稳定氯同位素分析技术及其在有机氯污染物研究中的应用

有机氯污染物是近几十年环境科学持续关注的热点,传统研究以环境化学为主。随着同位素分析技术日趋高效便捷,氯同位素分析技术也开始在有机污染研究中得到更多应用。本文综述了稳定氯同位素分析技术的研究进展,介绍了氯同位素技术在有机污染物研究中的应用现状,并对其研究趋势进行了展望。单体同位素分析技术有助于开展有机氯污染物的同位素相关理论及应用研究;双路-同位素质谱和热电离质谱方法是测试精度较高的两种氯同位素测试方法,但是前处理过程繁杂、样品用量较大,不能满足环境样品中痕量的有机氯污染物分析;在线同位素测试技术提高了分析方法的灵敏度,拓宽了单体氯同位素分析技术在环境有机污染研究中的应用范围,是未来环境有机污染研究的趋势之一, 有待深入研究。目前氯同位素分析主要应用在环境有机污染物的溯源、降解途径的辩识和降解效率的量化等方面,尚需加强相关理论和应用研究。     

高温自蔓延技术在环境保护领域中的应用

高温自蔓延技术具有反应温度高、能量利用效率高、处理过程快速、不需要大设备和设施投入等特点,已在环境保护和污染控制领域得到了广泛的关注及研究。本文回顾了近20年来高温自蔓延技术在环境保护领域应用的研究状况,主要从以下4个方面进行综述:(1)高温自蔓延技术在固体废物处理、处置中的应用;(2)高温自蔓延技术在高放废物固化、稳定化中的应用;(3)高温自蔓延技术在有机污染控制过程中的应用;(4)高温自蔓延技术合成环境功能材料的应用等。文中着重介绍了高温自蔓延技术在各应用领域所取得的理论和工程实践成果,特别是近年来机械诱发自蔓延、全废物型自蔓延和自蔓延废物处理流水线等技术在废物处理和资源回收领域的应用。此外,还指出了环保高温自蔓延研究领域的不足并展望了今后的发展趋势。     

同位素稀释高分辨气相色谱-高分辨质谱法测定土壤中痕量有机氯农药残留

建立了同位素稀释高分辨气相色谱-高分辨质谱测定土壤中痕量有机氯农药残留的分析方法。采用加速溶剂法萃取土壤样品,以正己烷/丙酮(体积比为1:1)为提取溶剂,提取液经过Florisil硅土固相萃取小柱净化后,采用高分辨DB-5MS毛细管色谱柱(30 m×0.25 mm×0.25 μm)分离,以保留时间和同位素特征离子丰度比定性,同位素峰面积比定量。实验结果表明,方法的回收率为77.3%～114.5%,相对标准偏差(RSD)≤10.81%（n=5）,检出限均小于0.04 pg/g。应用该方法检测某地区表层土壤中的有机氯农药,结果表明该方法适合测定环境土壤背景中痕量有机氯残留。     

Two-Dimensional Gas Chromatography. Concepts,Instrumentation, and Applications – Part 1: Fundamentals,Conventional Two-Dimensional Gas Chromatography,Selected Applications

The writer of this review published in 1978 a three-part article on two-dimensional gas chromatography in the first three issues of this journal [1]. The review was written at a time when capillary column GC was still in its infancy. Commercial columns were (essentially) unavailable and sample introduction into capillary columns was done exclusively in the split mode. Two-dimensional separations were explored in only a few laboratories. The limitations of capillary column technology made this exercise rather difficult. The introduction of fused silica capillary columns in the early eighties drastically changed the landscape in which gas chromatography was practiced. It took the chromatographic community just a few years to convert from packed columns to capillary columns. Instrumentation and accessories specifically designed for capillary column use came onto the market. This writer had great hopes that the revolution in capillary column GC would be mirrored in the development of instrumentation for Two-Dimensional Gas Chromatography. This never materialized. On the contrary, tentative steps taken by a few manufacturers and suppliers of chromatographic equipment fizzled out. It was perhaps the introduction of relatively inexpensive and user friendly GC/MS instrumentation, in combination with nearly indestructible fused silica capillary columns that took away the incentive to develop commercially viable Two-Dimensional Gas Chromatography. Much of the thinking went like this: why insist on good chromatography if mass spectrometry can do the job without the need for complete separation. Some progress in the further development of conventional Two-Dimensional Gas Chromatography has certainly been made over the last 20 years but there has not been a great deal of excitement. Applications have also been relatively sparse and they are limited to just a few areas. Science does not remain static and chromatography is no exception. Progress in gas chromatography is driven by new technology and ideas. Substantial improvements in two-dimensional GC were not forthcoming until Phillips and his research group introduced and implemented an entirely new form of Two-Dimensional Gas Chromatography, called comprehensive two-dimensional GC, or GC×GC. This breakthrough occurred only in 1991 [2]. It does take some time before scientists change attitudes and habits. There is always a time lag between the introduction of new technology and its general acceptance. The public's attitude toward comprehensive Two-Dimensional Gas Chromatography is probably no exception. The number of scientists who are actively pursuing this new branch of gas chromatography is still very small. It is often a single individual who carries the torch. J.B. Phillips' name is synonymous with comprehensive Two-Dimensional Gas Chromatography. He is not only its inventor and proponent but his fertile mind has initiated research in other related areas. Sadly, he passed away shortly before this review was written. This contribution is dedicated to his memory.     

