Preparations of TiO_2 film coated on foam nickel substrate by sol-gel processes and its photocatalytic activity for degradation of acetaldehyde

Anatase TiO2 films were successfully prepared on foam nickel substrates by sol-gel technique using tetrabutyl titanate as precursor. The characteristics of the TiO2 films were investigated by XPS, XRD, FE-SEM, TEM and UV-Vis absorption spectra. The photocatalytic activities of TiO2 films were investigated by photocatalytic degradation reactions of gaseous acetaldehyde, an indoor pollutant, under ultraviolet light irradiation. It was found that Ni^2＋ doping into TiO2 films due to the foam nickel substrates resulted in the extension of absorption edges of TiO2 films from UV region to visible light region. The pre-heating for foam nickel substrates resulted in the formation of NiO layer, which prevented effectively the injection of photogenerated electrons from TiO2 films to metal nickel. The TiO2 films displayed high photocatalytic activity for the degradation of acetaldehyde, and were enhanced by calcining the substrates and coating TiO2 films repeatedly. The high activity was mainly attributed to the improvement of the characteristics of substrate surface and the increase of active sites on photocatalyst.

Electrokinetic-mechanism of water and furfural oxidation on pulsed laser-interlaced Cu_(2)O and CoO on nickel foam

The electrocatalytic oxidation of biomass-derived furfural(FF)feedstocks into 2-furoic acid(FA)holds immense industrial potential in optics,cosmetics,polymers,and food.Herein,we fabricated Co O/Ni O/nickel foam(NF)and Cu_(2)O/Ni O/NF electrodes via in situ pulsed laser irradiation in liquids(PLIL)for the bifunctional electrocatalysis of oxygen evolution reaction(OER)and furfural oxidation reaction(FOR),respectively.Simultaneous oxidation of NF surface to NiO and deposition of CoO and/or Cu_(2)O on NF during PLIL offer distinct advantages for enhancing both the OER and FOR.CoO/NiO/NF electrocatalyst provides a consistently low overpotential of~359 m V(OER)at 10 m A/cm^(2),achieving the maximum FA yield(~16.37 m M)with 61.5%selectivity,79.5%carbon balance,and a remarkable Faradaic efficiency of~90.1%during 2 h of FOR at 1.43 V(vs.reversible hydrogen electrode).Mechanistic pathway via in situ electrochemical-Raman spectroscopy on CoO/NiO/NF reveals the involvement of phase transition intermediates(NiOOH and CoOOH)as surface-active centers during electrochemical oxidation.The carbonyl carbon in FF is attacked by hydroxyl groups to form unstable hydrates that subsequently undergo further oxidation to yield FA products.This method holds promise for large-scale applications,enabling simultaneous production of renewable building materials and fuel.

Engineering of Self-Supported Electrocatalysts on a Three-Dimensional Nickel Foam Platform for Efficient Water Electrolysis

Economical water electrolysis requires highly active non-noble electrocatalysts to overcome the sluggish kinetics of the two half-cell reactions,oxygen evolution reaction,and hydrogen evolution reaction.Although intensive efforts have been committed to achieve a hydrogen economy,the expensive noble metal-based catalysts remain under consideration.Therefore,the engineering of self-supported electrocatalysts prepared using a direct growth strategy on three-dimensional(3D)nickel foam(NF)as a conductive substrate has garnered significant interest.This is due to the large active surface area and 3D porous network offered by these electrocatalysts,which can enhance the synergistic eff ect between the catalyst and the substrate,as well as improve electrocatalytic performance.Hydrothermal-assisted growth,microwave heating,electrodeposition,and other physical methods(i.e.,chemical vapor deposition and plasma treatment)have been applied to NF to fabricate competitive electrocatalysts with low overpotential and high stability.In this review,recent advancements in the development of self-supported electrocatalysts on 3D NF are described.Finally,we provide future perspectives of self-supported electrode platforms in electrochemical water splitting.

