二硫化钼纳米片/碳纳米纤维杂化材料的制备及其析氢性能

以碳纳米纤维(CNFs)作为负载基体和反应器采用静电纺丝技术和碳化工艺生长和调控二硫化钼(MoS_2)纳米片。通过改变前驱体溶液浓度来调控纳米片的形貌和结构,利用MoS_2纳米片的高催化活性和CNFs高比表面积、良好的稳定性以及高电导率的协同作用,研究不同形貌和结构的杂化纳米材料在电催化析氢方面的应用,探索杂化材料形貌与性能之间的潜在规律。运用多种分析测试技术对制备得到的纳米杂化材料进行表征,并对所制备的MoS_2/CNFs杂化材料的电催化析氢性能(HER)进行研究,研究表明近似皮芯结构的MoS_2/CNFs-10杂化材料的电催化析氢性能最好,初始析氢过电位在220 mV,Tafel斜率为110m V·dec~(-1)。     

纳米多孔Ni、Ni3S2/Ni复合电极的制备及其电催化析氢性能

采用脱合金化和水热合成的方法制备纳米多孔Ni和纳米多孔Ni₃S₂/Ni复合电极。通过N₂吸附-脱附测试、XRD、SEM、TEM等方法表征电极的孔径分布、物相和微观结构。在1 mol·L^-1的NaOH溶液中,运用线性扫描伏安（LSV）曲线、交流阻抗（EIS）谱图、恒电流电解法等测试电极的电催化析氢性能。结果表明：在电流密度为50 mA·cm^-2时,与纳米多孔Ni相比,Ni₃S₂/Ni合金具有更低的析氢过电位以及更高的析氢活性,同时纳米多孔Ni₃S₂/Ni复合电极具有更低表观活化能和电子转移阻抗,进一步明确了过渡金属硫化物对电催化析氢性能的特殊贡献。     

钴铁双金属氧化物多孔纳米棒的制备及其电解水析氧性能

通过简单的钴铁前躯体热分解法制备了系列一维Co_1-xFe_xO_y（0≤x≤1）多孔纳米材料,并在1 mol·L^-1 KOH溶液中研究了其电解水析氧催化性能。研究发现不同Fe掺杂量对材料的结构与电解水析氧催化性能有较大的影响,其中16%（n/n）Fe掺杂量的Co_1-xFe_xO_y具有最优的析氧催化性能。在10 mA·cm^-2电流密度下其析氧过电位为345 mV,塔菲尔斜率为54 mV·dec^-1,并表现出优异的析氧稳定性能。廉价、高效的Co_1-xFe_xO_y多孔纳米棒材料有望成为优良的析氧催化剂用于电解水制氢。     

磷掺杂缺陷WS2纳米片诱导的高效析氢性能

通过超声剥离法制备二硫化钨(WS₂)纳米片,将纳米片和红磷(P)混合,用氩气(Ar)等离子体对混合物进行处理,制备了P掺杂缺陷WS₂纳米片。对制备的材料进行电催化析氢反应(hydrogen evolution reaction,HER)测试,结果表明P掺杂的缺陷WS₂纳米片相对于缺陷WS₂纳米片和WS₂纳米片表现出优越的HER催化活性(较小的过电位和Tafel斜率、优异的稳定性)。密度泛函理论计算结果表明,在WS₂结构中P原子和缺陷结构改善了其电子结构,使其具有更加合适的H⁺吸附能垒和H₂生成动力学性能,从而提高催化活性。     

磷掺杂缺陷WS2纳米片诱导的高效析氢性能

通过超声剥离法制备二硫化钨(WS₂)纳米片,将纳米片和红磷(P)混合,用氩气(Ar)等离子体对混合物进行处理,制备了P掺杂缺陷WS₂纳米片。对制备的材料进行电催化析氢(hydrogen evolution reaction,HER)测试,结果表明P掺杂的缺陷WS₂纳米片相对于缺陷WS₂纳米片和WS₂纳米片表现出优越的HER催化活性(较小的过电位和Tafel斜率,优异的稳定性)。密度泛函理论计算结果表明,在WS₂结构中P原子和缺陷结构改善了其电子结构,使其具有更加合适的H⁺吸附能垒和H₂生成动力学性能,从而提高催化活性。     