毛细管气相色谱法测定食品、中药中的有机氯农药

建立食品和中药中有机氯农药残留量的毛细管气相色谱检测方法。样品经有机溶剂超声提取,硫酸净化,采用OV-1701毛细管柱,不分流分流进样,程序升温分离,电子捕获检测器检测,外标法定量,平均回收率为84.3%~100.6%,RSD为1.28%~3.56%。该法操作简便,重复性及分离效果好。     

顶空固相微萃取气相色谱法测定水中有机氯农药及类似物

用溶胶凝胶聚甲基苯基乙烯基硅氧烷萃取探头,顶空固相微萃取与气相色谱法联用,电子捕获检测器测定湖水中的有机氯化合物,方法检出限小于35.3ng/L,相对标准偏差不大于11.8%(n=3),线性相关系数大于0.990,回收率为71.5%~115.5%。可用于水中痕量有机氯化合物的监测。     

气相色谱法测定中药材中有机氯农药的残留量

对中药中11种有机氯农药的毛细管气相色谱测定方法进行了研究。以水-丙酮（3：7,V／V）为提取剂,采用超声波辅助提取中药中残留的农药,经正己烷液一液分配,浓硫酸净化,采用不分流进样方式,用HP-5弹性石英毛细管柱经柱程序升温技术分离,并用电子捕获检测器检测,峰面积外标法定量,取得了较好的效果。方法的添加回收率在（80．2～118．4）％,相对标准偏差为（1．02～11．1）％,从而建立了中药中有机氯农药残留测定的新方法。     

加速溶剂萃取-磁固相萃取净化-气相色谱-质谱法测定土壤中16种多环芳烃和23种有机氯残留

建立了加速溶剂萃取（ASE）、磁固相萃取净化（MSPE）、气相色谱-质谱（GC-MS）测定土壤中多环芳烃和有机氯残留的方法。ASE萃取溶剂为丙酮-正己烷（1：1，v/v），萃取温度为100℃，萃取压力为11.032 MPa，加热时间为5 min，静态萃取时间为5 min，循环萃取3次，冲洗体积为60%萃取池体积，氮气吹扫100 s。然后采用室温制备法自制ZIF-8/nZVI磁性材料用于净化萃取液，将净化液浓缩定容后进行GC-MS测定。多环芳烃和有机氯的线性范围为5~200 μg/kg，线性相关系数（r²）均大于0.99；目标物的检出限（LOD，S/N=3）为0.04~1.21 μg/kg。所建方法成功用于土壤样品中16种多环芳烃和23种有机氯的测定，在3个加标水平下得到的加标回收率为63.9%~112.1%，相对标准偏差（RSD）为0.4%~26.2%。研究结果表明，该方法具有灵敏度高、重现性好、回收率高等特点，适用于土壤中多环芳烃和有机氯残留的检测。     

毛细管气相色谱法测定牛奶中有机氯和有机磷农药残留量

采用一个较快速、简单的方法测定牛血中有机氯和有机磷农药残留物。牛奶中农残经氯仿萃取和固相提取净化后，分别用气相色谱－电子捕获检测器和气相色谱－火焰光度检测器直接测定，色谱柱为ＨＰ－１接ＨＰ－５、ＤＢ１７大口径石英毛细管柱。本法对１７种有机氯农残的回收效率范围为７１．２％￣９９．７％，检测限为０．５￣９μｇ／ｋｇ。而１１种有机磷农残的回收率范围为７０．１％￣９６．１％，检测限则为０．０１￣０．０４ｍ     

人参中有机氯类农药残留的研究

结合气相色谱分析技术，对人参中有机氯类农药残留的检测方法及残留情况进行了研究，以探讨其安全性。