Pd(OAc)2与有机膦在氯代烷中的反应机理

应用电子自旋捕获技术(EPR-ST)研究了Pd(OAc)₂与有机膦dppm(二,二苯基膦甲烷)及dppe(二,二苯基膦乙烷)在氯代烷中反应生成新奇配合物PdCl₂[PPh₂CHClPPh₂]这一新反应的反应机理,所用捕获剂为PBN和POBN,得到EPR实验谱并进行了模拟.提出了反应机理并进行了讨论.反应经过dppm的均裂、夺氯、夺氢后生成新配体[PPh₂CHClPPh₂],然后发生配位取代和配位反应,生成新的配合物PdCl₂[PPh₂CHClPPh₂].并对影响反应的因素进行了探讨,溶剂效应在此类自由基反应中起重要作用,其极性对反应的发生影响很大,主要是对过渡态1及2的影响.Pd(OAc)₂在反应中既是反应物还是引发剂,在反应中起分子诱导作用.     

CCl2(A1B1)被甲烷及氯代甲烷猝灭动力学

用放电-LIF实验装置,对CCl4/Ar混合气体放电产生*CCl2,再用541.52nm激光将电子基态*CCl2激发到激发态A1B1(0,4,0)模pR1能级上,检测激发态*CCl2时间分辨荧光信号,测得室温下*CCl2(A1B1)被甲烷及氯代甲烷分子猝灭的实验结果,用三能级模型分析处理实验数据获得态分辨速率常数kq1,kq2和kq3值和*CCl2(A1B1→X1A1)及(a3B1→X1A1)自发辐射寿命分别为(0.83±0.03)μs和(3.12±0.25)μs.     

SAPO-34分子筛中多甲基苯分子与卤代甲烷偕甲基化反应的密度泛函理论研究

利用周期性密度泛函理论研究了SAPO-34分子筛催化转化卤代甲烷制取低碳烯烃反应的碳池主要成分多甲基苯分子的偕甲基化反应。氯甲烷和溴甲烷分子在SAPO-34分子筛内的吸附能分别是–18和–22 kJ/mol,由于氯和溴原子相似的电负性,氯甲烷和溴甲烷分子的吸附能并未被精确区分。以氯甲烷和溴甲烷为甲基化试剂,得到了几种多甲基苯分子的偕甲基化反应能及能垒,结果表明,六甲基苯分子(HMB)的偕甲基化反应为放热反应,而其余甲基苯分子的偕甲基化反应为吸热反应。对于上述两种甲基化试剂,体积最大的HMB均表现出最低的偕甲基化反应能垒,这可能是由于分子筛骨架与多甲基苯分子之间的静电相互作用增强了HMB的反应活性所致。     

Compound-specific stable isotope analysis of organic contaminants in natural environments: a critical review of the state of the art,prospects, and future challenges

Compound-specific stable isotope analysis (CSIA) using gas chromatography-isotope ratio mass spectrometry (GC/IRMS) has developed into a mature analytical method in many application areas over the last decade. This is in particular true for carbon isotope analysis, whereas measurements of the other elements amenable to CSIA (hydrogen, nitrogen, oxygen) are much less routine. In environmental sciences, successful applications to date include (i) the allocation of contaminant sources on a local, regional, and global scale, (ii) the identification and quantification of (bio)transformation reactions on scales ranging from batch experiments to contaminated field sites, and (iii) the characterization of elementary reaction mechanisms that govern product formation. These three application areas are discussed in detail. The investigated spectrum of compounds comprises mainly n-alkanes, monoaromatics such as benzene and toluene, methyl tert-butyl ether (MTBE), polycyclic aromatic hydrocarbons (PAHs), and chlorinated hydrocarbons such as tetrachloromethane, trichloroethylene, and polychlorinated biphenyls (PCBs). Future research directions are primarily set by the state of the art in analytical instrumentation and method development. Approaches to utilize HPLC separation in CSIA, the enhancement of sensitivity of CSIA to allow field investigations in the µg L^–1 range, and the development of methods for CSIA of other elements are reviewed. Furthermore, an alternative scheme to evaluate isotope data is outlined that would enable estimates of position-specific kinetic isotope effects and, thus, allow one to extract mechanistic chemical and biochemical information.Abbreviations BTEX benzene, toluene, ethylbenzene, xylenes - MTBE methyl tert-butyl ether - PAHs polycyclic aromatic hydrocarbons - VOCs volatile compounds - PCBs polychlorinated biphenyls - CSIA compound-specific (stable) isotope (ratio) analysis - GC-IRMS, GC/IRMS or GCIRMS gas chromatography-isotope ratio mass spectrometry - GC-C-IRMS, GC/C/IRMS or GCC-IRMS gas chromatography-combustion-isotope ratio mass spectrometry - irmGC/MS isotope ratio monitoring gas chromatograph-mass spectrometry - GC/P/IRMS gas chromatography-pyrolysis-isotope ratio mass spectrometry (used for D/H) - KIE kinetic isotope effect - PSIA position-specific isotope analysis (for intramolecular isotope distribution) - SNIF-NMR site-specific natural isotopic fractionation by nuclear magnetic resonance spectroscopy