Nano-porous manganese oxide formed by self-assembled agglomeration of nanocrystallites

We synthesized specific nano-porous dendritic structures similar to cedar leaves of manganese oxides using pulsed laser ablation (PLA) process, with the potential for use as highly active nano-catalysts. The nano-porous structures were formed by self-assembled agglomeration of nanocrystallites without templates. Furthermore, the dendritic nano-porous manganese oxide as an electrocatalyst showed a significant decrease in overpotential on oxygen reduction in alkaline electrolyte.     

Electrochemical codeposition of Pt/graphene catalyst for improved methanol oxidation

Pt/graphene electrocatalyst was uniformly deposited on a glassy carbon substrate using a pulsed galvanostatic electrodeposition method, which facilitated the simultaneous electrochemical reduction of graphene oxide and formation of Pt nanoparticles. Compared to the commercial carbon-supported Pt electrocatalyst, the electrochemically reduced Pt/graphene (Pt/ERG) catalyst exhibited improved electrocatalytic activity for methanol oxidation due to the synergistic effects of an increase in the number of catalytic reaction sites and an enhancement of the charge transfer rate.     

Pt／C气体扩散电极制备方法的探索

Ｐｔ／Ｃ气体扩散电极制备方法的探索马永林（青海教育学院,青海,西宁８１０００８）以Ｐｔ／Ｃ为电催化剂的气体扩散电极的制备方法是直接影响该电极电化学性能的重要因素。一般的制备方法是基于将Ｐｔ／Ｃ电催化剂和聚四氟乙烯以及某些有机物或表面活性剂的糊状物涂布...     

氧还原电化学催化剂研究的最新进展

燃料电池可以在接近室温条件下将氢或烃类中蕴含的巨大化学能通过电化学途径直接转化为清洁、稳定、可持续的电能,因而被视为极有前景的、能够满足日益增长的世界能源需求的终极解决方案之一.在一个典型的氢燃料电池中,氢在正极氧化而氧在负极还原,从动力学角度说,氧还原反应(ORR)比氢氧化反应进行的慢得多.无论是在酸性还是碱性条件下,氧的还原都可以一个四电子过程或是两个双电子过程进行,当然在酸性和碱性环境中反应的机理不同.铂一直是最有效的ORR催化剂,但受到价格昂贵、稳定性差和易中毒等因素的制约,目前非铂催化剂成为越来越引人瞩目的发展方向.本综述试图从分子催化剂、金属纳米材料催化剂、金属氧化物催化剂和新兴的二维材料催化剂等方面,选取近十年来最能代表ORR电化学催化剂方面成就的例子分析其优缺点,并为今后该领域的研究提供一些有益的思路.典型的分子催化剂是卟啉类化合物,当这种四齿的N4配体与过渡金属特别是铁、钴络合时,往往显示出良好的ORR催化性能,多数情况下其中的过渡金属中心、配体和碳支撑体系共同组成催化剂的活性中心.在另一些报道中,邻菲罗啉或是连吡啶型N2化合物也可以作为配体使用.第四和第五副族的很多金属形成的不同价态的氧化物都具有氧还原活性,比如MnOx,CoOx,TiOx,ZrOx,IrOx等.金属氧化物表现出易于修饰,不容易团聚和抗腐蚀等诸多优点,而其良好的ORR性能与表面的缺陷密切相关,因此钙钛矿型氧化物ABOx也引起人们的广泛关注,人们可以通过调节氧化物的晶型、尺寸和组成来获得更好的催化性能.近年来随着液相合成技术的发展,人们可以制备出理想形状和尺寸的单分散纳米粒子,然后通过旋涂、自组装等手段将其修饰到合适的电极上以获得增强性能的ORR催化剂.通过形状与尺寸调控,或组合成其它复杂的纳米结构,都有可能提高催化活性或是稳定性,因此有关纳米催化剂的研究日趋增多.在此基础上,考虑到石墨烯的可修饰性和良好的电化学性能,纳米材料复合石墨烯所形成的二维或三维结构也可提供很好的氧还原催化性能,而MoS2代替石墨烯作为支撑物所构成的二维催化剂也是值得注意的研究方向.综上所述,尽管现有的非铂催化剂仍难以完全满足商业化的要求,设计理念和合成方法的快速发展有望在不远的将来解决这一难题.而设计合成可控尺寸、形状、组成和表面形貌的纳米催化剂在很大程度上将加速这一进程.     

Electrochemical aspects of sol-gel synthesized MgCoO2 for aqueous supercapacitor and alkaline HER electrocatalyst applications

We report here the cost-effective synthesis of Magnesium Cobalt Oxide (MgCoO₂) sample by the sol-gel synthesis route labeled as MCO - 3. In presence of aqueous 1 M Lithium Sulphate (Li₂SO₄) electrolyte, we obtained a capacitance of 56 F/g, an energy density of 38 Wh/kg and a capacitance retention of 92.53 % (at 5 A/g) after undergoing 1000 charge-discharge cycles. For the aqueous 1 M Sodium Perchlorate (NaClO₄) electrolyte system, we found the capacitance, energy density and capacitance retention of 47 F/g, 31 Wh/kg and 91.41% (at 3.5 A/g for 1000 charge-discharge cycles), respectively. These results establish MgCoO₂ as suitable electrode material in aqueous lithium-ion and sodium-ion supercapacitor devices. Further, MCO - 3 in the presence of aqueous 1 M Potassium Hydroxide (KOH) electrolyte showed an overpotential of 400 mV and a Tafel slope of 174 mV/dec, making it a suitable candidate for alkaline Hydrogen Evolution Reaction (HER) electrocatalyst.     

