Antimony speciation in the environment:Recent advances in understanding the biogeochemical processes and ecological effects
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摘要
Antimony(Sb) is a toxic metalloid, and its pollution has become a global environmental problem as a result of its extensive use and corresponding Sb-mining activities. The toxicity and mobility of Sb strongly depend on its chemical speciation. In this review, we summarize the current knowledge on the biogeochemical processes(including emission, distribution,speciation, redox, metabolism and toxicity) that trigger the mobilization and transformation of Sb from pollution sources to the surrounding environment. Natural phenomena such as weathering, biological activity and volcanic activity, together with anthropogenic inputs, are responsible for the emission of Sb into the environment. Sb emitted in the environment can adsorb and undergo redox reactions on organic or inorganic environmental media, thus changing its existing form and exerting toxic effects on the ecosystem. This review is based on a careful and systematic collection of the latest papers during 2010–2017 and our research results, and it illustrates the fate and ecological effects of Sb in the environment.
Antimony(Sb) is a toxic metalloid, and its pollution has become a global environmental problem as a result of its extensive use and corresponding Sb-mining activities. The toxicity and mobility of Sb strongly depend on its chemical speciation. In this review, we summarize the current knowledge on the biogeochemical processes(including emission, distribution,speciation, redox, metabolism and toxicity) that trigger the mobilization and transformation of Sb from pollution sources to the surrounding environment. Natural phenomena such as weathering, biological activity and volcanic activity, together with anthropogenic inputs, are responsible for the emission of Sb into the environment. Sb emitted in the environment can adsorb and undergo redox reactions on organic or inorganic environmental media, thus changing its existing form and exerting toxic effects on the ecosystem. This review is based on a careful and systematic collection of the latest papers during 2010–2017 and our research results, and it illustrates the fate and ecological effects of Sb in the environment.
Antimony(Sb) is a toxic metalloid, and its pollution has become a global environmental problem as a result of its extensive use and corresponding Sb-mining activities. The toxicity and mobility of Sb strongly depend on its chemical speciation. In this review, we summarize the current knowledge on the biogeochemical processes(including emission, distribution,speciation, redox, metabolism and toxicity) that trigger the mobilization and transformation of Sb from pollution sources to the surrounding environment. Natural phenomena such as weathering, biological activity and volcanic activity, together with anthropogenic inputs, are responsible for the emission of Sb into the environment. Sb emitted in the environment can adsorb and undergo redox reactions on organic or inorganic environmental media, thus changing its existing form and exerting toxic effects on the ecosystem. This review is based on a careful and systematic collection of the latest papers during 2010–2017 and our research results, and it illustrates the fate and ecological effects of Sb in the environment.
引文
Abin,C.A.,Hollibaugh,J.T.,2014.Dissimilatory antimonate reduction and production of antimony trioxide microcrystals by a novel microorganism.Environ.Sci.Technol.48,681-688.
Alderton,D.,Serafimovski,T.,Burns,L.,Tasev,G.,2014.Distribution and mobility of arsenic and antimony at mine sites in fry Macedonia.Carpath.J.Earth Environ.9,43-56.
Alphazan,T.,Florian,P.,Thieuleux,C.,2017.Ethoxy and silsesquioxane derivatives of antimony as dopant precursors:unravelling the structure and thermal stability of surface species on SiO2.Phys.Chem.Chem.Phys.19,8595-8601.
Alvarez-Ayuso,E.,Otones,V.,Murciego,A.,Garcia-Sanchez,A.,Santa,R.I.,2012.Antimony,arsenic and lead distribution in soils and plants of an agricultural area impacted by former mining activities.Sci.Total Environ.439,35-43.
Amarasiriwardena,D.,Wu,F.,2011.Antimony:emerging toxic contaminant in the environment.Microchem.J.97,1-3.
An,Y.J.,Kim,M.,2009.Effect of antimony on the microbial growth and the activities of soil enzymes.Chemosphere 74,654-659.
An,Y.J.,Yang,C.Y.,2009.Fridericia peregrinabunda(Enchytraeidae)as a new test species for soil toxicity assessment.Chemosphere77,325-329.
Anawar,H.M.,Freitas,M.C.,Canha,N.,Santa-Regina,I.,2011.Arsenic,antimony,and other trace element contamination in a mine tailings affected area and uptake by tolerant plant species.Environ.Geochem.Health 33,353-362.
