Acid mine drainage (AMD) is one of the most important research subjects of mine environmental treatment and remediation. In recent years, quite a little scholars, at home and abroad, have studied the types, characteristics, formation sequence and assemblages of a majority of secondary mineral resources in acid mine drainage, and so on. And on this basis the secondary minerals, such as jarosite and schwertmannite, were experimentally tested, and the adsorption and passivation ability of several main secondary minerals to heavy metal ion was tested as well. In this paper, the types of secondary minerals found in the acid mine drainage which formed in different environments were summarized systematically and elaborately. In the past a dozen years, the formation sequence and assemblages of these secondary minerals were made a preliminary study. The formation conditions, chemical synthesis methods and conditions of jarosite and schwertmannite, Basaluminite, goethite, hematite, and other main secondary minerals which may have the application value were elaborately discussed and analyzed. And furthermore, the adsorption capacity and passivation of heavy metal ions was analyzed. In the end, the application prospects and application ways of these typical main secondary minerals in acid mine drainage were summed up.
Published in | Science Discovery (Volume 6, Issue 6) |
DOI | 10.11648/j.sd.20180606.27 |
Page(s) | 481-488 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2018. Published by Science Publishing Group |
Acid Mine Drainage (AMD), Secondary Mineral, Formation Sequence, Assemblages, Adsorption and Passivation
[1] | Gardea-Torresdey J L, Peralta-Videa J R, Delarosa G D. Phytoremediation of heavy metals and study of the metal coordination by X-ray absorption spectroscopy[J]. Coordinat Chem Rev, 2005, 249: 1797–1810. |
[2] | Tsukamoto T K, Killion H A. Column experiments for the microbiological treatment of acid mine drainage: low temperature, low pH and matrix investigations[J]. Water Res, 2004, 38 :1405–1418. |
[3] | España J S, Pamo E L , Santofimia E. Acid mine drainage in the Iberian Pyrite Belt (Odiel river watershed, Huelva, SW Spain):geochemistry, mineralogy and environmental implications [J]. Applied Geochemistry, 2005, 20:1320-1356. |
[4] | Kalin M, Fyson A, The chemistry of conventional and alternative treatment systems for the neutralization of acid mine drainage[J]. Sci. Total Environ, 2006, 366 :395–408. |
[5] | Kirby C S, Brady J A. Field determination of Fe2+ oxidation rates in acid mine drainage using a continuously-stirred tank reactor[J]. Applied Geochemistry,1998, 13(4): 509-520. |
[6] | 陈炳辉,王梦媛.氧化亚铁硫杆菌对方铅矿的生物氧化作用初步研究[J].地球与环境,2011,39(4):503-510. |
[7] | Wang Ling, Li Yan . Weathering behavior and metal mobility of tailings under an extremely arid climate at Jinchuan Cu-Ni sulfide deposit, Western China [J]. Journal of Geochemical Exploration, 2017, 173:1-12. |
[8] | Sheoran A S, Sheoran V. Heavy metal removal mechanism of acid mine drainage in wetlands: a critical review[J]. Minerals Engineering, 2006, 19:105–116. |
[9] | Blowes D W, Ptacek C J. The geochemistry of acid mine drainage[J]. Treatise on Geochemistry, 2003, 9 :149–204. |
[10] | España J S. The natural attenuation of two acidic effluents in Tharsis and La Zarza-Perrunal mines (Iberian Pyrite Belt ,Huelva , Spain)[J] .Environ Geol. 49(2005):253-266. |
[11] | Waychunas G A, Kim C S . 2005. Nanoparticulate iron oxide minerals in soils and sediments: unique properties and contaminant scanvenging mechanisms[J] .Journal of Nanoparticle Research, 7:409~ 433 |
