Fe-N共掺杂纳米碳材料的形貌对电化学还原反应的影响（英文）

众所周知,石墨烯片(GS)和碳纳米管是能源转化和储存应用中有效的催化剂.然而,过渡金属基氮(N)掺杂的体系中经常形成GS和碳纳米管的复合物,使得该体系内的构效关系研究变得十分困难.为了可控制备出含有理想物种的催化剂,作者尝试通过利用氮对碳纳米管生长的效应调节生成产物的形貌.本文中,作者采用一步法制备了一系列Fe-N共掺杂的GS、GS/竹节碳纳米管(BCNTs)复合物及BCNTs催化剂.为了评估碳形貌对催化剂性能的影响,作者采用氧气还原反应(ORR)及二氧化碳还原反应(CO2RR)作为模型反应.电化学测试结果表明,所有的样品当中仅含BCNTs的催化剂表现出最好的ORR活性(起始电位Eonset=1.02 VRHE)及CO2RR活性(CO生成法拉第效率FECO=91.1%,-0.6 VRHE).进一步的研究表明,优异的活性与独特的BCNTs中存在的缺陷、较大的比表面积、高含量的吡啶N及FeNx相关.该工作加深了作者对形貌相关的ORR及CO2RR过程的认识和理解.

ZrO_(2)纳米晶高效地催化电化学氮气还原成氨

通过电化学氮气还原反应合成氨,反应条件温和,反应过程中没有温室气体的排放,更满足“碳中和”和“碳达峰”的要求。但是,由于缺乏高效的电催化剂,产氨率和法拉第效率不高,限制该反应的工业应用。因此开发高效的催化剂是电化学氮气还原反应中非常关键但具有挑战性的课题。用简单易控的方法合成氧化锆纳米晶,并首次将氧化锆纳米晶作为电催化剂应用于电化学氮气还原反应中,实现了高效地氨合成。电化学测试结果表明,在0.1 mol/L的盐酸溶液中,氧化锆纳米晶的催化产氨量和法拉第效率均非常高,分别为27.93μg·h^(-1)·mg^(-1)和6.18%。

电化学氧化还原对废水中COD处理的研究进展

随着社会的进步,经济的迅速发展,人们对健康生活,绿色生活更加的注重。生活废水中不但含有大量的无机元素,还含有大量的有机物质,即化学需氧量(COD),较高的COD会超出水的自净能力,从而导致一系列的环境问题。传统的降解COD的方法是采用生化法,但是因为其成本高,针对性比较高,培养菌种的要求比较严格,导致不能大规模的推广,因此人们迫切需要寻找一种更加高效,快捷,经济的方法来取代传统的降解方法。本论文模拟生活废水的处理。采用3ml菜籽油与3000ml的蒸馏水混合为原料,电化学氧化还原反应的方法数据证明可以达到国家一级排放标准100mg/L。

中温固体氧化物燃料电池La_(1.6)Sr_(0.4)Ni_(1-x)Cu_xO_4阴极材料的制备及电化学性能

采用甘氨酸-硝酸盐法合成了中温固体氧化物燃料电池阴极材料La1.6Sr0.4Ni1-xCuxO4(x=0.2,0.4,0.6,0.8),利用X射线衍射(XRD)和扫描电子显微镜(SEM)对其结构和微观形貌进行了表征.结果表明,该阴极材料与固体电解质Ce0.9Gd0.1O1.95(CGO)在1000℃烧结时不发生化学反应,且烧结4h后,二者之间可形成良好的接触界面.利用电化学交流阻抗谱技术对阴极材料的电化学性能进行研究,结果显示,当Cu离子掺杂量(x)为0.6时,La1.6Sr0.4Ni0.4Cu0.6O4阴极具有最小的极化电阻,在空气中当测试温度为750℃时,极化电阻为0.35Ω·cm2.在不同氧分压条件下电化学阻抗谱分析结果表明,电极上的两个氧还原反应主要包含氧离子从三相界面向电解质CGO转移的过程和电荷的迁移过程,其中电荷的迁移过程为电极反应的速率控制步骤.La1.6Sr0.4Ni0.4Cu0.6O4电极在空气中700℃和阴极电流密度为45mA·cm-2时,阴极过电位为45mV.本研究的初步结果表明La1.6Sr0.4Ni1-xCuxO4材料是一种电化学性能较为优良的新型中温固体氧化物燃料电池(IT-SOFC)阴极材料.

