingping Zou
π-linked organic small molecular acceptor materials, (also known as A-π-A quasi-macromolecule (QM) acceptors) have attracted considerable attention in organic solar cells (OSCs) due to their well-defined structures, batch reproducibility, improved morphology, enhanced stability etc. Altering the π bridge unit is a simple yet effective way to modulate molecular configuration and packing motifs, and thus affecting the efficiency of the resulting OSCs. Herein, we synthesized three A-π-A QM acceptors, QM-1T, QM-2T and QM-3T, with different conjugation length of π bridge units (thiophene, bithiophene and terthiophene) and studied exquisitely controlling the molecular size to influence the active-layer morphology and device performance. The theoretical calculations and experimental characterization results show that QM-2T exhibits an increased absorption, upshifted LUMO level and more ordered stacking pattern thanks to the relatively suitable π bridge length. The well-controlled morphology in the blend of PM6:QM-2T also results in the much-improved and balanced electron and hole mobility. Accordingly, QM-2T-based OSC achieves a high open circuit voltage of 0.94 V without sacrificing short circuit current density, resulting for a higher device efficiency of 17.86% than QM-1T and QM-3T. These results highlight the significance of molecular geometric design by featuring conjugated π bridge lengths to achieve high-performance OSCs.
π-连接的有机小分子受体材料(又称 A-π-A 准大分子受体)因其结构明确、批量重现性好、形态改善、稳定性增强等优点,在有机太阳能电池(OSCs)中备受关注。改变π桥单元是调节分子构型和填料图案的一种简单而有效的方法,从而影响所得有机太阳能电池的效率。在此,我们合成了三种具有不同π桥单元(噻吩、双噻吩和三噻吩)共轭长度的A-π-A QM受体QM-1T、QM-2T和QM-3T,并研究了如何精细控制分子尺寸以影响有源层形貌和器件性能。理论计算和实验表征结果表明,由于π桥长度相对合适,QM-2T 表现出更高的吸收率、上移的 LUMO 水平和更有序的堆叠模式。PM6:QM-2T 共混物中良好的形貌也大大提高了电子和空穴迁移率的平衡。因此,与 QM-1T 和 QM-3T 相比,基于 QM-2T 的 OSC 在不牺牲短路电流密度的情况下实现了 0.94 V 的高开路电压,器件效率高达 17.86%。这些结果凸显了通过共轭π桥长度进行分子几何设计以实现高性能 OSC 的重要性。
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引用次数: 0
Borocarbonitride materials as metal-free catalysts for advanced catalysis 用作先进催化技术无金属催化剂的碳氮化硼材料
IF 11.9 2区 材料科学 Q1 CHEMISTRY, PHYSICAL Pub Date : 2024-10-15 DOI: 10.1039/d4ta04797d
Yan Wan, Chen Fang, Xu Yang, Jinli Liu, Yangming Lin
Heterogeneous catalysis has been inseparable from the fields of energy-related conversion and organic synthesis, etc. By virtue of the merits of low cost, earth-abundance, and low toxicity, metal-free catalysts, as alternative to metal-based catalyst, have been paid considerable attention. Amongst them, borocarbonitride materials emerges as an important class of layered metal-free functional material and possess a variety of stoichiometry and crystal structure, exhibiting some unique properties, such as tunable bandgap, good thermal conductivity, large surface area etc. and thereby being used as catalyst in various conversions. In the present review, we begin with an introduction of the structure and theoretical simulation of borocarbonitride materials, followed by a summary of the synthesis methods reported in the last five years. Then, in terms of the specific reactions, the recent representative research progress of borocarbonitride in the fields of thermocatalysis, electrocatalysis, and photocatalysis are discussed in detail. Finally, the challenges confronting in current research are pointed out and the future perspective are offered.
