【摘 要】
:
Focusing on a model system,i.e.the oxidative desulfurization(ODS)of dibenzothiophene(DBT)using H2O2 as oxidant in [HMIm]BF4 ionic liquid(IL),this work presents a theoretical elucidation of the dual ro
【机 构】
:
Institute of Theoretical Chemistry,Shandong University,Jinan,250100
论文部分内容阅读
Focusing on a model system,i.e.the oxidative desulfurization(ODS)of dibenzothiophene(DBT)using H2O2 as oxidant in [HMIm]BF4 ionic liquid(IL),this work presents a theoretical elucidation of the dual role of IL as catalyst and extractant by performing DFT calculations.It is found that as a catalyst,both the cation and anion of the IL play important roles in the oxidation process of DBT to dibenzothiophene sulfone(DBTO2): they act as respectively the donor and acceptor of intermolecular hydrogen bonds to promote the O-O and O-H cleavages of H2O2 and to stabilize transition state structures.With assistance of the IL,the barriers of two elementary steps involved in the transformation from DBT to DBTO2 are effectively decreased.As an extractant,both the cation and anion present stronger interactions with DBTO2 than DBT,which is attributed to the larger polarity of the former.Furthermore,calculated interaction energies of cation-molecule complexes are larger than those of anion-molecule complexes,indicating that the cation plays a more important role in the extraction and separation process of sulfur compound from fuels.
其他文献
具有稳定铁磁性和生物相容性的磁性纳米材料在自旋电子学、生物医学等方面有广泛的应用,因而一直是磁性材料设计与研究的热点。当前已经发现或者合成的典型单原子层材料,如石墨烯、氮化硼单层、过渡金属氧族化合物等,大部分不具有磁性或者只显示微弱磁性。我们将第一性原理计算与基于粒子群优化算法的结构搜索技术相结合,预测出一种新型的氮化铬单原子层材料,该材料可通过外延生长或者从块体CrN材料表面剥离等方式获得。通过
铂基催化剂是燃料电池的关键电极材料。如何提高铂基催化剂的使用效率、催化性能和稳定性是燃料电池发展和实际应用的核心问题之一。铂基材料的催化性能高度依赖于其尺寸大小、结构形状、表面原子排列和电子结构等。在纳米尺度对铂基催化剂进行结构设计和调控,对其催化性能的增强和高效利用极为关键。形状、粒径和成分可控地制备铂基纳米材料是获得新型高效低铂催化剂的有效途径,是当前研究的前沿和热点之一。在各种铂基纳米材料中
为了满足新一代便携式柔性电子器件的需求,在不牺牲超级电容器的功率密度和循环稳定性的前提下实现其能量密度的大幅提升成为现目前研究的热点[1,2]。在众多纳米结构的材料中,一维纳米阵列材料由于具有高的比表面积和优异的电子传输性能,在能量存储中具有重要的应用[3,4]。如何利用简便快速、绿色和经济的方法制备大面积有序的一维纳米材料,已成为国内外半导体纳米材料领域普遍关注的研究热点和难点。最近,我们结合电
Converting of greenhouse gas carbon dioxide using solar energy and water into renewable hydrocarbon fuels by “artificial photosynthesis” is one of the dream-technology which provides a sustainable way
在分子二维组装结构的构建与研究中,对样品退火是获得稳定结构或实现可控诱导结构转变的有效手段。间苯三甲酸分子(trimesic acid, TMA)在Ag(111)上,可形成与在Au(111)上类似的多级蜂巢状结构。对该类结构逐步退火,获得了包括“TMA-mosaic”在内的一系列组装结构。特别地,TMA-mosaic结构是一类典型的多级组装结构,并具有手性,每一单胞包含19个脱质子化的TMA分子。
高分辨电子能量损失谱和红外吸收光谱表明,低覆盖度的一氧化碳在Ru(0001)上的吸附占据顶位,随覆盖度的增加因CO分子间偶极-偶极相互作用发生吸附位的微调。利用化学修饰针尖的扫描隧道显微镜技术(Scanning Tunneling Microscope,STM)[1],清楚的观察到了一氧化碳在Ru(0001)表面上的吸附位点微调。观察到的一氧化碳吸附重构结构与低能电子衍射(Low Energy E
ZnO 在包括催化在内的各个领域应用广泛,并且在 CO2的活化转化这一研究热点中扮演着重要的角色,如 Cu/ZnO 催化 CO2/CO/H2合成甲醇[1],Pd/Cu/ZnO 催化 CO2/CH3OH 合成甲酸甲酯等[2]。尽管关于 CO2与 ZnO 表面作用的研究已有很多[1],然而分子水平的理解还有许多不足。基于此,我们利用超高真空扫描隧道显微镜(STM)研究了 CO2在 ZnO(10-10)
Samarium-catalyzed1,5-regioselective azide-alkyne [3+2]-cycloaddition,as the first example of rare earth metal-catalyzed cycloaddition of terminal alkynes to azides resulting in the formation of 1,5-d
Recently,Baos group have reported the synthesis of 3,5-disubstituted pyrazole and 3,5-disubstituted isoxazoles in excellent yields.[1,2] In this work,we aim to disclose the detailed mechanism for the
By studying four low-lying electronic states of the o-nitrophenol(two-singlet S0 and S1,and two-triplet T1 and T2)with SA-CASSCF(10,10)/6-31G(d,p)and MRCI+Q/cc-pVDZ methods,we calculated equilibrium s