草酸电还原制乙醇酸化学分析方法的研究

草酸阴极还原制乙醇酸的电解液可用简便的化学分析方法测定,其中草酸的定量可以钙盐沉淀后用高锰酸钾法测定;乙醛酸的定量用国家标准附以酸度计控制终点来测定;乙醇酸的定量用邻苯二甲酸酐来测定.本化学分析方法具有快速、简单、可靠的特点,具有重要的工业价值.

电催化CO_(2)还原立方体Cu_(2)O催化剂的制备及其在大面积膜电极反应器中的应用

电化学二氧化碳还原反应(carbon dioxide reduction reaction,CO_(2)RR)产乙烯目前已成为电催化CO_(2)RR领域的研究重点和热点.通过简单的化学沉淀耦合化学还原保护法成功获得了富含(111)晶面的立方体结构Cu_(2)O催化剂,系统研究了其在H型反应器以及零间距膜电极组件(membrane electrode assembly,MEA)反应器中的电化学性能.结果表明.富含(111)晶面的立方体结构Cu_(2)O催化剂表现出了优异的产乙烯活性;相比于H型反应器,零间距MEA反应器进行CO_(2)RR时的最佳法拉第效率(Faradaic efficiency,FE)提升了13.94%,总电流密度也基本可以满足工业化的需求(>200 mA/cm^(2));设计并组装的大面积(25 cm^(2))零间距MEA反应器在CO_(2)RR中表现出了优异的催化性能,且在槽压大于2.9 V时表现出了独特的“面积效应”.“面积效应”的出现表明零极距MEA反应器在有效面积放大时,除电极面积、电解质浓度、CO_(2)流速等关键因素的调控外,极板的流道设计、导电性优化等均可能会影响催化反应的电流密度.

苄基氯在银电极上电还原反应中间体的SERS光谱理论研究

以苄基自由基和苄基阴离子为研究对象,通过理论模拟的表面增强拉曼光谱(SERS),研究了这两种电还原中间体在银电极的吸附作用。该理论计算结果不仅为这两种中间体提供了更加完整的振动归属,而且进一步揭示了CH2面外弯曲振动呈现出大的频率位移和强的拉曼信号增强的原因。这个强的SERS谱带与CH2面外弯曲振动和苯环上C—H面外弯曲振动模的耦合相关,也与CH2基团与银表面吸附位的作用强度有关。

集成反应分离制备甘露醇的多元分流式装备开发

为优化现有生产过程中的产率、能耗与排放等综合性问题,自主提出一种将电化学还原反应与连续色谱分离相耦合的新工艺,结合机电一体化控制技术,研制出一种将反应分离耦合来制备甘露醇的多元分流式机电装备。其结构简单、操作简捷、过程绿色、节能减排、自动化程度高,可获取甘露醇纯度达93%以上,同时完全利用原料葡萄糖和甘露醇收率接近100%,具有理想的应用前景和推广价值。

CO_(2)捕集及电催化还原制甲酸研究进展

CO_(2)捕集与CO_(2)电催化还原技术是减少碳排放、提高碳的可再生循环利用率的重要途径.两种技术既独立存在,又可以作为碳循环周期中的上下环节相互结合,即先捕集并提纯混合气中的CO_(2),然后将收集到的高纯度CO_(2)进行电催化还原反应,将其进一步转化为更有用的化学品.本文首先总结了CO_(2)捕集技术的研究现状,然后考虑到甲酸作为目前经济和技术上最具潜力的还原产物,调研并汇总了近年来在CO_(2)电还原制甲酸领域中关于高效电催化剂的制备和反应器件设计方面取得的研究进展.针对两种技术的研究现状,最后提出加快和开发新型碳捕集与利用技术,开发低成本、高效、稳定的电催化剂和设计具有低欧姆电阻、高转化能效的反应器等可以作为未来的研究重点和发展方向.

