TiO2晶面依赖的Ir-TiOx相互作用对Ir/TiO2催化剂巴豆醛选择性加氢性能的影响

α,β-不饱和醇是一类重要的精细化学品,主要通过α,β-不饱和醛选择性加氢获得.由于α,β-不饱和醛分子中含有共轭的C=C键和C=O键,且后者键能更大,在热力学和动力学上均不利于C=O键的选择性加氢生成α,β-不饱和醇.因此,提高α,β-不饱和醛中C=O的加氢选择性是催化领域中一项挑战性的课题.巴豆醛属于典型的α,β-不饱和醛,研究其选择性加氢生成巴豆醇具有广泛的代表意义;Ir负载在具有还原性载体(如TiO2)上时,表现出很好的C=O加氢选择性,因此,成为近年来的研究热点.由于暴露不同晶面的TiO2具有不同的形貌和电子结构,因此研究Ir-TiO2相互作用的晶面依赖性及其对巴豆醛选择性加氢反应的影响具有重要意义.本文以分别暴露{101}、{100}和{001}晶面的锐钛矿TiO2纳米晶为载体,制备了负载型Ir/TiO2催化剂,系统研究了催化剂经过不同的预处理过程(在不同温度下H2还原和O2再氧化)后对巴豆醛的气相选择性加氢的性能.利用高分辨透射电镜、原位X射线光电子能谱和原位漫反射红外光谱及氨程序升温脱附等技术研究发现,预处理条件显著改变了Ir-TiOx的相互作用,包括Ir金属的几何、电子性质及催化剂表面酸性.这种相互作用与TiO2的暴露晶面密切相关,从而改变了不同Ir/TiO2催化剂上不同加氢反应行为.研究结果表明,经300℃预还原的Ir/TiO2-{101}催化剂催化性能最好,在80℃下初始反应速率为166.1 μmol g-Ir-1 s-1,巴豆醇的生成转化频率为0.022 s-1.与其他催化剂相比,Ir/TiO2-{101}催化剂表面Ir0浓度最高,表面酸度适中,因此表现出最佳的催化性能.同时Ir-TiOx界面在反应中的协同作用,对H2和巴豆醛分子中C=O键的吸附和活化起到了关键作用.然而当催化剂经过400℃的H2预还原后,由于产生了强的金属-载体相互作用使得TiOx对Ir粒子进行了包裹从而导致Ir-TiOx界面缺失,因而催化剂催化巴豆醛加氢性能降低.本文为理解金属-载体相互作用对巴豆醛选择性加氢反应的影响提供了新的见解,并为设计高性能α,β-不饱和醛选择性加氢催化剂提供了理论依据.     

Long-term super-resolution imaging of mitochondrial dynamics

Monitoring dynamics of mitochondria has become an essential approach to explore the function of mitochondria in living cells with the emergence of super-resolution fluorescence microscopy. However, long-term super-resolution imaging of mitochondria is still challenging due to the lack of photostable fluorescent probes and stable mitochondria-specific markers which are not affected by the changes of mitochondrial membrane potential. Here, we introduce a method for long-term imaging mitochondrial dynamic through the SNAP-tag fluorogenic probe based on 4-azetidinyl-naphthalimide derivatives. Using structured illumination microscopy (SIM), we observed the fusion and fission of mitochondria over a course of 16 min at 109 nm resolution. Furthermore, the interactions as well as fusion between mitochondria and lysosomes were studied during mitophagy at the nanoscale. Convincingly, the combination of SNAP-tag fluorogenic probes and super-resolution fluorescence microscopy will offer a new way to monitor dynamic mitochondria in living cells.     

Implications of Nitrogen Doping on Geometrical and Electronic Structure of the Fullerene Dimers

Because of its unsaturated bonds, C₆₀ is susceptible to polymerize into dimers. The implications of nitrogen doping on the geometrical and electronic structure of C₆₀ dimers have been ambiguous for years. A quarter‐century after the discovery of azafullerene dimer (C₅₉N)₂, we reported its single crystallographic structure in 2019. Herein, the unambiguous crystal structure information of (C₅₉N)₂ is elucidated specifically, revealing that the inter‐cage C—C single bond length of (C₅₉N)₂ is comparable with that of an ordinary C(sp³)‐C(sp³) single bond, and that the most stable conformer of (C₅₉N)₂ is gauche‐conformer with a dihedral angle of 66°. To amend the structural deviations, geometrical structure of (C₅₉N)₂ is optimized by a B3LYP‐D3BJ function, which is proved to be more consistent with its single crystal structure than those by the commonly used B3LYP function. Moreover, the calculation method is also suitable for other representative fullerene dimers, such as (C₆₀)₂ and its divalent anion. Additionally, the dissociation of (C₅₉N)₂ at 473 K under mass spectrometric conditions suggests the inter‐cage C—C bond is relatively weaker than an ordinary C—C single bond, which can be explained by the interaction energies of inter‐cages.     

