糠醛氧化合成糠酸

糠酸作为糠醛的重要下游产品,在食品制造、材料制备、光学技术、药物合成中具有重要的应用,可用于合成防腐剂、增塑剂、热固性树脂、香料以及多种药物。目前,关于糠醛的制备以及催化氢化制备下游产物的综述报道相对较多,但是还没有系统地整理评述糠醛氧化合成糠酸的相关工作。本文综述了近年来以糠醛为主要原料制备糠酸的研究进展情况,讨论了不同催化体系及在不同氧源存在下对糠酸选择性的影响,重点突出了非均相催化剂在糠酸的工业化制备中的应用前景,对糠酸制备的未来发展方向进行了展望。     

X射线荧光光谱法测定农田底泥中8种元素

建立X射线荧光光谱法测定农田底泥样品中砷、铬、铜、锰、镍、铅、锌、铁8种元素含量的分析方法.以塑料环粉末压片法制样,选用50种土壤、水系沉积物标准物质拟合校准曲线,探讨各元素的测定条件.当待测样品与建立校准曲线的标准样品粒径均小于75μm时,能够有效减少矿物效应和粒度效应的影响,从而提高检测准确度;各元素在各自的含量范...     

ATMP(氨基三甲叉膦酸)及其顺磁性Co(Ⅱ)配合物的核磁共振研究

本文用¹H、³¹P和¹³C核磁共振谱研究了ATMP(氨基三甲叉膦酸,以简式H₆L表示)及其顺磁性Co(Ⅱ)配合物。测定了不同C_co/C_ATMP摩尔比在不同pH值下的各向同性位移。定性地讨论顺磁性Co(Ⅱ)配合物在不同pH条件下的组成、电荷和空间构型变化对化学位移的影响。运用快速交换反应中化学位移与配合物浓度的关系,确定不同pH下的条件稳定常数。     

超高效液相色谱-串联质谱法测定大气细颗粒物中全氟烷基酸及其替代物

建立了超高效液相色谱-串联质谱(UPLC-MS/MS)同时测定大气细颗粒物(PM2.5)中全氟烷基酸(PFAAs)及其全氟辛烷磺酸(PFOS)替代物的方法.将采样后的石英滤膜截取1/2,剪碎后以甲醇作为提取溶剂,在40oC超声提取3次,将提取液合并,离心后将上清液经ENVI Carb固相萃取柱净化,流出液经氮气吹干后,...     

Mn掺杂VWTi催化剂宽温区脱硝实验研究

采用溶胶凝胶法制备了一系列锰掺杂VWTi催化剂,在固定床反应装置上测试了催化剂宽温区脱硝性能,同时考察了催化剂的制备工艺、烟气组分、反应温度、空速等因素对催化剂宽温区脱硝活性的影响,并借助BET、XRD、XPS、SEM和H2-TPR等手段对催化剂进行表征分析.结果表明,Mn掺杂显著提高了催化剂在200–300 ℃的脱硝...     

氧化石墨烯-富里酸复合光催化剂的制备与分析

以氧化石墨烯作为载体,通过一种方便的自组装方法将富里酸分子固定在氧化石墨烯上,合成新型复合光催化材料GO-FA,并通过SEM、XRD、XPS等一系列的分析手段对其进行表征测试.同时,以尼泊金甲酯模拟废水,结合自由基捕获试验对降解机理进行探讨并进行对不同降解影响因素进行探究.表征结果显示富里酸颗粒包裹在氧化石墨烯表面,表...     

