光还原铁离子活化过硫酸盐系统去除水中碘海醇

过渡金属Fe2+是最经济有效且环境友好的PS活化物质,但是Fe2+易于被氧化而失去活化能力导致Fe2+/PS体系持续效果较差。为了提高Fe2+活化PS氧化降解有机污染物的效率,本论文将医学上常用的碘化X射线显影剂（ICM）的典型代表碘海醇（Iohexol）作为目标污染物,研究其在UV/PS、Fe(C2O4)33-/PS、UV/Fe(C2O4)33-/PS和Fe2+/PS 4种高级氧化体系中的降解,考查Fe(C2O4 )33-浓度、紫外光强和pH对UV/Fe(C2O4)33-/PS体系中碘海醇降解和PS活化分解的影响,并且分析体系中Fe2+浓度变化及其转化率。结果表明：4种高级氧化体系中碘海醇的氧化分解率分别为：83.8%、7.0%、98.8%、69.9%,其中,UV/Fe(C2O4 )33-/PS体系能够通过紫外光促进铁离子还原,溶液中对PS起活化作用的Fe2+逐渐释出,对碘海醇的降解最为高效彻底。随着Fe(C2O4 )33-浓度的增加,UV/Fe(C2O4 )33-/PS体系中PS的分解率不断增加,而碘海醇的降解率却先增加后减少。4种不同初始Fe(C2O4 )33-浓度下（20 μM、50 μM、100 μM、200 μM）,碘海醇降解速率依次为：100 μM ＞ 200 μM ＞ 50 μM ＞ 20 μM。在UV/Fe(C2O4 )33-/PS体系中,Fe2+浓度均是先快速增加后缓慢下降,碘海醇的降解率、PS的分解率以及Fe2+的最高转化率均与光强正相关,与pH负相关。因此,利用紫外光还原铁离子能够极大的提高提高Fe2+活化PS效率,且体系对于光强、pH等影响因素有较强的适应能力,在水处理高级氧化领域的具有较大的应用前景。     

纳米碳颗粒/氮化碳复合材料的制备及光催化性能

通过一步热聚合法制备纳米碳颗粒/氮化碳复合材料,利用XRD、FTIR、TEM、DRS、PL等手段对纳米碳颗粒/氮化碳进行了系统表征,并考察其光催化降解罗丹明B的光催化性能。结果表明,纳米碳颗粒的负载可以显著改善复合材料的可见光吸收能力及光生电子/空穴的分离效率,当加入纳米碳颗粒的质量为10 mg时,所得到的纳米碳颗粒/氮化碳2在20 min内对罗丹明B的降解率可以达到96.5%,明显优于纯氮化碳材料。此外,纳米碳颗粒/氮化碳复合材料还表现出良好的稳定性。     

衣康酸光固化树脂的研究进展

被誉为"绿色技术"的光固化技术,不仅节能环保而且经济高效,已在众多领域得以应用。利用天然可再生资源制备光固化树脂对光固化技术的可持续发展具有重要意义。衣康酸作为一种来源广泛的天然可再生资源,其分子结构中同时含有不饱和双键和两个羧基,可替代丙烯酸、己二酸等石化资源合成各种光固化不饱和树脂,所得树脂综合性能优良。本文综述了衣康酸制备光固化树脂的研究进展,主要包括环氧衣康酸树脂、衣康酸聚酯、衣康酸聚酯丙烯酸酯、衣康酸聚氨酯丙烯酸酯等。由衣康酸合成的光固化树脂在涂料、生物医药和3D打印材料等领域具有重要的应用价值,为生物质资源的高值化利用提供了新途径。     

Photocatalytic syngas synthesis from CO2 and H2O using ultrafine CeO2-decorated layered double hydroxide nanosheets under visible-light up to 600 nm

The rational design of photocatalyst that can effectively reduce CO₂ under visible light(l>400 nm),and simultaneously precise control of the products syngas(CO/H2)ratio is highly desirable for the Fischer-Tropsch reaction.In this work,we synthesized a series of CeO₂-decorated layered double hydroxides(LDHs,Ce-x)samples for photocatalytic CO₂ reduction.It was found that the selectivity and productivity of CO and H₂ from photoreduction of CO₂ in conjunction with Ru-complex as photosensitizer performed an obvious“volcano-like”trend,with the highest point at Ce-0.15 and the CO/H₂ ratio can be widely tunable from 1/7.7 to 1/1.3.Furthermore,compared with LDH,Ce-0.15 also drove photocatalytic CO₂ to syngas under 600 nm irradiation.It implied that an optimum amount of CeO₂ modifying LDH promoted the photoreduction of CO₂ to syngas.This report gives the way to fully utilize the rare earth elements and provides a promising route to enhance the photo-response ability and charge injection efficiency of LDH-based photocatalysts in the synthesis of syngas with a tunable ratio under visible light irradiation.     

Novel Ag-AgBr decorated composite membrane for dye rejection and photodegradation under visible light

Photocatalytic membranes have received increasing attention due to their excellent separation and photodegradation of organic contaminants in wastewater. Herein, we bound Ag-AgBr nanoparticles onto a synthesized polyacrylonitrile-ethanolamine (PAN-ETA) membrane with the aid of a chitosan (CS)-TiO₂ layer via vacuum filtration and in-situ partial reduction. The introduction of the CS-TiO₂ layer improved surface hydrophilicity and provided attachment sites for the Ag-AgBr nanoparticles. The PAN-ETA/CS-TiO₂/Ag-AgBr photocatalytic membranes showed a relatively high water permeation flux (~ 47 L·m^–2·h^–1·bar^–1) and dyes rejection (methyl orange: 88.22%; congo red: 95%; methyl blue: 97.41%; rose bengal: 99.98%). Additionally, the composite membranes exhibited potential long-term stability for dye/salt separation (dye rejection: ~97%; salt rejection: ~6.5%). Moreover, the methylene blue and rhodamine B solutions (20 mL, 10 mg·L⁻¹) were degraded approximately 90.75% and 96.81% in batch mode via the synthesized photocatalytic membranes under visible light irradiation for 30 min. This study provides a feasible method for the combination of polymeric membranes and inorganic catalytic materials.     

