[1] Dellinger B, Lomnicki S, Khachatryan L, et al. Formation and stabilization of persistent free radicals [J]. Proceedings of the Combustion Institute, 2007, 31: 521-528.
[2] Lomnicki S, Truong H, Vejerano E, et al. Copper oxide-based model of persistent free radical formation on combustion-derived particulate matter [J]. Environ Sci Technol, 2008, 42(13): 4982-4988.
[3] Lyons M J, Gibson J F, Ingram D J E. Free-radicals produced in cigarette smoke [J]. Nature, 1958, 181(4614): 1003-1004.
[4] Lyons M J, Spence J B. Environmental free radicals [J]. British Journal of Cancer, 1960, 14(4): 703-708.
[5] Gehling W, Dellinger B. Environmentally persistent free radicals and their lifetimes in PM2.5 [J]. Environ Sci Technol, 2013, 47(15): 8172-8178.
[6] Tian L W, Koshland C P, Yano J, et al. Carbon-centered free radicals in particulate matter emissions from wood and coal combustion [J]. Energy & Fuels, 2009, 23: 2523-2526.
[7] Pryor W A, Hales B J, Premovic P I, et al. The radicals in cigarette tar: their nature and suggested physiological implications [J]. Science, 1983, 220(4595): 425-427.
[8] Hales B J, Case E E. Immobilized radicals. Ⅳ. Biological semiquinone anions and neutral semiquinones [J]. Biochim Biophys Acta Bioenerg, 1981, 637(2): 291-302.
[9] Valentin C, Neyman K M, Risse T, et al. Density-functional model cluster studies of EPR g tensors of Fs+ centers on the surface of MgO [J]. Journal of Chemical Physics, 2006, 124(4): 044708.
[10] Dellinger B, Lomnicki S M, Cook R L, et al. Effect of low temperature thermal treatment on soils contaminated with pentachlorophenol and environmentally persistent free radicals [J]. Environ Sci Technol, 2012, 46(11): 5971-5978.
[11] Vejerano E, Lomnicki E, Dellinger B. Formation and stabilization of combustion-generated environmentally persistent free radicals on an Fe(Ⅲ)2O3/silica surface [J]. Environ Sci Technol, 2011, 45(2): 589-594.
[12] Khachatryan L, Vejerano E, Lomnicki S, et al. Environmentally persistent free radicals (EPFRs). 1. Generation of reactive oxygen species in aqueous solutions [J]. Environ Sci Technol, 2011, 45(19): 8559-8566.
[13] Gehling W, Lomnicki S, Cook R, et al. Detection of environmentally persistent free radicals at a superfund wood treating site [J]. Environ Sci Technol, 2011, 45(15): 6356-6365.
[14] Valavanidis A, Lliopoulos N, Gotsis G, et al. Persistent free radicals, heavy metals and PAHs generated in particulate soot emissions and residue ash from controlled combustion of common types of plastic [J]. Journal of Hazardous Materials, 2008, 156(1/2/3): 277-284.
[15] 郭颖. 固废处置中持久性自由基/二恶英的排放特性及检测研究[D]. 杭州: 浙江大学, 2014: 82.
[16] Sneath H E, Hutchings T R, De Leij F A A M. Assessment of biochar and iron filing amendments for the remediation of a metal, arsenic and phenanthrene co-contaminated
spoil [J]. Environmental Pollution, 2013, 178: 361-366.
[17] Vejerano E, Lomnicki S M, Dellinger B. Formation and stabilization of combustiongenerated, environmentally persistent radicals on Ni(Ⅱ)O supported on a silica surface [J].
Environ Sci Technol, 2012, 46(17): 9406-9411.
[18] Squadrito G L, Cueto R, Dellinger B, et al. Quinoid redox cycling as a mechanism for sustained free radical generation by inhaled airborne particulate matter [J]. Free Radical
Biology and Medicine, 2001, 31(9): 1132-1138.
[19] Liao S H, Pan B, Li H, et al. Detecting free radicals in biochars and determining their ability to inhibit the germination and growth of corn, wheat and rice seedlings [J]. Environ Sci Technol, 2014, 48(15): 8581-8587.