Anayurt,R.A.,Sari,A.,Tuzen,M.,2009.Equilibrium,thermodynamic and kinetic studies on biosorption of Pb(II)and Cd(II)from aqueous solution by macrofungus(Lactarius scrobiculatus)biomass.Chem.Eng.J.151,255-261.
Anderson,C.G.,2012.The metallurgy of antimony.Chem.Erde-Geochem.72,3-8.
Andreae,M.O.,Asmode,J.F.,Foster,P.,Vantdack,L.,1981.Determination of anitmony(III),antimony(V),and methylantimony species in natural-waters by atomic-absorption spectrometry with hydride generation.Anal.Chem.53,1766-1771.
Andreae,M.O.,Froelich,P.N.,1984.Arsenic,antimony,and germanium biogeochemistry in the Baltic Sea.Tellus B 36,101-117.
Andrewes,P.,Cullen,W.R.,Polishchuk,E.,2000.Antimony biomethylation by Scopulariopsis brevicaulis:characterization of intermediates and the methyl donor.Chemosphere 41,1717-1725.
Andrewes,P.,Cullen,W.R.,Polishchuk,E.,Reimer,K.J.,2001.Antimony biomethylation by the wood rotting fungus Phaeolus schweinitzii.Appl.Organomet.Chem.15,473-480.
Anjum,A.,Datta,M.,2012.Adsorptive removal of antimony(III)using modified montmorillonite:a study on sorption kinetics.J.Anal.Sci.Meth.Instrum.02,167-175.
Armiento,G.,Nardi,E.,Lucci,F.,De Cassan,M.,Della,V.G.,Santini,C.,et al.,2017.Antimony and arsenic distribution in a catchment affected by past mining activities:influence of extreme weather events.Rend.Lincei-Sci.Fis.28,303-315.
Asaoka,S.,Takahashi,Y.,Araki,Y.,Tanimizu,M.,2012.Comparison of antimony and arsenic behavior in an Ichinokawa River water-sediment system.Chem.Geol.334,1-8.
Baceva,K.,Stafilov,T.,Matevski,V.,2015.Distribution and mobility of toxic metals in Thymus alsarensis Ronniger in the Allchar As-Sb-T1 mine,Republic of Macedonia.Plant Biosyst.149,884-893.
Baek,Y.W.,An,Y.J.,2011.Microbial toxicity of metal oxide nanoparticles(CuO,NiO,ZnO,and Sb2O3)to Escherichia coli,Bacillus subtilis,and Streptococcus aureus.Sci.Total Environ.409,1603-1608.
Baek,Y.W.,Lee,W.M.,Jeong,S.W.,An,Y.J.,2014.Ecological effects of soil antimony on the crop plant growth and earthworm activity.Environ.Earth Sci.71,895-900.
Baeza,M.,Ren,J.,Krishnamurthy,S.,Vaughan,T.C.,2010.Spatial distribution of antimony and arsenic levels in Manadas creek,an urban tributary of the Rio Grande in Laredo,Texas.Arch.Environ.Contam.Toxicol.58,299-314.
Bagherifam,S.,Lakzian,A.,Fotovat,A.,Khorasani,R.,Komarneni,S.,2014.In situ stabilization of As and Sb with naturally occurring Mn,Al and Fe oxides in a calcareous soil:bioaccessibility,bioavailability and speciation studies.J.Hazard.Mater.273,247.
Bai,Y.,Jefferson,W.A.,Liang,J.,Yang,T.,Qu,J.,2017.Antimony oxidation and adsorption by in-situ formed biogenic Mn oxide and Fe-Mn oxides.J.Environ.Sci.54,126-134.
Basu,A.,Saha,D.,Saha,R.,Ghosh,T.,Saha,B.,2014.A review on sources,toxicity and remediation technologies for removing arsenic from drinking water.Res.Chem.Intermed.40,447-485.
Beaudon,E.,Gabrielli,P.,Sierra-Hernandez,M.R.,Wegner,A.,Thompson,L.G.,2017.Central Tibetan Plateau atmospheric trace metals contamination:a 500-year record from the Puruogangri ice core.Sci.Total Environ.601,1349-1363.
Belzile,N.,Chen,Y.W.,Filella,M.,2011.Human exposure to antimony:I.Sources and intake.Crit.Rev.Environ.Sci.Technol.41,1309-1373.
Belzile,N.,Chen,Y.W.,Wang,Z.J.,2001.Oxidation of antimony(III)by amorphous iron and manganese oxyhydroxides.Chem.Geol.174,379-387.
Biver,M.,Shotyk,W.,2012.Experimental study of the kinetics of ligand-promoted dissolution of stibnite(Sb2S3).Chem.Geol.294,165-172.