Efficient photodegradation of phenol assisted by persulfate under visible light irradiation via a nitrogen-doped titanium-carbon composite

To realize the utilization of visible light and improve the photocatalytic efficiency of organic pollutant degradation in wastewater, a nitrogen-doped titanium-carbon composite (N-TiO₂/AC) prepared by sol-gel methods was applied in the photodegradation of phenol assisted by persulfate under visible light irradiation (named N-TiO₂/AC/PS/VIS). The results show that a synergistic effect exists between visible-light photocatalysis and persulfate activation. Compared with TiO₂/PS/VIS, the phenol degradation rate was found to be observably improved by 65% in the N-TiO₂/AC/PS/VIS system. This significant increase in degradation rate was mainly attributed to the following two factors: 1) The N and C doping can change the crystal structure of TiO₂, which extends the TiO₂ absorption wavelength range to the visible light region. 2) As an electron acceptor, PS can not only prevent electrons and holes from recombining with each other but can also generate strong oxidizing radicals such as ∙SO₄^– and ∙OH to accelerate the reaction dynamics. The process of phenol degradation was found to be consistent with the Langmuir pseudo-first-order kinetic model with an apparent rate constant k of 1.73 min^–1. The N-TiO₂/AC/PS/VIS process was proven to be a facile method for pollutant degradation with high pH adaptability, excellent visible-light utilization and good application prospects.     

Regulatory Light Chains in Cardiac Development and Disease

The role of regulatory light chains (RLCs) in cardiac muscle function has been elucidated progressively over the past decade. The RLCs are among the earliest expressed markers during cardiogenesis and persist through adulthood. Failing hearts have shown reduced RLC phosphorylation levels and that restoring baseline levels of RLC phosphorylation is necessary for generating optimal force of muscle contraction. The signalling mechanisms triggering changes in RLC phosphorylation levels during disease progression remain elusive. Uncovering this information may provide insights for better management of heart failure patients. Given the cardiac chamber-specific expression of RLC isoforms, ventricular RLCs have facilitated the identification of mature ventricular cardiomyocytes, opening up possibilities of regenerative medicine. This review consolidates the standing of RLCs in cardiac development and disease and highlights knowledge gaps and potential therapeutic advancements in targeting RLCs.     

重芳烃轻质化催化剂n（Ni）/n（Ni+Mo）的优化与分析

以β分子筛为载体,在保持金属总负载量不变的情况下,采用等体积浸渍法制备了4种不同n（Ni）/n（Ni+Mo）的催化剂。分别采用X射线衍射（XRD）、比表面积测试（BET）、氨程序升温脱附（NH₃-TPD）、氢程序升温还原（H₂-TPR）、氢程序升温脱附（H₂-TPD）和热重-差热分析（TG-DTG）等方法对催化剂进行了表征。结果表明,4种催化剂的酸量和酸强度相近,在n（Ni）/n（Ni+Mo）等于基准+0.2时,Mo与载体之间的相互作用最弱,其氢气吸附量最多且积炭量最少;采用某炼厂重整C₁₀⁺ 重芳烃对4种催化剂进行评价,结果表明n（Ni）/n（Ni+Mo）等于基准+0.2催化剂具有最优的催化活性和稳定性。上述结果表明,影响重芳烃轻质化催化剂活性和稳定性的关键因素是催化剂氢气吸附量的多少,氢气吸附量越多金属表面的溢流氢效应越明显,积炭前驱体被溢流氢及时消除,从而保护了催化剂的加氢活性中心不被积炭覆盖,有助于催化剂在较高活性下保持稳定。     

Fluorescent lamp promoted formaldehyde removal over CeO2 catalysts at ambient temperature

Exploring an alternative strategy with high efficiency and low cost to abate formaldehyde (HCHO) in indoor environment, is of increasing significance for people's health. CeO₂ catalysts prepared by hydrothermal, precipitation and calcination methods were investigated for HCHO removal at ambient temperature. It is found that indoor fluorescent light visibly boosts the catalytic performance of CeO₂ catalysts for HCHO decomposition at ambient temperature. Among the CeO₂ catalysts, CeO₂ prepared from hydrothermal method (CeO₂–H) exhibits a superior catalytic performance and an excellent durability by eight recycle times. Based on the characterization and analysis, the excellent catalytic performance of CeO₂–H is mainly contributed by its abundance of surface oxygen vacancies, and photogenerated electrons and hole activated by fluorescent light. This work shows a potential practicability in HCHO pollution elimination by taking full advantage of the existing lighting in indoor environments.     

Fe/Al金属间化合物光束合金化涂层的组织分层现象

在45钢表面预涂纯Al粉，用光束合金化的方法合成了Fe／Al化合物涂层。使用SEM、EDS、X-ray衍射研究了涂层的组织特点及物相组成。研究结果表明，Fe／Al化合物涂层发生了组织分层现象，表层为FeAl Fe3AlC0.5层，第二层为Fe3Al Fe3AlC0.5层。发生组织分层现象是由合金化过程熔池中Al的含量由表层到底部逐渐减小所引起的。其原因可能与Al的密度较低和熔池搅拌不充分有关。