CdS quantum dot sensitized p-type NiO as photocathode with integrated cobaloxime in photoelectrochemical cell for water splitting

CdS sensitized NiO electrode was used as the photoactive cathode in a photoelectrochemical cell for water splitting,avoiding the use of a sacrificial electron donor.Photocurrent increment under visible light irradiation was observed after integration of[Co（dmgH）₂（4-Me-py）Cl]（1） to the photocathode,suggesting 1 could accept electrons from photoexcited CdS for water reduction and NiO could move the holes in the valence band of CdS to anode for water oxidation.     

Interrogation of cobaloxime-based supramolecular photocatalyst architectures

This perspective provides a discussion of recent work focused on elucidating the fundamental interactions of artificial photosynthesis in newly developed supramolecular photocatalysts composed of linked chromophore and catalyst modules. Supramolecular photocatalyst architectures are of particular interest because of their potential to overcome many of the limitations of molecular or multimolecular systems and amenability to conventional and emerging physical characterization techniques. As such, changes to the oxidation state and/or physical structure of either chromophore or catalyst modules in response to light excitation is readily monitored with high spatial and temporal resolution. To illustrate this approach, the design evolution of photocatalysts based on Ru(II)poly(pyridyl) chromophores linked to cobaloxime-based H₂ catalysts is discussed. In this work, new synthesis, transient optical spectroscopy, and X-ray scattering were combined to develop next generation photocatalysts capable of ultrafast charge transfer and identification of a key intermediate for hydrogen photocatalysis. Recent and upcoming advances in light source capabilities are ideally suited to monitor light-generated transient structures and well-poised to dramatically impact the drive toward technologically relevant systems for artificial photosynthesis.     

New pyridinium based ionic dyes for the hydrogen evolution reaction

The presented work comprised the synthesis and characterization of new ionic organic dyes as potential photosensitizer (PS) in the photocatalytic H₂ evolution reaction. The presented dyes are consisting of donor-π-acceptor (D-π-A) structures that are commonly used for organic dyes for organic solar cells. The acceptor is based on a cationic pyridinium moiety. Furthermore, a complex was synthesized, in which a D-π-A photosensitizer is linked as ligand to cobaloxime. The latter is a common proton reduction catalyst. The attached ligand enabled a fast intramolecular electron transfer to the cobalt center. The resulted complex showed high stability and potential in the homogeneous photocatalytic H₂ evolution reaction. Finally, one ionic dye showed a high activity when combined with TiO₂ and Pt in a heterogeneous hydrogen evolution reactions with a TOF of up to 407 h^?1.     

吖啶和钴肟配合物协同光催化苯乙烯放氢二聚反应构筑1,2-二氢-1-芳基萘（英文）

芳基二氢萘类衍生物是许多生物活性的天然产物以及药物的常见结构单元,其合成一直都受到化学家们的关注.传统的1,2-二氢-1-芳基萘骨架化合物的构筑大都需要进行底物的预官能团化,在高温条件下进行,且产物的选择性较差,因此发展一种简单温和的制备方法很有必要.最近兴起的可见光催化因具有条件温和、环境友好等特点而成为了合成化学家的研究热点.近期研究发现,在可见光作用下利用吖啶光敏剂的强氧化能力,可以实现苯乙烯的加成.但此类反应需要当量的氧化剂或氢原子转移试剂,容易导致苯乙烯的二聚环合产物的进一步氧化或还原.我们在前期发展的"放氢交叉偶联"反应的基础上,利用吖啶光催化和钴肟催化的协同作用,实现了苯乙烯的放氢二聚反应,在室温下高效构筑了1,2-二氢-1-芳基萘骨架,反应条件温和,底物脱除的电子和质子在钴肟催化剂作用下以氢气的形式释放,反应具有中等及以上的收率.本文以苯乙烯为模型底物,吖啶为光敏剂,钴肟配合物为质子还原催化剂,在乙腈溶剂中,蓝色LED灯下光照24 h可以获得56%的产率,对于其它的光敏剂如fac-Ⅰr(ppy)3等则不能催化该反应.通过催化剂种类及用量筛选表明,7 mol%的Co(dmgH_2)pyCl配合物具有最好的反应效果,可以获得72%的收率.控制实验表明,光敏剂、钴肟催化剂和光照都是必须的.通过底物拓展我们发现,烷基、卤素等不同取代基的苯乙烯类化合物均可以获得较好的收率,不同苯乙烯之间也可以发生交叉反应.随后,我们进一步通过光谱和中间体捕获实验对反应机理进行了研究.自由基捕获实验说明反应过程可能涉及自由基历程;光谱淬灭实验表明苯乙烯和Co(dmgH_2)pyCl均可淬灭吖啶的发光,但苯乙烯淬灭吖啶的程度远大于Co(dmgH_2)pyCl淬灭吖啶的程度.在反应时苯乙烯的浓度远大于催化剂的溶度,因此,我们认为激发态吖啶首先与苯乙烯发生反应;可见光照射反应体系1 min后在440–500和550–650 nm处观察到明显的Co~Ⅱ和Co~Ⅰ的吸收峰.基于以上实验结果,我们提出了可能的催化循环:吖啶受光激发到达激发态后,首先与底物苯乙烯发生单电子转移生成苯乙烯正离子自由基和吖啶阴离子自由基Acr~·-Mes,Acr~·-Mes还原Co(dmgH_2)pyCl生成Co ~Ⅱ中间体,从而回到基态完成光催化循环.苯乙烯正离子自由基与另一分子苯乙烯加成环合,进而通过芳构化生成自由基中间体,再与Co Ⅱ作用生成目标产物1,2-二氢-1-芳基萘和Co~Ⅰ,Co~Ⅰ通过结合体系中的质子进而释放出氢气回到Co~ Ⅲ从而完成钴肟催化循环.     