[12] | 周立祥. 酸性矿山废水中生物成因次生高铁矿物的形成及环境工程意义[J]. 地学前缘, 15(6),(2008): 74-82. |
[13] | 王武名,鲁安怀. 矿酸浸液制备氢氧化铁过程中施威特曼石的形成与转变[J]. 岩石矿物学杂志,28(6),(2009): 581-586. |
[14] | Sienkiewicz E, Gasiorowski M.The evolution of a mining lake - From acidity to natural neutralization. Sci. Total Environ, 2016,558: 343-354. |
[15] | Nordstrom D K. Hydrogeochemical processes governing the origin, transport and fate of major and trace elements from mine wastes and mineralized rock to surface waters. Applied Geochemistry 26(2011):1777–1791. |
[16] | Carbone C, Dinelli E. The role of AMD secondary minerals in controlling environmental pollution: Indications from bulk leaching tests. Journal of Geochemical Exploration, 132 (2013) :188–200 |
[17] | Valente T, Grande J A. Mineralogy and environmental relevance of AMD-precipitates from the Tharsis mines, Iberian Pyrite Belt (SW, Spain). Applied Geochemistry ,39 (2013): 11–25 |
[18] | 陈莹,陈炳辉. 粤北大宝山AMD 水-表层沉积物的重金属分布特征及其影响因素[J]. 环境科学学报(2017) |
[19] | 刘奇缘,陈炳辉.粤北大宝山槽对坑酸性矿山废水中不同沉积层次生矿物研究[J].地球与环境,2017,45(3):259-266 |
[20] | 邹琦,陈莹. 广东大宝山铁龙 AMD 中赭色沉积物的含铁次生矿物研究[J].高校地质学报,2017,23(3):442-451. |
[21] | Marescotti P,Carbone C. Mineralogical and chemical evolution of ochreous precipitates from the Libiola Fe–Cu-sulfide mine (Eastern Liguria, Italy) [J]. Geochemistry , 2012 (27) :577–589 |
[22] | Lindsay M. 2015. Geochemical and mineralogical aspects of sulfide mine tailings [J]. Applied Geochemistry 57 (2015) :157–177 |
[23] | Candeias C, Ávila P F. Acid mine drainage from the Panasqueira mine and its influence on Zêzere river (Central Portugal) [J] . Journal of African Earth Sciences,2014, 99:705–712 |
[24] | Maza S N. Holocene ochreous lacustrine sediments within the Famatina Belt, NW Argentina: A natural case for fossil damming of an acid drainage system [J]. Journal of South American Earth Sciences, 2014,52:149-165 |
[25] | Nordstrom D K. Hydrogeochemical processes governing the origin, transport and fate of major and trace elements from mine wastes and mineralized rock to surface waters [J]. Applied Geochemistry,2011,26:1777–1791 |
[26] | Kefeni K K. Synthesis and characterization of magnetic nanoparticles and study their removal capacity of metals from acid mine drainage [J]. Chemical Engineering journal , 2015, 276 :222–231 |
[27] | Carrero S, Pérez-López R. The potential role of aluminium hydroxysulphates in the removal of contaminants in acid mine drainage [J]. Chemical Geology . 2015, 417: 414–423 |
[28] | Macías F, Caraballo M A. Natural pretreatmentand passive remediation of highly polluted acid mine drainage. [J] J. Environ. Manag,2012,104, 93–100. |
[29] | Caraballo M A, Macías F. Long term remediation of Highly polluted acid mine drainage: a sustainable approach to restore the environmental quality of the Odiel river basin [J]. Environ. Pollut, 2011, 159, 3613–3619. |
[30] | Lee G, Bigham J M, Faure G. Removal of trace metals by coprecipitation with Fe,Al and Mn from natural waters contaminated with acid mine drainage in the Ducktown Mining District, Tennessee. Appl. Geochem, 2002, 17, 569–581. |
[31] | SASAKI K, KONNO H. Morphology of jarosite-group compounds precipitated from biologically and chemically oxidized Fe ion [J].The Canadian Mineralogist, 2000, 38: 45−66. |
[32] | Gagliano W B, Brill M R, Bigham J M. Chemistry and mineralogy of ochreous sediments in a constructed mine drainage wetland[J] .Geochim Cosmochim Acta, 2002, 68:2119-2128. |
[33] | 王长秋,马生凤,鲁安怀.黄钾铁矾类矿物沉淀去除Cr(Ⅵ)的初步研究.矿物岩石地球化学通报,2006,25(4):335-338。 |
[34] | 陆建军, 陆现彩, 朱长见, 等. 氧化亚铁硫杆菌对矿山酸矿水中金属污染元素分布的影响[J] .南京大学学报:自然科学,2005, 41(2):113-119。 |