异相催化与能源转化、有机合成等领域密不可分。无金属催化剂具有成本低、地球资源丰富、毒性小等优点,作为金属基催化剂的替代品受到了广泛关注。其中,氮化硼材料是一类重要的层状无金属功能材料,具有多种化学计量和晶体结构,表现出一些独特的性能,如带隙可调、导热性好、比表面积大等,因而被用作各种转化过程中的催化剂。在本综述中,我们首先介绍了氮化硼材料的结构和理论模拟,然后总结了近五年来报道的合成方法。然后,从具体反应的角度,详细讨论了近期氮化硼在热催化、电催化和光催化领域的代表性研究进展。最后,指出了当前研究面临的挑战,并提出了未来展望。
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引用次数: 0
Asymmetric liquid crystalline donors with two different end groups enable efficient all-small-molecule organic solar cells 具有两个不同端基的不对称液晶供体可实现高效的全小分子有机太阳能电池
IF 11.9 2区 材料科学 Q1 CHEMISTRY, PHYSICAL Pub Date : 2024-10-15 DOI: 10.1039/d4ta06126h
Chenhe Wang, Tianyi Chen, Shuixing Li, Yecheng Shen, Jinyang Yu, Adiljan Wupur, Yongmin Luo, Mengting Wang, Xiukun Ye, Jiaying Wu, Minmin Shi, Hongzheng Chen
Asymmetric substitution on donors has been shown to be an effective approach to optimize the morphology and the photovoltaic performance of all-small-molecule organic solar cells (ASM-OSCs), but this strategy is rarely applied in liquid crystalline small molecule donors (SMDs). Herein, one of two rhodanine (R) end groups on the well-known liquid crystalline molecule BTR-Cl is replaced by 2-ethylhexyl cyanoacetate (CA), yielding three new asymmetric SMDs, BT-CAR2, BT-CAR4, and BT-CAR6, whose lengths of alkyl chains on the rhodanine groups are 2, 4, and 6 carbon atoms, respectively. The asymmetric structure enhances intermolecular interactions and three SMDs all exhibit highly ordered edge-on orientations in the solid states. Notably, the BT-CAR4:Y6 film achieves a finely tuned morphology due to the optimal miscibility between BT-CAR4 and Y6. Consequently, all three ASM-OSCs exhibit efficiencies of around 15%, significantly surpassing the previously reported efficiency of the BTR-Cl based counterpart (13.6%). Specifically, the BT-CAR4:Y6 device achieves the highest efficiency of 15.52%. This work presents a promising avenue for designing efficient SMDs for ASM-OSCs.
供体的不对称取代已被证明是优化全小分子有机太阳能电池(ASM-OSCs)形态和光电性能的有效方法,但这种策略很少应用于液晶小分子供体(SMDs)。在这里,著名的液晶分子 BTR-Cl 上的两个罗丹宁(R)端基团之一被氰基乙酸 2-乙基己酯 (CA) 取代,从而产生了三种新的不对称 SMD:BT-CAR2、BT-CAR4 和 BT-CAR6,其罗丹宁基团上的烷基链长度分别为 2、4 和 6 个碳原子。不对称结构增强了分子间的相互作用,三种 SMD 在固态下都表现出高度有序的边缘定向。值得注意的是,BT-CAR4:Y6 薄膜由于 BT-CAR4 和 Y6 之间的最佳混溶性而实现了精细的形态。因此,这三种 ASM-OSC 的效率都达到了 15%左右,大大超过了之前报道的基于 BTR-Cl 的对应效率(13.6%)。具体来说,BT-CAR4:Y6 器件的效率最高,达到 15.52%。这项工作为设计 ASM-OSC 的高效 SMD 提供了一条大有可为的途径。
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引用次数: 0
Regulating NO2 adsorption at ambient temperature by manipulating copper species as binding sites in copper-modified SSZ-13 zeolites 通过操纵铜改性 SSZ-13 沸石中作为结合位点的铜物种来调节常温下的二氧化氮吸附量
IF 11.9 2区 材料科学 Q1 CHEMISTRY, PHYSICAL Pub Date : 2024-10-15 DOI: 10.1039/d4ta04399e
Mingzhe Sun, Tianqi Wang, Calvin Ku, Aamir Hanif, Tian Tian, Bernt Johannessen, Qinfen Gu, Ziyi Li, Patrick H-L Sit, Jin Shang