Compressive properties and energy absorption characteristics of open-cell nickel foams

Open-cell nickel foams with different relative densities and pre-stretching degrees were subjected to room temperature quasi-static compressive tests to explore their compressive properties. The compressive properties of the nickel foams including yield strength, elastic modulus, energy absorption density and energy absorption efficiency were calculated accurately. The results show that the compressive properties of yield strength, elastic modulus and energy absorption density increase with the increase of relative density of nickel foams. The compressive properties are sensitive to the pre-stretching degree, and the values of yield strength, elastic modulus and energy absorption density decrease with the increase of pre-stretching degree. However, the energy absorption efficiency at the densification strain state exhibits the independence of relative density and pre-stretching degree. The value of energy absorption efficiency reaches its peak when the strain is at the end of the collapse plateau region.

NiFe-based nanostructures on nickel foam as highly efficiently electrocatalysts for oxygen and hydrogen evolution reactions

Water splitting,as an advanced energy conversion technology,consists of two half reactions,including oxygen evolution reaction(OER)and hydrogen evolution reaction(HER).However,the ideal electrocatalysts are noble metal based catalysts.Their high cost and scarcity in earth seriously restrict the large deployments.Ni Fe-based materials have attracted great attention in recent years due to their excellent catalytic properties for OER and HER.Nevertheless,their conductivity and electrochemical stability at high current density are unsatisfactory,resulting in ineffective water splitting due to high impedance and low stability.Recently,a series of catalysts coating Ni Fe-based materials on 3 D nickel foam were found to be extremely stable under the circumstance of high current density.In this review,we summarized the recent advances of NiFe-based materials on nickel foam for OER and HER,respectively,and further provided the perspectives for their future development.

Microstructure of nickel foam/Mg double interpenetrating composites

The magnesium matrix double interpenetrating composites reinforced by nickel foam were fabricated by pressureless infiltration technology.Then the morphology of the nickel reinforcement and the microstructures of composites were characterized by SEM.The results show that not only is the nickel foam reinforcement reticular in three dimensions,but also the struts of foam keep the network structure,which ensures that the Ni foam/Mg composites are double interpenetrating.The interface bonding of composites between magnesium matrix and nickel foam reinforcement is good,without reaction around the interface,which is the indispensable condition that advanced composites should possess.Magnesium matrix distributes in the windows of nickel foam,the triangle center holes and microhole of nickel struts,and the composites have double interpenetrating structure,which makes the composites have unique properties.

Sound absorption performance of various nickel foam-base multi-layer structures in range of low frequency

Commercial3D reticular nickel foam and its composite structure were investigated on the sound absorption at200-2000Hz.The absorption performance of foam plates1?5layers(1-layer thickness:2.3mm;porosity:89%;average pore-diameter:0.57mm)was found to be poor,and could be improved by adding backed cavum or front perforated thin sheet.The absorption coefficient could reach about0.4at1000-1600Hz for the composite structure of5-layer foam with a backed5mm-thick cavum,and even0.68at about1000Hz for that of2-layer foam with the same cavum and a perforated plate closely in front of the foam.

Highly-dispersed iron element decorated nickel foam synthesized by an acid-free and one-pot method for enzyme-free glucose sensor

The highly-dispersed iron element decorated Ni foam was prepared by simple immersion in a ferric nitrate solution at room temperature without using acid etching, and characterized by X-ray powder diffraction(XRD), scanning electron microscopy(SEM), EDAX spectrum(EDAX mapping) and Raman spectroscopy. The EDAX spectrum illustrated that iron element was highly-dispersed over the entire surface of nickel foam, and the Raman spectroscopy revealed that both Ni-O and Fe-O bonds were formed on the surface of the as-prepared electrode. Moreover, the iron element decorated Ni foam electrode can be used as non-enzymatic glucose sensor and it exhibits not only an ultra-wide linear concentration range of 1-18 mmol/L with an outstanding sensitivity of 1.0388 m A·mmol/(L·cm2), but also an excellent ability of stability and selectivity. Therefore, this work presents a simple yet effective approach to successfully modify Ni foam as non-enzymatic glucose sensor.