新型有机聚合物电致发光材料聚(2,3-二芳基-富马氰)的合成、表征及性能研究

利用标准Suzuki反应条件,通过双(4-溴苯基)富马氰和系列芳香族硼酸酯偶合,得到系列聚(2,3-二芳基富马氰).所获得的4种聚合物的合成收率均超过70%,数均分子量Mn为8400～140000;特性粘数[η]为0.31～0.77dLg-1(甲苯,30℃).聚合物溶于普通有机溶剂,具有良好的成膜性.4种聚合物的甲苯溶液显示相似的UV-vis光谱(λmax=413 nm).荧光光谱显示,甲苯溶液中,聚合物的最大发射波长在约544 nm处,荧光量子收率＞30%.聚合物薄膜的最大发射波长为560 nm.粉末X衍射显示,聚合物在2θ＜7°区产生较强的衍射峰,这些小角区的衍射峰所对应的烷氧基侧链间距d1和烷氧基侧链的碳原子数n显现良好的线性关系.热重分析(TGA)显示,氮气中,聚合物的5%重量损失温度＞340℃.电化学分析(CV)表明,在0.1 M支持电解质[Bu4N]BF4的乙腈溶液中,聚合物薄膜的氧化开始于0.68V(相对于Ag+/Ag电极),最大氧化峰值电位为1.03V;在0～-2.5V区域,聚合物的还原始于-1.34V,并在-1.65和-2.03V处给出两个峰值电位.相应的去还原电位为-1.67和-1.33 V.

劳伦斯伯克利国家实验室开发从CO_(2)中选择性地生成C_(2)化合物的层状催化剂

虽然铜催化的电化学还原反应为从CO_(2)制造有价值的化学品(例如乙醇或乙烯)提供了途径,然而,选择性地生成足够收率的C_(2)产物需要精确操控表面附近的微环境,从而更好地控制反应活性和产物选择性。劳伦斯伯克利国家实验室(LBL,Berkeley)的最新研究取得进展,其结果显示一种催化剂体系在C_(2)产品的活性和选择性方面远远超过了单一的铜催化剂体系。

自组装制备硅纳米线阵列及其光致发光特性研究

用微电化学催化腐蚀法制备了硅纳米线阵列,通过扫描电镜(SEM)观察了样品的表面形貌。用荧光光谱仪测量了有序硅纳米线阵列的光致发光特性,发现当激发波长增加时,有序硅纳米线阵列的光致发光峰位单调红移,发光强度也单调增强。对比多孔硅的发光机理和现有实验条件,对有序硅纳米线阵列可能的发光机理进行了讨论。

Preparation of nitrogen-doped carbon nanoblocks with high electrocatalytic activity for oxygen reduction reaction in alkaline solution

The oxygen reduction reaction （ORR） is traditionally performed using noble‐metals catalysts, e.g. Pt. However, these metal‐based catalysts have the drawbacks of high costs, low selectivity, poor stabili‐ties, and detrimental environmental effects. Here, we describe metal‐free nitrogen‐doped carbon nanoblocks （NCNBs） with high nitrogen contents （4.11%）, which have good electrocatalytic proper‐ties for ORRs. This material was fabricated using a scalable, one‐step process involving the pyrolysis of tris（hydroxymethyl）aminomethane （Tris） at 800℃. Rotating ring disk electrode measurements show that the NCNBs give a high electrocatalytic performance and have good stability in ORRs. The onset potential of the catalyst for the ORR is-0.05 V （vs Ag/AgCl）, the ORR reduction peak potential is-0.20 V （vs Ag/AgCl）, and the electron transfer number is 3.4. The NCNBs showed pronounced electrocatalytic activity, improved long‐term stability, and better tolerance of the methanol crosso‐ver effect compared with a commercial 20 wt%Pt/C catalyst. The composition and structure of, and nitrogen species in, the NCNBs were investigated using Fourier‐transform infrared spectroscopy, scanning electron microscopy, X‐ray photoelectron spectroscopy, and X‐ray diffraction. The pyroly‐sis of Tris at high temperature increases the number of active nitrogen sites, especially pyridinic nitrogen, which creates a net positive charge on adjacent carbon atoms, and the high positive charge promotes oxygen adsorption and reduction. The results show that NCNBs prepared by pyrolysis of Tris as nitrogen and carbon sources are a promising ORR catalyst for fuel cells.