Contradictory effect of gold nanoparticle-decorated molybdenum sulfide nanocomposites on amyloid-β-40 aggregation

The effect of gold nanoparticle-decorated molybdenum sulfide (AuNP-MoS₂) nanocomposites on amyloid-β-40 (Aβ₄₀) aggregation was investigated. The interesting discovery was that the effect of AuNP-MoS₂ nanocomposites on Aβ₄₀ aggregation was contradictory. Low concentration of AuNP-MoS₂ nanocomposites could enhance the nucleus formation of Aβ₄₀ peptides and accelerate Aβ₄₀ fibrils aggregation. However, although high concentration of AuNP-MoS₂ nanocomposites could enhance the nucleus formation of Aβ₄₀ peptides, it eventually inhibited Aβ₄₀ aggregation process. It might be attributed to the interaction between AuNP-MoS₂ nanocomposites and Aβ₄₀ peptides. For low concentration of AuNP-MoS₂ nanocomposites, it was acted as nuclei, resulting in the acceleration of the nucleation process. However, the structural flexibility of Aβ₄₀ peptides was limited as the concentration of AuNP-MoS₂ nanocomposites was increased, resulting in the inhibition of Aβ₄₀ aggregation. These findings suggested that AuNP-MoS₂ nanocomposites might have a great potential to design new multifunctional material for future treatment of amyloid-related diseases.     

Understanding the dehydrogenation mechanism over iron nanoparticles catalysts based on density functional theory

The conversion of chemical feedstock materials into high value-added products accompanied with dehydrogenation is of great value in the chemical industry.However,the catalytic dehydrogenation reaction is inhibited by a limited number of expensive noble metal catalysts and lacks understanding of dehydrogenation mechanism.Here,we report the use of heterogeneous non-noble metal iron nanoparticles(NPs) incorporated mesoporous nitrogen-doped carbon to investigate the dehydrogenation mechanism based on experiment observation and density functional theory(DFT) method.Fe NPs catalyst displays excellent performance in the dehydrogenation of 1,2,3,4-tetrahydroquinoline(THQ)with 100% selectivity and 100% conversion for 10-12 h at room temperature.The calculated adsorption energy implies that THQ prefers to adsorb on Fe NPs as compared with absence of Fe NPs.What is more,the energy barrier of transition state is relatively low,illustrating the dehydrogenation is feasible.This work provides an atomic scale mechanism guidance for the catalytic dehydrogenation reaction and points out the direction for the design of new catalysts.     

基于聚乙二醇接枝丙烯酸树酯光固化电解质的制备及性能研究

聚氧化乙烯(PEO)(聚乙二醇(PEG))和丙烯酸树脂在聚合物基电解质中具有很好的应用,本文通过紫外光引发单/双官能度的聚乙二醇接枝丙烯酸树脂单体聚合构建了离子电导率高、易于封装,可避免电解质泄漏的准固态聚合物电解质.通过调控聚乙二醇二甲基丙烯酸酯(PEGDA)和甲氧基聚乙二醇单甲基丙烯酸酯(PEGMA)2种单体的比例以及锂盐溶液的含量,成功制备出具有高离电导率的准固态聚合物电解质.采用傅里叶变换红外光谱仪(FTIR),电化学工作站对PEGMA/PEGDA基聚合物电解质进行表征,研究各组分比例对电解质的电化学性能影响.当PEGMA/PEGDA单体比例为75/25,锂盐溶液的占比为75%时,形成的薄膜状态电解质表现出1.96×10^?3 S·cm^?1的高离子电导率,较原始配比提高了14倍.将制备的电解质应用于电致变色器件,在580个变色循环后,器件依然可以实现稳定快速的颜色切换,2种颜色变换时间均在3 s以内,本文中研究的聚醚接枝丙烯酸树酯基电解质材料在电致变色器件中有较好的应用前景.     

