Recent advances and perspectives of zinc metal-free anodes for zinc ion batteries

Zinc-ion batteries(ZIBs) are recognized as potential energy storage devices due to their advantages of low cost, high energy density, and environmental friendliness. However, zinc anodes are subject to unavoidable zinc dendrites, passivation, corrosion, and hydrogen evolution reactions during the charging and discharging of batteries, becoming obstacles to the practical application of ZIBs. Appropriate zinc metal-free anodes provide a higher working potential than metallic zinc anodes, effectively solving the problems of zinc dendrites, hydrogen evolution, and side reactions during the operation of metallic zinc anodes. The improvement in the safety and cycle life of batteries creates conditions for further commercialization of ZIBs. Therefore, this work systematically introduces the research progress of zinc metal-free anodes in “rocking chair” ZIBs. Zinc metal-free anodes are mainly discussed in four categories: transition metal oxides,transition metal sulfides, MXene(two dimensional transition metal carbide) composites, and organic compounds, with discussions on their properties and zinc storage mechanisms. Finally, the outlook for the development of zinc metal-free anodes is proposed. This paper is expected to provide a reference for the further promotion of commercial rechargeable ZIBs.

Recent Advances in Mechanistic Understanding of Metal-Free Carbon Thermocatalysis and Electrocatalysis with Model Molecules

Metal-free carbon,as the most representative heterogeneous metal-free catalysts,have received considerable interests in electro-and thermo-catalytic reac-tions due to their impressive performance and sustainability.Over the past decade,well-designed carbon catalysts with tunable structures and heteroatom groups coupled with various characterization techniques have proposed numerous reaction mechanisms.However,active sites,key intermediate species,precise structure-activity relationships and dynamic evolution processes of carbon catalysts are still rife with controversies due to the monotony and limitation of used experimental methods.In this Review,we sum-marize the extensive efforts on model catalysts since the 2000s,particularly in the past decade,to overcome the influences of material and structure limitations in metal-free carbon catalysis.Using both nanomolecule model and bulk model,the real contribution of each alien species,defect and edge configuration to a series of fundamentally important reactions,such as thermocatalytic reactions,electrocatalytic reactions,were systematically studied.Combined with in situ techniques,isotope labeling and size control,the detailed reaction mechanisms,the precise 2D structure-activity relationships and the rate-determining steps were revealed at a molecular level.Furthermore,the outlook of model carbon catalysis has also been proposed in this work.

C-H-F氛围下金刚石薄膜的低温CVD生长过程分析

基于第一性原理的密度泛函理论对C-H-F氛围下低温CVD金刚石薄膜的生长过程进行仿真分析,计算H、F原子在氢终止金刚石表面发生萃取反应的吸附能、反应热与反应能垒,并分析CF_(3)、CF_(2)、CF 3种生长基团在带有活性位点基底上的吸附。结果表明:与H原子相比,F原子更容易在氢终止金刚石表面萃出H,并以HF形式脱附,且在C-H-F氛围下有利于在低温时产生更多的活性位点;CF_(3)、CF_(2)、CF基团在吸附后的结构和吸附能绝对值都更有利于金刚石相的生成,适当提高CF_(3)、CF_(2)、CF基团的浓度有助于实现金刚石相的更高速率生长。

退火处理对CVD生长石墨烯薄膜功函数的影响

通过退火处理去除了石墨烯薄膜上的吸附气体和杂质,改变了石墨烯表面吸附情况.利用原子力显微镜和开尔文扫描探针显微镜,对退火处理前后的石墨烯薄膜表面进行了原位扫描,分别得到其退火前、后的表面形貌和表面接触电势差图.根据表面接触电势差测量结果进一步计算其功函数,并对退火处理导致的功函数变化机理进行分析.结果表明:退火处理使得石墨烯薄膜与SiO_(2)衬底间的水分子层逸出,从而导致石墨烯薄膜与SiO_(2)衬底间距减小,降低了石墨烯薄膜的P型掺杂水平,使得费米能级上升、石墨烯薄膜功函数减小.