Boamponsem,L.K.,Adam,J.I.,Dampare,S.B.,Nyarko,B.J.B.,Essumang,D.K.,2010.Assessment of atmospheric heavy metal deposition in the Tarkwa gold mining area of Ghana using epiphytic lichens.Nucl.Instrum.Methods Phys.Res.Sect.BBeam Interact.Mater.Atoms 268,1492-1501.
Borcinov,R.A.,Jamieson,H.,Lalinsk-Volekov,B.,Majzlan,J.,Stevko,M.,Chovan,M.,2017.Mineralogical controls on antimony and arsenic mobility during tetrahedrite-tennantite weathering at historic mine sites Spania Dolina-Piesky and Lubietova-Svatodusna,Slovakia.Am.Mineral.102,1091-1100.
Briki,M.,Zhu,Y.,Gao,Y.,Shao,M.,Ding,H.,Ji,H.,2017.Distribution and health risk assessment to heavy metals near smelting and mining areas of Hezhang,China.Environ.Monit.Assess.189,458.
Bullough,F.,Weiss,D.J.,Dubbin,W.E.,Coles,B.J.,Barrott,J.,Sengupta,A.K.,2010.Evidence of competitive adsorption of Sb(III)and As(III)on activated alumina.Ind.Eng.Chem.Res.49,2521-2524.
Buschmann,J.,Canonica,S.,Sigg,L.,2005.Photoinduced oxidation of antimony(III)in the presence of humic acid.Environ.Sci.Technol.39,5335-5341.
Cai,Y.,Mi,Y.,Zhang,H.,2016b.Kinetic modeling of antimony(III)oxidation and sorption in soils.J.Hazard.Mater.316,102-109.
Cai,F.,Ren,J.,Tao,S.,Wang,X.,2016a.Uptake,translocation and transformation of antimony in rice(Oryza sativa L.)seedlings.Environ.Pollut.209,169-176.
Canepari,S.,Marconi,E.,Astolfi,M.L.,Perrino,C.,2010.Relevance of Sb(III),Sb(V),and Sb-containing nano-particles in urban atmospheric particulate matter.Anal.Bioanal.Chem.397,2533-2542.
Carneado,S.,Hernández-Nataren,E.,López-Sánchez,J.F.,Sahuquillo,A.,2015.Migration of antimony from polyethylene terephthalate used in mineral water bottles.Food Chem.166,544-550.
Carneado,S.,Lopez-Sanchez,J.F.,Sahuquillo,A.,Klontzas,E.,Froudakis,G.E.,Pergantis,S.A.,2017.Antimony speciation in spirits stored in PET bottles:identification of a novel antimony complex.J.Anal.Atom.Spectrom.32,1109-1118.
Carvalho,P.C.S.,Neiva,A.M.R.,Silva,M.M.V.G.,2010.Geochemistry of waters close to abandoned As-Au and Sb-Au mines from Valongo,northern Portugal.Geochim.Cosmochim.Acta 74,A146.
Chapa-Martínez,C.A.,Hinojosa-Reyes,L.,Hernández-Ramírez,A.,Ruiz-Ruiz,E.,Maya-Trevi?o,L.,Guzmán-Mar,J.L.,2016.An evaluation of the migration of antimony from polyethylene terephthalate(PET)plastic used for bottled drinking water.Sci.Total Environ.565,511-518.
Chen,J.,Liu,G.,Kang,Y.,Wu,B.,Sun,R.,Zhou,C.,et al.,2013.Atmospheric emissions of F,As,Se,Hg,and Sb from coal-fired power and heat generation in China.Chemosphere 90,1925-1932.
Chen,Z.,Wei,Y.,Zhao,D.,Shangguan,Y.,Hou,H.,Zeng,Q.,2015.Effect of arbuscular mycorrhizal fungi on antimony uptake and antioxidative responses of Medicago sativa in antimony polluted soil.J.Agro-Environ.Sci.34,1053-1059.
Cidu,R.,Biddau,R.,Dore,E.,Vacca,A.,Marini,L.,2014.Antimony in the soil-water-plant system at the Su Suergiu abandoned mine(Sardinia,Italy):strategies to mitigate contamination.Sci.Total Environ.497,319-331.
Coelho,D.R.,Miranda,E.S.,Saint'Pierre,T.D.,Roma,P.F.J.,2014.Tissue distribution of residual antimony in rats treated with multiple doses of meglumine antimoniate.Mem.Inst.Oswaldo Cruz 109,420-427.
