1,4-二苯基-1,3-丁二烯的氰基蒽敏化光氧化反应

某些不能与单线态氧(~1O_2)起反应的烯烃、炔烃、硫醚和环氧化合物,在以氰基蒽为敏化剂的条件下,可发生经由光敏电子转移机理的氧化反应.近年来,Santamaria 等,Foote 等和我们都在研究这类反应.本文报道以9,10-二氰基蒽(DCA)为敏化剂、反,反-1,4-二苯基-1,3-丁二烯为反应物的电子转移光敏氧化反应,并讨论了反应机理.     

缺电子芳烃侧链基的光氧化

研究了9,10-二氰蒽(DCA)和四氯对苯二醌(TCBQ)敏化的甲苯、对氯甲苯、对氰基甲苯和对硝基甲苯的电子转移光氧化反应。DCA和TCBQ均可敏化甲苯和对氯甲苯的光氧化。产物为相应的取代苯甲酸和取代苯甲醛。DCA和TCBQ均不能有效敏化对氰基甲苯和对硝基甲苯的光氧化, 但在反应体系中加入与反应物等摩尔的联苯为共敏化剂后, 两者即可顺利氧化为相应的取代苯甲酸和取代苯甲醛。通过荧光淬灭和共敏化剂联苯、无水盐高氯酸镁、O2捕获剂对苯二醌以及电子给体对二甲氧基苯等外加试剂对光氧化的影响讨论了反应历程。     

缺电子芳烃侧链基的光氧化

研究了9,10-二氰蒽(DCA)和四氯对苯二醌(TCBQ)敏化的甲苯、对氯甲苯、对氰基甲苯和对硝基甲苯的电子转移光氧化反应。DCA和TCBQ均可敏化甲苯和对氯甲苯的光氧化。产物为相应的取代苯甲酸和取代苯甲醛。DCA和TCBQ均不能有效敏化对氰基甲苯和对硝基甲苯的光氧化, 但在反应体系中加入与反应物等摩尔的联苯为共敏化剂后, 两者即可顺利氧化为相应的取代苯甲酸和取代苯甲醛。通过荧光淬灭和共敏化剂联苯、无水盐高氯酸镁、O2捕获剂对苯二醌以及电子给体对二甲氧基苯等外加试剂对光氧化的影响讨论了反应历程。     

蒈烯芳氰敏化光氧化反应的研究——Ⅱ.光敏氧化产物的分布及其反应机理

本文报道蒈烯在不同溶剂中光敏氧化反应产物的组成和分布及其与溶剂及敏化剂性质的关系。研究结果指出在以孟加拉玖瑰红(RB)为敏化剂时,主要生成典型的“ene”型产物,而以9,10—二腈基蒽敏化蒈烯的光氧化反应除生成“ene”型产物外还生成相当量的非“ene”型产物。实验证明蒈烯芳氰敏化光氧化反应过程,首先发生电子转移,而后产生自由基中间体和单重态氧并生成相应产物。     

硝酮化合物对9-氰蒽荧光猝灭作用的研究

本工作对硝酮化合物猝灭9-氰蒽荧光的机制进行了研究,发现不同的9-氰蒽/硝酮体系可能经历包括电子转移、能量转移及竞争吸收等不同的猝灭过程。其中α,N-二苯基硝酮对荧光猝灭遵循电子转移机制,分别形成猝灭剂和敏化剂的离子自由基,但硝酮正离子自由基不能导致环化反应发生,结果还表明：硝酮化合物的四π电子1,3偶极结构在猝灭过程中起主要作用,因此当光环化反应破环1,3偶极结构生成氧氮丙啶时,即失去其原有的猝灭能力,导致已被猝灭的荧光重新回复。     

二氢吡喃光敏氧化反应的研究

本文研究了二氢吡喃的氰基蒽(9,10-二氰基蒽、9-氰基蒽)敏化光氧化反应。在几种不同溶剂(乙腈、二氯甲烷、苯、四氯化碳)中,其敏化光氧化反应所生成的产物、产物分布及溶剂同位素效应与典型单线态氧的氧化反应相同。荧光淬灭、激基复合物的生成和自由能的变化支持了电子转移反应机理。我们认为,反应首先经过敏化剂的激发单线态与反应底物之间的电子转移反应,尔后在反应过程中生成了活性中间体单线态氧1O2。     