Atmospheric NO2 pollution poses significant risks to human health and the environment even at low concentrations, necessitating the development of efficient technologies for its removal under ambient conditions. This study developed copper (Cu)-modified SSZ-13 zeolites (referred to as Cun+SSZ-13 where n represents the valence state of Cu) for NO2 removal by adsorption. Cun+SSZ-13 zeolites containing Cu species with different valence states and proportions were prepared by reducing Cu2+-exchanged SSZ-13 zeolite (Cu2+SSZ-13) using H2 at different temperatures. The Cun+SSZ-13 reduced at 190 oC showed the highest NO2 removal capacity (1.79 mmol/g), outperforming prinstine SSZ-13 and Cu2+SSZ-13 by 52.3% and 19.4%, respectively. The improvement was due to the increased amount of adsorption sites (Cu+ and H+) and the stronger affinity of Cu+ than Cu2+ towards NO2, as confirmed by density functional theory (DFT) calculations. The generation of Cu0 nanoparticles and moisture in zeolites during reduction were undesirable for NO2 adsorption. However, this could be eliminated by lowering the reduction temperature and applying a thermal activation, respectively. This work provides systematical methods for designing zeolite adsorbents for ambient NO2 removal and offers insights into the burgeoning filed of air pollution control.
大气中的二氧化氮即使浓度很低,也会对人类健康和环境造成严重危害,因此有必要开发在环境条件下去除二氧化氮的高效技术。本研究开发了铜(Cu)改性 SSZ-13 沸石(简称 Cun+SSZ-13,n 代表 Cu 的价态),用于吸附去除二氧化氮。通过在不同温度下使用 H2 还原 Cu2+ 交换的 SSZ-13 沸石(Cu2+SSZ-13),制备了含有不同价态和比例 Cu 物种的 Cun+SSZ-13 沸石。在 190 oC 下还原的 Cun+SSZ-13 的二氧化氮去除能力最高(1.79 mmol/g),分别比 prinstine SSZ-13 和 Cu2+SSZ-13 高出 52.3% 和 19.4%。密度泛函理论(DFT)计算证实,吸附位点(Cu+ 和 H+)增加以及 Cu+ 对 NO2 的亲和力强于 Cu2+。在还原过程中,沸石中产生的 Cu0 纳米颗粒和水分不利于二氧化氮的吸附。然而,通过降低还原温度和采用热活化技术,可以分别消除这种情况。这项研究为设计用于去除环境中二氧化氮的沸石吸附剂提供了系统的方法,并为正在蓬勃发展的空气污染控制领域提供了启示。
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引用次数: 0
Enhancing the Surface Lewis Basicity of Phosphorene-Hosted NiO Nanosheets for Sensitive and Selective H2S Gas Sensing 增强膦炔基 NiO 纳米片的表面路易斯碱度,实现灵敏和选择性 H2S 气体传感
IF 11.9 2区 材料科学 Q1 CHEMISTRY, PHYSICAL Pub Date : 2024-10-14 DOI: 10.1039/d4ta05682e
Yahui Tian, Wenfang Zhai, Jie Su, Yuxin Zhao, Zhengfei Dai, Wei Gan, Hui Li
The selective detection of toxic gases is crucial for human health and air-quality monitoring, necessitating specialized customizations in the structure of sensing materials. In this study, we have profiled a black phosphorene (BP) hosted NiO nanosheet heterostructure for the sensitive and selective detection of trace H2S gas. Both the theoretical and experimental investigations have indicated the electron transfer from the BP to NiO at the p-p interface, resulting in the electron-rich state of NiO and enhanced surface Lewis basicity. Such a Lewis basic surface would intrinsically empower the acidic H2S adsorption towards the boosted H2S detection. Resultantly, the optimized NiO/BP heterostructure showcases the improved H2S sensing response with 1.9 and 3.5 times higher than those of NiO and BP at 150 °C to 5 ppm H2S. It also illustrates the stable sensing with fast kinetics, low detectable limit (50 ppb), enhanced humid-resistivity, and H2S selectivity. Computational calculations suggest that the NiO/BP structure can realize the chemisorption manner with a negative free energy (-0.82 eV) toward sensitive/selective H2S sensing. This research puts forward the surface acidity/basicity as the criterion in rationalizing the efficient H2S sensor through interface modification.