Sound absorption of several various nickel foam multilayer structures at aural frequencies sensitive for human ears

Using the three-dimensional reticular nickel foam as experimental material, the sound absorption performance was investigated for several various multilayer structures in the frequency range of 2000-4000 Hz, which is aurally sensitive for human ears. The results showed that the 7.5 mm-thick foam sample, which was formed by piling of 5-layer foam plate（thickness： 1.5 mm; porosity： 96%; average pore-diameter： 0.65 mm） could exhibit an excellent sound absorption effect at 4000 Hz, with the absorption coefficient about 0.8. Constituting alternate air gap with the total thickness of about 18.5 mm can greatly improve the absorption performance at relatively low frequencies of 2000-3150 Hz, with the absorption coefficient up to about 0.5 or more. In addition, the research showed that alternate piling up the perforated plate inside the foam plates can also achieve a quite good effect of sound absorption at relatively low frequencies.

Removal of nickel from spent electroless nickel-plating bath with nickel foam cathode

The electrochemical method was used to remove nickel ion from spent electroless nickel plating bath (pH=5 3). An electrolytic cell was composed of a porous nickel foam cathode and an inert RuO 2/Ti anode. Nickel ions were reduced and deposited on the surface of the nickel foam cathode. The effect of current density (i), linear velocity of wastewater(v), gap between cathode and anode(d C/A) and reaction time(t) on nickel removal rate and current efficiency were studied. As reaction time prolonged, nickel removal rate increased while current efficiency decreased. And larger v and smaller d C/A can enhance nickel removal rate and increase current efficiency by promoting mass transfer and dropping concentration polarization. The effect of current density on nickel removal by electrochemistry was related to other parameters. After three hours’ electrolysis with i=1 0 A/dm2, v=18 5 cm/min and d C/A=0 5 cm, nickel removal rate and current efficiency reached 85 6% and 29 1%, respectively.

Porous Cobalt Oxide@Layered Double Hydroxide Core-Shell Architectures on Nickel Foam as Electrode for Supercapacitor

The high performance of an electrode relies largely on a scrupulous design of nanoarchitectures and smart hybridization of electroactive materials.A porous core-shell architecture in which one-dimensional cobalt oxide(Co_3O_4)nanowire cores are grown on nickel foam prior to the growth of layered double hydroxide(LDH)shells is fabricated.Hydrothermal precipitation and thermal treatment result in homogeneous forests of 70-nm diameter Co_3O_4 nanowire,which are wrapped in LDH-nanosheet-built porous covers through a liquid phase deposition method.Due to the unique core-shell architecture and the synergetic effects of Co_3O_4and NiAl-LDH,the obtained Co_3O_4@LDH electrode exhibits a capacitance of 1 133.3F/g at a current density of 2A/g and 688.8F/g at 20A/g(5.3F/cm^(2 )at 9.4mA/cm^(2 )and 3.2F/cm^(2 )at 94mA/cm^2),which are better than those of the individual Co_3O_4nanowire.Moreover,the electrode shows excellent cycling performance with a retention rate of 90.4%after 3 000cycles at a current density of 20A/g.

阴极电阻分布对电镀泡沫镍电流密度影响的研究

采用挂镀和阴极移动连续镀两种模式,研究泡沫镍平面电流密度分布规律。结果表明:挂镀模式使电流密度分布呈四周高中央低,阴极移动连续镀模式受接触点和液下电镀沉积量的影响,电流密度分布有上高下低、中部高两头低等几种形式。

