Cerny J, Pavlikova H (1994) Structural analysis of low rank coal extract and their relation to parent coal. Energy Fuel 8(2):375-379.
Classification of coals, ISO 11760-2005, ISO/TC27.
Dack SW, Hobday MD, Smith TD, Pilbrow JR (1983) Free radical involvement in the oxidation of Victorian brown coal. Fuel 62: 1510-1512.
Dai GL (2011) Comprehensive Experimental study on low temperature oxidation and spontaneous combustion of coal. Xuzhou: China University of Mining and Technology press. pp: 45-53.
Deng J, Yang Y, Zhang YN, Liu B, Shi CM (2018) Inhibition effect of three commercial inhibitors for spontaneous coal combustion. Energy 160: 1174-1185.
Dyrkacz GR, Bloomquist CA (2015) Binary solvent extractions of upper freeport coal. Energy Fuel 15(6): 1409-1413.
Fei J, Li WY, Xie KC (2002) Research on coal structure using FTIR. Journal of China University of Mining & Technology 5: 362-366.
Ibarra J, Munoz E, Moliner R (1996) FTIR study of the evolution of coal structure during the coalification process. Organic Geochemistry 24(6/7): 725-735.
Kudynska J, Buckmaster HA (1996) Low-temperature oxidation kinetics of high-volatile bituminous coal studied by dynamic in situ 9 GHz c. w. e. p. r. spectroscopy. Fuel 75: 872-878.
Li CQ, Takanohash IT, Saito I (2002) The behavior of free radicals in coal at temperatures up to 300 °C in various organic solvents, using in situ EPR spectroscopy. Energy Fuel 16(5): 1116-1120.
Li ZH (1996) Mechanism of free radical reaction in spontaneous combustion of coal. Journal of China University of Mining & Technology 25(3): 111-114.
Liotta R, Brons G, Isaacs J (1983) Oxidative weathering of Illinois No. 6 Coal. Fuel 63: 781-791.
Liu JX, Jiang XM, Han XX, Shen J, Zhang H (2014) Chemical properties of superfine pulverized coals. Part 2. Demineralization effects on free radical characteristics. Fuel 115(12): 685-696.
Liu JX, Jiang XM, Shen J, Zhang H (2015) Influences of particle size, ultraviolet irradiation and pyrolysis temperature on stable free radicals in coal. Powder Technol 272, 64-74.
Mathews JP, Chaffee AL (2012) The molecular representations of coal: A review. Fuel 96: 1-14.
Petersen HI (2006a) The petroleum generation potential and effective oil window of humic coals related to coal composition and age. International Journal of Coal Geology 67(4): 221-248.
Petersen HI, Nytoft HP (2006b) Oil generation capacity of coals as a function of coal age and aliphatic structure. Organic Geochemistry 37(5): 558-583.
Pilar G, Peter J, Fanor M (1999) The use of differential scanning calorimetry to identify coals susceptible to spontaneous combustion. Thermochimica Acta 336 (1-2): 41-46.
Pilawa B, Więckowski AB, Pietrzak R, Wachowska H (2002) Oxidation of demineralized coal and coal free of pyrite examined by EPR spectroscopy. Fuel 81(15): 1925-1931.
Pis JJ, Puente G, Fuentea E, Moránb A, Rubiera F (1996) A study of the self- heating of fresh and oxidized coals by differential thermal analysis. Thermochim Acta 279(6): 93-101.
Retcofsky HL, Stark JM, Friedel RA (1968) Electron spin resonance in American coals. Analytical Chemistry 40(11): 1699-1704.
Shi T, Deng J, Wang XF, Wang ZY (2004) Mechanism of spontaneous combustion of coal at initial stage. Journal of Fuel Chemistry and Technology 6: 652–657.
Shi T, Wang XF, Deng J, Wang ZY (2005) The mechanism at the initial stage of the room-temperature oxidation of coal. Combust Flame 140:332-345.
Wang DM (2008) Science of Mine fire. Xuzhou: China University of Mining and Technology press pp: 47-53.
Wang DM, Xin HH, Qi XY, Dou GL, Zhong XX (2014) Mechanism and relationships of elementary reactions in spontaneous combustions of coal: The coal oxidation kinetics theory and application. Journal of China Coal Society 39(08): 1667-1674.
Wang DM, Xin HH, Qi XY, Dou GL, Zhong XX (2014) Mechanism and relationships of elementary reactions in spontaneous combustion of coal: The coal oxidation kinetics theory and application. Journal of china coal society 39(9): 1667-1674.
Wang JR, Jin ZX, Deng CB (2014) Quantum Chemical Theory of Coal Spontaneous Combustion. Beijing: Science Press. pp: 189-202.
Wang K (2013) Study on the oxidation and spontaneous combustion characteristics of Jurassic coal in Northern Shaanxi. Master Thesis in the Xi’an University of Science and Technology.
Wood SU, Harris IJ (1992) Effects of drying methods on the low temperature reactivity of Victorian brown coal to oxygen. Fuel 71(2): 183-192.