Partially Oxidized Graphene/Metallic Single‐Walled Carbon Nanotubes Film‐Coated Electrode for Nanomolar Detection of Dopamine

Enriched metallic single‐walled carbon nanotubes (mSWCNTs) were dispersed in aqueous solution of partially oxidized graphene (po‐Gr). As‐prepared po‐Gr/mSWCNTs suspension was used to modify glassy carbon electrode (GCE) surface, which showed high electrocatalytic activity for dopamine (DA) oxidation in pH 7.0 phosphate buffered saline (PBS) solution. Using po‐Gr/mSWCNTs/GCE we could detect DA from 350 to 3600 nM, with a detection limit down to 25 nM in physiological condition (in pH 7.0 PBS); whereas, po‐Gr/GCE (without mSWCNTs) and bare GCE produced measurable signals only at or above 200 nM DA. Thus, the po‐Gr/mSWCNTs film we fabricated is a promising nanomaterial for fabrication of biosensors for nanomolar detection of DA.     

Evolution of Vanadium Redox Flow Battery in Electrode

The vanadium redox flow battery (VRFB) is a highly regarded technology for large-scale energy storage due to its outstanding features, such as scalability, efficiency, long lifespan, and site independence. This paper provides a comprehensive analysis of its performance in carbon-based electrodes, along with a comprehensive review of the system‘s principles and mechanisms. It discusses potential applications, recent industrial involvement, and economic factors associated with VRFB technology. The study also covers the latest advancements in VRFB electrodes, including electrode surface modification and electrocatalyst materials, and highlights their effects on the VRFB system‘s performance. Additionally, the potential of two-dimensional material MXene to enhance electrode performance is evaluated, and the author concludes that MXenes offer significant advantages for use in high-power VRFB at a low cost. Finally, the paper reviews the challenges and future development of VRFB technology.     

Effects of sonochemical approach and induced contraction of core–shell bismuth sulfide/graphitic carbon nitride as an efficient electrode materials for electrocatalytic detection of antibiotic drug in foodstuffs

Ultrasonic-enhanced surface-active bismuth trisulfide based core–shell nanomaterials were developed and used as an efficient modified electrode material to construct a highly sensitive antibiotic sensor. The core–shell Bi₂S₃@GCN electrode material was directly synthesized by in-situ growth of GCN on Bi₂S₃ to form core–shell like nanostar (Ti-horn, 30 kHz, and 70 W/cm²). The electrocatalyst of Bi₂S₃@GCN nanocomposites was efficaciously broadened towards electrochemical applications. As synthesized Bi₂S₃@GCN promoted the catalytic ability and electrons of GCN to transfer to Bi₂S₃. The single-crystalline GCN layers were uniformly grown on the surface of the Bi₂S₃ nanostars. Under the optimal conditions of electrochemical analysis, the CPL sensor exhibited responses directly proportional to concentrations (toxic chemical) over a range of 0.02–374.4 μM, with a nanomolar detection limit of 1.2 nM (signal-to-noise ratio S/N = 3). In addition, the modified sensor has exhibited outstanding selectivity under high concentrations of interfering chemicals and biomolecules. The satisfactory CPL recoveries in milk product illustrated the credible real-time application of the proposed Bi₂S₃@GCN sensors for real samples, indicating promising potential in food safety department and control. Additionally, the proposed electrochemical antibiotic sensor exhibited outstanding performance of anti-interfering ability, high stability and reproducibility.     

利用机器学习靶向设计先进电催化剂

随着能源需求增长与化石燃料资源枯竭之间的矛盾日益突出,以及石油、天然气等不可再生资源的燃烧带来的环境问题和全球变暖,清洁可再生能源越来越受到人们的重视.因此,包括能源转换和可逆能源使用等的可持续发展技术受到广泛关注.其中,电催化被认为是清洁能源转化的重要方法.目前,电催化反应的催化剂仍以贵金属为主.但贵金属昂贵的价格极...     

Boosting CO2 Electroreduction to Multi-carbon Products via Oxygen-rich Vacancies and Ce4+−O2−−Cu+ Structure in Cu/CeO2 for Stabilizing Cu+

Cu is a promising electrocatalyst for the CO₂ reduction reaction (CO₂RR) to produce high-value C₂₊ products. Due to the fierce competition of the hydrogen evolution reaction, the slow diffusion of CO₂, and the high energy barrier of the C−C coupling reaction, it is still challenging to achieve high activity and high selectivity to produce multi-carbon products on copper-based electrocatalysts. In this work, we synthesized Cu/CeO₂ catalysts with varying amounts of Cu doping, aiming at effectively converting CO₂ into C₂₊ products through electroreduction. At a copper doping level of 9.77 wt%, the catalyst exhibited a current density of 16.8 mA cm⁻² using a standard H-type cell, achieving a C₂₊ faradaic efficiency (FE) of 78.3 %. Through additional experiments and material characterization, we confirmed that controlling the Cu loading on the surface of CeO₂ is an effective way to regulate the ratio of Cu⁺ to Cu⁰ active sites and the number of oxygen vacancies. Furthermore, the strong electron interaction between Ce⁴⁺−O²⁻−Cu⁺ structure can stabilize Cu⁺ species and enhance the overall stability of the catalyst. This strategy enhances the selectivity towards C₂₊ products and effectively suppresses the competing hydrogen evolution reaction.