Direct Excitation of Aldehyde to Activate the C(sp2)−H Bond by Cobaloxime Catalysis toward Fluorenones Synthesis with Hydrogen Evolution

A new way to form fluorenones via the direct excitation of substrates instead of photocatalyst to activate the C(sp²)−H bond under redox-neutral condition is reported. Our design relies on the photoexcited aromatic aldehyde intermediates that can be intercepted by cobaloxime catalyst through single electron transfer for following β-H elimination. The generation of acyl radical and successful interception by a metal catalyst cobaloxime avoid the use of a photocatalyst and stoichiometric external oxidants, affording a series of highly substituted fluorenones, including six-membered ketones, such as xanthone and thioxanthone derivatives in good to excellent yields, and with hydrogen as the only byproduct. This catalytic system features a readily available metal catalyst, mild reaction conditions and broad substrate scope, in which sunlight reaction and scale-up experiments by continuous-flow approach make the new methodology sustainable and amenable for potentially operational procedures.     

Photocatalytic hydrogen production from acidic aqueous solution in BODIPY-cobaloxime-ascorbic acid homogeneous system

For the first time, iodinated BODIPY dyes with phenylamine or 8-hydroxylquinoline moiety at the meso-position on the BODIPY core were tested for the light-driven production of H₂ from the acidic aqueous solutions.     

The synthesis,characterization, and electrochemistry of molecular cobaloxime/organocobaloxime: catalysts for cycloaddition of carbon dioxide and epoxides

The new cobaloxime (1), organocobaloxime (2), and their intramolecular hydrogen (O–H?O) bridges replaced by Cu(II)-containing multinuclear cobaloximes (3–10) were synthesized and characterized by elemental analysis, ¹H and ¹³C NMR spectra, FT-IR spectra, UV–vis spectra, LC-MS spectra, molar conductivity measurements, melting point measurements, and magnetic susceptibility measurements. Their electrochemical properties were investigated using cyclic voltammetric techniques in DMSO solution. The cobaloxime or organocobaloxime (1, 2) were used as precursors, replacing intramolecular O–H?O bridges, forming multinuclear complexes (3–10). Then, these compounds were used as homogeneous catalysts for cyclic carbonate synthesis from carbon dioxide (CO₂) and epoxides. In the catalytic experiments, dimethyl amino pyridine (DMAP) was used as co-catalyst, since DMAP was a more active base with higher yield compared to other Lewis bases. It is not necessary to use solvent according to catalytic test results, important in green chemistry.     

Synthesis, characterization and structure-property relationship studies of cobaloximes with dithienylglyoxime as the equatorial ligand

The synthesis of cobaloximes, X/RCo(dThgH)₂Py (X = Cl, R = Me, Et, n-Pr, n-Bu and Bn) has been described. All the complexes have been characterized by elemental analyses and NMR spectral studies. The molecular structures of ClCo(dThgH)₂Py, MeCo(dThgH)₂Py, EtCo(dThgH)₂Py and BnCo(dThgH)₂Py complexes are determined by X-ray crystallography. The electron withdrawing nature of 2-thienyl ring affects the NMR as well as electrochemical behavior of these complexes. The electrochemical reduction from Co(III) to Co(II) and from Co(II) to Co(I) are much easier in ClCo(dThgH)₂Py as compared to chlorocobaloximes with the other dioximes (gH, dmgH, dpgH, dmestgH). The molecular oxygen insertion in the Co−C bond of benzyl complex (6) has been examined and a comparison of its reaction rate with other similar cobaloximes is discussed. The structural features of a dioxy complex Bn(O₂)Co(dThgH)₂Py (7) have also been reported.