选择性检测有毒气体对人类健康和空气质量监测至关重要,因此有必要对传感材料的结构进行专门定制。在本研究中,我们研究了一种黑色磷化物(BP)与氧化镍纳米片的异质结构,用于灵敏、选择性地检测痕量 H2S 气体。理论和实验研究都表明,在 p-p 界面上,电子从 BP 转移到 NiO,导致 NiO 处于富电子状态,并增强了表面的路易斯碱性。这种路易斯碱性表面将从本质上增强对酸性 H2S 的吸附,从而提高对 H2S 的检测能力。因此,经过优化的 NiO/BP 异质结构在 150 °C、5 ppm H2S 条件下的 H2S 检测响应分别是 NiO 和 BP 的 1.9 倍和 3.5 倍。它还显示了稳定的传感、快速的动力学、较低的检测限(50 ppb)、增强的耐湿性和 H2S 选择性。计算表明,NiO/BP 结构能以负自由能(-0.82 eV)的化学吸附方式实现灵敏/选择性 H2S 传感。这项研究提出了以表面酸碱性为标准,通过界面改性实现高效 H2S 传感器的合理化。
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引用次数: 0
Towards Advanced Electrochemical Horizon: Ion Selectivity and Energy Harnessing Through Hybrid Capacitive Deionization with Carbon-Coated NaTi2(PO4)3 and N-rich Carbon Nests 迈向先进的电化学地平线:通过碳涂层 NaTi2(PO4)3 和富含 N 的碳巢混合电容式去离子技术实现离子选择性和能量利用
IF 11.9 2区 材料科学 Q1 CHEMISTRY, PHYSICAL Pub Date : 2024-10-14 DOI: 10.1039/d4ta04413d
Hanie Sharifpour, Farzaneh Hekmat, Saeed Shahrokhian, Likun Pan
Two-third coverage of the Earth’s surface, saltwater softening sounds like the most feasible approach to bridging the gap between drinking water generation and its growing demand. Today numerous capacitive devices have been developed for emerging either water softening or charge storage from resource recovery, their dual potent functionality has been rarely investigated. The reinforced selective sodium-removal and charge-storage capacities using a combination between sodium capturing in sorption step and sodium releasing from regeneration step through a CDI process. Leveraging unique and reversible Na+-removal character, sodium superionic conductors (NASICON)-particularly those altered using carbons, emerge as prospective candidates for hybrid capacitive deionization (HCDI). Despite the great desalination ability of HCDIs, the unbalanced ion-capturing and rising possibility of co-ion expulsion has led up to a real bottleneck can significantly tackle with placing an ion exchange membrane (IEM) between the electrolyte and the electrode. Herein, the state-of-the-art Na+ selective technology has been engineered using well-matched carbon-coated NaTi2(PO4)3 (NTP−C) and N-rich carbon nests (NCNs) as negative and positive electrodes, respectively. The performance of the fabricated HCDI benefit from a commendable salt adsorption capacity (SAC) of 96.8 mg g−1, salt adsorption rate (SAR) of 2.42 mg g−1 min−1, specific energy consumption (Es) of 18.5 j mg−1NaCl within sorption step, alongside perfect energy storage capacity (Q) of 46.52 C g−1 in very low concentration of 500 ppm of NaCl in regeneration step. The NTP−C//NCN HCDI systems rendered remarkable cycle stability with almost over 92.3 and 91.3% retention in salt adsorption and charge storage capacities, respectively, after 30 continuous cycles. The Na+ selective remove-capability of the fabricated HCDIs was explored by comparing their Na+ removal capacity in the absence and presence of Mg2+, Ca2+ and K+ ions (S Na+/X > 2.5) which rendered a superior sodium removal efficiency (SRE%) of almost over 50% from both pure and contaminated mixtures. All in all, high-yield energy-efficient HCDI device with remarkable Na+ selectivity was developed, which sound promising for selective ion removal even in the coexistence of background ions. As a direct consequence of high charge storage capacity, the fabricated HCDI deserve credit for energy applications, so inaugurations a pioneer horizon towards the commercialization of HCDI technologies.