Metal-Free 2D/2D van der Waals Heterojunction Based on Covalent Organic Frameworks for Highly Efficient Solar Energy Catalysis

Covalent organic frameworks(COFs)have emerged as a kind of rising star materials in photocatalysis.However,their photocatalytic activities are restricted by the high photogenerated electron-hole pairs recombination rate.Herein,a novel metal-free 2D/2D van der Waals heterojunction,composed of a two-dimensional(2D)COF with ketoenamine linkage(TpPa-1-COF)and 2D defective hexagonal boron nitride(h-BN),is successfully constructed through in situ solvothermal method.Benefitting from the presence of VDW heterojunction,larger contact area and intimate electronic coupling can be formed between the interface of TpPa-1-COF and defective h-BN,which make contributions to promoting charge car-riers separation.The introduced defects can also endow the h-BN with porous structure,thus providing more reactive sites.Moreover,the TpPa-1-COF will undergo a structural transformation after being integrated with defective h-BN,which can enlarge the gap between the conduction band position of the h-BN and TpPa-1-COF,and suppress electron backflow,corroborated by experimental and density functional theory calculations results.Accordingly,the resulting porous h-BN/TpPa-1-COF metal-free VDW heterojunction displays out-standing solar energy catalytic activity for water splitting without co-catalysts,and the H_(2) evolution rate can reach up to 3.15 mmol g^(−1) h^(−1),which is about 67 times greater than that of pristine TpPa-1-COF,also surpassing that of state-of-the-art metal-free-based photocatalysts reported to date.In particular,it is the first work for constructing COFs-based heterojunctions with the help of h-BN,which may provide new avenue for designing highly efficient metal-free-based photocatalysts for H_(2) evolution.

Mist CVD生长的雾滴迁移与早期沉积研究

第三代半导体材料α-Ga_(2)O_(3)因其超宽带隙(5.3 eV)和超高巴利加优值(6726)在制造高功率器件等电子器件方面更具优势。在α-Ga_(2)O_(3)的诸多生长方法中,Mist CVD简化了前体输运,是亚稳相薄膜较有前景的生长技术。针对早期雾滴分布会制约薄膜质量的问题,使用计算流体力学(CFD)对α-Ga_(2)O_(3)的水平热壁Mist CVD系统进行了多相流反应的瞬态数值仿真研究。基于雾滴迁移与气化模型,研究影响雾滴蒸发时间的因素,解释了雾滴迁移长度对初始外延质量和平均生长速率的作用。在影响α-Ga_(2)O_(3)薄膜生长分布的诸多变量中,对衬底温度、衬底位置及衬底角度等关键参数进行了优化。结果表明,26.5°的衬底角度、距离出口78 cm的衬底位置和550℃的衬底温度具有较好的雾滴迁移分布,是有利于薄膜成核生长的优化条件,为实际生长与制备提供生长参数。

新型CVD金刚石涂层刀具铣削高性能各向同性石墨研究

利用自主研发的新型CVD金刚石复合涂层刀具对自行研制的高密高强各向同性石墨材料进行了铣削加工试验,对比测试了新型CVD金刚石复合涂层刀具与PCD刀具的切削性能。试验结果表明,PCD刀具铣削加工25min其后刀面磨损已超过磨钝标准0.3 mm,新型CVD金刚石复合涂层刀具加工到45 min时,其后刀面磨损量仅为0.25 mm,这说明新型CVD金刚石复合涂层刀具高速铣削石墨时表现出良好的耐磨性和使用寿命,可以适应高性能各向同性石墨的加工需求。铣削加工试验还发现新型CVD金刚石复合涂层刀具加工的石墨表面质量在初期不如PCD刀具,但在更长时间加工情况下,其加工表面质量优于PCD刀具。