脊椎状NiCo2O4纳米棒的制备及其析氧和氧还原性能研究

以水热法并进一步焙烧合成脊椎状NiCo₂O₄纳米棒,通过透射电子显微镜（TEM）、X射线衍射仪（XRD）、X射线光电子能谱仪（XPS）和热重分析仪（TG）等来表征其结构形态及热稳定性.采用线性扫描法（LSV）、循环伏安（CV）研究所制备催化剂的在玻碳和旋转圆盘电极上的电催化活性：在0.1 mol·L^-1 KOH溶液中的电催化析氧反应（OER）和电催化氧还原反应（ORR）.研究结果表明,所制备的脊椎状NiCo₂O₄纳米棒有大量的不饱和态,200℃焙烧制备的脊椎状NiCo₂O₄纳米棒析氧过电位最小可达309 mV,Tafel斜率145.6 mV/dec,其氧还原极限电流密度在1600 rmp可达到5.095 mA·cm^-2,电子转移数在3.2~3.8之间,接近四电子转移机理,其优良电化学性能可能是由于暴露了更多的边缘缺陷的缘故.     

双金属离子调控型镍钴氧化物纳米片用于非对称超级电容器

通过水热-煅烧两步法制备了系列镍钴氧化物（NCO）纳米片。通过改变前驱体溶液中的镍、钴离子物质的量之比,进而调控NCO纳米片中的过渡金属离子比例。NCO纳米片的晶相、形貌和结构利用X射线衍射、扫描电子显微镜和X射线光电子能谱表征。此外,对NCO纳米片的电化学性能进行测试。结果表明,NCO-2（Ni_1.95Co₁O_x）纳米片在0.5 A·g^-1电流密度下,比电容为1 096.88 F·g^-1,且经过5 000次循环后具有78.26%的循环稳定性。以NCO-2为正极、活性碳为负极构成的非对称超级电容器,在功率密度为576 W·kg^-1时,能量密度为57.70 Wh·kg^-1。     

微波原位合成Ag NPs/MoS2复合材料及其电化学性能

二硫化钼纳米片（MoS₂）受到带电杂质、结构缺陷和易聚集等因素的影响，导致其电子转移性能下降，使其应用受限。将银纳米颗粒（Ag NPs）与少层MoS₂纳米片复合，可提升MoS₂纳米片的电化学性能。本研究创新性地采用微波还原法，使Ag NPs原位沉积于MoS₂，得到Ag NPs/MoS₂复合材料。结果表明，将Ag NPs/MoS₂复合材料修饰于丝网印刷电极（screen printed elec-trodes，SPE）后，测得的循环伏安（cyclic voltammetry，CV）曲线峰电流值为同浓度单一MoS₂修饰电极的1.8倍，方波伏安（square wave voltammetry，SWV）曲线峰电流值为单一MoS₂修饰电极的3.4倍，电化学阻抗谱（electrochemical impedance spectroscopy，EIS）的电子转移阻抗值（R_et）仅为167 Ω，相比MoS₂/SPE的R_et （320 Ω）显著减小，说明Ag NPs与MoS₂复合可显著增强单一MoS₂的电化学性能。此外，还推测了高导电性Ag NPs/MoS₂复合材料的导电机理。最后，基于Ag NPs/MoS₂复合材料构建了电化学传感器并对前列腺特异性抗原（PSA）进行检测。结果表明，该传感器针对PSA的检测限为0.009 ng·mL^-1，线性检测范围为0.1~1 000 ng·mL^-1，灵敏度为0.011 μA·mL·ng^-1。     

MoS2/CNFs对电极膜厚对染料敏化太阳能电池性能影响

通过静电纺丝技术和水热法成功获得了碳纳米纤维负载二维层状硫化钼（MoS₂/CNFs）,将其作为对电极组装的染料敏化太阳能电池（DSSCs）表现出优异的电化学特性。在DSSCs制备过程中,对电极膜厚对电池性能有很大影响,所以本文重点探究了喷涂法制备的对电极膜厚对其组装的染料敏化电池光电性能影响,获得最佳对电极膜厚。实验结果表明当MoS₂/CNFs复合对电极材料膜厚为8 μm时,电池光电转换效率达到最大值7.78%。     