Transition metal-nitrogen sites for electrochemical carbon dioxide reduction reaction

Electrochemical CO2 reduction reaction(CO2RR)powered by renewable electricity has emerged as the most promising technique for CO2 conversion,making it possible to realize a carbon‐neutral cycle.Highly efficient,robust,and cost‐effective catalysts are highly demanded for the near‐future practical applications of CO2RR.Previous studies on atomically dispersed metal‐nitrogen(M‐Nx)sites constituted of earth abundant elements with maximum atom‐utilization efficiency have demonstrated their performance towards CO2RR.This review summarizes recent advances on a variety of M‐Nx sites‐containing transition metal‐centered macrocyclic complexes,metal organic frameworks,and M‐Nx‐doped carbon materials for efficient CO2RR,including both experimental and theoretical studies.The roles of metal centers,coordinated ligands,and conductive supports on the intrinsic activity and selectivity,together with the importance of reaction conditions for improved performance are discussed.The mechanisms of CO2RR over these M‐Nx‐containing materials are presented to provide useful guidance for the rational design of efficient catalysts towards CO2RR.

含2-N,N-二甲氨基嘧啶环与噻吩环结构的共轭聚合物的合成及其性能

合成了一种新型单体2-N,N-二甲氨基-4,6-二氯嘧啶(ADNP)。以二氯-1,3-双(二苯基磷)丙烷基镍(Ⅱ)作催化剂,通过2,5-二溴噻吩格氏试剂与该单体共聚得到了一种新型共轭聚合物,聚[(2-N,N-二甲胺基嘧啶-4,6-二)-2,5-噻吩](PThPm)。采用FT-IR、1H-NMR等测试手段对新型单体与共聚物的结构进行了表征,并用UV-Vis、荧光光谱、X射线衍射、循环伏安、热重分析(TGA)等测试方法对单体和共聚物进行了性能分析。结果表明:共聚物在420nm处出现UV-Vis吸收峰,在528nm处出现荧光发射峰;共聚物的DMF溶液存在酸致变色现象,加入CF3COOH和CH3SO3H后,溶液由淡绿黄色转变为淡红色,UV-Vis吸收峰发生红移;PThPm共聚物有一定的结晶性和热稳定性;在-1.8^+1.8V之间出现电致变色现象,电极周围的溶液颜色从深蓝色变成深红色。

氧空位Co_(3)O_(4)纳米线阵列的制备及其高效电催化合成氨

室温下的电化学氮还原反应(NRR)为合成氨提供了一条温和的途径。然而,常温常压下电化学NRR的活性和选择性较差。过渡金属氧化物上的氧空位可以为N;分子的吸附和活化提供独特的活性位点。制备了一种氧空位Co_(3)O_(4)(V-Co_(3)O_(4))纳米线阵列。喇曼光谱和X射线光电子能谱(XPS)测试显示氧空位可以稳定地存在于V-Co_(3)O_(4)纳米线阵列上。电化学测试表明,V-Co_(3)O_(4)具有高效的电化学氮还原反应活性和选择性。在工作电极上施加-0.3 V时,氨的产量高达10.9μg·h;·cm^(-2),法拉第效率为6.3%。这种低成本的过渡金属氧化物是有前途的固氮催化剂之一。

Magneli phase titanium sub-oxide conductive ceramic Ti_nO_(2n-1) as support for electrocatalyst toward oxygen reduction reaction with high activity and stability