Cohen,S.M.,Chowdhury,A.,Arnold,L.L.,2016.Inorganic arsenic:a non-genotoxic carcinogen.J.Environ.Sci.49,28-37.
Corrales,I.,Barcelo,J.,Bech,J.,Poschenrieder,C.,2014.Antimony accumulation and toxicity tolerance mechanisms in Trifolium species.J.Geochem.Explor.147,167-172.
Courtin-Nomade,A.,Rakotoarisoa,O.,Bril,H.,Grybos,M.,Forestier,L.,Foucher,F.,et al.,2012.Weathering of Sb-rich mining and smelting residues:insight in solid speciation and soil bacteria toxicity.Chem.Erde-Geochem.72,29-39.
Craig,P.J.,Jenkins,R.O.,Dewick,R.,Miller,D.P.,1999.Trimethylantimony generation by Scopulariopsis brevicaulis during aerobic growth.Sci.Total Environ.229,83-88.
Cullen,W.R.,Liu,Q.,Lu,X.,McKnight-Whitford,A.,Peng,H.,Popowich,A.,et al.,2016.Methylated and thiolated arsenic species for environmental and health research-a review on synthesis and characterization.J.Environ.Sci.49,7-27.
Cutter,G.A.,Cutter,L.S.,Featherstone,A.M.,Lohrenz,S.E.,2001.Antimony and arsenic biogeochemistry in the western Atlantic Ocean.Deep-Sea Res.II Top.Stud.Oceanogr.48,2895-2915.
Czégény,Z.,Jakab,E.,Blazsó,M.,Bhaskar,T.,Sakata,Y.,2012.Thermal decomposition of polymer mixtures of PVC,PET and ABS containing brominated flame retardant:formation of chlorinated and brominated organic compounds.J.Anal.Appl.Pyrolysis 96,69-77.
Dai,C.,Zhou,Z.,Zhou,X.,Zhang,Y.,2014.Removal of Sb(III)and Sb(V)from aqueous solutions using nZVI.Water Air Soil Pollut.225,1-12.
Das,S.K.,Das,A.R.,Guha,A.K.,2007.A study on the adsorption mechanism of mercury on Aspergillus versicolor biomass.Environ.Sci.Technol.41,8281-8287.
Das,R.,Khezri,B.,Srivastava,B.,Datta,S.,Sikdar,P.K.,Webster,R.D.,et al.,2015.Trace element composition of PM2.5and PM10from Kolkata-a heavily polluted Indian metropolis.Atoms.Pollut.Res.6,742-750.
Day,B.M.,Coles,M.P.,Hitchcock,P.B.,2012.Neutral and anionic antimony(III)species supported by a bicyclic guanidinate.Eur.J.Inorg.Chem.2012(5),841-846.
De Gregori,I.,Quiroz,W.,Pinochet,H.,Pannier,F.,Potin-Gautier,M.,2007.Speciation analysis of antimony in marine biota by HPLC-(UV)-HG-AFS:extraction procedures and stability of antimony species.Talanta 73,458-465.
Ding,Y.Z.,Wang,R.G.,Guo,J.K.,Wu,F.C.,Xu,Y.M.,Feng,R.W.,2015a.The effect of selenium on the subcellular distribution of antimony to regulate the toxicity of antimony in paddy rice.Environ.Sci.Pollut.Res.22,5111-5123.
Ding,W.,Wang,Y.J.,Yu,Y.T.,Zhang,X.Z.,Li,J.J.,Wu,F.,2015b.Photooxidation of arsenic(III)to arsenic(V)on the surface of kaolinite clay.J.Environ.Sci.36,29-37.
Do Hur,S.,Soyol-Erdene,T.O.,Hwang,H.J.,Han,C.,Gabrielli,P.,Barbante,C.,et al.,2013.Climate-related variations in atmospheric Sb and Tl in the EPICA Dome C ice(East Antarctica)during the past 800,000 years.Glob.Biogeochem.Cycles 27,930-940.
Dordevic,D.,Stortini,A.M.,Relic,D.,Mihajlidi-Zelic,A.,Huremovic,J.,Barbante,C.,et al.,2014.Trace elements in size-segregated urban aerosol in relation to the anthropogenic emission sources and the resuspension.Environ.Sci.Pollut.Res.21,10949-10959.
Dousova,B.,Buzek,F.,Herzogova,L.,Machovic,V.,Lhotka,M.,2015.Effect of organic matter on arsenic(V)and antimony(V)adsorption in soils.Eur.J.Soil Sci.66,74-82.