Ag3PO4/MoS2纳米片复合催化剂制备及可见光催化性能

采用机械球磨法成功制备Ag₃PO₄/MoS₂纳米片复合催化剂。运用X射线衍射仪（XRD）、透射电子显微镜（TEM）、扫描电子显微镜（SEM）、紫外可见漫反射光谱（UV-Vis）和荧光发射光谱（PL）对复合催化剂的结构和形貌进行了表征。结果表明,Ag₃PO₄纳米粒子均匀地附着在MoS₂纳米片层结构上,两者形成紧密结合。以亚甲基蓝为模拟污染物,研究复合催化剂在可见光照射下的光催化特性;通过循环实验考察复合催化剂的稳定性。结果显示,含有1%的MoS₂纳米片与Ag₃PO₄形成的复合催化剂在30 min内对亚甲基蓝的降解率为95%,其降解动力学常数是纯相Ag₃PO₄的2倍。经过5次循环实验后复合催化剂对于亚甲基蓝的降解率为84%,而纯Ag₃PO₄对于亚甲基蓝的降解率仅为35%。Ag₃PO₄/MoS₂纳米片复合催化剂具有优良的光催化活性和高稳定性,主要归因于二硫化钼纳米片与磷酸银形成异质结,磷酸银激发的电子和二硫化钼纳米片产生的空穴直接复合,从而促使光生电子从磷酸银晶体表面快速分离,减轻了磷酸银的光电子腐蚀,同时也提高了复合物的光催化活性。     

Bifunctional Electrocatalyst with 0D/2D Heterostructure for Highly Efficient Hydrogen and Oxygen Generation

A novel MoS₂ quantum dots/CoSe₂ nanosheet (MoS₂ QDs/CoSe₂) hybrid with 0D/2D heterostructure has been developed. The CoSe₂ nanosheets (NSs) enable an excellent oxygen evolution reaction (OER) activity with increasing vacancy configuration on one hand, while the MoS₂ QDs serve as an eminent hydrogen evolution reaction (HER) catalyst on the other. By integrating MoS₂ QDs and CoSe₂ NSs, the hybrid exhibits excellent electrocatalytic performances in HER and OER. The unique 0D/2D hetero‐interface increases the exposed active sites and facilitates electron transfer, thereby boosting the electrocatalytic activity. Relatively low overpotentials of 82 mV and 280 mV are required to drive the current density of 10 mA/cm² for HER and OER, with corresponding Tafel slopes of 69 and 75 mV/dec, respectively. As such, this work provides an efficient yet simple approach to construct bifunctional electrocatalysts with enhanced activity and stability.     

Ultrathin MoS2 Nanosheets Supported on N‐doped Carbon Nanoboxes with Enhanced Lithium Storage and Electrocatalytic Properties

Molybdenum disulfide (MoS₂) has received considerable interest for electrochemical energy storage and conversion. In this work, we have designed and synthesized a unique hybrid hollow structure by growing ultrathin MoS₂ nanosheets on N‐doped carbon shells (denoted as C@MoS₂ nanoboxes). The N‐doped carbon shells can greatly improve the conductivity of the hybrid structure and effectively prevent the aggregation of MoS₂ nanosheets. The ultrathin MoS₂ nanosheets could provide more active sites for electrochemical reactions. When evaluated as an anode material for lithium‐ion batteries, these C@MoS₂ nanoboxes show high specific capacity of around 1000 mAh g^?1, excellent cycling stability up to 200 cycles, and superior rate performance. Moreover, they also show enhanced electrocatalytic activity for the electrochemical hydrogen evolution.     

