A hollow tubular NiCo layacknered double hydroxide@Ag nanowire structure for high-power-density flexible aqueous Ni//Zn battery

Flexible aqueous Ni//Zn batteries have attracted much attention as promising candidates for energy storage in the field of flexible electronics.However,the Ni-based cathodes still face the challenges of poor conductivity,confined charge/mass transfer,and non-flexibility.In this work,we designed a hollow tubular structure consisting of a conductive silver nanowire (Ag NW) wrapped by active Ni Co layered double hydroxide (LDH),for enhancing the electrical conductivity,improving the charge/mass transfer kinetics,and facilitating the ion penetration.By optimizing the contents of Ni,Co and Ag NW,the Ni_(4)Co LDH@Ag_(1.5)NW composite shows a maximum specific capacity of 115.83 m Ah g^(-1)at 0.1 A g^(-1)measured in a two-electrode system.Highlightingly,the flexible aqueous Ni//Zn battery assembled by Ni_(4)Co LDH@Ag_(1.5)NW interwoven with multi-walled carbon nanotube cathode and Zn foil anode realizes a high power density of 160μW cm^(-2)at the energy density of 23.14μWh cm^(-2),which is superior compared with those of oxide/hydroxide based devices and even higher than those of many carbon-based supercapacitors,showing its promising potentials for flexible energy storage applications.

Ultrathin nanosheets of cobalt-nickel hydroxides hetero-structure via electrodeposition and precursor adjustment with excellent performance for supercapacitor

A homogeneous better-dispersed ultrathin nanosheets（ca. 5 nm） of cobalt-nickel layered double hydroxides（LDH） supported on nickel foam scaffold was synthesized using controllable electrodeposition approach for high efficiency electrode materials of new supercapacitor. The morphology and electrochemical performances of the samples can be controlled by adjusting the precursor ratio, i.e., Ni（OAc）2/Co（NO3）2 molar ratio in the electrodeposition approach. With the increase of this molar ratio, the electrochemical performances give a volcano trend. When the optimized molar ratio is 0.64/0.36, the hybrid delivered a high specific capacitance of 1587.5 F g-1 at a current density of 0.5 A g-1, with good rate capability（1155 F g-1 was retained even at 10 A g-1） and a robust recycle stability（remaining 91.5% after 1000 cycles at 5 A g-1）. The good performance could be attributed to the enlarged interlayer spacing, ultrathin nanosheets and synergistic effects between Co（OH）2 and Ni（OH）2. Furthermore, an asymmetric supercapacitor with a high energy density of 34.5 Wh kg-1 at 425 W kg-1 and excellent cycling stability of 85.4% after 5000 charge-discharge cycles at 2 A g-1 was fabricated. We believe that this fantabulous new electrode material would have encouraging applications in electrochemical energy storage and a wide readership.

Bimetallic Ni-Fe catalysts derived from layered double hydroxides for CO methanation from syngas

Carbon deposition and sintering of active components such as nano particles are great challenges for Ni-based catalysts for CO methanation to generate synthetic natural gas from syngas. Facing the challenges, bimetallic catalysts with different Fe content derived from layered double hydroxide containing Ni, Fe, Mg, A1 elements were prepared by co-precipitation method. Nanoparticles of Ni-Fe alloy were supported on mixed oxides of aluminium and magnesium after calcination and reduction. The catalysts were characterized by Brunner- Emmett-Teller （BET）, X-ray diffraction, hydrogen tem- perature programmed reduction, inductively coupled plasma, X-ray photoelectron spectroscopy, transmission electron microscopy and thermogravimetric techniques, and their catalytic activity for CO methanation was investigated. The results show that the Ni-Fe alloy catalysts exhibit better catalytic performance than mono- metallic catalysts except for the Ni4Fe-red catalyst. The Ni2Fe-red catalyst shows the highest CO conversion （100% at 260-350 ~C）, as well as the highest CH4 selectivity （over 95% at 280-350 ~C）, owing to the formation of Ni-Fe alloy. In stability test, the Ni2Fe-red catalyst exhibits great improvement in both anti-sintering and resistance to carbon formation compared with the Ni0Fe-red catalyst. The strong interaction between Ni and Fe element in alloy and surface distribution of Fe element not only inhibits the sintering ofnanoparticles but restrains the formation of Ni clusters.

