nach oben

Journal of Material Cycles and Waste Management

Erschienen in:

22.02.2023 | SPECIAL FEATURE: REGIONAL CASE STUDY

Mercury emission from underground coal fires: a typical case in China

verfasst von: Qingyi Cao, Yingchao Cheng, Taketoshi Kusakabe, Yahui Qian, Handong Liang, Masaki Takaoka

Erschienen in: Journal of Material Cycles and Waste Management | Ausgabe 5/2023

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

Mercury, a highly toxic environmental pollutant with a global circulation, must be controlled worldwide. Taking the Wuda underground coal fires, one of the most severe coal fire disaster areas in China, as a typical case, this paper systematically introduces the serious environmental output and strong environmental pollution of mercury from underground coal fires. Smoke with unusually high mercury concentrations was released from surface vents and cracks, resulting in significant enrichment of mercury in the air and surface sediments. A portion of mercury (particulate and reactive gaseous mercury) was deposited near the fire zones, but the positive high mercury fluxes of the surface soils indicated that mercury would again escape from the soil–air interface. The annual gaseous mercury emissions from the underground coal fires in China were estimated to reach 4.85 tonnes. Underground coal-fired mercury can be identified as an essential part of the global mercury cycle. Although some remediation measures were implemented, the development of coal fires proved difficult to control and was destined to be accompanied by the continuous release of mercury. Given the widespread distribution of coal fire cases worldwide, mercury pollution from underground coal fires deserves attention in the future.

Vorheriger Artikel Removal of Hg2+ ions by adsorption using (TiO2@MnO2)-NPs nanocomposite

Nächster Artikel Environmental policy and legal framework for controlling mercury emissions from stationary sources: a case study in Taiwan

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Nur mit Berechtigung zugänglich

Stracher GB, Taylor TP (2004) Coal fires burning out of control around the world: thermodynamic recipe for environmental catastrophe. Int J Coal Geol 59(1–2):7–17 CrossRef

Gambhir A, Tavoni M (2019) Direct air carbon capture and sequestration: how it works and how it could contribute to climate-change mitigation. One Earth 1(4):405–409CrossRef

Elahi E, Khalid Z, Tauni MZ, Zhang H, Lirong X (2022) Extreme weather events risk to crop-production and the adaptation of innovative management strategies to mitigate the risk: a retrospective survey of rural Punjab, Pakistan. Technovation 117:102255CrossRef

Kuenzer C, Stracher GB (2012) Geomorphology of coal seam fires. Geomorphology 138(1):209–222CrossRef

Sehn JL, de Leão FB, da Boit K, Oliveira ML, Hidalgo GE, Sampaio CH, Silva LF (2016) Nanomineralogy in the real world: a perspective on nanoparticles in the environmental impacts of coal fire. Chemosphere 147:439–443CrossRef

Querol X, Izquierdo M, Monfort E, Álvarez E, Font O, Moreno T, Wang Y (2008) Environmental characterization of burnt coal gangue banks at Yangquan, Shanxi Province, China. Int J Coal Geol 75(2):93–104CrossRef

Kataka MO, Matiane AR, Odhiambo BDO (2018) Chemical and mineralogical characterization of highly and less reactive coal from Northern Natal and Venda-Pafuri coalfields in South Africa. J Afr Earth Sci 137:278–285CrossRef

Heffern EL, Coates DA (2004) Geologic history of natural coal-bed fires, Powder River basin, USA. Int J Coal Geol 59(1–2):25–47CrossRef

Zhang X, Kroonenberg SB, De Boer CB (2004) Dating of coal fires in Xinjiang, northwest China. Terra Nova 16(2):68–74CrossRef

10.

Zeng Q, Dong J, Zhao L (2018) Investigation of the potential risk of coal fire to local environment: a case study of Daquanhu coal fire, Xinjiang region, China. Sci Total Environ 640:1478–1488CrossRef

11.

Silva LF, Oliveira ML, Neace ER, O’Keefe JM, Henke KR, Hower JC (2011) Nanominerals and ultrafine particles in sublimates from the Ruth Mullins coal fire, Perry County, Eastern Kentucky, USA. Int J Coal Geol 85(2):237–245CrossRef

12.

Syed TH, Riyas MJ, Kuenzer C (2018) Remote sensing of coal fires in India: a review. Earth Sci Rev 187:338–355CrossRef

13.

Onifade M, Genc B, Said KO, Fourie M, Akinseye PO (2022) Overview of mine rescue approaches for underground coal fires: a South African perspective. J S Afr Inst Min Metall 122(5):213–226CrossRef

14.

