1[1]Bloemen H J T, Burn J. Chemistry and Analysis of Volatile Organic Compounds in the Environment. New York: Blackie Academic & Profess-Lowal, 1993
2[2]Riederer M, Sch?nherr J. Accumulation and transport of (2,4- dichlorophenoxy) acetic acid in plant cuticles: 1. Sorption in the cuticular membrane and its components. Ecotox Environ Safety, 1984, 8: 236~247
3[3]Welke B, Ettlinger K, Riederer M. Sorption of volatile organic chemicals in plant surface. Environ Sci Technol, 1998, 32: 1099~1104
4[4]Platts J A, Abraham M H. Partition of volatile organic compounds from air and from water into plant cuticular matrix: An LFER analysis. Environ Sci Technol, 2000, 34(2): 318~323
5[5]Wilson L Y, Famine G R. Using theoretical descriptors in quantitative structure activity relationships: some toxicological indices. J Med Chem, 1991, 34(5): 1668~1674
6[6]Chen J W, Wang L S. Using MTLSER model and AM1 Hamiltonian in quantitative structure activity relationship studies of alky (1-phen- ylsulfonyl) cycloalkane-carboxylates. Chemosphere, 1997, 35(3): 623~631
7Ren Biye.Novel atomic-level-based AI topological descriptors: Application to QSPR/QSAR modelling[J].J Chem Inf Comput Sci, 2002, 42(4):858-868.
8Finizio A, Mackay D, Bidleman T. Octanol-air partition coefficient as a predictor of partitioning of semi-volatile organic chemicals to aerosols. Atmos Environ, 1997,31(15): 2289-2296.
9Harner T, Bidleman T. Octanol-air partition coefficient for describing particle/gas partitioning of aromatic compounds in urban air. Environ Sci Technol, 1998,32(10): 1494-1502.
10Jang M, Kamens R. A predictive model for adsorptive gas partitioning of SOCs on fine atmospheric inorganic dust particles. Environ Sci Technol, l999,33(11): 1825-1831.
