玻纤负载α-Fe_(2)O_(3)/CuFe_(2)O_(4)异质结薄膜的制备 及其催化性能

为了克服传统芬顿催化剂的降解速率慢、pH适用范围窄、难回收等缺点,采用浸涂溶胶-凝胶法制备了玻璃纤维负载的α-Fe_(2)O_(3)/CuFe_(2)O_(4)异质结薄膜(FCGF),对其结构、形态和化学组成进行表征,并将其用于亚甲基蓝的光芬顿催化降解,考察其催化活性、pH值适用性和重复使用稳定性。结果表明:CuFe2O4颗粒生长在α-Fe_(2)O_(3)颗粒表面,形成α-Fe_(2)O_(3)/CuFe_(2)O_(4)异质结;在模拟太阳光辐射条件下,加入2 g FCGF和20 mmol/L的H_(2)O_(2),50 mL质量浓度为30 mg/L的MB溶液在40 min后降解率达到97%,而在相同条件下加入α-Fe_(2)O_(3)与CuFe_(2)O_(4)降解率分别为20%和30%,其催化活性的增强可归因于异质结光催化剂产生的光诱导电位差驱动的光生载流子的有效分离;同时,FCGF在宽pH范围显示出较高活性,pH=10时,MB溶液40 min后降解效率仍达到63%;FCGF具有良好的稳定性,5次循环后其催化性能没有衰减,反应40 min后MB降解率仍可达97%。

CuFe_(2)O_(4)改性荔枝壳生物炭对水中盐酸四环素的吸附研究

为实现“以废治污”的目标,以废弃荔枝壳为原料制备生物炭(BC),并采用共沉淀法制备出CuFe_(2)O_(4)改性荔枝壳生物炭复合吸附材料(CuFe_(2)O_(4)@BC)用于水体中盐酸四环素(TCH)的去除。通过BET、SEM-EDS、XRD、FTIR分析了复合吸附材料的微观结构和理化特性,证实了CuFe_(2)O_(4)在荔枝壳生物炭上成功合成且分布均匀。考察了溶液pH、材料投加量、环境温度等因素对CuFe_(2)O_(4)@BC吸附TCH性能的影响,结果表明,相较于改性前BC,CuFe_(2)O_(4)@BC对TCH的吸附能力显著提升,且当pH=5、投加量为0.7 g/L、温度为298 K时,对20 mg/L TCH的去除率达86.34%。吸附过程更符合准二级动力学模型和Freundlich等温模型,吸附过程是以化学吸附为主导的多分子层吸附。

CuFe_(2)O_(4)氧载体与小麦秆-煤化学链共气化研究

以小麦秆与印尼褐煤为原料,制备具有尖晶石结构的CuFe_(2)O_(4)复合氧载体,在自制多功能反应器上,系统研究了CuFe_(2)O_(4)氧载体反应活性及小麦秆和印尼褐煤化学链共气化特性,重点关注小麦秆和煤不同掺混比、气化温度、氧载体过量系数和水蒸气输入量这4个关键运行参数的影响。结果表明:CuFe_(2)O_(4)复合氧载体中Cu-Fe的协同作用有助于晶格氧的有效传递和反应活性的提升,而小麦秆和印尼褐煤化学链共气化时碳转化率及冷煤气效率比单一燃料的大,促进了高品质合成气的形成;小麦秆和褐煤在与CuFe_(2)O_(4)化学链气化过程中的最优运行参数为共气化温度950℃、氧载体过量系数0.2、水蒸气通入体积流量0.125 mL/min、小麦秆-印尼褐煤掺混质量比1∶1,在此最优条件下,合成气产量高达1.262 m^(3)/kg,H_(2)与CO体积比为1.69,碳转化率为89.7%,合成气选择性为63.2%。

Carbon-doped CuFe_(2)O_(4) with C-O-M channels for enhanced Fenton-like degradation of tetracycline hydrochloride: From construction to mechanism