Duan,L.Q.,Song,J.M.,Li,X.G.,Yuan,H.M.,2010.The behaviors and sources of dissolved arsenic and antimony in Bohai Bay.Cont.Shelf Res.30,1522-1534.
Duan,L.Q.,Song,J.M.,Yuan,H.M.,Li,X.G.,Li,N.,Ma,J.K.,2014.Distribution,chemical speciation and source of trace elements in surface sediments of the Changjiang Estuary.Environ.Earth Sci.72,3193-3204.
Duester,L.,Diaz-Bone,R.A.,Kosters,J.,Hirner,A.V.,2005.Methylated arsenic,antimony and tin species in soils.J.Environ.Monit.7,1186-1193.
Duester,L.,van der Geest,H.G.,Moelleken,S.,Hirner,A.V.,Kueppers,K.,2011.Comparative phytotoxicity of methylated and inorganic arsenic-and antimony species to Lemna minor,Wolffia arrhiza and Selenastrum capricornutum.Microchem.J.97,30-37.
Dupont,D.,Arnout,S.,Jones,P.T.,Binnemans,K.,2016.Antimony recovery from end-of-life products and industrial process residues:a critical review.J.Sustain.Metall.2,79-103.
El Shanawany,S.,Foda,N.,Hashad,D.I.,Salama,N.,Sobh,Z.,2017.The potential DNA toxic changes among workers exposed to antimony trioxide.Environ.Sci.Pollut.Res.24,12455-12461.
Ettler,V.,Tejnecky,V.,Mihaljevic,M.,Sebek,O.,Zuna,M.,Vanek,A.,2010.Antimony mobility in lead smelter-polluted soils.Geoderma 155,409-418.
Evangelou,M.W.H.,Hockmann,K.,Pokharel,R.,Jakob,A.,Schulin,R.,2012.Accumulation of Sb,Pb,Cu,Zn and Cd by various plants species on two different relocated military shooting range soils.J.Environ.Manag.108,102-107.
Fae Gomes,G.M.,Mendes,T.F.,Wada,K.,2011.Reduction in toxicity and generation of slag in secondary lead process.J.Clean.Prod.19,1096-1103.
Fan,J.,Wang,Y.,2016.Atmospheric emissions of As,Sb,and Se from coal combustion in Shandong province,2005-2014.Pol.J.Environ.Stud.25,2339-2347.
Fan,J.X.,Wang,Y.J.,Fan,T.T.,Cui,X.D.,Zhou,D.M.,2014.Photo-induced oxidation of Sb(III)on goethite.Chemosphere 95,295.
Fan,J.X.,Wang,Y.J.,Fan,T.T.,Dang,F.,Zhou,D.M.,2016.Effect of aqueous Fe(II)on Sb(V)sorption on soil and goethite.Chemosphere 147,44-51.
Fawcett,S.E.,Jamieson,H.E.,2011.The distinction between ore processing and post-depositional transformation on the speciation of arsenic and antimony in mine waste and sediment.Chem.Geol.283,109-118.
Fawcett,S.E.,Jamieson,H.E.,Nordstrom,D.K.,Mccleskey,R.B.,2015.Arsenic and antimony geochemistry of mine wastes,associated waters and sediments at the Giant Mine,Yellowknife,Northwest Territories,Canada.Appl.Geochem.62,3-17.
Feng,R.,Liao,G.,Guo,J.,Wang,R.,Xu,Y.,Ding,Y.,et al.,2016.Responses of root growth and antioxidative systems of paddy rice exposed to antimony and selenium.Environ.Exp.Bot.122,29-38.
Feng,R.,Wei,C.,Tu,S.,Ding,Y.,Wang,R.,Guo,J.,2013.The uptake and detoxification of antimony by plants:a review.Environ.Exp.Bot.96,28-34.
Filella,M.,2010.Alkyl derivatives of antimony in the environment.Met.Ions Life Sci.7,267-301.
Filella,M.,Belzile,N.,Chen,Y.W.,2002a.Antimony in the environment:a review focused on natural waters I.Occurrence.Earth-Sci.Rev.57,125-176.
Filella,M.,Belzile,N.,Chen,Y.W.,2002b.Antimony in the environment:a review focused on natural waters II.Relevant solution chemistry.Earth-Sci.Rev.59,265-285.
Filella,M.,Belzile,N.,Chen,Y.W.,2012.Human exposure to antimony.II.Contents in some human tissues often used in biomonitoring(hair,nails,teeth).Crit.Rev.Environ.Sci.Technol.42,1058-1115.