Tan B, Zhang F, Zhang Q, Wei H, Shao Z (2019) Firefighting of subsurface coal fires with comprehensive techniques for detection and control: a case study of the Fukang coal fire in the Xinjiang region of China. Environ Sci Pollut Res 26(29):29570–29584CrossRef

15.

Hong X, Liang H, Chen Y, Liu Y, Shi Y (2018) Distribution of fluorine in the surface dust of Wuda coal base, Inner Mongolia of Northern China. J Geochem Explor 188:390–397CrossRef

16.

Anna M, Andrey F, Eugenia V (2022) Comparison of the performance of different methods to stabilize mercury-containing waste. J Mater Cycles Waste Manag 24(3):1134–1139CrossRef

17.

Choi Y, Rhee SW (2022) Comprehensive analysis on mercury stream of cold cathode fluorescent lamps (CCFLs) in Korea (Republic of). J Mater Cycles Waste Manag 24(6):2375–2384CrossRef

18.

Pirrone N, Cinnirella S, Feng X, Finkelman RB, Friedli HR, Leaner J, Telmer K (2010) Global mercury emissions to the atmosphere from anthropogenic and natural sources. Atmos Chem Phys 10(13):5951–5964CrossRef

19.

Hower JC, Henke K, O’Keefe JM, Engle MA, Blake DR, Stracher GB (2009) The Tiptop coal-mine fire, Kentucky: preliminary investigation of the measurement of mercury and other hazardous gases from coal-fire gas vents. Int J Coal Geol 80(1):63–67CrossRef

20.

U.S Department of Labor Occupational Safety Health Administration (2004) Safety and health topics: mercury (vapor) (as Hg). http://www.oshs.gov/dts/chemicalsampling/data/CH_250510.html. Accessed 18 Jan 2009

21.

Jaffe D, Prestbo E, Swartzendruber P, Weiss-Penzias P, Kato S, Takami A, Kajii Y (2005) Export of atmospheric mercury from Asia. Atmos Environ 39(17):3029–3038CrossRef

22.

Li C, Sun J, Shi J, Liang H, Cao Q, Li Z, Gao Y (2020) Mercury sources in a subterranean spontaneous combustion area. Ecotoxicol Environ Saf 201:110863CrossRef

23.

Kong B, Li Z, Yang Y, Liu Z, Yan D (2017) A review on the mechanism, risk evaluation, and prevention of coal spontaneous combustion in China. Environ Sci Pollut Res 24(30):23453–23470CrossRef

24.

Zhang J, Guan HY, Cao DY (2008) Underground coal fires in China: origin, detection, fire-fighting, and prevention. China Coal Industry Publishing House, Beijing (in Chinese)

25.

Voigt S, Rüter H (2006) The Sino German coal fire research initiative—research concepts and general aspects of coal seam fire mitigation. In: Buhrow C, Schächter HN, Schmidt R (eds) Kolloquium Ressourcen und Umwelt 2006—Kohle und China, 30–31 März 2006, pp 247–253 (Freiberg, Germany)

26.

Shan B, Wang G, Cao F, Wu D, Liang W, Sun R (2019) Mercury emission from underground coal fires in the mining goaf of the Wuda Coalfield, China. Ecotoxicol Environ Saf 182:109409CrossRef

27.

Hong X, Yang K, Liang H (2021) Characterization of acidity and sulfate in dust obtained from the Wuda coal base, northern China: spatial distribution and pollution assessment. Environ Sci Pollut Res 28(25):33219–33230CrossRef

28.

Song Z, Kuenzer C (2017) Spectral reflectance (400–2500 nm) properties of coals, adjacent sediments, metamorphic and pyrometamorphic rocks in coal-fire areas: a case study of Wuda coalfield and its surrounding areas, northern China. Int J Coal Geol 171:142–152CrossRef

29.

Cao QY, Qian YH, Liang HD, Wang Z (2019) The species and spatial distribution characteristics of atmospheric particulate mercury in Wuda-Wusitai Industrial Park, China. China Environ Sci 39(12):4989–4998

30.

Hong X, Liang H, Lv S, Jia Y, Zhao T, Liang W (2017) Mercury emissions from dynamic monitoring holes of underground coal fires in the Wuda Coalfield, Inner Mongolia, China. Int J Coal Geol 181:78–86CrossRef

31.