[35] | Marescotti P, Carbone C. Mineralogical and chemical evolution of ochreous precipitates from the Libiola Fe–Cu-sulfide mine (Eastern Liguria, Italy) [J]. Geochemistry , 2012, (27) :577–589 |
[36] | 朱长见,陆建军,陆现彩. 氧化亚铁硫杆菌作用下形成的黄钾铁矾 SEM 的研究[J]. 高校地质学报,2005, 11(2):234-238。 |
[37] | 王长秋,马生凤,鲁安怀.黄钾铁矾的形成条件研究及其环境意义[J]. 岩石矿物学杂志,2005, 24(6):607-611。 |
[38] | Dutrizac J E. The physical chemistry of iron precipitation in the zinc industry. In Lead-Zinc-Tin"80 (J.M. Cigan et al., eds)1980: 532-564. |
[39] | McGregor R G ,Blowes D W. The physical , chemical and mineralogical properties of three cemented layers within sulfide-bearing mine tailings[J] .Journal of Geochemical Exploration , 2002, 76 (3):195 ~207 . |
[40] | 苏贵珍,陆建军,陆现彩等.施氏矿物吸附Cu2+及氧化亚铁硫杆菌的实验研究.岩石矿物学杂志,2009,28(6):575-580。 |
[41] | Bigham J M, Schwertmann U, Carlson L, et al. A poorly crystallized oxyhydroxysulfate of iron formed by bacterial oxidation of Fe(Ⅱ) in acid mine waters [J]. Geochim Cosmochim Acta, 1990, 54:2743–2758. |
[42] | Bigham J M, Carlson L, Murad E. Schwertmannite, a new iron oxyhydroxysulphate from Pyhäsalmi, Finland, and other localities [J].Miner Mag, 1994, 58: 641–648. |
[43] | 周立祥,陈福星. 2005. 一种专性吸附剂的生物合成及其用于吸附去除水中砷铬的方法[P]. 中国专利:CN200510094428.8 |
[44] | Regenspurg S, Brand A and Peiffer S. Formation and stability of schwertmannite in acidic mining lakes[J] .Geochimica et Cosmochimica Acta , 2004, 68: 1185~1197 |
[45] | Loan M,Cowley J M,Hart R,et al. Evidence on the structure of synthetic schwertmannite [J]. American Mineralogist,2004,89:1735-1742. |
[46] | Jonsson J, Persson P, Sjoberg S. Schwertmannite precipitated from acid mine drainage :Phase transformation, sulphate release and surface properties[J] .Applied Geochemistry ,2005, 20:179 ~191. |
[47] | 周顺桂,周立祥,陈福星.施氏矿物 Schwertmannite 的微生物法合成、鉴定及其重金属的吸附性能[J]. 光谱学与光谱分析,2007, 27(2): 367-370。 |
[48] | 廖岳华, 周立祥.极端酸性环境下形成的施威特曼石 (schwertmannite)及其环境学意义[J] .岩石矿物学杂志, 2007,26(2):177~ 183。 |
[49] | Hollingworth S E, Bannister F A. Basaliminite and hydrobasaluminite, two new minerals from Northamptonshire [J]. J. Mineral. Soc,1950, 29: 1–17. |
[50] | Nordstrom D K, Alpers C N. Geochemistry of acid mine waters. In: Plumlee, G.S., Logsdon, M. (Eds.)[J]. Society & Economic Geologists ,1999, 6: 133–160. |
[51] | Bigham J M, Nordstrom D K. Iron and aluminum hydroxy sulfates from acid sulfate waters [J]. Rev. Mineral. Geochem, 2000, 40:351–403. |
[52] | Andersen S, Flores R.G, Madeira V S. 2012. Synthesis and characterization of iron oxides nanoparticles obtained from acid mine drainage treatment and their catalytic properties to toluene oxidation [J]. Industrial and Engineering Chemistry Research, 2012, 51 (2):767-774. |
[53] | Wei X, Viadeiro R C. Synthesis of magnetite nanoparticles with ferric iron recovered from acid mine drainage: implications for environmental engineering. Colloids and Surfaces [J]. Physicochemical and Engineering Aspects , 2007, 294: 280-286. |
[54] | Liang X, Zhong Y, Zhu S. The decolorization of Acid Orange II in non-homogeneous Fenton reaction catalyzed by natural vanadium-titanium magnetite[J]. Journal of Hazardous Materials , 2010, 181: 112-120. |
[55] | Flores R G, Andersen S. Recovery of iron oxides from acid mine drainage and their application as adsorbent or catalyst[J]. Journal of Environmental Management ,2012, 111: 53-60. |
APA Style
Cao Lina, Chen Binghui. (2018). Secondary Minerals and Their Significance from AMD. Science Discovery, 6(6), 481-488. https://doi.org/10.11648/j.sd.20180606.27
ACS Style