Carbon-doped copper ferrite(C–CuFe_(2)O_(4))was synthesized by a simple two-step hydrothermal method,which showed enhanced tetracycline hydrochloride(TCH)removal efficiency as compared to the pure CuFe_(2)O_(4) in Fenton-like reaction.A removal efficiency of 94%was achieved with 0.2 g L^(-1) catalyst and 20 mmol L^(-1) H_(2)O_(2) within 90 min.We demonstrated that 5%C–CuFe_(2)O_(4) catalyst in the presence of H_(2)O_(2) was significantly efficient for TCH degradation under the near-neutral pH(5–9)without buffer.Multiple techniques,including SEM,TEM,XRD,FTIR,Raman,XPS M€ossbauer and so on,were conducted to investigate the structures,morphologies and electronic properties of as-prepared samples.The introduction of carbon can effectively accelerate electron transfer by cooperating with Cu and Fe to activate H_(2)O_(2) to generate·OH and·O_(2)^(-).Particularly,theoretical calculations display that the p,p,d orbital hybridization of C,O,Cu and Fe can form C–O–Cu and C–O–Fe bonds,and the electrons on carbon can transfer to metal Cu and Fe along the C–O–Fe and C–O–Cu channels,thus forming electron-rich reactive centers around Fe and Cu.This work provides lightful reference for the modification of spinel ferrites in Fenton-like application.

CuFe_(2)O_(4)/Al_(2)O_(3)非均相活化过一硫酸盐降解盐酸四环素

基于过一硫酸盐的高级氧化工艺因其在环境修复中的独特优势而引起了广泛的研究兴趣。然而开发低成本、高效的催化剂活化过一硫酸盐仍是降解有机污染物的关键问题。采用柠檬酸溶胶-凝胶法成功合成了一种磁性可回收复合材料(即Cu Fe_(2)O_(4)/Al_(2)O_(3)),并首次作为一种非均相催化剂用于活化过一硫酸盐(PMS)降解水中盐酸四环素(TC·HCl)。用X射线衍射仪研究了复合材料晶体结构和相形成。系统考察了PMS浓度、催化剂投加量和初始溶液p H对催化活性的影响以及不同水基质下对TC·HCl的降解影响。结果表明,在PMS浓度为0.3 g/L、Cu Fe_(2)O_(4)/Al_(2)O_(3)投加量为0.2 g/L、初始溶液p H为4.7的最佳条件下,反应10 min后Cu Fe_(2)O_(4)/Al_(2)O_(3)/PMS体系可降解约95.1%的TC·HCl。循环实验和磁性测试结果表明,Cu Fe_(2)O_(4)/Al_(2)O_(3)具有良好的稳定性和磁性。因此,Cu Fe_(2)O_(4)/Al_(2)O_(3)可作为一种高效催化剂非均相活化PMS处理含TC·HCl废水。

CuFe_(2)O_(4)粉末催化电化学氧化降解氯霉素性能研究

氯霉素因抗菌作用良好、生产成本低廉而得到广泛运用,但因为其降解效率较低,在水中检出频率很高,所以对人和环境造成了一定的影响。本文制备的CuFe_(2)O_(4)粉末既可以作为粒子电极,也可以作为活化过硫酸盐(PS)的催化剂,应用在电化学体系(EC)中可催化氧化降解废水中的氯霉素。本文系统研究了操作参数对氯霉素的影响。在CuFe_(2)O_(4)粉末添加量为3.0 g/L,PS浓度为0.004 mol/L,初始pH值为5,恒定电流为0.05 A的曝气状态下,通过180 min处理后氯霉素的去除率为100%。简而言之,EC/CuFe_(2)O_(4)/PS系统可以有效应用于修复被氯霉素污染的地表水和地下水。