硫化钴装饰BiVO4光阳极提升其光电化学水分解性能

太阳能驱动的光电化学(PEC)水分解可以有效地将太阳能转化为化学能,作为解决环境排放和能源危机最具前景的途径之一,已经引起了科学界的广泛关注.PEC水分解系统由两个半反应组成:在光阳极上的析氧反应(OER)和光阴极上的析氢反应(HER).PEC系统的太阳能转化效率主要由光阳极/电解质界面的OER过程所决定,这是一个非常复杂且涉及质子偶联的多步四电子转移过程.钒酸铋(BiVO₄)是应用于PEC水分解的典型且具有实际应用前景的光阳极材料之一.然而,由于不良的表面电荷转移、电荷在光阳极/电解质结面处的表面复合以及缓慢的OER动力学等因素,导致BiVO₄的PEC性能受到严重限制.本文开发了一种新颖有效的解决方案,以低成本、高电导率和具有快速电荷转移能力的硫化钴装饰来提升BiVO₄光阳极的PEC活性,X射线多晶衍射(XRD)、X射线光电子能谱(XPS)、扫描电子显微镜(SEM)、透射电子显微镜(TEM)等表征,研究结果表明CoS成功装饰于BiVO₄表面.采用紫外-可见吸收光谱(UV-VisDRS)研究了BiVO₄和复合光阳极CoS/BiVO₄的光学性质,结果表明,与纯的BiVO₄相比,CoS/BiVO₄光阳极在可见光范围内光吸收能力有所增强.将制备的BiVO₄和CoS/BiVO₄光阳极应用于PEC分解水实验中,结果表明,相对于1.23 V可逆氢电极,在光照下,CoS/BiVO₄光阳极的光电流密度显著提升,可高达3.2 m Acm^-2,是纯BiVO₄的2.5倍以上.与纯BiVO₄相比,CoS/BiVO₄光阳极的起始氧化电位显示出负向偏移0.2 V,表明析氧过电势得到有效减小.入射光子转换效率(IPCE)测试结果表明,CoS/BiVO₄光阳极的入射光子转换效率在500 nm之前的可见光范围内得到明显提升,其中,CoS/BiVO₄的IPCE值在380 nm处达到最大.此外,由于CoS的装饰作用,CoS/BiVO₄光阳极的电荷注入效率和电荷分离效率均得到较大的提升,分别达到75.8%(相较于纯BiVO₄光阳极的36.7%)和79.8%(相较于纯BiVO₄光阳极的66.8%).电化学阻抗谱(EIS)测试结果表明,通过CoS的装饰,CoS/BiVO₄光阳极的界面电荷转移电阻得到有效降低,证明其界面电荷转移动力学得到有效提升.光致发光光谱测试结果表明,CoS的装饰显著提高了BiVO₄的光生电子-空穴对的分离效率,进一步证明BiVO₄表面的CoS装饰在其PEC分解水中起着非常积极的作用.本文为通过表面修饰设计应用于PEC水分解的有效的光阳极提供了新思路.     

亲锂电解液在LiNi0.6Mn0.2Co0.2O2／Li二次锂金属电池中的电化学性能

金属锂电池被认为是具有良好前景的下一代高能量密度电池。然而,传统的碳酸酯类电解液与锂的亲和性差,在循环过程中由于锂枝晶的生长和固体电解质膜（SEI）的不稳定导致金属锂电池性能快速衰减。采用1.2 mol／L六氟磷酸锂（LiPF₆）／二氟草酸硼酸锂（LiDFOB）／氟代碳酸乙烯酯（FEC）／碳酸二乙酯（DEC）,并添加了双三氟甲磺酰亚胺锂（LiTFSI）作为电解液,对其在LiNi_0.6Mn_0.2Co_0.2O₂／40 μm-Li（单位面积上负／正极材料的实际容量的比N／P＝2.85）电池中的电化学性能进行了研究。LiNi_0.6Mn_0.2Co_0.2O₂／40 μm-Li电池表现出优异的循环稳定性（循环120圈后,容量保持率>93%）和倍率性能（3C倍率下放电比容量为110 mA·h／g）。良好的电化学性能主要归因于该电解液可以在金属锂表面形成致密且稳定的SEI,并抑制锂枝晶的产生。     

基于混酸回流制备碳点的中和过程

Carbon dots (C dots) are relatively novel carbon nanomaterials that have attracted significant interest due to their unique photoluminescence, good biocompatibility, and stability. The preparation methods of C dots was usually summarized into "top-down" and "bottom-up", and mixed acid reflux is a top-down strategy that can be used to synthesize C dots, during which neutralization is a necessary step that can significantly influence the properties and potential applications of the final product. Previously, this research area mainly focused on tuning the properties of C dots by changing the starting materials and/or varying the reaction conditions; the influence of the reagents used during neutralization has been largely ignored. As the previously reported C dots prepared by mixed acid reflux were obtained from different starting materials under varied conditions, a meaningful comparison is difficult. Herein, yellow-emitting C dots were prepared by mixed acid-refluxing a carbon-rich material derived from fullerene carbon soot. For the same batch of as-prepared C dots, the influences of four reagents, i.e., NaOH, Na₂CO₃, K₂CO₃, and NH₃·H₂O, during neutralization on the structures and photoluminescence of the resulting C dots were investigated in detail. The results of thermogravimetric analysis, Fourier transform infrared spectroscopy, and X-ray photoelectron spectroscopy clearly showed that the reagent used during neutralization can affect the degree of dissociation of the acidic functional groups on the C dots. This is further supported by examination of the C dot/surfactant mixtures where subtle changes in the phase behavior were observed. Structural changes of the C dots cause variations in their surface states, ultimately altering the optical characteristics, including UV-vis absorption and fluorescence. Among the treated C dots, the sample prepared with Na₂CO₃ showed the strongest emission under the same excitation wavelength, while that prepared with NH₃·H₂O exhibited a distinct red shift (~8 nm) in the emission curve. The results presented herein provide clear evidence that neutralization reagent selection is important for optimizing the properties of the resulting C dots obtained by mixed acid reflux. In addition, the photoluminescence of the C dots can be influenced by their counterions, providing a novel method for tuning the properties of C dots while explaining their behavior in saline solutions. In short, the basicity of the neutralizing reagent and the type of counterions affect the structure of the C dots surface, which brings different performances. This work reminds researchers that it is necessary to use the type of neutralizing reagent as an experimental condition when preparing C dots in the future.