SCN掺杂提高CsPbI3胶体量子点的稳定性和光探测性能

无机卤化物钙钛矿CsPbI₃胶体量子点因其优越的光电性能在光伏和发光器件领域中表现出极大的发展前景。然而,CsPbI₃较差的稳定性阻碍了实际应用。为此,我们采用SCN?离子掺杂CsPbI₃(SCN-CsPbI₃)量子点用于提高量子点的光学性能和稳定性。研究表明,SCN?离子掺杂不仅减少了量子点缺陷、改善了光学性能,还提高了Pb-X键能、量子点结晶质量以及钙钛矿结构稳定性。结果表明,SCN-CsPbI₃量子点的荧光量子产率(PLQY)超过90%,远高于未掺杂原始样品(PLQY为68%)。高的荧光量子产率表明量子点具有较低的缺陷态密度,这归咎于缺陷的减少。空间限制电荷和时间分辨荧光光谱等研究也证实SCN?离子掺杂减少了量子点的缺陷。此外,SCN-CsPbI₃量子点展现出很好的抗水性能,其荧光强度在水中浸泡4 h后依然保持85%的初始值。而未掺杂原始样品的荧光性能很快消失,这是因为水诱导其相变。基于SCN-CsPbI₃量子点的光电探测器表现出宽波域响应(400–700 nm),高的响应率(90 mA·W^?1)和超过1011 Jones的探测度,远高于未掺杂原始量子点探测器的性能(响应率为60 mA·W^?1和探测度为1010 Jones)。     

Organophosphine bearing multiple hydrogen-bond donors for asymmetric Michael addition reaction of 1-oxoindane-2-carboxylic acid ester via dual-reagent catalysis

Multiple hydrogen bonds containing nucleophilic phosphines derived from dipeptide dual-reagents catalyzed asymmetric Michael addition reactions between indene esters and activated olefins in high yields and good to excellent enantioselectivities under mild reaction conditions. The success of current highly selective reactions should provide inspiration for expansion to other reactions and would open up new paradigms for the synthesis of indanone derivatives bearing chiral quaternary carbon centers.     

Ruthenium(II)-catalyzed para-selective CH difluoroalkylation of aromatic aldehydes and ketones using transient directing groups

A Ru(II)-catalyzed para-difluoroalkylation of aromatic aldehydes and ketones with a transient directing group has been developed. It utilizes less expensive ruthenium catalysts and allows facile access to challenging difluoroalkylated aldehydes. The mechanism studies suggest that the distinct coordination mode of ruthenium complex with imine moieties is responsible for para-selectivity.     

Site-Specific Detection of Free Radicals in Membranes Using an Amphiphilic Spin Trap

The detection of free radicals and related species has attracted considerable attention in recent years due to their critical roles in physiological and pathological processes. Among the various methods for the detection of free radicals, electron spin resonance coupled with spin-trapping technique has been an effective approach for the characterization and quantification of free radicals due to its high specificity. In this study, we designed and synthesized a novel amphiphilic spin trap, 2-(diethoxyphosphoryl)-2-heptadecanyl-3,4-dihydro-2H-pyrrole-1-oxide (DEPHdPO), from 5-(diethoxyphosphoryl)-5-methyl-1-pyrroline-N-oxide with a long hydrocarbon chain at the C-5 position of the pyrroline ring, providing the amphiphilic character. The free-radical-trapping ability of DEPHdPO was evaluated by capturing hydroxyl radicals (^·OH), superoxide anions (\( {\text{O}}_{2}^{ \cdot - } \)), and carbon-centered free radicals in a model membrane prepared from sodium dodecyl sulfate (SDS). The results indicate that the hydrophobic hydrocarbon chain of DEPHdPO can be inserted into the inner core of SDS micelles, and the hydrophilic nitronyl functional moiety is located on the surface layer. Thus, various free radicals, including ^·OH radicals, \( {\text{O}}_{2}^{ \cdot - } \) anions, and carbon-centered radicals could be site-specifically detected near the membrane surface. Moreover, DEPHdPO could be successfully located on the surface of thylakoid membranes, and the nearby photo-initiated \( {\text{O}}_{2}^{ \cdot - } \) anions could be trapped site-specifically.