CuFe_(2)O_(4)改性脱硫渣氧载体与褐煤的反应特性

基于烟气脱硫渣采用改进的提纯工艺和优化参数获得高纯度和反应活性的CaSO_(4),以此作为模板剂结合溶胶凝胶燃烧合成法制备了CuFe_(2)O_(4)改性活化并具有“核-壳”结构的CaSO_(4)-CuFe_(2)O_(4)混合氧载体。在固定床反应器上研究了还原反应温度和循环次数作用下自制CaSO_(4)-CuFe_(2)O_(4)混合氧载体与煤化学链燃烧特性,系统研究了CaSO_(4)副反应与CuFe_(2)O_(4)交互作用下不同气相硫的释放和演化。研究表明,改性脱硫渣与煤反应时,CuFe_(2)O_(4)还原产物Cu、FeO通过未反应CaSO_(4)及已还原的CaS形成的熔融界面获得了其中未能利用的晶格氧,实现了本身的原位氧化,不仅明显提高了改性脱硫渣的反应活性,促进了煤的转化,同时也促进了未反应CaSO_(4)中晶格氧的定向传递和梯级利用。进一步,综合考虑煤的碳转化率以及气相硫的释放特性,确定了改性脱硫渣与煤的最佳反应条件为900℃。而循环实验发现,CaSO_(4)-CuFe_(2)O_(4)氧载体在多次循环中CaSO_(4)副反应不能完全抑制,少量气相硫的逸出加之还原氧载体的部分烧结导致反应活性衰减。

MgX_(2)O_(4)(X=Cr、Fe、Mn)型尖晶石B位点阳离子对乙烷化学链氧化脱氢生成乙烯的影响

化学链循环氧化脱氢技术(CL-ODH)是一个多功能的平台,它可以利用载氧体中晶格氧的选择性氧化这一特性,实现乙烷向乙烯的高值化转化。本研究探讨了MgX_(2)O_(4)(X=Cr、Fe或Mn)型尖晶石载氧体中B位元素对乙烷CL-ODH性能的影响。采用固定床和H_(2)-TPR、O_(2)-TPD、TG、原位拉曼、SEM、TEM等方法对MgX_(2)O_(4)尖晶石进行了性能测试和表征。结果表明,MgCr_(2)O_(4)仅释放微量表面吸附氧,更倾向于催化乙烷转化为焦炭和氢气。MgFe_(2)O_(4)通过提供更多的表面晶格氧,促进乙烷深度氧化成CO_(2)。MgMn_(2)O_(4)载氧体在乙烷CL-ODH反应中能够释放出大量的体相晶格氧,它可以选择性燃烧氢气以推进反应正向进行,增加乙烯的选择性,实现了73.72%的乙烷转化率和81.46%的乙烯选择性。此外,MgMn_(2)O_(4)催化剂在乙烷CL-ODH反应中进行了30次的氧化还原循环实验,表现出稳定的反应性能,在整个循环测试中乙烯收率大约为62.00%。MgX_(2)O_(4)尖晶石氧化物中B位元素影响了其晶格氧的供应能力,从而影响了其在乙烷CL-ODH反应中的性能。

富含氧空位的Bi_(4)O_(5)Br_(2)超薄纳米片用于高效压电催化生成过氧化氢

过氧化氢是一种重要的化工原料,广泛应用于工业和生活中的多个领域.然而,目前工业上主要采用蒽醌法生产过氧化氢,该过程存在高污染和高能耗等问题.为解决上述问题,研发人员一直致力于开发新的、环保的过氧化氢生产方法.近年研究发现,压电催化生产过氧化氢是一种有前途的过氧化氢生产策略,但较低的能量转换效率阻碍了其进一步应用.Bi_(4)O_(5)Br_(2)材料因具有独特的层状晶体结构,高的化学稳定性,良好的可见光吸收及合适的能带结构被认为是具有较好应用前景的光催化材料.虽然Bi_(4)O_(5)Br_(2)的非中心对称结构赋予其独特的压电性能,但该特性往往被研究者忽视,导致其压电潜力未被充分利用.特别是,关于缺陷工程如何影响Bi_(4)O_(5)Br_(2)的压电性能仍存在许多未知之处,需要深入挖掘和探明.本文通过调节水热过程中乙二醇和水溶剂的比例构建了含有不同浓度氧空位的超薄Bi_(4)O_(5)Br_(2)(≈5 nm)纳米片,并研究其在纯水体系中的压电催化生成过氧化氢性能.X射线粉末衍射和高分辨率透射电镜结果证明Bi_(4)O_(5)Br_(2)催化剂的成功合成;X射线光电子能谱和电子顺磁共振(EPR)结果证明氧空位的成功构建.不同气氛下的催化性能实验、活性物种EPR测试和捕获实验结果均表明,过氧化氢的生成主要通过氧还原反应,同时需要水氧化反应的协同作用.此外,旋转环盘电流测试和捕获实验结果进一步表明,过氧化氢的生成主要通过两步单电子的氧还原反应.同时,压电力显微镜和多物理场仿真软件有限元模拟结果表明,超薄结构和氧空位共同增强了所制样品的压电响应和压电电势,因此促进了压电诱导的电荷分离和转移,进而产生更大的压电电流响应和更小的电化学阻抗.差分电荷和Bader电荷研究结果表明,氧空位的存在增强了催化剂与氧气之间的电荷传输和相互作用.密度泛函理论计算结果表明,氧空位增强了催化剂对氧气的吸附和活化能力,并大幅降低反应过程的吉布斯自由能.具有最优氧空位浓度的Bi_(4)O_(5)Br_(2)超薄纳米片表现出很好的催化生成过氧化氢性能,在纯水体系中过氧化氢的生成速率为620μmol g^-(1)h^(-1)(是不含氧空位Bi_(4)O_(5)Br_(2)的2.54倍),在牺牲体系中的生成速率为2700μmol g^-(1)h^(-1),催化性能优于大多数已报道的压电催化剂.综上,本文揭示了Bi_(4)O_(5)Br_(2)作为新型压电催化剂在高效合成过氧化氢中的潜力,丰富了压电催化合成过氧化氢的材料体系,同时为探索缺陷工程和纳米结构协同增强材料压电催化活性提供了参考.