盐水软化覆盖了地球表面三分之二的面积,听起来似乎是弥合饮用水生产与日益增长的需求之间差距的最可行方法。目前已开发出许多电容式装置,用于软化水或从资源回收中存储电荷,但很少有人研究它们的双重功效。通过 CDI 工艺,利用吸附步骤中的钠捕获和再生步骤中的钠释放相结合的方法,增强了选择性钠去除和电荷存储能力。钠超离子导体(NASICON)具有独特的可逆钠去除特性,尤其是那些使用碳元素改变的钠超离子导体,因此有望成为混合电容式去离子技术(HCDI)的候选材料。尽管混合电容式去离子技术具有很强的脱盐能力,但其不平衡的离子捕获能力和共离子驱逐可能性的上升导致了一个真正的瓶颈,而在电解质和电极之间放置离子交换膜(IEM)则可以显著解决这一问题。在此,我们采用了最先进的 Na+ 选择性技术,将匹配良好的碳涂层 NaTi2(PO4)3 (NTP-C) 和富含 N 的碳巢 (NCN) 分别作为负极和正极。所制备的 HCDI 性能优异,其盐吸附容量(SAC)为 96.8 mg g-1,盐吸附速率(SAR)为 2.42 mg g-1 min-1,吸附步骤中的比能量消耗(Es)为 18.5 j mg-1NaCl,同时在再生步骤中,在 500 ppm 的极低浓度 NaCl 下具有 46.52 C g-1 的完美储能容量(Q)。NTP-C//NCN HCDI 系统具有显著的循环稳定性,在连续循环 30 次后,盐吸附和电荷存储容量的保持率分别达到 92.3% 和 91.3%。通过比较其在无 Mg2+、Ca2+ 和 K+ 离子(S Na+/X > 2.5)和有 Mg2+、Ca2+ 和 K+ 离子(S Na+/X >2.5)情况下的 Na+ 清除能力,探索了所制造的 HCDI 的 Na+ 选择性清除能力。总之,我们开发出了具有显著 Na+ 选择性的高产能高效 HCDI 设备,即使在背景离子共存的情况下,也有望实现选择性离子去除。高电荷存储容量的直接结果是,所制造的 HCDI 在能源应用方面值得称赞,因此为 HCDI 技术的商业化开创了先河。
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引用次数: 0
Achieved Excellent Low-field Energy Storage Properties and High Density in Bi0.48Na0.48Ba0.04TiO3-based Oxide Ceramics via The Interposing of (Na0.97Bi0.01)+/Ta5+ at A/B Sites 通过在 A/B 位插入 (Na0.97Bi0.01)+/Ta5+ 实现 Bi0.48Na0.48Ba0.04TiO3 基氧化物陶瓷的优异低场储能特性和高密度
IF 11.9 2区 材料科学 Q1 CHEMISTRY, PHYSICAL Pub Date : 2024-10-14 DOI: 10.1039/d4ta06319h
Jiwei Du, Tianhui Shi, Qin Feng, Ronghao Jia, Jianan Hu, Changlai Yuan, Xinpeng Wang, Xiyong Chen, Nengneng Luo, Jiwei Zhai
Lead-free dielectric ceramics are one of the most essential candidates for reforming pulsed power capacitors, nevertheless the formidable hurdles posed by the high hysteresis and low energy storage properties. Dielectric ceramic capacitors with ultra-high energy storage performance usually need to be realized under the condition of high electric field. Its application in miniaturized integrated electronic devices is severely limited. In this work, the A-site deficiency is designed in Na0.97Bi0.01TaO3-modified Bi0.48Na0.48Ba0.04TiO3 lead-free relaxor ferroelectric ceramics to increase oxygen vacancy content, achieve local disorder and construct local multi-phase coexistence. Which causes low hysteresis with excellent high energy density at low electric fields (LEFs). The conclusions indicate that introduction of A-site deficiency would improve the concentration of oxygen vacancy while reconstructing the local structure disorder. Benefiting from the synergistic effect of both, A high energy recoverable density of ~7.98 J cm−3 and an efficiency  of ~83.7% can be measured in 0.84Bi0.48Na0.48Ba0.04TiO3-0.16Na0.97Bi0.01TaO3 modified ceramics under 330 kV cm−1. Furthermore, the modified ceramics have acceptable frequency stability (0.5–130 Hz) and temperature stability (RT–180 °C) with exactly discharge density. This finding develops an innovative strategy for fabricate energy-storage ceramics under low electric field conditions.