Ultrathin Ni/V-layered double hydroxide nanosheets for efficient visible-light-driven photocatalytic nitrogen reduction to ammonia

Ammonia is important for industrial development and human life.The traditional Haber Bosch method converts nitrogen into ammonia gas at high temperatures and pressures,causing serious pollution and greenhouse gas emissions.These problems prompt the nitrogen fixation method to proceed in a sustainable way.Ultrathin Ni/V-layered double hydroxides(Ni/V-LDHs)nanosheets with different proportions were prepared successfully for photocatalystic reduction of nitrogen to ammonia,through aqueous miscible organic solvent method(AMO)to achieve the higher surface area and rich oxygen vacancies,containing more carriers and active sites to enhance nitrogen reduction.And the optimal catalyst of Ni/V-LDHs 11 AMO possesses the highest photocatalytic efficiency(176μmol·g^(-1)·h^(-1)),indicating its potential application prospects in catalyst fields.Consequently,this work achieves an environmentally friendly,low-cost and efficient conversion method for nitrogen reduction to ammonia through solar energy.

Ni离子掺杂对CoAl双氢氧化物电化学电容的影响

CoAl LDHs with different molar ratio of Ni have been prepared by chemical co -precipitation method.XRD results show that these materials have layered struc tures.Electrochemical tests show that Co(Ni)Al LDHs as electrode material hav e typical capacit ive properties in a wide voltage range of0.0to0.6V;Co(Ni)Al LDH(Ni∶Co =4∶6)as an electrode material has the highest capacitance of960F · g -1 and good cycling performance.But the poor capacitive properties of NiAl LDH electrode are showed in a narrow voltage range of0.3to0.55V.

Ni/Al-LDH/MCNTs原位复合材料的制备与电化学性能

以Ni(NO3)2·6H2O、Al(NO3)3·9H2O、尿素和MCNTs为原料,采用原位均相沉淀法制备了MCNTs含量(质量分数)分别为1%、3%和5%的Ni/Al-LDH/MCNTs复合电极活性材料。采用X射线衍射(XRD)、傅里叶变换红外光谱(FTIR)和场发射扫描电子显微镜(FESEM)表征了材料的微观结构和形貌;采用循环伏安(CV)、电化学交流阻抗(EIS)和充放电测试研究了该复合材料作为镍氢电池正极材料的电化学性能。结果表明,在Ni/Al-LDH中复合MCNTs能够提高材料的电化学活性,降低电化学反应电阻,显著改善材料的大电流充放电性能。其中MCNTs含量为3%的Ni/Al-LDH/MCNTs复合材料具有最佳的电化学性能,在200、500、1000和2000mA·g-1电流密度下的放电比容量分别为330、321、307和288 mA·h·g-1,而未复合MCNTs的Ni/Al-LDH在2000 mA·g-1电流密度下放电比容量仅为205 mA·h·g-1。

还原氧化石墨烯/Al-Ni层状双氢氧化物复合物的制备及其电化学电容行为

以硝酸镍和硝酸铝为原料,尿素作为还原剂和沉淀剂,通过水热法一步合成了不同配比的还原氧化石墨烯/Al-Ni层状双氢氧化物复合物(rGO/LDH)。用X射线衍射(XRD),红外光谱(FT-IR),拉曼光谱(Raman)和场发射扫描电镜(FESEM)对其结构和形貌进行物理表征。采用循环伏安,恒电流充放电等电化学方法系统研究了所制备样品的电化学性能。结果表明,当Al-Ni层状双氢氧化物(LDH)与还原氧化石墨烯(rGO)的配比为96.2∶3.8时,复合物具有最佳的电容性能。在电流密度为1A·g-1时,其比电容高达918.4F·g-1,远高于纯Al-Ni层状双氢氧化物(LDH)的比电容(732F·g-1)。