CuBi_(2)O_(4)/Bi_(2)WO_(6)Z型异质结用于光电类芬顿体系下高效降解环丙沙星

针对目前水环境中抗生素污染严重的问题,使用简单的溶剂热法制备了CuBi_(2)O_(4)/Bi_(2)WO_(6)(CBWO)Z型异质结催化剂.扫描电子显微镜分析结果表明,其结构为棒状和纳米片状.能量色散元素图谱显示,Cu,W,Bi和O元素均匀分散在CBWO-60中;使用X射线衍射和傅里叶变换红外光谱探究了催化剂的晶体结构和化学键、官能团组成;BET表征结果证明,CBWO-60具有较高的比表面积.X射线光电子能谱(XPS)证明Cu^(+)和Cu^(2+)共存,促进了芬顿(Fenton)反应的循环进行,XPS结合能的位移证明了异质结中CuBi_(2)O_(4)和Bi_(2)WO_(6)之间具有强的电子相互作用,而不是物理混合;使用紫外⁃可见漫反射光谱和价带-X射线光电子能谱分析了异质结的能带结构;利用光致发射光谱、电化学阻抗谱和瞬态光电流响应谱探究了催化剂的电荷转移情况.在该系列催化剂中,CBWO-60在光电类芬顿(PEF-like)体系中对环丙沙星(CIP)的降解效率最高,90 min时,降解效率为98.0%.同时,溶液初始pH在2~6范围时,体系始终能够维持有效的CIP去除效率,与传统芬顿体系相比,该体系的pH应用范围得到了有效拓宽.在PEF-like体系中,CBWO-60对喹诺酮类、磺胺类和四环素类抗生素均表现出较强的降解能力,充分证明了CBWO-60的普适性.CBWO-60在连续5次循环实验后,对CIP仍保持87.8%的降解率,并且反应后催化剂的晶体结构没有发生改变.根据高效液相色谱⁃质谱的结果,提出了CIP降解的5种可能途径.

生物炭负载CuFe_(2)O_(4)催化过硫酸氢钾降解罗丹明B

采用柠檬酸络合法制备了尖晶石CuFe_(2)O_(4)改性生物炭(CuFe_(2)O_(4)@PBC)材料,利用XRD、SEM和XPS表征催化剂的形貌和结构。研究了不同因素对CuFe_(2)O_(4)@PBC催化过硫酸氢钾降解罗丹明B(RhB)的影响。分析结果表明,RhB初始浓度为10 mg/L,催化剂投加量为0.2 g/L,PMS浓度为0.5 mmol/L时,在中性(pH=7)条件下反应90 min可降解98.6%的RhB。CuFe_(2)O_(4)@PBC/PMS体系具有良好的pH适应能力和抵抗外界环境影响的能力。自由基猝灭实验分析证明^(1)O_(2)、O_(2)^(·-)和SO_(4)^(·-)是降解RhB的主要活性自由基。循环利用实验表明催化剂经过四次重复使用后仍然能够保持85%以上的降解率。