Wang G, Cao F, Shan B, Meng M, Wang W, Sun R (2019) Sources and assessment of mercury and other heavy metal contamination in soils surrounding the Wuda underground coal fire area, Inner Mongolia, China. Bull Environ Contam Toxicol 103(6):828–833CrossRef

32.

Li C, Liang H, Chen Y, Bai J, Cui Y (2018) Distribution of surface soil mercury of Wuda old mining area, Inner Mongolia, China. Hum Ecol Risk Assess Int J 24(5):1421–1439CrossRef

33.

Cao QY, Yang L, Ren WY, Song YL, Huang SY, Wang YT, Wang ZY (2021) Spatial distribution of harmful trace elements in Chinese coalfields: an application of WebGIS technology. Sci Total Environ 755:142527CrossRef

34.

Liang Y, Liang H, Zhu S (2014) Mercury emission from coal seam fire at Wuda Inner Mongolia, China. Atmos Environ 83:176–184CrossRef

35.

Liang Y, Liang H, Zhu S (2016) Mercury emission from spontaneously ignited coal gangue hill in Wuda coalfield, Inner Mongolia, China. Fuel 182:525–530CrossRef

36.

Engle MA, Radke LF, Heffern EL, O’Keefe JM, Hower JC, Smeltzer CD, ter Schure A (2012) Gas emissions, minerals, and tars associated with three coal fires, Powder River Basin, USA. Sci Total Environ 420:146–159CrossRef

37.

O’Keefe JM, Henke KR, Hower JC, Engle MA, Stracher GB, Stucker JD, Lemley EW (2010) CO₂ CO, and Hg emissions from the Truman Shepherd and Ruth Mullins coal fires, eastern Kentucky, USA. Sci Total Environ 408(7):1628–1633CrossRef

38.

Pone JDN, Hein KA, Stracher GB, Annegarn HJ, Finkleman RB, Blake DR, Schroeder P (2007) The spontaneous combustion of coal and its by-products in the Witbank and Sasolburg coalfields of South Africa. Int J Coal Geol 72(2):124–140CrossRef

39.

Fu X, Feng X, Sommar J, Wang S (2012) A review of studies on atmospheric mercury in China. Sci Total Environ 421:73–81CrossRef

40.

Wang Z, Chen Z, Duan N, Zhang X (2007) Gaseous elemental mercury concentration in atmosphere at urban and remote sites in China. J Environ Sci 19(2):176–180CrossRef

41.

Fang F, Wang Q, Li J (2001) Atmospheric particulate mercury concentration and its dry deposition flux in Changchun City, China. Sci Total Environ 281:229–236CrossRef

42.

Kono Y, Tomiyasu T (2014) Variations in atmospheric mercury concentration in Kagoshima City during 2010–2012. Bunseki Kagaku 63(1):17–21CrossRef

43.

Huang HC, Lee CL, Lai CH, Fang MD, Lai IC (2012) Transboundary movement of polycyclic aromatic hydrocarbons (PAHs) in the Kuroshio Sphere of the western Pacific Ocean. Atmos Environ 54:470–479CrossRef

44.

Li C, Liang H, Liang M, Chen Y, Zhou Y (2018) Soil surface Hg emission flux in coalfield in Wuda, Inner Mongolia, China. Environ Sci Pollut Res 25(17):16652–16663CrossRef

45.

Choi HD, Holsen TM (2009) Gaseous mercury fluxes from the forest floor of the Adirondacks. Environ Pollut 157(2):592–600CrossRef

46.

Kyllönen K, Hakola H, Hellén H, Korhonen M, Verta M (2012) Atmospheric mercury fluxes in a southern boreal forest and wetland. Water Air Soil Pollut 223(3):1171–1182CrossRef

47.

Lindberg SE, Zhang H, Gustin M, Vette A, Marsik F, Owens J, Xiao Z (1999) Increases in mercury emissions from desert soils in response to rainfall and irrigation. J Geophys Res Atmos 104(D17):21879–21888CrossRef

48.

Engle MA, Gustin MS, Zhang H (2001) Quantifying natural source mercury emissions from the Ivanhoe Mining District, north-central Nevada, USA. Atmos Environ 35(23):3987–3997CrossRef

49.

Gabriel MC, Williamson DG, Zhang H, Brooks S, Lindberg S (2006) Diurnal and seasonal trends in total gaseous mercury flux from three urban ground surfaces. Atmos Environ 40(23):4269–4284CrossRef

50.