[20] Fang G D, Gao J, Liu C, et al. Key role of persistent free radicals in hydrogen peroxide activation by biochar: implications to organic contaminant degradation [J]. Environ Sci Technol, 2014, 48(3): 1902-1910.
[21] Fang G D, Liu C, Gao J, et al. Manipulation of persistent free radicals in biochar to activate persulfate for contaminant degradation [J]. Environ Sci Technol, 2015, 49(9): 5645-5653.
[22] Cains P W, McCausland L J, Fernandes A R, et al. Polychlorinated dibenzo-p-dioxins and dibenzofurans formation in incineration: effects of fly ash and carbon source [J]. Environ Sci Technol, 1997, 31(3): 776-785.
[23] Fuertes A B, Arbestain M C, Sevilla M, et al. Chemical and structural properties of carbonaceous products obtained by pyrolysis and hydrothermal carbonisation of corn stover [J].
Australian Journal of Soil Research, 2010, 48(6/7): 618-626.
[24] Kiruri L W, Khachatryan L, Dellinger B, et al. Effect of copper oxide concentration on the formation and persistency of environmentally persistent free radicals (EPFRs) in
particulates [J]. Environ Sci Technol, 2014, 48(4): 2212-2217.
[25] Vejerano E, Lomnicki S, Dellinger B. Lifetime of combustion-generated environmentally persistent free radicals on Zn(Ⅱ)O and other transition metal oxides [J]. Environ Monit, 2012, 14(10): 2803-2806.
[26] Pryor W A. Oxy-radicals and related species: their formation, lifetimes, and reactions [J]. Annu Rev Physiol, 1986, 48: 657-667.
[27] Finkelstein E, Rosen G M, Rauckman E J. Production of hydroxyl radical by decomposition of superoxide spin-trapped adducts [J]. Mol Pharmacol, 1982, 21(2): 262-265.
[28] Rasmussen P E, Wheeler A J, Hassan N M, et al. Monitoring personal, indoor, and outdoor exposures to metals in airborne particulate matter: risk of contamination during sampling, handling and analysis [J]. Atmospheric Environment, 2007, 41(28): 5897-5907.
[29] Mahne S, Chuang G C, Pankey E, et al. Environmentally persistent free radicals decrease cardiac function and increase pulmonary artery pressure [J]. American Journal of Physiology-Heart and Circulatory Physiology, 303(9): 1135-1142.
[30] Balakrishna S, Lomnicki S, McAvey K M, et al. Environmentally persistent free radicals amplify ultrafine particle mediated cellular oxidative stress and cytotoxicity [J]. Particle and
Fibre Toxicology, 2009, 6: 11.
[31] Dugas T R, Hebert V Y, Dellinger B, et al. Environmentally persistent free radicals are redox active and more cytotoxic than the average ultrafine particle [J]. Free Radical Biology and Medicine, 2009, 47: S121.
[32] Fahmy B, Ding L, You D H, et al. In vitro and in vivo assessment of pulmonary risk associated with exposure to combustion generated fine particles [J]. Environmental Toxicology and Pharmacology, 2010, 29(2): 173-182.
[33] Truong H, Lomnicki S, Dellinger B. Potential for misidentification of environmentally persistent free radicals as molecular pollutants in particulate matter [J]. Environ Sci Technol,
2010, 44(6): 1933-1939.
[34] Saravia J, Lee G I, Lomnicki S, et al. Particulate matter containing environmentally persistent free radicals and adverse infant respiratory health effects: a review [J]. Journal of Biochemical and Molecular Toxicology, 2013, 27(1): 56-68.
[35] Lee G I, Saravia J, You D H, et al. Exposure to combustion generated environmentally persistent free radicals enhances severity of influenza virus infection [J]. Particle and Fibre
Toxicology, 2014, 11(57): 1-10.
[36] Fang G D, Zhu C Y, Dionysiou D D, et al. Mechanism of hydroxyl radical generation from biochar suspensions: implications to diethyl phthalate degradation [J]. Bioresour Technol, 2015, 176: 210-217.
[37] Fang G D, Gao J, Dionysiou D D, et al. Activation of persulfate by quinones: free radical reactions and implication for the degradation of PCBs [J]. Environ Sci Technol, 2013, 47(9):
4605-4611. |