脱硫渣-CuFe_(2)O_(4)混合载氧体煤化学链燃烧性能

将脱硫石膏中废弃的CaSO_(4)加以资源化利用,制备成钙基载氧体应用于化学链燃烧,具有原料易得、成本低廉和载氧率高的特点。以脱硫渣为原料,先进行提纯处理,根据课题组采用的模板-溶胶凝胶燃烧合成法制备CaSO_(4)-CuO、CaSO_(4)-Fe_(2)O_(3)、CaSO_(4)-CuFe_(2)O_(4)混合载氧体。在高温固定床反应器上对这4种载氧体与煤进行了5次还原氧化循环试验,研究4种脱硫渣系列煤化学链的反应机理和硫释放规律。试验发现基于提纯后的脱硫渣,制备的脱硫渣-CuO反应活性明显提高,且负载CuO减少了含硫气体的释放;脱硫渣-Fe_(2)O_(3)提高了氧载体反应活性对煤气化的催化作用;脱硫渣-CuFe_(2)O_(4)混合载氧体提高了碳转化率,具有良好的反应活性和循环特性,应用于煤化学链燃烧完全可行;掺入Cu、Fe元素的脱硫渣载氧体,活性明显提高,但在多次循环过程中混合载氧体出现了部分烧结、失活现象;在脱硫渣混合载氧体与煤的副反应中,Cu、Fe元素表现出良好的固硫效果,其中脱硫渣-CuFe_(2)O_(4)混合载氧体与煤副反应中,释放的SO_(2)气体体积分数峰值仅为37×10^(-6)。

CuFe_(2)O_(4)/硅藻土复合材料活化过一硫酸盐降解酸性橙

通过柠檬酸辅助溶胶-凝胶法制备了一种磁性复合材料CuFe_(2)O_(4)/硅藻土(CFD)。通过SEM、XRD、FTIR、XPS表征了其微观形貌结构和元素价态,考察了不同氧化体系、CFD质量浓度、过一硫酸盐(PMS)质量浓度、溶液初始pH、反应温度、阴离子种类对CFD降解酸性橙7(AO7)的影响,探讨了CFD降解AO7的机制。结果表明,CFD上的球形颗粒CuFe_(2)O_(4)能够分散地负载在硅藻土表面上,减少了CuFe_(2)O_(4)的团聚,且CFD上的表面羟基及Fe^(3+)/Fe^(2+)、Cu^(2+)/Cu^(+)/之间的价态循环参与了PMS的活化。在CFD质量浓度为0.50 g/L、溶液初始pH为6.68、PMS质量浓度为0.30 g/L、AO7质量浓度为50 mg/L、反应温度为30℃的条件下,60 min时100 mL该体系对AO7的降解率为96.88%,CFD+PMS体系降解AO7过程符合准一级动力学模型,其对AO7的降解速率常数比CuFe_(2)O_(4)+PMS体系提升了1.98倍。CFD+PMS体系具有较广的pH适用范围(5~11)和较低的活化能(31.77 kJ/mol)。降解过程的主要活性物质为单线态氧(^(1)O_(2))和·O_(2)^(–),同时也有SO_(4)^(–)·、·OH产生。

In situ confined vertical growth of Co_(2.5)Ni_(0.5)Si_(2)O_(5)(OH)_(4)nanoarrays on rGO for an efficient oxygen evolution reaction

Rational design of oxygen evolution reaction(OER)catalysts at low cost would greatly benefit the economy.Taking advantage of earth-abundant elements Si,Co and Ni,we produce a unique-structure where cobalt-nickel silicate hydroxide[Co_(2.5)Ni_(0.5)Si_(2)O_(5)(OH)_(4)]is vertically grown on a reduced graphene oxide(rGO)support(CNS@rGO).This is developed as a low-cost and prospective OER catalyst.Compared to cobalt or nickel silicate hydroxide@rGO(CS@rGO and NS@rGO,respectively)nanoarrays,the bimetal CNS@rGO nanoarray exhibits impressive OER performance with an overpotential of 307 mV@10 mA cm^(-2).This value is higher than that of CS@rGO and NS@rGO.The CNS@rGO nanoarray has an overpotential of 446 mV@100 mA cm^(-2),about 1.4 times that of the commercial RuO_(2)electrocatalyst.The achieved OER activity is superior to the state-of-the-art metal oxides/hydroxides and their derivatives.The vertically grown nanostructure and optimized metal-support electronic interactions play an indispensable role for OER performance improvement,including a fast electron transfer pathway,short proton/electron diffusion distance,more active metal centers,as well as optimized dualatomic electron density.Taking advantage of interlay chemical regulation and the in-situ growth method,the advanced-structural CNS@rGO nanoarrays provide a new horizon to the rational and flexible design of efficient and promising OER electrocatalysts.

