非水溶性席夫碱铁疏水异相光催化降解有毒有机污染物

通过化学方法合成了疏水性金属有机复合物双（水杨醛）邻苯二胺席夫碱铁（Fe-Bis-Schiff-base- salicylaldehyde-o-Phenylenediamine,Fe-SPA）。在水溶性介质体系中,以Fe-SPA疏水特性作为异相光催化剂降解有毒有机污染物,在pH 7.2介质,可见光（λ>420nm）照射下,通过Fe-SPA活化H2O2降解有毒有机污染物罗丹明B（Rhodamine B,RhB）、亚甲基蓝（Methylene Blue trihydrate,MB）和2,4-二氯苯酚（2,4-Dichlorophenol,2,4-DCP）,研究了Fe-SPA的光催化特性。在实验条件下,反应150min RhB褪色完全,反应300min MB 褪色完全,反应10h DCP降解率达到65%。采用ESR（电子顺磁共振）跟踪测定活性氧化物种,检测到催化体系中产生了高氧化活性羟基自由基。通过RhB体系降解过程中的紫外-可见光谱和红外光谱分析,表明目标底物有效降解且最终转化为胺类和羧酸类小分子。在水溶性介质体系中,Fe-SPA以疏水特性作为异相光催化剂具有良好的稳定性,循环使用5次,光催化活性基本稳定。     

甲醛光催化氧化的反应机理

采用程序升温脱附（TPD）, 电子自旋共振（ESR）及自旋捕获 电子自旋共振(ST ESR)等物理方法对甲醛光催化氧化过程中,反应物的吸附状态、自由基中间物种及反应机理 进行了研究.结果表明,在光催化氧化空气中微量甲醛的反应条件下,吸附在催化剂表面的空 气中的氧气被光生电子还原为•O－2,微量水被空穴氧化为•OH.二者为甲醛的深度氧化提供了高活性的氧化剂.甲醛是通过中间产物甲酸而氧化为终点 产物二氧化碳的.     

γ射线辐照的多晶态嘧啶核苷类中自旋捕捉自由基的ESR研究——Ⅱ.胸苷和脱氧胞苷盐酸盐

本文以NtB(亚硝基特丁烷)为捕捉剂,利用自旋捕捉(Spin Trapping)和ESR方法,研究了γ射线辐照的多晶态胸苷和脱氧胞苷盐酸盐中产生的室温自由基。对它们分别确定了三种类型与两种类型的碱基自由基,此与单晶ESR研究结果完全一致,从而获得它们R·自旋加合物的标准ESR波谱。此外,对脱氧胞苷盐酸盐还确定了在单晶ESR研究中未被鉴别的核糖自由基HO(5′)HC(4′)H<及由其演变而成的—(5′)H_2自由基。     

脂二胺在颜料分散体中光化学反应活泼自由基的ESR研究

用自旋捕捉技术与ESR相结合的方法研究了脂二胺在ZnO、TiO₂的庚烷或苯的分散体系中光诱导的电子转移过程。观察到DMPO与氮中心自由基加合物的ESR信号,表明捕捉到的自由基是脂二胺与光生空穴作用而产生的胺的阳离子自由基。     

有机锡化合物光解活泼自由基的ESR研究

本文用自旋捕捉技术与ESR相结合的方法,研究了六种有机锡化合物的光解反应历程。结果表明:有机锡化合物紫外光照时,碳-锡键发生均裂,产生碳中心和锡中心自由基。其中碳中心自由基易被捕捉剂α-苯基-N-特丁基氮氧化物(PBN)或2,3,5,6-四甲基亚硝基苯(ND)所捕获;而锡中心自由基可与菲醌形成稳定的环状加合物。由于环状加合物中配体的不同,产生的空间效应也不同,从而导致加合物中的未偶电子云密度发生变化,给出相异的ESR信号。     

过硫酸盐和脂肪二元叔胺体系引发烯类聚合的反应与机理的研究

本文研究了过硫酸盐和脂肪二元叔胺体系引发丙烯酰胺水溶液聚合的反应和机理。发现脂肪二元叔胺具有很高的促进聚合活性。测定了聚合反应表观活化能和动力学方程。端基分析表明聚合物中含有胺端基。用自由基捕捉技术和ESR波谱方法研究了脂肪二元叔胺与过硫酸盐体系的初级自由基,证实脂肪二元叔胺参与了引发烯类聚合的反应。提出了引发反应机理。     

抗坏血酸与过氧化氢反应的自旋捕捉-ESR研究

利用自旋捕捉-ESR方法研究了分析纯抗坏血酸(Aa)与医用维生素C注射液(Vc)的自氧化和过氧化氢反应,在自氧化反应中只观察到去氢抗坏血酸负离子基A-.,而与过氧化氢反应时除观察到A-.外,还观测到另外数种自由基,经计算机拟合后得到这些自由基或其5,5-二甲基-1-吡咯啉-1-氧化物(DMPO)加合物的ESR谱参数,在此基础上推测出该反应的机理.     