基于Al/Ni双氢氧化物纳米线无酶葡萄糖传感器的研究

本文采用多孔聚碳酸酯(PC)模板在加热条件下通过溶液渗透和共沉淀制得了Al/Ni双氢氧化物纳米线,并将其修饰到玻碳电极制成无酶葡萄糖传感器。考察了该传感器在不同扫描速度时的循环伏安行为,比较了裸玻碳电极、不同修饰电极对响应电流的影响。在优化条件下进行葡萄糖检测,线性范围为2.0×10-5～1.3×10-3 mol/L,检出限可以达到5.0×10-6 mol/L。该方法快捷、灵敏、分析性能好,操作简便。可将其应用于血清中葡萄糖含量的测定。

原位共沉淀法制备Ni-Mg-Al-LDHs/γ-Al_2O_3催化前驱体在甲烷二氧化碳重整反应体系中的性能评价（英文）

通过原位共沉淀的方法在γ-Al2O3表面上合成了Ni-Mg-Al-LDHs(水滑石),合成的Ni-Mg-Al-LDHs/γ-Al2O3作为催化前驱体经过不同的热处理还原方式得到催化剂Cat-1、Cat-2和Cat-3.用X射线衍射(XRD)、透射电镜(TEM)、N2吸附-脱附测试(BET)以及热重-差热分析(TG-DTA)对催化剂的形貌结构和抗积碳能力进行了表征测试;通过甲烷二氧化碳重整反应体系对催化剂的反应活性和稳定性进行了评价.结果表明催化剂前驱体的预处理方式对催化剂的反应性能具有较大的影响.Ni-Mg-Al-LDHs/γ-Al2O3直接经过H2/Ar常压高频冷等离子体炬的分解还原所获得的催化剂Cat-3表现出了最佳的催化活性和稳定性.TEM表征表明催化活性组分在Cat-3上的分散性更好,颗粒粒径更小.BET结果证明Cat-3具备较大的比表面积(195.8 m2?g-1).Ni-Mg-Al水滑石的结构赋予了催化剂活性组分在载体γ-Al2O3上均匀的分散性,同时常压高频冷等离体炬对催化剂的表面结构以及活性组分的还原具有进一步的优化作用,两者的协同作用使Ni-Mg-Al-LDHs/γ-Al2O3在甲烷二氧化碳反应体系中具备优良的催化活性和抗积碳性能.