Reaction characteristics investigation of CeO_(2)-enhanced CaSO_(4) oxygen carrier with lignite

Calcium sulfate(CaSO_(4))has been verified as a promising oxygen carrier(OC)in the chemical looping combustion(CLC)for its high oxygen capacity,abundant reserve and low cost,but its low reactivity and deleterious sulfur species emission from the side reactions of CaSO_(4) should be well considered for its wide application in CLC.In order to promote the reactivity of CaSO_(4) and increase its potential to inhibit the gaseous sulfur emission,a CeO_(2)-enhanced CaSO_(4) OC mixed OC of core–shell structure was prepared using the combined template synthesis method.Reaction characteristics of the prepared CaSO_(4)-CeO_(2) mixed OC with a typical lignite was first conducted and systematically investigated,and an improved reactivity of the prepared CaSO_(4)-CeO_(2) mixed OC was demonstrated than its single component CaSO_(4) or CeO_(2) due to the fast transfer and exchange of oxygen from the CaSO_(4) substrate to coal via the doped CeO_(2).Furthermore,the solid products formed from the mixed CaSO_(4)-CeO_(2) OC with the selected coal were collected and analyzed.Especially,evolution and redistribution of the sulfur species of different forms were focused.At the latter reaction stage of YN reaction with the CaSO_(4)-CeO_(2) mixed OC,the SO_(2) emitted from the side reactions of CaSO_(4) was greatly diminished and the doped CeO_(2) was proven effective to directionally fix the SO_(2) released to turn into different solid sulfur compounds,which were determined as Ce_(2)O_(2)S,Ce_(2)S_(3) and Ce_(2)(SO_(4))_(3)·5H_(2)O and formed through the different pathways.In addition,good regeneration of the reduced CaSO_(4)-CeO_(2) mixed OC could be reached in spite of the unavoidable interaction between the included minerals in coal and the reduced mixed OC.Overall,the combined template method-made CaSO_(4)-CeO_(2) mixed OC reported herein was not only endowed with enhanced reactivity for coal conversion,but also owned the potential to directionally fix the gaseous sulfur emission,which is quite applicable as OC for simultaneous decarbonatization and desulfurization in the real CLC process.

Co_(2)P_(4)O_(12)/NF纳米线阵列的制备与电解水性能研究

以CoCl_(2)·6H_(2)O为原料,通过溶剂热法和磷化工艺在泡沫镍表面构建Co_(2)P_(4)O_(12)阵列,Co_(2)P_(4)O_(12)纳米线直径约200 nm。采用SEM、TEM和XRD进行形貌和晶体学特性表征,并利用三电极体系在碱性环境下测量电化学性能。在析氢过程中,只需要122 mV过电位就能达到10 mA·cm^(-2)电流密度。析氧过程中,仅需要334 mV的过电位就能达到15 mA·cm^(-2)电流密度。组装的电解池在15 mA·cm^(-2)的电流密度下工作40 h后电解槽电压没有发生明显变化,展现出很好的稳定性。Co_(2)P_(4)O_(12)/NF是一种有潜力的双功能催化剂。

CeO_(2)/CuFe_(2)O_(4)氧载体CH_(4)化学链重整耦合CO_(2)热催化还原研究

CH_(4)化学链重整耦合CO_(2)热催化还原,既能灵活调控所制备合成气的H_(2)/CO比,又能实现两种温室气体的高值化利用,具有极大的应用前景。采用溶胶-凝胶燃烧合成法制备不同质量掺杂比的CeO_(2)/CuFe_(2)O_(4)氧载体,在自制多功能固定床反应器中,系统考察了改性氧载体与CH_(4)部分氧化以及还原氧载体对CO_(2)的热催化还原性能,并通过连续氧化还原实验发现,与单一氧化物组分相比,CeO_(2)掺杂强化的CuFe_(2)O_(4)复合氧载体对CH_(4)和CO_(2)具有更高的反应活性。其中30%CeO_(2)掺杂量的混合氧载体具有最高的CH_(4)转化率,且在多次氧化还原循环反应中保持较高且稳定的CO_(2)转化率,表明其良好的反应性能和循环稳定性。