Filella,M.,Belzile,N.,Chen,Y.W.,2013a.Human exposure to antimony.III.Contents in some human excreted biofluids(urine,milk,saliva).Crit.Rev.Environ.Sci.Technol.43,162-214.
Filella,M.,Belzile,N.,Chen,Y.W.,2013b.Human exposure to antimony.IV.Contents in human blood.Crit.Rev.Environ.Sci.Technol.43,2071-2105.
Filella,M.,Belzile,N.,Lett,M.C.,2007.Antimony in the environment:a review focused on natural waters.III.Microbiota relevant interactions.Earth-Sci.Rev.80,195-217.
Flakova,R.,Zenisova,Z.,Sracek,O.,Krcmar,D.,Ondrejkova,I.,Chovan,M.,et al.,2012.The behavior of arsenic and antimony at Pezinok mining site,southwestern part of the Slovak Republic.Environ.Earth Sci.66,1043-1057.
Fort,M.,Grimalt,J.O.,Querol,X.,Casas,M.,Sunyer,J.,2016.Evaluation of atmospheric inputs as possible sources of antimony in pregnant women from urban areas.Sci.Total Environ.544,391-399.
Foucault,Y.,Leveque,T.,Xiong,T.,Schreck,E.,Austruy,A.,Shahid,M.,et al.,2013.Green manure plants for remediation of soils polluted by metals and metalloids:ecotoxicity and human bioavailability assessment.Chemosphere 93,1430-1435.
Fu,Z.,Wu,F.,Amarasiriwardena,D.,Mo,C.,Liu,B.,Zhu,J.,et al.,2010.Antimony,arsenic and mercury in the aquatic environment and fish in a large antimony mining area in Hunan,China.Sci.Total Environ.408,3403-3410.
Fu,Z.,Wu,F.,Mo,C.,Liu,B.,Zhu,J.,Deng,Q.,et al.,2011.Bioaccumulation of antimony,arsenic,and mercury in the vicinities of a large antimony mine,China.Microchem.J.97,12-19.
Fu,L.,Shozugawa,K.,Matsuo,M.,2018.Oxidation of antimony(III)in soil by manganese(IV)oxide using X-ray absorption fine structure.J.Environ.Sci.https://doi.org/10.1016/j.jes.2018.01.003.
Gadd,G.M.,2009.Biosorption:critical review of scientific rationale,environmental importance and significance for pollution treatment.J.Chem.Technol.Biotechnol.84,13-28.
Gaga,E.O.,Dogeroglu,T.,Ozden,O.,Ari,A.,Yay,O.D.,Altug,H.,et al.,2012.Evaluation of air quality by passive and active sampling in an urban city in Turkey:current status and spatial analysis of air pollution exposure.Environ.Sci.Pollut.Res.19,3579-3596.
Gandois,L.,Tipping,E.,Dumat,C.,Probst,A.,2010.Canopy influence on trace metal atmospheric inputs on forest ecosystems:speciation in throughfall.Atmos.Environ.44,824-833.
Gao,B.,Lu,J.,Zhou,H.D.,Yin,S.H.,Hao,H.,2012.The distribution,accumulation and potential source of seldom monitored trace elements in sediments of Beijiang River,South China.Water Sci.Technol.65,2118-2124.
Gebel,T.,1997.Arsenic and antimony:comparative approach on mechanistic toxicology.Chem.Biol.Interact.107,131-144.
Gil-Diaz,T.,Schafer,J.,Pougnet,F.,Abdou,M.,Dutruch,L.,Eyrolle-Boyer,F.,et al.,2016.Distribution and geochemical behaviour of antimony in the Gironde estuary:a first qualitative approach to regional nuclear accident scenarios.Mar.Chem.185,65-73.
Goyenechepatino,D.A.,Valderrama,L.,Walker,J.,Saravia,N.G.,2008.Antimony resistance and trypanothione in experimentally selected and clinical strains of Leishmania panamensis.Antimicrob.Agents Chemother.52,4503-4506.
Guillamot,F.,Calvert,V.,Millot,M.V.,Criquet,S.,2014.Does antimony affect microbial respiration in Mediterranean soils?A microcosm experiment.Pedobiologia 57,119-121.
Guo,X.,Wang,K.,He,M.,Liu,Z.,Yang,H.,Li,S.,2014.Antimony smelting process generating solid wastes and dust:characterization and leaching behaviors.J.Environ.Sci.26,1549-1556.