以9,10-二氰基蒽为敏化剂对几种硫醚光氧化初级反应机理的研究

本文研究了多种硫醚化合物对9,10-二氰基蒽(DCA)的荧光猝灭过程,并观察到DCA与硫醚间形成的激基复合物的荧光发射峰。这些证据表明,受光激发后DCA与硫醚之间发生了电子转移。以DCA作敏化剂可氧化异丁基硫醚、羟乙基硫醚以及难以被单线态氧氧化的苯基硫醚。其反应机理可能经历了电子转移,生成氧负离子(superoxide),然后再氧化硫醚生成亚砜这样的过程。     

9,10-二氰基蒽光敏化香豆素加成反应的研究

光化学中的电子转移反应近年来引起了人们广泛的重视。9,10-二氰基蒽(DCA)作为贫电子敏化剂敏化的各类烯烃的光氧化反应,光重排反应,光加成反应等均有报道。我们在研究DCA光敏化香豆素反应时发现,香豆素与DCA能够发生电子转移的给体—受体加成反应,联苯(BP)可以充当二次电子转移体加速反应。     

共轭二烯在硅胶表面上的光氧化反应

本文选用了trans, trans-1,4-二苯基-1,3-丁二烯(DPB)分别与单重量态氧(^1O2)敏化剂亚甲基蓝(MB)或贫电子敏化剂9,10-二氰基蒽(DCA)共同吸附在硅胶表面上, 通过其光敏氧化反应来比较DPB吸附在硅胶表面与DPB在溶液中反应的异同.     

光氧化反应研究——Ⅷ.苊酮作为电子给体的电子转移光氧化反应机理

研究了苊酮(ANO)在9,10-二氰蒽(DCA)敏化下的光氧化反应与机理。实验发现,该反应具有逐步氧化模式,依次生成1,8-(3′-羟基)-斗-萘内酯和1,8-萘二甲酸酐。通过循环伏安,荧光淬灭和激基络合物检测,DCA/联苯共敏化反应以及CIDNP效应等研究,证明苊酮可以作为电子给体与单线态DCA发生热力学上有利的电子转移过程。     

Dicyanoanthracene sensitized photo-oxygenation of olefins : Electron transfer and singlet oxygen mechanisms

Cyanoaromatic sensitizers, in particular 9,10-dicyanoanthracene (DCA), sensitize the photo-oxygenation of olefins by two distinct mechanisms. In the case of aryl substituted olefins (OL), which react extremely slowly (if at all) with singlet oxygen, the reaction proceeds by way of electron transfer to produce discrete radical ions (DCA^-and OL⁺). In the presence of oxygen, this ionic process results, ultimately, in the cleavage of the olefin to carbonyl compounds along with production of some epoxide and other minor by-products. Aromatic ethers can interfere with this process by reducing the radical cation by electron transfer, resulting in net quenching of the reaction. With simple alkenes the DCA-sensitized reaction takes a different course, producing hydroperoxide products with distributions which are very similar to those obtained with the singlet oxygen ene reaction. Careful study has shown that this reaction does, indeed, proceed by way of singlet oxygen, which is produced by at least two mechanisms : (1) enhanced intersystem crossing, in which ¹DCA is quenched by interaction with the olefin, leading to a low yield of ³DCA, which subsequently reacts with oxygen to produce singlet oxygen; and (2) direct reaction of ¹DCA with oxygen. At limiting high oxygen concentration, this process produces 2 mol of singlet oxygen for each mol of ¹DCA quenched; the mechanism involves energy transfer to produce ³DCA and 1 mol of singlet oxygen ; the ³DCA reacts again with oxygen to produce a second mol of singlet oxygen. The complex kinetic behaviour of simple olefins in the presence of DCA can be satisfactorily rationalized by these mechanisms.     