磁性易分离CuFe_(2)O_(4)/坡缕石活化过硫酸盐降解罗丹明B

该文采用新型磁性易分离的CuFe_(2)O_(4)/坡缕石(CuFe_(2)O_(4)/Pal)活化PMS,实现了RhB的高效降解。文章考察了催化剂投加量、PMS浓度、初始pH值、RhB的初始浓度等因素对RhB降解的影响。结果表明:当初始pH为3.0,RhB浓度为10 mg/L,催化剂投加量为0.3 g/L,PMS浓度为0.1 g/L时,降解120 min,RhB的降解效率为99.99%。CuFe_(2)O_(4)/Pal活化PMS降解RhB符合伪一阶动力学模型。通过自由基淬灭实验鉴定结果表明,在CuFe_(2)O_(4)/Pal+PMS体系中1O2和O2·-是降解RhB的主要自由基。稳定性分析实验表明:催化剂具有很好的稳定性,循环使用4次,RhB的降解效率都可以达到91%以上。

尖晶石型c-CuFe_(2)O_(4)催化过硫酸盐降解偶氮染料

以三水合硝酸铜、九水合硝酸铁为原料,在柠檬酸辅助下通过溶胶-凝胶-自蔓延燃烧法制备了尖晶石型纳米铁酸铜(c-CuFe_(2)O_(4)),采用SEM、EDX、XRD、VSM对材料进行了表征。利用c-CuFe_(2)O_(4)/过硫酸盐(PDS)体系对偶氮染料活性黑5(RB5)进行催化氧化处理,考察了c-CuFe_(2)O_(4)投加量、初始PDS浓度、反应温度、初始pH、常见无机阴离子和腐殖酸对催化体系的影响。结果表明,300℃煅烧制备得到的c-CuFe_(2)O_(4)催化性能最好,当温度为25℃、RB5初始质量浓度为100 mg/L、c-CuFe_(2)O_(4)-300投加量为1 g/L、初始PDS浓度为8 mmol/L、初始pH为9.00时,RB5的去除率可以达到92.9%,其降解过程遵循准一级动力学模型。猝灭实验发现,催化位点在材料表面和孔隙部位,反应依赖材料表面二价铜/三价铜循环以及游离Cu^(2+)的均相催化,SO_(4)^(–)·和·OH是主要活性产物。c-CuFe_(2)O_(4)具有超顺磁性,可以通过磁分离回收,4次循环实验后能够保持80%以上的去除率。

NiO-Doped Fe_(2)O_(3)/MgO Properties for the Chemical Looping Oxidative Dehydrogenation of Ethane

Ethane chemical looping oxidative dehydrogenation(CL-ODH)to ethylene is a new technology for ethylene preparation.Fe_(2)O_(3)/MgO oxygen carrier was prepared using the co-precipitation method.The influence of added NiO and its different loadings on Fe_(2)O_(3)/MgO were investigated.Then,a series of oxygen carriers were applied in the CL-ODH of the ethane cycle system.Brunauer-Emmett-Teller(BET),X-ray diffractometry(XRD),X-ray photoelection spectroscopy(XPS),and H2-temperature programmed reduction(TPR)were used to characterize the physicochemical properties of these oxygen carriers.It was confirmed that an interaction between NiO and Fe_(2)O_(3) occurred based on the XPS and H2-TPR results.Based on the CL-ODH activity performance tests conducted in a fixed-bed reactor,it was revealed that ethylene selectivity was significantly improved after NiO addition.Fe_(2)O_(3)-10%NiO/MgO showed the best activity performance with 93%ethane conversion and 50%ethylene selectivity at a reaction temperature of 650℃,atmospheric pressure,and space velocity of 7500 mL/(g·h).