基于NiZn层状双金属氢氧化物制备高效电催化CO_(2)还原的原子分散Ni-N-C催化剂

大气中CO_(2)浓度不断上升导致大量的环境问题,如冰川融化、温室效应、极端天气等,利用电化学方法将CO_(2)经还原反应(CO_(2)RR)转化为有价值的燃料或化学品是解决该问题的可行策略.由于CO_(2)具有稳定的化学键(C=O,806 kJ mol^(-1)),需设计具有优异活性和高选择性的催化剂.近年研究结果表明,过渡金属锚定在N掺杂碳载体上而制得的催化剂(M-N-C)具有较高的原子利用率、独特的活性金属中心电子结构以及存储量丰富,因而被认为是CO_(2)还原为CO的理想电催化剂.目前已经提出了多种方法来制备M-N-C催化剂,包括原子层沉积、基于金属-有机骨架的离子交换、基于载体修饰策略的吸附固化和受限热解.然而,这些方法存在制备过程繁琐或难以大规模生产的问题.同时,采用高温热解制备的M-N-C催化剂,金属活性位点易被其致密的结构包裹,难以完全暴露出来.但有效的活性位点对M-N-C的催化性能起着至关重要的作用,因此有必要研制一种简便、高效的方法来抑制金属原子聚集.超薄二维碳骨架已被证明可以缩短反应物的扩散路径并有利于暴露催化剂活性位点.本文将NiZn层状双金属氢氧化物(NiZn-LDHs)在多羟基化合物中进行剥离形成单层,同时通过控制单层NiZn-LDHs、多羟基化合物和三聚氰胺共同热解,宏量化制得Ni-N-C催化剂.X射线衍射(XRD)和透射电子显微镜(TEM)结果表明,在焙烧过程中,可通过改变单层NiZn-LDHs在多羟基化合物中的含量控制Ni-N-C材料中镍纳米颗粒的生成;焙烧过程中Zn挥发能使Ni-N-C材料形成更多中孔,增加碳骨架比表面积和孔径.中孔通道和碳基底超薄特性结合可以促进CO_(2)向内部活性位点扩散,增加反应物与活性位点的接触.XPS结果表明,Ni-N-C材料中Ni原子通过与N配位,锚定在超薄碳骨架上,且存在Niδ+中心(0<δ<2).X射线近边吸收和扩展X射线吸收精细结构分析表明,Ni-N-C-1中的Ni处于低价态(0<δ<2),这与XPS分析一致,且Ni为原子级分散;小波变换分析表明,Ni和N的配位数为3.9.利用H型电解池评估Ni-N-C材料电催化CO_(2)还原性能表明,Ni-N-C-1具有优异的CO_(2)还原活性,在-0.6至-1.0 V电位范围内,FE_(CO)都大于90%,且在-4.9 V时,FE_(CO)为95.2%,CO电流密度为24 mA cm^(-2);在-0.8 V电位,工作25 h后Ni-N-C-1的CO电流密度基本保持不变,说明Ni-N-C-1为稳定的CO_(2)RR催化剂.通过密度泛函理论计算研究了Ni-N-C材料电催化CO_(2)还原为CO的电化学演化历程,结果表明,该反应过程分四个步骤:CO_(2)吸附到单个Ni原子位点上;转移形成*COOH的质子/电子对;*COOH在释放H_(2)O的同时获得质子形成*CO;*CO从Ni位点解吸.相应步骤的吉布斯自由能分别为0.54,1.69,-0.99和-0.98 eV.Ni-N-C中Ni原子与配位N原子之间的强相互作用导致Ni原子的电子损失,Ni原子有0.85 e缺陷,周围的N原子有0.15 e堆积,这有利于CO_(2)的吸附.总之,本文采用单层NiZn-LDHs为金属源,开发了一种简便且可宏量化制备CO_(2)RR单原子催化剂的新方法.

Ni-Al层状双金属氢氧化物制备及其超级电容特性

采用滴加法制备了Ni-Al层状双金属氢氧化物。用扫描电子显微镜(SEM)、能量色散谱仪和X射线衍射仪等方法对样品进行形貌和结构表征。结果表明:样品是由大小在几百纳米到几微米的多晶颗粒组成。颗粒具有层状结构且表面粗糙多孔。通过循环伏安法和恒流充放电法对样品的电化学性能进行测试。结果表明:扫描电压速度为5 mV/s时,Ni-Al层状双金属氢氧化物电极的比电容达到1 872 F·g^(-1)。随着扫描电压速度的增加,电极的比电容逐渐降低。当扫描电压速度为100 mV/s时,电极的比电容降到了248 F·g^(-1)。随着充放电电流密度的升高,电极的比电容逐渐降低。当电流密度从0.5 A·g^(-1)升高到3 A·g^(-1)时,电极比电容的保持率约为78.7%。