Liu F, Cheng H, Yang K, Zhao C, Liu Y, Peng M, Li K (2014) Characteristics and influencing factors of mercury exchange flux between soil and air in Guangzhou City. J Geochem Explor 139:115–121CrossRef

51.

Schroeder WH, Beauchamp S, Edwards G, Poissant L, Rasmussen P, Tordon R, Banic CM (2005) Gaseous mercury emissions from natural sources in Canadian landscapes. J Geophys Res Atmos 110:D18302CrossRef

52.

Ericksen JA, Gustin MS, Xin M, Weisberg PJ, Femandez GCJ (2006) Air–soil exchange of mercury from background soils in the United States. Sci Total Environ 366:851–863CrossRef

53.

Miller MB, Howard DA, Pierce AM, Cook KR, Keywood M, Powell J, Gustin MS, Edwards GC (2021) Atmospheric reactive mercury concentrations in coastal Australia and the Southern Ocean. Sci Total Environ 751:141681CrossRef

54.

Fu XW, Feng X, Dong ZQ, Yin RS, Wang JX, Yang ZR, Zhang H (2010) Atmospheric gaseous elemental mercury (GEM) concentrations and mercury depositions at a high-altitude mountain peak in south China. Atmos Chem Phys 10:2425–2437CrossRef

55.

Sun G, Feng X, Yang C, Zhang L, Yin R, Li Z, Wu Y (2020) Levels, sources, isotope signatures, and health risks of mercury in street dust across China. J Hazard Mater 392:122276CrossRef

56.

Trasande L, Landrigan PJ, Schechter C (2005) Public health and economic consequences of methyl mercury toxicity to the developing brain. Environ Health Perspect 113(5):590–596CrossRef

57.

Qian Y, Liang Y, Cao Q, Wang Z, Shi Y, Liang H (2022) Concentration and speciation of mercury in atmospheric particulates in the Wuda coal fire area, Inner Mongolia, China. Environ Sci Pollut Res 29(3):3879–3887CrossRef

58.

Liu S, Nadim F, Perkins C, Carley RJ, Hoag GE, Lin Y, Chen L (2002) Atmospheric mercury monitoring survey in Beijing, China. Chemosphere 48(1):97–107CrossRef

59.

Xiu GL, Shi SY, Zhang DN (2003) Preliminary study on characteristics of particulate mercury in fine particles in ambient air. Shanghai Environ Sci 22(5):310–316 (in Chinese)

60.

Ebinghaus R, Kock HH, Temme C, Einax JW, Löwe AG, Richter A et al (2002) Antarctic springtime depletion of atmospheric mercury. Environ Sci Technol 36:1238–1244CrossRef

61.

Weiss-Penzias P, Amos H, Selin N, Gustin M, Jaffe D, Obrist D et al (2015) Use of a global model to understand speciated atmospheric mercury observations at five high-elevation sites. Atmos Chem Phys 15:1161–1173CrossRef

62.

Karbassi A, Nasrabadi T, Rezai M et al (2014) Pollution with metals (As, Sb, Hg, Zn) in agricultural soil located close to Zarshuran gold mine, Iran. Environ Eng Manag J 13:155–220

63.

Higueras P, Oyarzun R, Biester H et al (2003) A first insight into mercury distribution and speciation in soils from the Almaden district, Spain. J Geochem Explor 80:95–104CrossRef

64.

Pataranawat P, Parkpian P, Polprasert C et al (2007) Mercury emission and distribution: potential environmental risks at a small-scale gold mining operation, Phichit Province, Thailand. J Environ Sci Health Part A 42(8):1081–1093CrossRef

65.

Hower JC, O’Keefe JM, Henke KR, Wagner NJ, Copley G, Blake DR, Silva LF (2013) Gaseous emissions and sublimates from the Truman Shepherd coal fire, Floyd County, Kentucky: a re-investigation following attempted mitigation of the fire. Int J Coal Geol 116:63–74CrossRef

66.

Querol X, Zhuang X, Font O, Izquierdo M, Alastuey A, Castro I, López-Soler A (2011) Influence of soil cover on reducing the environmental impact of spontaneous coal combustion in coal waste gobs: a review and new experimental data. Int J Coal Geol 85(1):2–22CrossRef

67.

Li C, Shi J, Cao Q, Luo Y, Liang H, Du C, Shi J (2021) Role of H+, HF, SO42− and kaolin in fixing Hg of coal fire sponge. Sci Total Environ 772:14551CrossRef

68.