无铅介电陶瓷是重整脉冲功率电容器的最重要候选材料之一,但其高滞后性和低储能特性构成了巨大障碍。具有超高储能性能的电介质陶瓷电容器通常需要在高电场条件下才能实现。这严重限制了其在微型集成电子设备中的应用。本研究在 Na0.97Bi0.01TaO3 改性 Bi0.48Na0.48Ba0.04TiO3 无铅弛豫铁电陶瓷中设计了 A 位缺陷,以增加氧空位含量,实现局部无序,构建局部多相共存。这导致了低电场(LEFs)下的低滞后和出色的高能量密度。结论表明,A-位点缺陷的引入会提高氧空位的浓度,同时重建局部结构的无序性。得益于二者的协同效应,在 330 kV cm-1 下,0.84Bi0.48Na0.48Ba0.04TiO3-0.16Na0.97Bi0.01TaO3 修饰陶瓷可测量出 ~7.98 J cm-3 的高能量恢复密度和 ~83.7% 的效率 。此外,改性陶瓷在精确放电密度下具有可接受的频率稳定性(0.5-130 Hz)和温度稳定性(RT-180 °C)。这一发现为在低电场条件下制造储能陶瓷提供了一种创新策略。
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引用次数: 0
Edge sites on platinum electrocatalysts are responsible for discharge in the hydrogen evolution reaction 铂电催化剂上的边缘位在氢气进化反应中起放电作用
IF 11.9 2区 材料科学 Q1 CHEMISTRY, PHYSICAL Pub Date : 2024-10-14 DOI: 10.1039/d4ta04887c
Vipin Adavan Kiliyankil, Wei Mao, Yurie Takahashi, Wei Gong, Shigeru Kabayama, Yuki Hamasaki, Katsuyuki Fukutani, Hiroyuki Matsuzaki, Ichiro Sakata, Kenji Takeuchi, Morinobu Endo, Bunshi Fugetsu
The hydrogen evolution reaction (HER) on platinum electrocatalysts involves the generation of hydrogen atoms and the formation of hydrogen molecules. It is commonly believed that the sites on the surfaces of the terrace (111, 110, and 100) domains are responsible for the formation of hydrogen molecules. However, the electrochemistry of the hydrogen atom generation is not well understood. We created edge-rich platinum electrocatalysts by using nano-fabrics comprising entire single-walled carbon nanotubes (SWCNTs) as templates and supports. We then conducted the HER on the edge-rich platinum/SWCNT hybridized electrocatalysts and gained new insights into the electrochemical properties and functions of the edge sites. We propose that the edge sites are oxidized and serve two important functions: they act as atomic barriers, allowing electrons to accumulate within the terrace (111, 110, and 100) domains, and they transfer the electrons to the hydronium ions in the electrical double layer through discharge. Enhancing the discharge capability of the electrocatalysts is an efficient way to reduce the amount of platinum required, and this can be applied to various precious metal-based electrocatalysts to enhance their electrocatalytic activities and durability.