Cao Lina; Chen Binghui. Secondary Minerals and Their Significance from AMD. Sci. Discov. 2018, 6(6), 481-488. doi: 10.11648/j.sd.20180606.27
@article{10.11648/j.sd.20180606.27, author = {Cao Lina and Chen Binghui}, title = {Secondary Minerals and Their Significance from AMD}, journal = {Science Discovery}, volume = {6}, number = {6}, pages = {481-488}, doi = {10.11648/j.sd.20180606.27}, url = {https://doi.org/10.11648/j.sd.20180606.27}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.sd.20180606.27}, abstract = {Acid mine drainage (AMD) is one of the most important research subjects of mine environmental treatment and remediation. In recent years, quite a little scholars, at home and abroad, have studied the types, characteristics, formation sequence and assemblages of a majority of secondary mineral resources in acid mine drainage, and so on. And on this basis the secondary minerals, such as jarosite and schwertmannite, were experimentally tested, and the adsorption and passivation ability of several main secondary minerals to heavy metal ion was tested as well. In this paper, the types of secondary minerals found in the acid mine drainage which formed in different environments were summarized systematically and elaborately. In the past a dozen years, the formation sequence and assemblages of these secondary minerals were made a preliminary study. The formation conditions, chemical synthesis methods and conditions of jarosite and schwertmannite, Basaluminite, goethite, hematite, and other main secondary minerals which may have the application value were elaborately discussed and analyzed. And furthermore, the adsorption capacity and passivation of heavy metal ions was analyzed. In the end, the application prospects and application ways of these typical main secondary minerals in acid mine drainage were summed up.}, year = {2018} }
TY - JOUR T1 - Secondary Minerals and Their Significance from AMD AU - Cao Lina AU - Chen Binghui Y1 - 2018/12/12 PY - 2018 N1 - https://doi.org/10.11648/j.sd.20180606.27 DO - 10.11648/j.sd.20180606.27 T2 - Science Discovery JF - Science Discovery JO - Science Discovery SP - 481 EP - 488 PB - Science Publishing Group SN - 2331-0650 UR - https://doi.org/10.11648/j.sd.20180606.27 AB - Acid mine drainage (AMD) is one of the most important research subjects of mine environmental treatment and remediation. In recent years, quite a little scholars, at home and abroad, have studied the types, characteristics, formation sequence and assemblages of a majority of secondary mineral resources in acid mine drainage, and so on. And on this basis the secondary minerals, such as jarosite and schwertmannite, were experimentally tested, and the adsorption and passivation ability of several main secondary minerals to heavy metal ion was tested as well. In this paper, the types of secondary minerals found in the acid mine drainage which formed in different environments were summarized systematically and elaborately. In the past a dozen years, the formation sequence and assemblages of these secondary minerals were made a preliminary study. The formation conditions, chemical synthesis methods and conditions of jarosite and schwertmannite, Basaluminite, goethite, hematite, and other main secondary minerals which may have the application value were elaborately discussed and analyzed. And furthermore, the adsorption capacity and passivation of heavy metal ions was analyzed. In the end, the application prospects and application ways of these typical main secondary minerals in acid mine drainage were summed up. VL - 6 IS - 6 ER -