Xiao Y, Ma L, Wang ZP, Deng J, Wang W, Xiang X (2007) Research on characteristic temperature in coal spontaneous combustion with thermal gravity analysis method. Coal Science and Technology 05: 73-76.
Xu T, Wang DM, Xin HH, Qi XY (2019) Experimental study on the temperature rising characteristic of spontaneous combustion of coal. Journal of Mining & Safety Engineering 29(04): 575-580.
Xu YL, Wang LY, Tian N, Zhang JP, Yu MG (2017) Spontaneous combustion coal parameters for the Crossing-Point Temperature(CPT) method in a Temperature-Programmed System(TPS).Fire Safety Journal 91: 147-154.
Yang S (2005) Study on the active groups' reaction activeness on self-ignition coal. Coal Mine Modernization 65: 59-60.
YU MG, Jia HL, Yu SJ, Pan RK (2006) Calculation of micro-structure parameter of Wuda bituminous coal and relationship-analysis between coal structure and coal spontaneous combustion. Journal of China Coal Society 31(5): 610-614.
Yu MG, Zheng YM, Lu C, Jia HL (2009) Thermal analysis experiment on low-temperature oxidation and pyrolysis of coal. China Safety Science Journal 09: 83-86.
Zhang YN (2013) Study on the microcosmic characteristics and macro parameters in the process of coal oxidation and spontaneous combustion. PhD Thesis in the Xi’an University of Science and Technology.
Zhang YT, Shi XQ, Li YQ, Wen H, Huang Y, Li SS, Liu YR (2017) Inhibiting effects of Zn/Mg/Al layer double hydroxide on coal spontaneous combustion. Journal of China Coal Society 42(11): 2892-2899.
Zhang YT, Li YQ, Huang Y, LI SS, Wang WF (2018a) Characteristics of mass, heat and gaseous products during coal spontaneous combustion using TG/DSC-FTIR technol. Journal of Thermal and Analysis Calorimetry 131(3): 2963-2974.
Zhang YT, Shi XQ, Li YQ, Liu YR (2018b) Characteristics of carbon monoxide production and oxidation kinetics during the decaying process of coal spontaneous combustion. Canadian Journal of Chemical Engineering 96:1752-1761.
Zhang YT, Liu YR, Shi XQ , Yang CP, Wang WF, Li YQ (2018c) Risk evaluation of coal spontaneous combustion on the basis of auto-ignition temperature. Fuel 233: 68-76.
Zhang YT, Yang CP, Li YQ, Huang Y, Zhang J, Zhang YB, Li QP (2019) Ultrasonic extraction and oxidation characteristics of functional groups during coal spontaneous combustion .Fuel 242:287-294.
Cerny J, Pavlikova H (1994) Structural analysis of low rank coal extract and their relation to parent coal. Energy Fuel 8(2):375-379.
Classification of coals, ISO 11760-2005, ISO/TC27.
Dack SW, Hobday MD, Smith TD, Pilbrow JR (1983) Free radical involvement in the oxidation of Victorian brown coal. Fuel 62: 1510-1512.
Dai GL (2011) Comprehensive Experimental study on low temperature oxidation and spontaneous combustion of coal. Xuzhou: China University of Mining and Technology press. pp: 45-53.
Deng J, Yang Y, Zhang YN, Liu B, Shi CM (2018) Inhibition effect of three commercial inhibitors for spontaneous coal combustion. Energy 160: 1174-1185.
Dyrkacz GR, Bloomquist CA (2015) Binary solvent extractions of upper freeport coal. Energy Fuel 15(6): 1409-1413.
Fei J, Li WY, Xie KC (2002) Research on coal structure using FTIR. Journal of China University of Mining & Technology 5: 362-366.
Ibarra J, Munoz E, Moliner R (1996) FTIR study of the evolution of coal structure during the coalification process. Organic Geochemistry 24(6/7): 725-735.
Kudynska J, Buckmaster HA (1996) Low-temperature oxidation kinetics of high-volatile bituminous coal studied by dynamic in situ 9 GHz c. w. e. p. r. spectroscopy. Fuel 75: 872-878.
Li CQ, Takanohash IT, Saito I (2002) The behavior of free radicals in coal at temperatures up to 300 °C in various organic solvents, using in situ EPR spectroscopy. Energy Fuel 16(5): 1116-1120.
Li ZH (1996) Mechanism of free radical reaction in spontaneous combustion of coal. Journal of China University of Mining & Technology 25(3): 111-114.
Liotta R, Brons G, Isaacs J (1983) Oxidative weathering of Illinois No. 6 Coal. Fuel 63: 781-791.
Liu JX, Jiang XM, Han XX, Shen J, Zhang H (2014) Chemical properties of superfine pulverized coals. Part 2. Demineralization effects on free radical characteristics. Fuel 115(12): 685-696.
Liu JX, Jiang XM, Shen J, Zhang H (2015) Influences of particle size, ultraviolet irradiation and pyrolysis temperature on stable free radicals in coal. Powder Technol 272, 64-74.
Mathews JP, Chaffee AL (2012) The molecular representations of coal: A review. Fuel 96: 1-14.
Petersen HI (2006a) The petroleum generation potential and effective oil window of humic coals related to coal composition and age. International Journal of Coal Geology 67(4): 221-248.