Magneli phase titanium sub-oxide conductive ceramic Tin O2n-1 was used as the support for Pt due to its excellent resistance to electrochemical oxidation, and Pt/Tin O2n-1 composites were prepared by the impregnation-reduction method. The electrochemical stability of Tin O2n-1 was investigated and the results show almost no change in the redox region after oxidation for 20 h at 1.2 V(vs NHE) in 0.5 mol/L H2SO4 aqueous solution. The catalytic activity and stability of the Pt/Tin O2n-1 toward the oxygen reduction reaction(ORR) in 0.5 mol/L H2SO4 solution were investigated through the accelerated aging tests(AAT), and the morphology of the catalysts before and after the AAT was observed by transmission electron microscopy. At the potential of 0.55 V(vs SCE), the specific kinetic current density of the ORR on the Pt/Tin O2n-1 is about 1.5 times that of the Pt/C. The LSV curves for the Pt/C shift negatively obviously with the half-wave potential shifting about 0.02 V after 8000 cycles AAT, while no obvious change takes place for the LSV curves for the Pt/Tin O2n-1. The Pt particles supported on the carbon aggregate obviously, while the morphology of the Pt supported on Tin O2n-1 remains almost unchanged, which contributes to the electrochemical surface area loss of Pt/C being about 2times that of the Pt/Tin O2n-1. The superior catalytic stability of Pt/Tin O2n-1 toward the ORR could be attributed to the excellent stability of the Tin O2n-1 and the electronic interaction between the metals and the support.

A combinatorial descriptor for volcano relationships of electrochemical nitrogen reduction reaction

Though touted as a potential way to realize clean ammonia synthesis,electrochemical ammonia synthesis is currently limited by its catalytic efficiency.Great effort has been made to find catalysts with improved activity toward electrochemical nitrogen reduction reaction(eNRR).Rational screening of catalysts can be facilitated using the volcano relationship between catalytic activity and adsorption energy of an intermediate,namely,the activity descriptor.In this work,we proposeΔG^(*)_(NH_(2))+ΔG^(*)_(NNH)as a combinatorial descriptor,which shows better predictive power than traditional descriptors using the adsorption free energies of single intermediates.The volcano plots based on the combinatorial descriptor exhibits peak activity fixedly at the descriptor value corresponding to the formation free energy of NH3,regardless of the catalyst types;while the descriptor values correspond to the top activities for eNRR on volcano plots based on single descriptors usually vary with the types of catalysts.

Study on Kinetics of Cathodic Reduction of Dissolved Oxygen in 3.5% Sodium Chloride Solution

Electrochemical reduction of dissolved oxygen in seawater on metals is of great importance for corrosion studies. The present paper studied cathodic reduction of dissolved oxygen on Q235 carbon steel in 3.5% sodium chloride （NaCl） solutions by cyclic voltammetry （CV）, electrochemical impedance spectroscopy （EIS）, rotating disk electrode （RDE） and rotating ring-disk electrode （RRDE）. The cyclic voltammetric results demonstrated the cathodic process on Q235 carbon steel in O2-saturated 3.5% NaCl solution contains three reactions： dissolved oxygen reduction, iron oxides reduction and hydrogen evolution. The peak potential of oxygen reduction reaction （ORR） is - 0.85 V vs Ag/AgCl, 3 molL^-1 KCI. The EIS results indicated that the ORR occurring on Q235 carbon steel is a 4-electron process and that no finite diffusion is caused by the intermediate of H2O2 produced by ORR. The RDE and RRDE voltammograms confirmed the EIS results and it was found that the number of transferred electrons for ORR was nearly 4, i.e., dissolved oxygen reduced to water.

不同浸渍时间对CuO/Cu@BC电极催化CO2还原性能的影响

将具有3D网状结构的细菌纤维素(BC)膜作为催化剂载体,通过原位化学还原法制备了负载Cu和Cu O纳米复合材料的催化剂电极(Cu O/Cu@BC),并通过改变BC膜的浸渍时间实现电极结构调控以探索最佳条件。结果表明,具有3D球形结构的Cu O/Cu24h@BC电极对CO2还原表现出较好的电子传输性能和更高的电流密度。Cu O/Cu24h@BC电极的电化学比表面积最大,达12 mF/cm2。Cu O/Cu24h@BC电极可将CO2电催化转化为CO,且产生CO的法拉第效率为52%。