一步TCVD法制备大面积碳纳米管冷阴极及其场致发射性能研究

本文提出一步热化学气相沉积法(TCVD)热解二茂铁,并直接在硅衬底上制备大面积(1 cm^(2))、高质量碳纳米管(CNTs)场致发射冷阴极阵列的制备工艺.通过调控二茂铁的热解温度(650~1000℃),获得了最佳的二茂铁的碳转化效率以及高结晶度的碳纳米管阵列.研究了不同热解温度下制备的碳纳米管微观形貌及其对场致发射性能的影响机制.场致发射实验测试表明在热解温度850℃条件下制备的碳纳米管冷阴极其开启电场(10μA/cm^(2))和阈值电场(1 mA/cm^(2))分别为1.32 V/μm和2.64 V/μm,最大电流密度为14.51 mA/cm^(2),对应的场增强因子为13267,表现出良好的场发射性能.本文提出的一步制备碳纳米管冷阴极阵列的制备方法无需任何蚀刻气体或光刻图案工艺,该方法安全、经济、可重复性好,在碳纳米管场发射冷阴极领域具有广阔的应用前景.

氮化硼包覆碳化硅纤维表面CVD法生长碳纳米管研究

目的通过调节化学气相沉积(CVD)的工艺参数,实现碳纳米管(CNTs)在氮化硼(BN)包覆的碳化硅纤维(SiCf)表面的可控生长。方法通过控制单一变量,采用扫描电子显微镜、热重分析、X射线光电子能谱等表征手段,系统地研究了CVD工艺参数和BN表面改性对CNTs形貌、长度、含量的影响。结果通过改变CVD工艺参数,实现了对CNTs形貌、长度、含量的调节与控制,获得了CNTs和BN协同改性的SiC纤维(SiC@BN-CNTs)。其中,SiC@BN-OH在反应温度为700℃、反应时间为20 min等参数下具有最大的CNTs产率(质量分数为10.6%),且形貌良好、含量较高。结论浸渍催化剂和缩短碳源与载体的距离对生长CNTs有积极影响,增加了CNTs的长度和生长密度;通过调节反应温度和时间能够实现对CNTs长度、含量的精确控制,从而获得高质量、高结晶度的CNTs;在反应器中,气体和催化剂的含量相互影响,在制备过程中需要考虑气体和催化剂的比例,按比例同时增加气体和催化剂的流入速率能够获得更好的结果。BN表面羟基化改性处理增强了BN对催化剂的吸附,促进了催化剂颗粒的分散,提高了CNTs的产率。

CVD参数对镀镍碳纤维原位生长CNFs形貌的影响及生长机理分析

碳纤维具有低密度、高模量及高力学强度等优势,是常见的复合材料增强体。通过表面改性的方式,实现碳纤维表面纳米碳材料的有效复合,可获得更优的材料性能。而目前常见的制备方法,可能存在催化剂引入过程损伤纤维、反应时间长等缺点。因此,探索工业化大规模负载纳米尺度碳材料的制备工艺十分必要。采用商用镀镍碳纤维为原料,通过调节化学气相沉积法(CVD)参数,实现不同形貌碳纳米纤维(CNFs)在镀镍碳纤维表面的有效负载,通过SEM、EDS和TEM等表征方式,结合扩散理论和V-S-L模型,分析催化剂厚度对催化剂形态的影响及CVD参数对各形貌产物的影响机理。结果表明,当催化剂层较厚时,催化剂以连续的片状形态存在,主要控制因素为热失配而非表面张力。H_(2)比例较高时,反应以扩散为主导,形貌趋向于催化剂位于中间的粗大CNFs阵列;H2比例较低时,反应以催化为主导,形貌趋向于具有夹层的CNFs团簇。