Ni-Fe层状双金属氢氧化物的制备及性能研究

采用水热法制备了Ni-Fe层状双金属氢氧化物(Ni-Fe LDHs),研究了反应温度、反应时间、镍铁比和柠檬酸三钠用量对Ni-Fe LDHs生长的影响,并研究其对甲基橙和亚甲基蓝的吸附性能。利用X-射线衍射、扫描电镜和交变梯度磁强计等测试方法研究了工艺条件对Ni-Fe-LDHs形貌、粒径、结晶性和磁性能的影响。实验结果表明:延长反应时间或升高反应温度都不利于得到结晶性好的Ni-Fe-LDHs。镍铁比对样品的结晶性和形貌有重要影响;镍铁比为2∶1,样品的结晶性和磁性能最好,增加镍铁比,得到片层组装形成得花状结构;镍铁比为3∶1时,Ni-Fe-LDHs对甲基橙和亚甲基蓝表现出良好的吸附性。

均相沉淀法制备Ni/Al⁃LDHs/rGO复合电极材料的电化学性能

以Ni(NO3)2·6H2O、Al(NO3)3·9H2O、尿素以及氧化石墨烯(GO)为原料,利用简便的均相沉淀法合成了GO复合量(质量分数)分别为0、0.2%、0.5%、0.8%和1.0%的Ni/Al⁃LDHs/rGO复合电极材料。采用XRD、FT⁃IR、TGA和FESEM表征了材料的结构和表面形貌,利用循环伏安(CV)、交流阻抗(EIS)和充放电测试研究了Ni/Al⁃LDHs/rGO复合材料作为Ni⁃MH电池正极材料的电化学性能。结果表明,复合GO可以明显提高Ni/Al⁃LDHs的电化学性能,其中GO复合量为0.8%的Ni/Al⁃LDHs/rGO样品表现出最为优异的综合电化学性能,例如在2000 mA/g电流密度下,其放电比容量(288 mA·h/g)比未复合GO的Ni/Al⁃LDH样品放电比容量(205 mA·h/g)高出40.5%。

原位氧化法制备Zn-Ni氢氧化物纳米片及其电荷存储特性研究

通过简单、低成本的化学浴沉积法在泡沫镍上原位生成了Zn-Ni氢氧化物(Zn-Ni double hydroxides)纳米片。SEM观察结果表明,Zn-Ni氢氧化物纳米片均匀附着在泡沫镍表面,形成均一的多孔纳米片阵列层。此外,还有大量的Zn-Ni氢氧化物纳米片聚集成多孔团聚体,分布于泡沫镍骨架的空隙处,从而获得较高的活性物质负载量(4.27 mg/cm^2)。CV、CP和电化学阻抗测试表明,Zn-Ni氢氧化物纳米片在2 mol/L KOH电解液中充放电电流密度1 A/g时,比电容为746.2 F/g(面积电容为3.18 F/cm^2);3000次充放电循环后,仍保持70.9%的初始比电容。

Ni^(2+)含量对Ni-Al双金属氢氧化物的电化学性能的影响

通过调控Ni^(2+)含量,利用双水解法成功制备了具有层状结构的Ni-Al双金属氢氧化物,并研究了Ni^(2+)含量对Ni-Al双金属氢氧化物电化学性能的影响。实验结果表明:随着Ni^(2+)含量的增加,Ni-Al双金属氢氧化物的电化学性能随之提升;当Ni^(2+)和Al^(3+)的摩尔比为1∶2时,Ni-Al双金属氢氧化物具有最佳的电化学性能,其比电容在5 mV/s的扫描速度下可达1380 F/g,在电流密度3 A/g下进行1000次循环充放电测试后,比电容保持率仍能维持在66.7%;当Ni^(2+)和Al^(3+)的摩尔比大于1∶2时,Ni-Al双金属氢氧化物的电化学性能反而略微降低。此外,讨论了Ni^(2+)含量对Ni-Al双金属氢氧化物的制备和性能的影响机理。