Guo,X.,Wu,Z.,He,M.,2009.Removal of antimony(V)and antimony(III)from drinking water by coagulation-flocculation-sedimentation(CFS).Water Res.43,4327-4335.
Guo,Y.Q.,Xue,X.M.,Yan,Y.,Zhu,Y.G.,Yang,G.D.,Ye,J.,2016.Arsenic methylation by an arsenite S-adenosylmethionine methyltransferase from Spirulina platensis.J.Environ.Sci.49,162-168.
Hamamura,N.,Fukushima,K.,Itai,T.,2013.Identification of antimony-and arsenic-oxidizing bacteria associated with antimony mine tailing.Microbes Environ.28,257-263.
Han,Y.,Zhang,F.,Wang,Q.,Zheng,S.,Guo,W.,Feng,L.,et al.,2016.Flavihumibacter stibioxidans sp nov.,an antimony-oxidizing bacterium isolated from antimony mine soil.Int.J.Syst.Evol.Microbiol.66,4676-4680.
Hartmann,L.M.,Craig,P.J.,Jenkins,R.O.,2003.Influence of arsenic on antimony methylation by the aerobic yeast Cryptococcus humicolus.Arch.Microbiol.180,347-352.
He,M.,Wan,H.,2004.Distribution,speciation,toxicity and bioavailability of antimony in the environment.Prog.Chem.16,131-135.
He,M.,Wang,X.,Wu,F.,Fu,Z.,2012.Antimony pollution in China.Sci.Total Environ.421,41-50.
He,M.,Xie,N.,Yu,W.,Yang,R.,1992.Antimony in the environment.Environ.Prot.2,44.
He,M.,Yang,J.,1999.Effects of different forms of antimony on rice during the period of germination and growth and antimony concentration in rice tissue.Sci.Total Environ.243,149-155.
Herath,I.,Vithanage,M.,Bundschuh,J.,2017.Antimony as a global dilemma:geochemistry,mobility,fate and transport.Environ.Pollut.223,545-559.
Hiller,E.,Lalinska,B.,Chovan,M.,Jurkovic,L.,Klimko,T.,Jankular,M.,et al.,2012.Arsenic and antimony contamination of waters,stream sediments and soils in the vicinity of abandoned antimony mines in the Western Carpathians,Slovakia.Appl.Geochem.27,598-614.
Hockmann,K.,Lenz,M.,Tandy,S.,Nachtegaal,M.,Janousch,M.,Schulin,R.,2014.Release of antimony from contaminated soil induced by redox changes.J.Hazard.Mater.275,215-221.
Hong,S.,Soyol-Erdene,T.O.,Hwang,H.J.,Hong,S.B.,Do Hur,S.,Motoyama,H.,2012.Evidence of global-scale As,Mo,Sb,and Tl atmospheric pollution in the Antarctic snow.Environ.Sci.Technol.46,11550-11557.
Hu,X.,Guo,X.,He,M.,Li,S.,2016.pH-dependent release characteristics of antimony and arsenic from typical antimony-bearing ores.J.Environ.Sci.44,171-179.
Hu,X.,He,M.,2017.Organic ligand-induced dissolution kinetics of antimony trioxide.J.Environ.Sci.56,87-94.
Hu,X.,He,M.,Kong,L.,2015a.Photopromoted oxidative dissolution of stibnite.Appl.Geochem.61,53-61.
Hu,X.,He,M.,Li,S.,2015b.Antimony leaching release from brake pads:effect of p H,temperature and organic acids.J.Environ.Sci.29,11-17.
Hu,X.,He,M.,Li,S.,Guo,X.,2017.The leaching characteristics and changes in the leached layer of antimony-bearing ores from China.J.Geochem.Explor.176,76-84.
Hu,X.,Kong,L.,He,M.,2014.Kinetics and mechanism of photopromoted oxidative dissolution of antimony trioxide.Environ.Sci.Technol.48,14266-14272.
Huang,Y.,Chen,Z.,Liu,W.,2012.Influence of iron plaque and cultivars on antimony uptake by and translocation in rice(Oryza sativa L.)seedlings exposed to Sb(III)or Sb(V).Plant Soil 352,41-49.
Iijima,A.,2010.Clarification of the predominant emission sources of antimony in airborne particulate matter and estimation of their impacts on the atmosphere.Bunseki Kagaku 59,151-152.
