基于氮掺杂活性炭催化氧化合成氮甲基氧化吗啉的研究

以三聚氰胺为氮源,商用活性炭为研究对象,通过“浸渍吸附+高温热处理”的方式制得系列氮掺杂活性炭,并用于催化氧化合成氮甲基氧化吗啉（NMMO）。采用N₂吸附/脱附、Raman、XPS等对氮掺杂活性炭的孔结构和表面性质进行了表征。结果表明：随着三聚氰胺负载量的增大,氮掺杂活性炭的表面碱性含氮官能团含量增大,进而体现出更好的催化氧化合成NMMO活性。最佳催化剂（ACO850-20N）在催化剂加量为0.02 wt%,反应温度70 ℃和反应时间4 h的工艺条件下,氮甲基吗啉的转化率和NMMO收率可达99.76%和94.31%。      

中温冷水机组诱导系统分析

中温冷水机组诱导系统由三部分组成:中温冷水机组、集约型空气处理机组、末端诱导室。集约型空气处理机组采用椭圆管换热技术实现13℃低温送风的同时,将供回水温度提高至10/20℃。对该系统及一次回风系统进行分析,对比结果发现,处理相同房间空气时,中温冷水机组诱导系统的输入比一次回风系统输入少178.28k W,可节能42.29%;中温冷水机组诱导系统的损失比一次回风系统的损失低,两系统对应效率分别为9.49%和5.58%。     

《应用化学》第31卷(1～12期)总目次

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磺酸功能化介孔聚合物催化“一锅法”无溶剂合成3,4-二氢嘧啶-2(1H)-酮

通过软模剂合成方法合成了高度有序具有二维六方(p6mm)的FDU-15介孔聚合物材料.利用气固相磺化法制备得到新型磺酸基功能化介孔聚合物固体酸(FDU-SO3H).通过X-射线衍射(XRD)、扫描电镜(SEM)及元素分析等测试手段对FDU-SO3H介孔材料的物化性能进行了表征.在无溶剂条件下,FDU-SO3H能有效地催化以芳香醛、乙酰乙酸甲酯和尿素(或硫脲)的三组分一锅法的Biginelli反应.在优化实验的条件下,合成了一系列3,4-二氢嘧啶-2(1H)-酮衍生物.考察了加料顺序、溶剂及反应底物对Biginelli反应的影响.苯甲醛、乙酰乙酸甲酯和尿素在无溶剂,90℃加热1 h的条件下反应,3,4-二氢嘧啶-2(1H)-酮的产率为91%.探讨了Biginelli可能的反应机理.实验结果证明,FDU-SO3H不仅具有催化活性高、对环境友好及在空气中稳定等优点,而且重复使用后仍能保持优异的催化活性.     

具有红光发射的稀土上转换发光纳米晶及其介孔直接功能化

红光发射稀土上转换发光纳米晶(UCNPs)在光动力治疗(PDT)等方面具有特定的优势。将油溶性的UCNPs通过表面改性转变为水溶性,对其在生物医疗、疾病诊断等方面的应用具有重要意义。利用一种简单易行的方法将具有红光发射的UCNPs进行介孔直接功能化表面修饰,制备了一种具有良好水溶性的纳米材料NaYF4:Yb/Er/Mn@mSiO2。实验结果表明该材料核-壳结构明显,形貌均一,在980 nm的激发下保持了上转换发光特性。该材料在光动力治疗等方面具有良好的潜在应用价值。     

含Ti的HMS介孔材料催化剂及其对丙烯环氧化催化性能的研究

分别用水热合成法和气相四氯化钛(TiCl4)接枝法制备了Ti-HMS和Ti/HMS催化剂.表征结果表明,经过气相TiCl4接枝后的样品依然保持HMS(Hexagonal Mesoporous Silica,缩写为HMS)介孔材料特征,钛(Ti)物种主要以四配位的活性位形式存在.经过甲基接枝处理的催化材料,增加了表面的疏水性.丙烯环氧化反应结果表明,SN-Ti/HMS具有更高的催化性能.在2 500 h的稳定试验中,过氧化氢异丙苯(CHP)转化率大于99.0%,环氧丙烷(PO)选择性大于96.0%.研究和优化了环氧化反应工艺条件.采用浓度为30%的CHP为原料,CHP重量空速为1.0 h-1,床层温度为100℃,反应压力为3.0 MPa.     