Liang Y, Zhu S, Liang H (2018) Mercury enrichment in coal fire sponge in Wuda coalfield, Inner Mongolia of China. Int J Coal Geol 192:51–55CrossRef

69.

Rumayor M, Gallego JR, Rodríguez-Valdés E, Díaz-Somoano M (2017) An assessment of the environmental fate of mercury species in highly polluted brownfields by means of thermal desorption. J Hazard Mater 325:1–7CrossRef

70.

Kuenzer C, Zhang J, Sun Y, Jia Y, Dech S (2012) Coal fires revisited: The Wuda coal field in the aftermath of extensive coal fire research and accelerating extinguishing activities. Int J Coal Geol 102:75–86CrossRef

71.

Zhou J, Feng X, Liu H, Zhang H, Fu X, Bao Z, Zhang Y (2013) Examination of total mercury inputs by precipitation and litterfall in a remote upland forest of Southwestern China. Atmos Environ 81:364–372CrossRef

72.

Bergquist BA, Blum JD (2007) Mass-dependent and-independent fractionation of Hg isotopes by photoreduction in aquatic systems. Science 318(5849):417–420CrossRef

73.

Wu ZJ, Ye HF, Shan YL, Chen B, Li JS (2020) A city-level inventory for atmospheric mercury emissions from coal combustion in China. Atmos Environ 223:117245CrossRef

74.

United Nations Environment Programme (2019) Global Mercury Assessment 2018

75.

Liang Y, Zhang J, Wang L, Luo H, Ren T (2019) Forecasting spontaneous combustion of coal in underground coal mines by index gases: a review. J Loss Prev Process Ind 57:208–222CrossRef

76.

Deng J, Ge S, Qi H, Zhou F, Shi B (2021) Underground coal fire emission of spontaneous combustion, Sandaoba coalfield in Xinjiang, China: investigation and analysis. Sci Total Environ 777:146080CrossRef

77.

Engle MA, Olea RA, O’Keefe JM, Hower JC, Geboy NJ (2013) Direct estimation of diffuse gaseous emissions from coal fires: current methods and future directions. Int J Coal Geol 112:164–172CrossRef

78.

Tian FC, Liang YT, Zhu HQ, Chen MY, Wang JC (2022) Application of a novel detection approach based on non-dispersive infrared theory to the in-situ analysis on indicator gases from underground coal fire. J Cent South Univ 29:1840–1855CrossRef

79.

O’Keefe JM, Neace ER, Lemley EW, Hower JC, Henke KR, Copley G, Blake DR (2011) Old Smokey coal fire, Floyd County, Kentucky: estimates of gaseous emission rates. Int J Coal Geol 87(2):150–156CrossRef

80.

Hou X, Guo L, Wang F, Xu Y, Dong X, Gao D, Sun Y (2019) Research on sources appointment of abnormal co in underground mine. Feb-Fresenius Environ Bull 28(4):2897–2907

81.

Cao QY, Yang L, Qian YH, Liang HD (2020) Study on mercury species in coal and pyrolysis-based mercury removal before utilization. ACS Omega 5(32):20215–20223CrossRef

82.

Rumayor M, Diaz-Somoano M, Lopez-Anton MA, Martinez-Tarazona MR (2013) Mercury compounds characterization by thermal desorption. Talanta 114:318–322CrossRef

Titel: Mercury emission from underground coal fires: a typical case in China
verfasst von: Qingyi Cao
Yingchao Cheng
Taketoshi Kusakabe
Yahui Qian
Handong Liang
Masaki Takaoka
Publikationsdatum: 22.02.2023
Verlag: Springer Japan
Erschienen in: Journal of Material Cycles and Waste Management / Ausgabe 5/2023
Print ISSN: 1438-4957
Elektronische ISSN: 1611-8227
DOI: https://doi.org/10.1007/s10163-023-01616-9

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Weitere Artikel der Ausgabe 5/2023

Maximizing resource efficiency: opportunities for energy recovery from municipal solid waste in Europe

The effect of alkaline pretreatment on the anaerobic digestion of fruit and vegetable wastes from a central food distribution market

Removal of Hg2+ ions by adsorption using (TiO2@MnO2)-NPs nanocomposite

Critical enablers and inhibitors for economic sustainability in the supply and demand of end-of-life vehicles in Malaysia: a SWOT analysis

Assessment of heavy metal distribution and contamination in the sediment of the Ciujung Watershed, Banten Province, Indonesia

Recovery of precious metals from e-wastes through conventional and phytoremediation treatment methods: a review and prediction