微波辐射制备Bi_(2)O_(3)/NiF光阳极及模拟日光下光电催化氧化降解罗丹明B

针对粉体Bi_(2)O_(3)光催化剂光利用效率低及难回收再利用等技术问题,采用浸渍—微波辐射技术在泡沫镍(NiF)上负载Bi_(2)O_(3)来制备Bi_(2)O_(3)/NiF光阳极,并借助SEM,XRD,XPS等手段及电化学工作站分析方法研究了光阳极的形貌结构及光电催化氧化性能.结果显示,花簇状的Bi_(2)O_(3)成功地负载在NiF的三维骨架上,Bi_(2)O_(3)/NiF具有优异的光电转化效率.在最佳制备条件,当光电流密度为15µA/cm^(2),外加电压为2V、RhB初始浓度为8mg/L、pH值为3的条件下,Bi_(2)O_(3)/NiF光电催化氧化降解罗丹明B(RhB)的效率可达95.35%,Bi_(2)O_(3)/NiF光电催化氧化降解RhB符合一级反应动力学方程,自由基淬灭实验证实h+在Bi_(2)O_(3)/NiF光电催化氧化降解RhB过程中起着主要作用.

泡沫镍对B_(4)C陶瓷/TC4真空钎焊接头的强化机制

B_(4)C陶瓷与TC4钛合金进行真空钎焊时,由于两者之间的热膨胀性能存在较大差异,容易因过大的残余应力而产生开裂现象。本文采用添加泡沫镍中间层的方法成功实现了B_(4)C陶瓷与TC4钛合金无开裂缺陷真空钎焊,并观察了钎焊接头微观组织,计算分析了接头残余应力和弹性应变能。结果表明:真空钎焊接头的剪切强度达到88.6 MPa;泡沫镍中间层的添加一方面可有效缓解活性元素Ti对B_(4)C陶瓷基体的过度溶解,减少TiC、TiB_(2)等脆性化合物的形成,并促进了钎料成分的均匀分布;另一方面,软化坍塌的泡沫镍骨架结构分割了熔化的钎料,造成多个小熔合区,从而使焊缝组织受力更加均匀,同时残余应力也获得了一定程度的缓解,有利于B_(4)C陶瓷与TC4钛合金形成良好的连接。B_(4)C陶瓷与TC4钛合金在泡沫镍中间层的加入后应力得到缓解,也进一步验证了陶瓷/金属异种材料的连接可通过多孔材料进行应力释放。

镀液pH对电沉积镍-钼-磷合金薄膜组织结构及性能的影响

[目的]镀液pH是影响金属电沉积过程的关键因素之一,进而影响着沉积层的组织结构和性能。[方法]采用直流电沉积法在泡沫镍(NF)上制备Ni-Mo-P合金薄膜。采用X射线衍射仪(XRD)、扫描电镜(SEM)和能谱仪(EDS)分析了不同pH下所得Ni-Mo-P合金薄膜的晶相结构、微观形貌及元素组成,并通过电化学方法考察了镀液pH对Ni-Mo-P合金薄膜析氢性能及耐蚀性的影响。[结果]在pH为7~11范围内电沉积所得的Ni-Mo-P合金薄膜均呈现非晶态结构,但组织结构及性能有差异。pH为9时所得的Ni-Mo-P合金薄膜表面最为光滑平整,载量最大,并且耐腐蚀性能最好。pH为10时所得Ni-Mo-P合金薄膜的析氢催化活性最佳。[结论]通过调整镀液的pH,可电沉积得到具备不同组织结构及性能的Ni-Mo-P合金薄膜。

高效三维电极电Fenton降解苯酚实验研究

酚类化合物是一种有毒污染物,难以生物降解。电Fenton技术是去除酚类物质的有效手段之一。通过热溶剂—涂覆—焙烧法制备Fe_(3)O_(4)负载碳纳米管修饰泡沫镍(Fe_(3)O_(4)/CNT/NF)粒子电极,可在电解系统中同时产生H_(2)O_(2)和Fe^(2+)。以Fe_(3)O_(4)/CNT/NF作为粒子电极构建三维电极电Fenton系统对苯酚进行降解,苯酚去除率明显高于基于Fe_(3)O_(4)/NF和NF粒子电极的三维电极及二维电极体系。对反应条件进行优化后,在降解时间60 min、极板间距3.0 cm、Fe_(3)O_(4)/CNT/NF粒子电极投加量8.0 g/L、电流350 mA、电解质浓度100 mmol/L、初始pH为4的条件下,苯酚去除率可达76.23%。猝灭实验结果表明,该体系中羟基自由基(·OH)在降解过程中起主要作用。此外,电极稳定性能优异,6次循环实验后对苯酚的去除率仅降低6.09%。