Petersen HI, Nytoft HP (2006b) Oil generation capacity of coals as a function of coal age and aliphatic structure. Organic Geochemistry 37(5): 558-583.
Pilar G, Peter J, Fanor M (1999) The use of differential scanning calorimetry to identify coals susceptible to spontaneous combustion. Thermochimica Acta 336 (1-2): 41-46.
Pilawa B, Więckowski AB, Pietrzak R, Wachowska H (2002) Oxidation of demineralized coal and coal free of pyrite examined by EPR spectroscopy. Fuel 81(15): 1925-1931.
Pis JJ, Puente G, Fuentea E, Moránb A, Rubiera F (1996) A study of the self- heating of fresh and oxidized coals by differential thermal analysis. Thermochim Acta 279(6): 93-101.
Retcofsky HL, Stark JM, Friedel RA (1968) Electron spin resonance in American coals. Analytical Chemistry 40(11): 1699-1704.
Shi T, Deng J, Wang XF, Wang ZY (2004) Mechanism of spontaneous combustion of coal at initial stage. Journal of Fuel Chemistry and Technology 6: 652–657.
Shi T, Wang XF, Deng J, Wang ZY (2005) The mechanism at the initial stage of the room-temperature oxidation of coal. Combust Flame 140:332-345.
Wang DM (2008) Science of Mine fire. Xuzhou: China University of Mining and Technology press pp: 47-53.
Wang DM, Xin HH, Qi XY, Dou GL, Zhong XX (2014) Mechanism and relationships of elementary reactions in spontaneous combustions of coal: The coal oxidation kinetics theory and application. Journal of China Coal Society 39(08): 1667-1674.
Wang DM, Xin HH, Qi XY, Dou GL, Zhong XX (2014) Mechanism and relationships of elementary reactions in spontaneous combustion of coal: The coal oxidation kinetics theory and application. Journal of china coal society 39(9): 1667-1674.
Wang JR, Jin ZX, Deng CB (2014) Quantum Chemical Theory of Coal Spontaneous Combustion. Beijing: Science Press. pp: 189-202.
Wang K (2013) Study on the oxidation and spontaneous combustion characteristics of Jurassic coal in Northern Shaanxi. Master Thesis in the Xi’an University of Science and Technology.
Wood SU, Harris IJ (1992) Effects of drying methods on the low temperature reactivity of Victorian brown coal to oxygen. Fuel 71(2): 183-192.
Xiao Y, Ma L, Wang ZP, Deng J, Wang W, Xiang X (2007) Research on characteristic temperature in coal spontaneous combustion with thermal gravity analysis method. Coal Science and Technology 05: 73-76.
Xu T, Wang DM, Xin HH, Qi XY (2019) Experimental study on the temperature rising characteristic of spontaneous combustion of coal. Journal of Mining & Safety Engineering 29(04): 575-580.
Xu YL, Wang LY, Tian N, Zhang JP, Yu MG (2017) Spontaneous combustion coal parameters for the Crossing-Point Temperature(CPT) method in a Temperature-Programmed System(TPS).Fire Safety Journal 91: 147-154.
Yang S (2005) Study on the active groups' reaction activeness on self-ignition coal. Coal Mine Modernization 65: 59-60.
YU MG, Jia HL, Yu SJ, Pan RK (2006) Calculation of micro-structure parameter of Wuda bituminous coal and relationship-analysis between coal structure and coal spontaneous combustion. Journal of China Coal Society 31(5): 610-614.
Yu MG, Zheng YM, Lu C, Jia HL (2009) Thermal analysis experiment on low-temperature oxidation and pyrolysis of coal. China Safety Science Journal 09: 83-86.
Zhang YN (2013) Study on the microcosmic characteristics and macro parameters in the process of coal oxidation and spontaneous combustion. PhD Thesis in the Xi’an University of Science and Technology.
Zhang YT, Shi XQ, Li YQ, Wen H, Huang Y, Li SS, Liu YR (2017) Inhibiting effects of Zn/Mg/Al layer double hydroxide on coal spontaneous combustion. Journal of China Coal Society 42(11): 2892-2899.
Zhang YT, Li YQ, Huang Y, LI SS, Wang WF (2018a) Characteristics of mass, heat and gaseous products during coal spontaneous combustion using TG/DSC-FTIR technol. Journal of Thermal and Analysis Calorimetry 131(3): 2963-2974.
Zhang YT, Shi XQ, Li YQ, Liu YR (2018b) Characteristics of carbon monoxide production and oxidation kinetics during the decaying process of coal spontaneous combustion. Canadian Journal of Chemical Engineering 96:1752-1761.
Zhang YT, Liu YR, Shi XQ , Yang CP, Wang WF, Li YQ (2018c) Risk evaluation of coal spontaneous combustion on the basis of auto-ignition temperature. Fuel 233: 68-76.
Zhang YT, Yang CP, Li YQ, Huang Y, Zhang J, Zhang YB, Li QP (2019) Ultrasonic extraction and oxidation characteristics of functional groups during coal spontaneous combustion .Fuel 242:287-294.