CVD关键工艺参数对(Ni,Pt)Al涂层高温防护性能影响

采用化学气相沉积(CVD)工艺,在不同沉积温度和沉积真空度下分别在镍基单晶合金上制备了三种(Ni,Pt)Al涂层,研究了CVD关键工艺参数对(Ni,Pt)Al涂层高温防护性能的影响。借助X射线衍射仪(XRD)、扫描电子显微镜(SEM)和能谱仪(EDS)等表征方法系统分析了三种(Ni,Pt)Al涂层的相结构、显微组织和化学成分。结果表明:在同一沉积真空度下随着沉积温度升高,涂层衍射峰向大角度方向偏移;在同一沉积温度下随着沉积压力变大,涂层衍射峰向小角度方向偏移;随着沉积温度和沉积压力的同时提升,涂层表面的晶粒尺度呈现增大趋势,涂层厚度也随之增加;经1100℃/250 h静态氧化和900℃/100 h燃气热腐蚀性能评价后,沉积温度为1080℃且沉积真空度为300 mbar的涂层样品,其氧化动力学增重值均小于其他两种涂层样品,该工艺制备的涂层高温防护性能最佳。控制涂层表面局部位置氧化膜内显微裂纹的过早萌生与滋长行为,以及降低燃气热腐蚀诱发的非稳态氧化膜脱落残留的凹坑数量是改善(Ni,Pt)Al涂层高温抗氧化腐蚀性能的CVD工艺优化方向。

特种气体CVD沉积技术在合成石英制备中的应用与优化

这篇文章深入研究了化学气相沉积工艺在石英制造中的应用,并出了一个解决方案了可能的改进策略。经过精心调控多种化学元素的反应环境,我们最终成功地提升了石英的纯净度和结晶体的优良程度。实验数据揭示,在石英合成过程中,气体成分的比例及反应的温度和压力条件,对于提炼得到的石英材料的微观构造以及性能特点起到了关键性影响。此外,我们分析了化学气相沉积技术在能耗与投入产出比方面的表现情况,目的是评估这一技术在工业生产中的潜在应用价值。经过深度探究,我们最终裁定,特殊气体在化学气相沉积技术中的应用,不仅大幅提升石英的制造质量和效率,也拓展了石英制品的广泛应用范围。

Direct Growth of Graphene on Silicon by Metal-Free Chemical Vapor Deposition

The metal-free synthesis of graphene on singlecrystal silicon substrates, the most common commercial semiconductor, is of paramount significance for many technological applications. In this work, we report the growth of graphene directly on an upside-down placed,single-crystal silicon substrate using metal-free, ambientpressure chemical vapor deposition. By controlling the growth temperature, in-plane propagation, edge-propagation, and core-propagation, the process of graphene growth on silicon can be identified. This process produces atomically flat monolayer or bilayer graphene domains, concave bilayer graphene domains, and bulging few-layer graphene domains. This work would be a significant step toward the synthesis of large-area and layer-controlled, high-quality graphene on single-crystal silicon substrates.

Rational design of carbon-based metal-free catalysts for electrochemical carbon dioxide reduction: A review

Electrochemical CO2 reduction to chemicals or fuels presents one of the most promising strategies for managing the global carbon balance, which yet poses a significant challenge due to lack of efficient and durable electrocatalyst as well as the understanding of the CO2 reduction reaction(CO2RR) mechanism.Benefiting from the large surface area, high electrical conductivity, and tunable structure, carbon-based metal-free materials(CMs) have been extensively studied as cost-effective electrocatalysts for CO2RR.The development of CMs with low cost, high activity and durability for CO2RR has been considered as one of the most active and competitive directions in electrochemistry and material science.In this review article,some up-to-date strategies in improving the CO2RR performance on CMs are summarized.Specifically, the approaches to optimize the adsorption of CO2RR intermediates, such as tuning the physical and electronic structure are introduced, which can enhance the electrocatalytic activity of CMs effectively.Finally, some design strategies are proposed to prepare CMs with high activity and selectivity for CO2RR.