铂电催化剂上的氢进化反应(HER)涉及氢原子的生成和氢分子的形成。人们普遍认为,台阶(111、110 和 100)表面的位点是形成氢分子的原因。然而,人们对氢原子生成的电化学原理并不十分了解。我们利用由整根单壁碳纳米管(SWCNT)组成的纳米织物作为模板和支撑,制造出了富集边缘的铂电催化剂。然后,我们对富集边缘铂/SWCNT 杂化电催化剂进行了 HER 研究,对边缘位点的电化学性质和功能有了新的认识。我们认为,边缘位点是氧化的,具有两个重要功能:作为原子屏障,允许电子在台阶(111、110 和 100)畴内聚集;通过放电将电子转移到电双层中的氢离子。增强电催化剂的放电能力是减少铂金用量的有效方法,可应用于各种贵金属电催化剂,以提高其电催化活性和耐久性。
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引用次数: 0
Sodium Storage Performance of a High Entropy Sulfide Anode with Reduced Volume Expansion 减少体积膨胀的高熵硫化物阳极的钠储存性能
IF 11.9 2区 材料科学 Q1 CHEMISTRY, PHYSICAL Pub Date : 2024-10-14 DOI: 10.1039/d4ta05122j
Jianping Ma, Jinyi Guo, Weizheng Li, Xiaohan Yang, Chengde Huang
Metal sulfides are prominent candidates for sodium-ion batteries (SIBs) anodes owing to their high theoretical capacities and superior conductivities, but their performance is hindered by volume expansion during cycling. This study introduces an approach for mitigating these issues by incorporating high-entropy structures into sulfides. We synthesized a high-entropy sulfide (HES) (FeCoNiCuZn)In2S4 (MS5) and medium- and low-entropy sulfides for comparison. Physical and chemical characterization confirmed the successful formation of the HES, the uniform distribution of elements and the presence of sulfur vacancies. We show that high-entropy doping shows alleviate volume expansion during cycling and enhance sodium storage capacity, thereby improving electrochemical performance. After 800 cycles at a current density of 1 A g-1, MS5 exhibits a reversible capacity of 412.7 mAh g-1. When the current density is increased to 5 A g-1, it can still stably cycle for 800 cycles with a capacity retention rate of up to 88%. Density functional theory calculations supported the experimental findings, indicating that the introduction of high-entropy structures enhances the structural stability and Na+ migration, and increases the number of reactive sites. This study highlights the potential of HES materials for use in the anode of next-generation SIBs, offering insights into their design and application in improved energy-storage solutions.