溶液中亚硝基特丁烷二聚体-单体平衡反应的研究

自旋捕捉剂能将反应过程中生成的瞬态自由基变成较稳定的自旋加合物.通过对自旋加合物的 ESR 研究可以提供有关反应中间过程的信息.因此它对研究高分子聚合和降解过程、催化反应及某些有机反应的自由基历程很有价值,引起人们广泛的重视.应用最多的捕捉剂是亚硝基特丁烷(t-BuNO).t-BuNO 在固态时以二聚体形式存在,而在溶液中则会发生离解平衡反应:     

电极过程自由基中间体的ESR研究(Ⅳ)——脂肪胺的电解氧化

本文用自旋捕捉技术与ESR相结合的方法研究了6种脂肪胺电解氧化过程中产生的瞬态自由基。结果表明,阳极上脂肪胺氧化产生相应的正离子自由基,而后脱去α-C上的质子得到一碳中心自由基,此自由基能被捕捉剂PBN所捕获;阴极上发生H~+还原反应,所得的氢原子也可被PBN捕获。     

MAQO和它的环糊精包结物的电子自旋共振研究

报导2-甲基-3乙酰基喹喔啉1，4-二氧化物（MAQO）和它与α-环糊精（α-CD），β-环糊精（β-CD）包结物在室温下应用紫外光（λ＝360nm）进行原位光化学反应生成自由基的电子自旋共振研究结果，推断MAQO在紫外光作用下首先生成激发态（MAQO）*，然后进一步发生光化学反应导致N＝C双键转移而生成氮氧自由基并为ESR所检测到．从ESR检测结果猜想，在非含氢溶剂中是生成较稳定的且又相距很远的氮氧双自由基；而在含氢溶剂中，由于发生夺氢反应而生成稳定的氮氧单自由基．当MAQO－α－CD包结物在含氢溶剂中发生光化学反应时亦生成氮氧单自由基；但其ESR谱的超精细结构（hfs）和线宽均发生了变化，推断环糊精包结在MAQO分子苯环一端，受环糊精的微环境空间阻碍效应．     

Photobleaching of pollutant dye catalyzed by p-n junction ZnO-CuO photocatalyst under UV-visible light activation

The p-n junction ZnO/CuO nanocomposite photocatalysts are prepared via the copreripitation route. The detailed structural, compositional and optical characterization and physico-chemical properties of the obtained products are analyzed by X-ray diffraction (XRD), UV-vis diffuse reflectance spectroscopy (UV-vis DRS), photoluminscience spectra (PL) and electron spin resonance (ESR) spin-trapping techniques. The experimental results showed that the absorption wavelength range of the ZnO/CuO nanocomposite was notably extended towards the visible-light region (400–500 nm). The photocataltic activity of the ZnO/CuO nanocomposite was evaluated based on the decomposition of by methyl orange (MeO) in aqueous solution under UV-vis light irradiation. The photocatalytic activity of ZnO/CuO nanocomposite is found much better than of bare ZnO photocatalyst under the identical conditions. Factors influencing photocatalytic activity and the mechanism of photocatalysis reaction were also addressed.     

Turn On of a Ruthenium(II) Photocatalyst by DNA-Templated Ligation

Here, the synthesis of a Ru^II photocatalyst by light-directed oligonucleotide-templated ligation reaction is described. The photocatalyst was found to have tremendous potential for signal amplification with >15000 turnovers measured in 9 hours. A templated reaction was used to turn on the activity of this ruthenium(II) photocatalyst in response to a specific DNA sequence. The photocatalysis of the ruthenium(II) complex was harnessed to uncage a new precipitating dye that is highly fluorescent and photostable in the solid state. This reaction was used to discriminate between different DNA analytes based on localization of the precipitate as well as for in cellulo miRNA detection. Finally, a bipyridine ligand functionalized with two different peptide nucleic acid (PNA) sequences was shown to enable template-mediated ligation (turn on of the ruthenium(II) photocatalysis) and recruitment of substrate for templated photocatalysis.     

Covalent Organic Frameworks toward Diverse Photocatalytic Aerobic Oxidations

Photoactive two-dimensional covalent organic frameworks (2D-COFs) have become promising heterogenous photocatalysts in visible-light-driven organic transformations. Herein, a visible-light-driven selective aerobic oxidation of various small organic molecules by using 2D-COFs as the photocatalyst was developed. In this protocol, due to the remarkable photocatalytic capability of hydrazone-based 2D-COF-1 on molecular oxygen activation, a wide range of amides, quinolones, heterocyclic compounds, and sulfoxides were obtained with high efficiency and excellent functional group tolerance under very mild reaction conditions. Furthermore, benefiting from the inherent advantage of heterogenous photocatalysis, prominent sustainability and easy photocatalyst recyclability, a drug molecule (modafinil) and an oxidized mustard gas simulant (2-chloroethyl ethyl sulfoxide) were selectively and easily obtained in scale-up reactions. Mechanistic investigations were conducted using radical quenching experiments and in situ ESR spectroscopy, all corroborating the proposed role of 2D-COF-1 in photocatalytic cycle.     