WC-Co硬质合金/CVD金刚石涂层刀具研究现状

化学气相沉积(Chemical vapor deposition,CVD)金刚石涂层刀具具有高硬度、优异的耐磨性、良好的冲击韧性和化学稳定性,能满足高效率、高精度的加工要求,逐渐成为切削铝和高硅铝合金、碳纤维增强复合材料及石墨等轻质量高强度难加工材料的主流涂层刀具。基于WC-Co硬质合金为基体的CVD金刚石涂层刀具在切削加工过程中容易发生CVD金刚石涂层的剥落,自主研发结合性能优良、长时间加工稳定的WC-Co硬质合金/CVD金刚石涂层刀具仍是该领域国内外发展的必然趋势。目前,研究者为了提高WC-Co硬质合金/CVD金刚石涂层刀具的结合性能,采用化学刻蚀法和机械处理法相结合去除WC-Co硬质合金基体表层中的Co粘结相,发现其能增强涂层与基体的结合强度,但基体表层Co粘结相含量的减少容易导致基体中形成脆化层,降低基体的强度和韧性。为了减少基体的强度和韧性损失,研究者在WC-Co硬质合金基体和金刚石涂层之间制备稳定的含Co中间化合物或沉积中间层,成功阻挡Co粘结相的热扩散。除了上述方法外,研究者还通过调控金刚石涂层工艺参数和结构,将微米晶与纳米晶金刚石层叠相结合,来提高金刚石涂层刀具的摩擦学性能和涂层与基体间结合强度。本文综述了WC-Co硬质合金/CVD金刚石涂层刀具的应用进展,明确了WC-Co硬质合金与CVD金刚石涂层间附着失效是刀具切削加工中最主要的失效形式,详细分析了影响附着失效的主要原因。在此基础上,着重介绍了各种优化工艺对增强涂层刀具性能影响的最新研究进展;指出了WC-Co硬质合金/CVD金刚石涂层刀具的性能受化学刻蚀、机械刻蚀、形成含钴化合物层、沉积中间层等基体前处理以及金刚石涂层工艺参数和结构的影响较大,对于不同牌号或不同厂家生产的同种牌号的WC-Co硬质合金基材,需要进行不同的表面前处理,而针对不同的切削加工材料,需要采用合适的金刚石涂层沉积工艺和结构以提高涂层与基材之间的结合强度,进而提高刀具的性能;最后提出了研制一种普适性强的基体前处理、涂层工艺和结构创新策略,以实现不同应用场景下WC-Co硬质合金/CVD金刚石涂层刀具的高效长寿命切削,可能是未来的研究方向。

Surface/interface engineering of high-efficiency noble metal-free electrocatalysts for energy-related electrochemical reactions

To date,much efforts have been devoted to the high-efficiency noble metal-free electrocatalysts for hydrogen-and oxygen-involving energy conversion reactions,due to their abundance,low cost and nultifunctionally.Surface/interface engineering is found to be effective in achieving novel physicochemical properties and synergistic effects in nanomaterials for electrocatalysis.Among various engineering strategies,heteroatom-doping has been regarded as a most promising method to improve the electrocatalytic performance via the regulation of electronic structure of catalysts,and numerous works were reported on the synthesis method and mechanism investigation of heteroatom-doping electrocatalysts,though the heteroatom-doping can only provide limited active sites.Engineering of other defects such as vacancies and edge sites and construction of heterostructure have shown to open up a potential avenue for the development of noble metal-free electrocatalysts.In addition,surface functionalization can attach various molecules onto the surface of materials to easily modify their physical or chemical properties,being as a promising complement or substitute for offering materials with catalytic properties.This paper gives the insights into the diverse strategies of surface/interface engineering of the highefficiency noble metal-free electrocatalysts for energy-related electrochemical reactions.The significant advances are summarized.The unique advantages and mechanisms for specific applications are highlighted.The current challenges and outlook of this growing field are also discussed.