Electrochemically exfoliated Ni-doped MoS2 nanosheets for highly efficient hydrogen evolution and Zn-H2O battery

Thanks to tunable physical and chemical properties, two-dimensional (2D) materials have received intensive interest, endowing their excellent electrocatalytic performances for applications in energy conversion. However, their catalytic activities are largely determined by poor adsorption energy and limited active edge sites. Herein, a one-step electrochemical exfoliation strategy was developed to fabricate 2D Ni-doped MoS₂ nanosheets (Ni-EX-MoS₂) with a lateral size of ～500 nm and thickness of ～3.5 nm. Profiting from high electrical conductivity and abundant exposing active sites, Ni-EX-MoS₂ catalyst displayed an admirable performance for electrochemical hydrogen evolution reaction (HER) with a low overpotential of 145 mV at 10 mA/cm² as well as a small Tafel slope of 89 mV/dec in alkaline media, which are superior to those of the most reported MoS₂-based electrocatalysts. The formed Ni species with tuning electronic structure played a crucial role as primary active center of Ni-EX-MoS₂, as well as the forming stable 1T/2H phase MoS₂ interface demonstrated a synergistic effect on electrocatalytic HER performance. Further, Ni-EX-MoS₂ was employed as a cathode electrode for alkaline Zn-H₂O battery, which displayed a high power density of 3.3 mW/cm² with excellent stability. This work will provide a simple and effective guideline for design of electrochemically exfoliated transition metal-doped MoS₂ nanosheets to inspire their practical applications in energy catalytic and storage.     

Heterostructures of NiFe LDH hierarchically assembled on MoS2 nanosheets as high-efficiency electrocatalysts for overall water splitting

Typically, rational interfacial engineering can effectively modify the adsorption energy of active hydrogen molecules to improve water splitting efficiency. NiFe layered double hydroxide (NiFe LDH) composite, an efficient oxygen evolution reaction (OER) catalyst, suffers from slow hydrogen evolution reaction (HER) kinetics, restricting its application for overall water splitting. Herein, we construct the hierarchical MoS₂/NiFe LDH nanosheets with a heterogeneous interface used for HER and OER. Benefiting the hierarchical heterogeneous interface optimized hydrogen Gibbs free energy, tens of exposed active sites, rapid mass- and charge-transfer processes, the MoS₂/NiFe LDH displays a highly efficient synergistic electrocatalytic effect. The MoS₂/NiFe LDH electrode in 1 mol/L KOH exhibits excellent HER activity, only 98 mV overpotential at 10 mA/cm². Significantly, when it assembled as anode and cathode for overall water splitting, only 1.61 V cell voltage was required to achieve 10 mA/cm² with excellent durability (50 h).     

Nanostructured MoS2 Nanorose/Graphene Nanoplatelet Hybrids for Electrocatalysis

Tailoring and enhancing electrocatalytic activity is of the utmost importance from the viewpoints of sustainable energy and sensing. MoS₂ and graphene show great promise for the electrocatalysis of many reactions. Given that both graphene and MoS₂ are highly anisotropic in nature, with edge planes that are several orders of magnitude more catalytically active than basal planes, a new hybrid material with maximized edge‐plane density to provide efficient electron transfer, high catalytic activity, and conductive cores was engineered. The hybrid material consists of radial MoS₂ nanosheets with a high density of edge planes and unsaturated active sulfur atoms as well as interspersed with conductive graphene nanoplatelets. This hybrid material exhibits excellent activity for the hydrogen evolution reaction and the detection of DNA nucleobases. Such a nanoengineered, nanostructured hybrid material may play a major role in future electrocatalytic devices.     

Bottom-Up Synthesized MoS2 Interfacing Polymer Carbon Nanodots with Electrocatalytic Activity for Hydrogen Evolution

The preparation of an MoS₂–polymer carbon nanodot (MoS₂-PCND) hybrid material was accomplished by employing an easy and fast bottom-up synthetic approach. Specifically, MoS₂-PCND was realized by the thermal decomposition of ammonium tetrathiomolybdate and the in situ complexation of Mo with carboxylic acid units present on the surface of PCNDs. The newly prepared hybrid material was comprehensively characterized by spectroscopy, thermal means, and electron microscopy. The electrocatalytic activity of MoS₂-PCND was examined in the hydrogen evolution reaction (HER) and compared with that of the corresponding hybrid material prepared by a top-down approach, namely MoS₂-PCND(exf-fun), in which MoS₂ was firstly exfoliated and then covalently functionalized with PCNDs. The MoS₂-PCND hybrid material showed superior electrocatalytic activity toward the HER with low Tafel slope, excellent electrocatalytic stability, and an onset potential of −0.16 V versus RHE. The superior catalytic performance of MoS₂-PCND was rationalized by considering the catalytically active sites of MoS₂, the effective charge/energy-transfer phenomena from PCNDs to MoS₂, and the synergetic effect between MoS₂ and PCNDs in the hybrid material.     