金属硫化物因其理论容量高、导电性能优异而成为钠离子电池(SIBs)阳极的主要候选材料,但在循环过程中其性能会受到体积膨胀的影响。本研究介绍了一种通过在硫化物中加入高熵结构来缓解这些问题的方法。我们合成了高熵硫化物 (HES) (FeCoNiCuZn)In2S4 (MS5),并合成了中熵和低熵硫化物进行比较。物理和化学表征证实了高熵硫化物的成功形成、元素的均匀分布以及硫空位的存在。我们的研究表明,高熵掺杂可以缓解循环过程中的体积膨胀,提高钠的存储容量,从而改善电化学性能。在电流密度为 1 A g-1 的条件下循环 800 次后,MS5 显示出 412.7 mAh g-1 的可逆容量。当电流密度增加到 5 A g-1 时,它仍能稳定地循环 800 次,容量保持率高达 88%。密度泛函理论计算支持了实验结果,表明高熵结构的引入增强了结构稳定性和 Na+ 迁移,并增加了反应位点的数量。这项研究凸显了 HES 材料用于下一代 SIB 阳极的潜力,为它们在改进型储能解决方案中的设计和应用提供了启示。
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引用次数: 0
Advances in the application of first principles calculations to phosphate-based NASICON battery materials 将第一性原理计算应用于磷酸盐基 NASICON 电池材料的进展
IF 11.9 2区 材料科学 Q1 CHEMISTRY, PHYSICAL Pub Date : 2024-10-14 DOI: 10.1039/d4ta04943h
Zhongyi Cui, Shilong Sun, Gexuan Ning, Lisi Liang, Zeming Wang, Jiangyu Qiao, Lixing Zhang, Jin Chen, Zhuyue Zhang
Sodium-ion batteries are a promising area of research, and phosphate-based sodium superionic conductor (NASICON) materials have received significant attention from researchers due to their high structural stability and ionic conductivity. First principles calculations have been employed to facilitate the research process. This paper introduces the application of first principles calculations in the study of battery materials. It reviews the research progress of the application of first principles calculations in phosphate-based NASICON structured cathode, anode and electrolyte materials, which mainly include the intrinsic properties of the materials and the study of ionic doping modification of some of the materials. It is demonstrated that NASICON materials exhibit excellent structural stability, an appropriate working voltage (approximately 2–4.2 V for cathode materials and below 2 V for anode materials) and an exceptional sodium ion transport performance (Na+ migration barrier less than 1 eV), which collectively render them highly promising for application. However, the poor electronic conductivity (mostly semiconductor materials, with a band gap of 2–3 eV or so) limits the performance of the material. Ion doping can improve the electronic conductivity of the material to a certain extent, but the NASICON battery materials still cannot be compared with the current commercial lithium-ion battery materials. Consequently, multiple ion doping and conductive material modification will be some of the future research directions. As computers and computing software progress, first principles calculations could eventually become the standard approach for studying battery materials. This strategy might make it more straightforward to select the best battery materials and modification methods while including experimental testing to enhance the phosphate-based NASICON materials' overall performance and develop new battery materials.
钠离子电池是一个前景广阔的研究领域,而基于磷酸盐的钠超离子导体(NASICON)材料因其高度的结构稳定性和离子导电性而受到研究人员的极大关注。第一性原理计算已被用于促进研究进程。本文介绍了第一性原理计算在电池材料研究中的应用。它回顾了第一性原理计算在磷酸盐基 NASICON 结构正极、负极和电解质材料中的应用研究进展,主要包括材料的固有特性和部分材料的离子掺杂改性研究。研究表明,NASICON 材料具有出色的结构稳定性、适当的工作电压(阴极材料约为 2-4.2 V,阳极材料低于 2 V)和优异的钠离子传输性能(Na+ 迁移势垒小于 1 eV),这些优点使其极具应用前景。然而,较差的电子导电性(主要是半导体材料,带隙在 2-3 eV 左右)限制了材料的性能。离子掺杂能在一定程度上改善材料的电子导电性,但 NASICON 电池材料仍无法与目前的商用锂离子电池材料相比。因此,多重离子掺杂和导电材料改性将是未来的研究方向。随着计算机和计算软件的进步,第一原理计算最终可能成为研究电池材料的标准方法。这种策略可以更直接地选择最佳电池材料和改性方法,同时通过实验测试来提高基于磷酸盐的 NASICON 材料的整体性能,并开发新的电池材料。
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Journal of Materials Chemistry A
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