Ni-Al-LDH/γ-Al_2O_3催化剂的制备及活性评价

分别以Ni(NO_3)_2·6H_2O和γ-Al_2O_3为二价和三价阳离子源,采用尿素水解法在γ-Al_2O_3载体上合成Ni-Al-LDH水滑石结构,并对其进行了XRD和FT-IR表征。以此为前驱体通过高温焙烧制得Ni-Al-LDH/γ-Al_2O_3催化剂。与等体积法制备的Ni/γ-Al_2O_3催化剂相比,Ni-Al-LDH/γ-Al_2O_3催化剂在甲烷干重整中不仅具有更高的催化活性,而且能够在一定程度上抑制逆水煤气反应。在反应温度为800℃,空速为48L·g^(-1)·h^(-1)的条件下,反应20h未失活,Ni-Al-LDH/γ-Al_2O_3催化剂上甲烷和二氧化碳转化率较Ni/γ-Al_2O_3催化剂约高8%。

Enabling high-efficiency ethanol oxidation on NiFe-LDH via deprotonation promotion and absorption inhibition

Nucleophile oxidation reaction(NOR), represented by ethanol oxidation reaction(EOR), is a promising pathway to replace oxygen evolution reaction(OER). EOR can effectively reduce the driving voltage of hydrogen production in direct water splitting. In this work, large current and high efficiency of EOR on a Ni, Fe layered double hydroxide(NiFe-LDH) catalyst were simultaneously achieved by a facile fluorination strategy. F in NiFe-LDH can reduce the activation energy of the dehydrogenation reaction, thus promoting the deprotonation process of NiFe-LDH to achieve a lower EOR onset potential. It also weakens the absorption of OH-and nucleophile electrooxidation products on the surface of NiFe-LDH at a higher potential, achieving a high current density and EOR selectivity, according to density functional theory calculations. Based on our experiment results, the optimized fluorinated NiFe-LDH catalyst achieves a low potential of 1.386 V to deliver a 10 mA cm^(-2)EOR. Moreover, the Faraday efficiency is greater than 95%, with a current density ranging from 10 to 250 mA cm^(-2). This work provides a promising pathway for an efficient and cost-effective NOR catalyst design for economic hydrogen production.

三维石墨烯基Co-Ni双氢氧化物复合材料的制备及其电化学性能

石墨烯具有高的机械强度和大的比表面积。以石墨烯、硝酸镍和硝酸钴为原料,水合肼为还原剂,采用水热法制备了三维石墨烯基Co-Ni双氢氧化物(GCN),用XRD、SEM、循环伏安、恒电流充放电测试方法对石墨烯和不同比例的GCN的结构和电化学性能进行表征研究。结果表明,在电流密度为1 A/g时,比容量可达1 230 F/g,并且循环500周后,比容量仍能保持91.6%,有望成为超级电容器的电极材料。

高分散LDHs基催化剂制备及硝基化合物还原性能测试——科研转化的综合化学实验

基于科研成果设计了一个综合化学实验——高分散复合金属氢氧化物(LDHs)基催化剂可控制备及硝基化合物还原性能测试。实验内容涉及无机功能材料和催化材料合成实验,催化材料晶体结构、形貌、化学键表征,催化反应性能评价和动力学研究等。通过实验的设计开展,促使学生初步掌握科学研究方法,增强学生独立思考、探索创新的意识,培养学生科研动手能力以及利用所学化学知识解决实际问题的能力,为新时代高素质、创新型复合人才的培养起到推动作用。

镍镁铝类水滑石的超分子结构、电子性质及稳定性

以Ni2+同晶取代Mg2+的方式构建镍镁铝类水滑石(HT)的周期性计算模型,通过进行密度泛函理论计算,研究了含镍水滑石的的超分子结构、电子性质及稳定性.结果表明,随着镍离子逐渐取代镁离子,金属离子之间的平均距离逐渐减小,层间距逐渐增大,与实验结果一致.与此同时,电子逐渐从主体层板向客体阴离子传递,导致主客体之间的静电作用力及整体超分子作用力逐渐增强,结合能的绝对值逐渐增大,体系的稳定性增加.在微观结构上,电子传递行为使层板中平均金属―氧键键长逐渐减小,且金属配位角的畸变情况得到一定程度的缓解,这些变化都有利于形成更稳定的体系,说明镍铝类水滑石在理论上比镁铝水滑石更稳定.