In-situ construction of Z-scheme g-C_3N_4/WO_3 composite with enhanced visible-light responsive performance for nitenpyram degradation

Developing an excellent photocatalysis system to remove pesticides from water is an urgent problem in current environment purification field.Herein,a Z-scheme WO_3/g-C_3N_4 photocatalyst was prepared by a facile in-situ calcination method,and the photocatalytic activity was investigated for degradation of nitenpyram(NTP) under visible light.The optimal Z-scheme WO_3/g-C_3N_4 photocatalyst displayed the highest rate constant(0.036 min~(-1)),which is about 1.7 and 25 times higher than that of pure g-C_3N_4 and WO_3,respectively.The improvement of photocatalytic performance is attributed to fast transfer of photogene rated carriers in the Z-scheme structure,which are testified by electron spin resonance(ESR)experiments,photocurrent and electrochemical impedance spectra(EIS) measurements.Moreover,the effects of typical water environmental factors on the degradation NTP were systematically studied.And the possible degradation pathways of NTP were deduced by the intermediates detected by highperformance liquid chro matography-mass spectrometry(HPLC-MS).This work will not only contribute to understand the degradation mechanism of pesticides in real water environmental condition,but also promote the development of new technologies for pesticide pollution control as well as environmental remediation.     

Reduced graphene oxide as a solid-state electron mediator in Z-scheme photocatalytic water splitting under visible light

The effectiveness of reduced graphene oxide as a solid electron mediator for water splitting in the Z-scheme photocatalysis system is demonstrated. We show that a tailor-made, photoreduced graphene oxide can shuttle photogenerated electrons from an O(2)-evolving photocatalyst (BiVO(4)) to a H(2)-evolving photocatalyst (Ru/SrTiO(3):Rh), tripling the consumption of electron-hole pairs in the water splitting reaction under visible-light irradiation.     

稀土-沸石-TiO2三元体系光催化材料的性能研究

以钛酸丁酯、稀土硝酸盐、斜发沸石为主要原料,用溶胶-凝胶法制备了稀土-沸石-TiO2三元体系的光催化剂.使用IR,TG-DSC,XRD,SEM等手段对样品进行了表征; 以甲基橙为目标物,太阳光为光源,用光解率对光催化剂性能进行了评价.实验表明,随着沸石负载TiO2量的增加,光催化剂的3 h光解率也逐渐提高; 反应体系的温度越高,光解率越大; 当溶液pH约等于5时,光解率达到最大.     

Vanadia-catalyzed solar photooxidation of aniline

Vanadia photocatalyzes the oxidation of aniline to azobenzene in ethanol. The reaction was studied using natural sunlight and UV irradiation (365 nm) as a function of [aniline], catalyst loading, airflow rate, solvent composition, etc. The photocatalyst exhibits sustainable catalytic activity. The product formation is greater with illumination at 254 nm than at 365 nm. Electron donors such as triphenylphosphine, diphenylamine, and hydroquinone enhance the photocatalysis. The singlet oxygen quencher azide ion fails to inhibit the catalysis. The photocatalysis takes place in both protic and aprotic solvents. The mechanism of photocatalysis is discussed and the product formation analyzed using a kinetic model.     

Characterization of an LED based photoreactor to degrade 4-chlorophenol in an aqueous medium using coumarin (C-343) sensitized TiO2

A detailed performance evaluation of a simple high intensity LED based photoreactor exploiting a narrow wavelength range of the LED to match the spectrum of a dye in a photocatalysis system is reported. A dye sensitized (coumarin-343, lambda max = 446 nm) TiO 2 photocatalyst was used for the degradation of 4-chlorophenol (4-CP) in an aqueous medium using the 436 nm LED based photoreactor. The LED reactor performed competitively with a conventional multilamp reactor and sunlight in the degradation of 4-CP. Light intensities entering the reaction vessel were measured by conventional ferrioxalate actinometry. The results can be fitted by approximate first order kinetic behavior in this system. Hydroxyl radicals were detected by spin trapping EPR, and effects of OH radical quenchers on kinetics suggest that the reaction is initiated by these radicals or their equivalents. LEDs operating at competitive intensities offer a number of advantages to the photochemist or the environmental engineer via long life, efficient current to light conversion, narrow bandwidth, forward directed output, and direct current power for remote operation. Matching light source spectrum to chromophore is a key.     

A Modular Tubular Flow System with Replaceable Photocatalyst Membranes for Scalable Coupling and Hydrogenation

Heterogeneous photocatalysis is effective for the selective synthesis of value-added chemicals at lab-scale, yet falls short of requirements for mass production (low cost and user friendliness). Here we report the design and fabrication of a modular tubular flow system embedded with replaceable photocatalyst membranes for scalable photocatalytic C−C, C−N homocoupling and hydrogenation reactions, which can be operated in either circular and continuous flow mode with high performance. The photocatalyst membranes almost fully occupy the volume of the reactor, thus enabling optimal absorption of the incident light. Additionally, the porous structured photocatalyst membranes facilitate the mass transfer of the reactants to efficiently use the active sites, resulting in 0^th-order reaction kinetics and a high space-time yield compared to the batch reaction system at practical application levels and prolonged reaction times.