Hexagonal boron nitride:A metal-free catalyst for deep oxidative desulfurization of fuel oils

Oxidative desulfurization(ODS)has been proved to be an efficient strategy for the production of clean fuel oil.Numerous metal-based materials have been employed as excellent ODS catalysts,but being hindered by their high-cost and potential secondary pollution.In this work,we employed graphene analogous hexagonal boron nitride(h-BN)as a metal-free catalyst for ODS with hydrogen peroxide(H2O2)as the oxidant.The h-BN catalyst was characterized and proved to be a few-layered structure with relatively high specific surface areas.The h-BN catalyst showed a 99.4%of sulfur removal in fuel oil under the optimized reaction conditions.Besides,the h-BN can be recycled for 8 times without significant decrease in the catalytic performance.Detailed mechanism analysis found that it is the boron radicals in h-BN activated H2O2 to generate·OH species,which can readily oxidize sulfides to corresponding sulfones for separation.This work would provide another choice in choosing metal-free catalysts for ODS.

Metal-free carbocatalysis for electrochemical oxygen reduction reaction: Activity origin and mechanism

Although scientists have conducted long-term and extensive studies on oxygen reduction reaction(ORR)catalyzed by metal-free carbon materials,they mainly have focused on the preparation and properties of various doped carbon materials.There is still a lack of systematic scientific guidance on the relationship between the surface structure regulation and activity of carbon-based catalysts.In this review,some of electrochemical and computational fundamental concepts about ORR are concisely summarized.The effects of edge defect and nonmetallic doping of carbon materials on ORR behavior and mechanism have been reviewed,and activity origin identification and intermediate conversion mechanism have been discussed.The outlooks for future researches on metal-free ORR electrocatalysis are suggested.

Ten years of carbon-based metal-free electrocatalysts

Since the discovery of the first carbon-based metal-free electrocatalysts(C-MFECs,i.e.,N-doped carbon nanotubes)for the oxygen reduction reaction in 2009,the field of C-MFECs has grown enormously over the last 10 years.C-MFECs,as alternatives to nonprecious transition metals and/or precious noble metal-based electrocatalysts,have been consistently demonstrated as efficient catalysts for oxygen reduction,oxygen evolution,hydrogen evolution,carbon dioxide reduction,nitrogen reduction,and many other(electro-)chemical reactions.Recent research and development of C-MFECs have indicated their potential applications in fuel cells,metal-air batteries,and hydrogen generation through water oxidation as well as electrochemical production of various commodity chemicals,such as ammonia,alcohols,hydrogen peroxide,and other useful hydrocarbons.Further research and development of C-MFECs would surely revolutionize traditional energy conversion and storage technologies with minimal environmental impact.In this short review article,we summarize the journey of C-MFECs over the past 10 years with an emphasis on materials development and their structure-property characterization for applications in fuel cells and metal-air batteries.Current challenges and future prospects of this emerging field are also discussed.

Nanocarbon-based metal-free and non-precious metal bifunctional electrocatalysts for oxygen reduction and oxygen evolution reactions

The oxygen reduction/evolution reactions(ORR/OER) are a key electrode process in the development of electrochemical energy conversion and storage devices,such as metal-air batteries and reversible fuel cells.The search for low-cost high-performance nanocarbon-based metal-free and non-precious metal bifunctional electrocatalysts for ORR/OER alternatives to the widely-used noble metal-based catalysts is a research focus.This review aims to outline the opportunities and available options for these nanocarbon-based bifunctional electrocatalysts.Through discussion of some current scientific issues,we summarize the development and breakthroughs of these electrocatalysts.Then we provide our perspectives on these issues and suggestions for some areas in the further work.We hope that this review can improve the interest in nanocarbon-based metal-free and non-precious metal bifunctional electrocatalysts for ORR/OER.