Synthesis and Thermal Decomposition of Mn-Al Layered Double Hydroxides

In this paper, the synthesis and thermal decomposition behavior of hydrotalcite-like Mn-Al layered double hydroxide (LDH) have been investigated. First, the Mn-Al LDH was synthesized by the coprecipitation method using various anions such as Cl⁻, CO²⁻₃, NO⁻₃, SO²⁻₄ or dicarboxylic acids (DCA). The single phase of the Mn-Al LDH was obtained when Cl⁻, NO⁻₃ or DCA was used as a guest anion. In the case of CO²⁻₃ or SO²⁻₄, the solid products included MnCO₃ or shigaite as a by-product. The crystallinity of the Cl/Mn-Al LDH was greatly influenced by a drying temperature and that the crystallinity of the Cl/Mn-Al LDH dried at room temperature was found to rise about 6 times in comparison with that dried at 333 K. The DCA/Mn-Al LDH was found to have an expanding LDH structure, supporting that the LDH basal layers were bridged by the intercalated DCA anion. Then, the thermal decomposition of the DCA/Mn-Al LDH has been examined, and the intercalated DCA was found to be decomposed at lower temperature than DCA itself. The oxidation number of Mn ion rose with increasing the heat treatment temperature and was +2.70 with crystallizing Mn₃O₄ after being heated at 973 K. The thermal decomposition of guest DCA was thought to be accelerated by the strong catalytic action of Mn ion in the host hydroxide basal layers.     

Photodegradation of poly(ether sulphone) Part 2. Wavelength and atmosphere dependence

The photodegradation of poly(ether sulphone) (PES) was investigated systematically by time‐of‐flight SIMS (ToF‐SIMS) and x‐ray photoelectron spectroscopy (XPS). The effect of varying the irradiation dose, wavelength and the atmosphere was studied along with mechanistic photooxidation studies using ¹⁸O₂. Photoinduced ? SO₃H group formation was observed at 199, 260 and 315 nm for an oxygen‐containing atmosphere only. Photoinduced ? OH group formation is observed at all investigated wavelengths and atmospheres. Photoinduced cross‐linking was an important process in a vacuum. The oxygen reacts quickly with the PES surface during photoirradiation and chain scission was found to be the dominant process, and oxygen incorporation was found to be non‐specific but pronounced for ? SO₃H group formation. It was found that for conditions where processes are affected by photoirradiation the extent is observed to follow the UV absorption and showed little dependence on the wavelength. The wavelength only affects the extent of the process in question, which is ascribed to a fast equilibrium of the absorbed energy. The photoinduced processes are very sensitive towards the presence of the smallest amounts of oxygen in the atmosphere. Copyright © 2004 John Wiley & Sons, Ltd.     

卟啉-Salen化合物对含氮杂环客体的分子识别

A novel porphyrin-salen compound and corresponding zinc(Ⅱ)porphyrin-salen compound(ZnPSC_(10))cova-lently linked by a flexible alkoxy chain(—O(CH)_(10)O—)have been synthesized and characterized.Molecular rec-ognition of three N-heterocyclic guests,pyridine,1,4-diazobycyclo[2,2,2]octane(DABCO)and pyrazine,with thehost ZnPSC_(10)was investigated.Binding constants were determined by means of UV-vis titration method.Thebinding mode of ZnPSC_(10)with DABCO has been discussed in detail by using ~1H NMR.It was found that the con-formations of the recognition system changed from closed to open with the adding of DABCO.     

Cyclic porphyrin dimers as hosts for coordinating ligands

Bicovalently linked tetraphenylporphyrins bearing dioxypentane groups at the opposite (transoid, H₄A) and adjacent (cisoid, H₄B) aryl groups have been synthesised. Protonation of the free-base porphyrins leads to fully protonated species H₈A⁴⁺/H₈A⁴⁺ accompanied by expansion of cavity size of the bisporphyrins. The electrochemical redox studies of these porphyrins and their Zinc(II) derivatives revealed that the first ring oxidation proceeds through a two-electron process while the second ring oxidation occurs at two distinct one-electron steps indicating unsymmetrical charge distribution in the oxidized intermediate. The axial ligation properties of the Zinc(Il) derivatives of H₄A/H₄B with DABCO and PMDA investigated by spectroscopic and single crystal X-ray diffraction studies showed predominant existence of 1: I complex. The Zn₂A.DABCO complex assumes an interesting eclipsed structure wherein DABCO is located inside the cavity between the two porphyrin planes with Zn-N distances at 2.08 and 2.22 ?. The Zn atoms are pulled into the cavity due to coordination towards nitrogen atoms of DABCO and deviate from the mean porphyrin plane by 0.35 ?. The electrochemical redox potentials of the axially ligated metal derivatives are found to be sensitive function of the relative coordinating ability of the ligands and the conformation of the hosts.     