High‐Resolution Electrochemical Mapping of the Hydrogen Evolution Reaction on Transition‐Metal Dichalcogenide Nanosheets

High‐resolution scanning electrochemical cell microscopy (SECCM) is used to image and quantitatively analyze the hydrogen evolution reaction (HER) catalytically active sites of 1H‐MoS₂ nanosheets, MoS₂, and WS₂ heteronanosheets. Using a 20 nm radius nanopipette and hopping mode scanning, the resolution of SECCM was beyond the optical microscopy limit and visualized a small triangular MoS₂ nanosheet with a side length of ca. 130 nm. The electrochemical cell provides local cyclic voltammograms with a nanoscale spatial resolution for visualizing HER active sites as electrochemical images. The HER activity difference of edge, terrace, and heterojunction of MoS₂ and WS₂ were revealed. The SECCM imaging directly visualized the relationship of HER activity and number of MoS₂ nanosheet layers and unveiled the heterogeneous aging state of MoS₂ nanosheets. SECCM can be used for improving local HER activities by producing sulfur vacancies using electrochemical reaction at the selected region.     

Hierarchical Nanoboxes Composed of Co9S8−MoS2 Nanosheets as Efficient Electrocatalysts for the Hydrogen Evolution Reaction

The development of hydrogen evolution catalysts based on nonprecious metals is essential for the practical application of water‐splitting devices. Herein, the synthesis of Co₉S₈?MoS₂ hierarchical nanoboxes (HNBs) as efficient catalysts for the hydrogen evolution reaction (HER) is reported. The surface of the hollow cubic structure was organized by CoMoS₄ nanosheets formed through the reaction of MoS₄^2? and Co²⁺ released from the cobalt zeolite imidazole framework (ZIF‐67) templates under reflux in a mixture of water/ethanol. The formation process for the CoMoS₄ HNB structures was characterized by TEM images recorded at various reaction temperatures. The amorphous CoMoS₄ HNBs were converted through sequential heat treatments into CoS_x?MoS₂ and Co₉S₈?MoS₂ HNBs. Owing to their unique chemical compositions and structural features, Co₉S₈?MoS₂ HNBs have a high specific surface area (124.6 m² g^?1) and superior electrocatalytic performances for the HER. The Co₉S₈?MoS₂ HNBs exhibit a low overpotential (η₁₀) of 106 mV, a low Tafel slope of 51.8 mV dec^?1, and long‐term stability in an acidic medium. The electrocatalytic activity of Co₉S₈?MoS₂ HNBs is superior to that of recently reported values, and these HNBs prove to be promising candidates for the HER.     

Tuning the Intrinsic Activity and Electrochemical Surface Area of MoS2 via Tiny Zn Doping: Toward an Efficient Hydrogen Evolution Reaction (HER) Catalyst

Molybdenum sulfide (MoS₂) is considered as an alternative material for commercial platinum catalysts for electrocatalytic hydrogen evolution reaction (HER). Improving the apparent HER activity of MoS₂ to a level comparable to that of Pt is an essential premise for the commercial use of MoS₂. In this work, a Zn-doping strategy is proposed to enhance the HER performance of MoS₂. It is shown that tiny Zn doping into MoS₂ leads to the enhancement of the electrochemical surface area, increases in proportion of HER active 1T phase in the material and formation of catalytic sites of higher intrinsic activity. These benefits result in a high-performance HER electrocatalyst with a low overpotential of 190 mV(@10 mA cm⁻²) and a low Tafel slope of 58 mV dec⁻¹. The origin for the excellent electrochemical performance of the doped MoS₂ is rationalized with both experimental and theoretical investigations.