大孔树脂分离提取人参茎叶中的人参皂甙

选择了10种大孔吸附树脂,比较其对人参茎叶提取液中人参皂甙的吸附量和解析率,筛选了较优的人参皂甙吸附剂,并对其吸附动力学曲线和动态解析曲线进行了探究。实验结果表明,人参茎叶提取液经LX-R2树脂吸附,用浓度70%的乙醇洗脱,人参皂甙解吸率达92%以上,纯度达85%以上。静态的、动态的吸附、解吸实验表明大孔树脂LX-R2为分离人参皂甙较为理想的吸附材料。     

CH4 reforming with CO2 for syngas production over La2O3 promoted Ni catalysts supported on mesoporous nanostructured γ-A12O3

Nanostructured -y-A12O3 with high surface area and mesoporous structure was synthesized by sol-gel method and employed as catalyst support for nickel catalysts in methane reforming with carbon dioxide. The prepared samples were characterized by XRD, N2 adsorption-desorption, TPR, TPO, TPH, NH3-TPD and SEM techniques. The BET analysis showed a high surface area of 204 m2.g-1 and a narrow pore-size distribution centered at a diameter of 5.5 nm for catalyst support. The BET results revealed that addition of lanthanum oxide to aluminum oxide decreased the specific surface area. In addition, TPR results showed that addition of lanthanum oxide increased the reducibility of nickel catalyst. The catalytic evaluation results showed an increase in methane conversion with increasing lanthanum oxide to 3 mol% and further increase in lanthanum content decreased the catalytic activity. TPO analysis revealed that the coke deposition decreased with increasing lanthanum oxide to 3 mol%. SEM and TPH analyses confirmed the formation of whisker type carbon over the spent catalysts. Addition of steam and Oxide to drv reformin feed increased the methane conversion and led to carbon free ooeration in combined orocesses.     

石墨烯纳米孔的制备及λ-DNA穿孔初步研究

纳米孔测序是有可能实现"$1,000 Genome"目标的技术之一.近年来,研究较多的纳米孔有蛋白质纳米孔和硅基材料的固态纳米孔.蛋白孔寿命比较短,而基于硅基底的固态纳米孔深度显著超过单链DNA相邻碱基的间距,所以,无法实现DNA的单个碱基的分辨.作者用聚焦离子束先制造氮化硅基底,并在该基底上铺设石墨烯,再用聚焦电子束刻蚀石墨烯,获得直径10 nm以下的纳米孔,初步分析了DNA穿越纳米孔时产生的电信号及穿孔噪音,向单层石墨烯纳米孔测序DNA迈出了一步.     

溶剂诱导翻转Pickering乳液用于原位循环使用酶催化剂

Separation and recycling of catalysts are crucial for realizing the objectives of sustainable and green chemistry but remain a great challenge, especially for enzyme biocatalysts. In this work, we report a new solvent-induced reversible inversion of Pickering emulsions stabilized by Janus mesosilica nanosheets (JMSNs), which is then utilized as a strategy for the in situ separation and recycling of enzymes. The interfacial active solid particle JMSNs is carefully characterized by scanning electron microscopy (SEM), transmission electron microscopy (TEM), nitrogen sorption experiments, Fourier transform infrared (FT-IR) spectroscopy, and thermogravimetric analysis (TGA).The JMSNs are demonstrated to show order-oriented mesochannels with a large specific surface area, and the hydrophobic octylgroup is selectively modified on one side of the nanosheets. Furthermore, the inversion is found to be a fast process that is strongly dependent on the interfacial activity of the solid emulsifier JMSNs. Such a phase inversion is also a general process that can be realized in various oil/water phasic systems, including ethyl acetate-water, octane-water, and cyclohexane-water systems. By carefully analyzing the capacity of JMSNs with different surface wettabilities for phase inversion, a triphase contact angle (θ) close to 90° and a critical oil-water ratio of 1 : 2 are identified as the key factors to achieve solvent-induced phase inversion via a catastrophic phase inversion mechanism. Importantly, this reversible phase inversion is suitable for the separation and recycling of enzyme biocatalysts that are sensitive to changes in the reaction medium. Specifically, during the reaction, the organic substrates are dissolved in the oil droplets and the water-soluble catalysts are dispersed in the water phase, while a majority of the product is released into the upper oil phase and the enzyme catalyst is confined inside the water droplets in the bottom layer after phase inversion. The perpendicular mesochannels of JMSNs provide a highly accessible reaction interface, and their excellent interfacial activity allows for more than 10 rounds of consecutive phase inversions by simply adjusting the ratio of oil to water in the system. Using the enzymatic hydrolysis kinetic resolution of racemic acetate as an example, our Pickering emulsion system shows not only a 3-fold enhanced activity but also excellent recyclability. Because no sensitive chemical reagents are used in this phase inversion process, the intrinsic activities of the catalysts can be preserved even after seven cycles. The current study provides an alternative strategy for the separation and recycling of enzymes, in addition to revealing a new innovative application for Janus-type nanoparticles.