Tuning the concentration of surface/bulk oxygen vacancies in CeO2 nanorods to promote highly efficient photodegradation of organic dyes

To enhance the photodegradation ability of CeO₂ for organic dyes, an effective strategy is to introduce oxygen vacancies (V_o). In general, the introduced V_o are simultaneously present both on the surface and in the bulk of CeO₂. The surface oxygen vacancies (V_o-s) can decrease the band gap, thus enhancing light absorption to produce more photogenerated e⁻ for photodegradation. However, the bulk oxygen vacancies (V_o-b) will inhibit photocatalytic activity by increasing the recombination of photogenerated e⁻ and V_o-b. Therefore, regulating the concentrations of V_o-s to V_o-b is a breakthrough for achieving the best utilization of photogenerated e⁻ during photodegradation. We used an easy hydrothermal method to achieve tunable concentrations of V_o-s to V_o-b in CeO₂ nanorods. The optimized CeO₂ presents a 70.2% removal of rhodamine B after 120 min of ultraviolet−visible light irradiation, and a superior photodegradation performance of multiple organics. This tuning strategy for V_o also provides guidance for developing other advanced metal-oxide semiconductor photocatalysts for the photodegradation of organic dyes.     

Photo-oxygenations de composes aromatiques sensibilisees par des accepteurs d'electron

Photo-oxygenation of aromatic compounds sensitized by electron acceptors, like 9-10 dicyanoanthracene (DCA) is shown to proceed by two distinct mechanisms each one beginning by an electron-transfer step: in the first way superoxide ion [O₂^?] is involved and in the second one singlet oxygen [¹O₂^*] is produced according to an unusual process.     

Photooxygenations par transfert d'electron sensibilisees par le dicyano-9,10 anthracene. Role du solvant et formation d'oxygene singulet.

Photooxygenation of naphtalenic compounds sensitized by electron acceptors like 9,10 dicyanoanthracene (DCA) is shown to proceed by two distinct ways depending on the solvent polarity. In a polar solvent superoxide ion (O₂^-.) as well as singlet oxygen (¹O₂★) are involved while in a non polar solvent only singlet oxygen is produced.     

Taming of Singlet Oxygen: Towards Artificial Oxygen Carriers Based on 1,4-Dialkylnaphthalenes

Naphthalene endoperoxides are known as convenient sources of singlet oxygen (O₂, ¹Δ_g), which is the major product of endoperoxide cycloreversion reaction. However, their potential as carriers of ground-state molecular oxygen (O₂, ³Σ_g) similar to artificial oxygen carriers remains largely unexplored. This is due to the extreme reactivity and cytotoxic effects of the released singlet oxygen. We now report that a compound with a bimodular design, which incorporates an endoperoxide and an efficient physical quencher of singlet oxygen, 1,4-diazabicyclo[2.2.2]octane (DABCO), produces exclusively ground-state molecular oxygen. This result, coupled with the fact that oxygen release rates from endoperoxides are highly amenable to fine-tuning in a very broad range, and open to targeting by ligand attachment, raises the potential of these compounds far above any comparable chemical, or even biochemical sources. In cell culture experiments, we showed that the addition of the endoperoxide-quencher conjugate can enhance and sustain cell proliferation.     

Kinetics Study on Reaction of Atenolol with Singlet Oxygen by Directly Monitoring the 1O2 Phosphorescence

The pharmaceutically active compound atenolol, a kind of $\beta$-blockers, may result in adverse effects both for human health and ecosystems if it is excreted to the surface water resources. To effectively remove atenolol in the environment, both direct and indirect photodegradation, driven by sunlight play an important role. Among indirect photodegradation, singlet oxygen (¹O₂), as a pivotal reactive species, is likely to determine the fates of atenolol. Nevertheless, the kinetic information on the reaction of atenolol with singlet oxygen has not been well investigated and the reaction rate constant is still ambiguous. Herein, the reaction rate constant of atenolol with singlet oxygen is investigated directly through observing the decay of the ¹O₂ phosphorescence at 1270 nm. It is determined that the reaction rate constant between atenolol and ¹O₂ is 7.0×10⁵ (mol/L)$^{-1}\cdot$s^-1 in D₂O, 8.0×10⁶ (mol/L)$^{-1}\cdot$s^-1 in acetonitrile, and 8.4×10⁵ (mol/L)$^{-1}\cdot$s^-1 in EtOH, respectively. Furthermore, the solvent effects on the title reaction were also investigated. It is revealed that the solvents with strong polarity and weak hydrogen donating ability are suitable to achieve high rate constant values. These kinetics information on the reaction of atenolol with singlet oxygen may provide fundamental knowledge to the indirect photodegradation of $\beta$-blockers.