原位合成Au/泡沫镍磁性基底用于表面增强拉曼快速检测血清中免疫抑制剂代谢物

该文采用处理后的泡沫镍为反应模板,直接还原氯金酸溶液,经实验条件优化,原位制备了纳米金-泡沫镍多孔磁性复合表面增强拉曼散射(SERS)基底(Au-NFs)。泡沫镍三维网状具有大的比表面积和粗糙度,可稳定负载纳米金,通过Au—S键化学吸附更多的目标分子6-巯基嘌呤。复合基底的磁特性易于磁分离富集,避免血液共存物对SERS检测6-巯基嘌呤的干扰。利用磁场诱导纳米金-泡沫镍聚集,可进一步优化纳米金局域等离子场分布,形成SERS热点,大大提升了分析灵敏度,对于探针分子4-巯基吡啶的检出限可达5×10^(-9)mol/L。在外磁场优化条件下,基于Au-NFs复合SERS基底定量检测6-巯基嘌呤,在5×10^(-7)~1×10^(-8) mol/L浓度范围内有良好的线性,检出限为1×10^(-9) mol/L。该Au-NFs基底无需样品预处理,可实现血清中6-巯基嘌呤的快速分析,加标回收率在92.8%~107%范围内,表明方法可靠。

In-Sn@NiO作为无酶型葡萄糖传感器的研究

以泡沫镍为基底通过原位生长和电化学沉积法制备了高灵敏无酶型葡萄糖传感器In-Sn@NiO复合材料。X射线衍射和X光电子能谱测试结果证明In、Sn元素成功复合到NiO电极表面;电化学测试结果表明,In-Sn@NiO复合电极材料的灵敏度高达3.51 mA/(mmol/L·cm^(2)),线性范围为2~18 mmol/L,检出限为69.09μmol/L。该电极材料对干扰物的电流响应不超过5%,说明其有良好的选择性。

改性泡沫镍作为水裂解高效电催化剂的研究

水裂解是一种先进的能量转化技术,由析氧反应(OER)和析氢反应(HER)两个半反应组成。电解水制取高纯氢技术是目前能源开发的一个重要领域。电解水的关键技术是制备高效催化、稳定耐用的电极,用于降低电解水析氢反应和析氧反应的过电位。然而,催化材料的选择是研究电解水制取氢气和氧气的一个重要方向。本文主要综述了利用三维泡沫镍基制造纳米结构材料用于水裂解的最新进展以及局限性和前景。

Growth of Ag/g-C_(3)N_(4) nanocomposites on nickel foam to enhance photocatalytic degradation of formaldehyde under visible light

Formaldehyde is a pollutant that significantly affects the indoor air quality.However,conventional remediation approaches can be challenging to deal with low-concentration formaldehyde in an indoor environment.In this study,Photocatalysts of Ag/graphitic carbon nitride(g-C_(3)N_(4))/Ni with 3D reticulated coral structure were prepared by thermal polymerization and liquid phase photo-deposition,using nickel foam(NF)as the carrier.Experiments demonstrated that when the Ag concentration was 3%,and the relative humidity was 60%,the Ni/Ag/g-C_(3)N_(4)showed the maximum degradation rate of formaldehyde at 90.19%under visible light irradiation,and the formaldehyde concentration after degradation was lower than the Hygienic standard stated by the Chinese Government.The porous structure of Ni/Ag/g-C_(3)N_(4)and the formation of Schottky junctions promoted the Adsorption efficiency and degradation of formaldehyde,while the nickel foam carrier effectively promoted the desorption of degradation products.Meanwhile,the degradation rate was only reduced by3.4%after 16 recycles,the three-dimensional porous structure extended the lifetime of the photocatalyst.This study provides a new strategy for the degradation of indoor formaldehyde at low concentrations.