Iijima,A.,Sato,K.,Ikeda,T.,Sato,H.,Kozawa,K.,Furuta,N.,2010.Concentration distributions of dissolved Sb(III)and Sb(V)species in size-classified inhalable airborne particulate matter.J.Anal.At.Spectrom.25,356-363.
Iqbal,M.,Saeed,A.,Edyvean,R.G.J.,2013.Bioremoval of antimony(III)from contaminated water using several plant wastes:optimization of batch and dynamic flow conditions for sorption by green bean husk(Vigna radiata).Chem.Eng.J.225,192-201.
Jablonska-Czapla,M.,Szopa,S.,Zerzucha,P.,Lyko,A.,Michalski,R.,2015.Chemometric and environmental assessment of arsenic,antimony,and chromium speciation form occurrence in a water reservoir subjected to thermal anthropopressure.Environ.Sci.Pollut.Res.22,15731-15744.
Jain,A.,Raven,K.P.,Loeppert,R.H.,1999.Arsenite and arsenate adsorption on ferrihydrite:surface charge reduction and net OH-release stoichiometry.Environ.Sci.Technol.33,1179-1184.
Jenkins,R.O.,Craig,P.J.,Goessler,W.,Miller,D.,Ostah,N.,Irgolic,K.J.,1998.Biomethylation of inorganic antimony compounds by an aerobic fungus:Scopulariopsis brevicaulis.Environ.Sci.Technol.32,882-885.
Jenkins,R.O.,Forster,S.N.,Craig,P.J.,2002.Formation of methylantimony species by an aerobic prokaryote:Flavobacterium sp.Arch.Microbiol.178,274-278.
Kalantzi,I.,Mylona,K.,Sofoulaki,K.,Tsapakis,M.,Pergantis,S.A.,2017.Arsenic speciation in fish from Greek coastal areas.J.Environ.Sci.56,300-312.
Kameda,T.,Honda,M.,Yoshioka,T.,2011.Removal of antimonate ions and simultaneous formation of a brandholzite-like compound from magnesium-aluminum oxide.Sep.Purif.Technol.80,235-239.
Kameda,T.,Yagihashi,N.,Grause,G.,Yoshioka,T.,2009.Preparation of Fe-Al layered double hydroxide and its application in Sb removal.Fresenius Environ.Bull.18,1006-1010.
Kappen,P.,Ferrando-Miguel,G.,Reichman,S.M.,Innes,L.,Welter,E.,Pigram,P.J.,2017.Antimony leaching and chemical species analyses in an industrial solid waste:surface and bulk speciation using To F-SIMS and XANES.J.Hazard.Mater.329,131-140.
Khalid,N.,Ahmad,S.,Toheed,A.,Ahmed,J.,2000.Potential of rice husks for antimony removal.Appl.Radiat.Isot.52,31-38.
Kim,Y.H.,Wyrzykowska-Ceradini,B.,Touati,A.,Krantz,Q.T.,Dye,J.A.,Linak,W.P.,et al.,2015.Characterization of size-fractionated airborne particles inside an electronic waste recycling facility and acute toxicity testing in mice.Environ.Sci.Technol.49,11543-11550.
Kolbe,F.,Weiss,H.,Morgenstern,P.,Wennrich,R.,Lorenz,W.,Schurk,K.,et al.,2011.Sorption of aqueous antimony and arsenic species onto akaganeite.J.Colloid Interface Sci.357,460-465.
Kong,L.,He,M.,2016.Mechanisms of Sb(III)photooxidation by the excitation of organic Fe(III)complexes.Environ.Sci.Technol.50,6974-6982.
Kong,L.,He,M.,Hu,X.,2016.Rapid photooxidation of Sb(III)in the presence of different Fe(III)species.Geochim.Cosmochim.Acta 180,214-226.
Kong,L.,Hu,X.,He,M.,2015.Mechanisms of Sb(III)oxidation by pyrite-induced hydroxyl radicals and hydrogen peroxide.Environ.Sci.Technol.49,3499-3505.
Krachler,M.,Zheng,J.,Koerner,R.,Zdanowicz,C.,Fisher,D.,Shotyk,W.,2005.Increasing atmospheric antimony contamination in the northern hemisphere:snow and ice evidence from Devon Island,Arctic Canada.J.Environ.Monit.7,1169-1176.
Kulp,T.R.,Miller,L.G.,Braiotta,F.,Webb,S.M.,Kocar,B.D.,Blum,J.S.,et al.,2014.Microbiological reduction of Sb(V)in anoxic freshwater sediments.Environ.Sci.Technol.48,218-226.
Kuperman,R.G.,Checkai,R.T.,Simini,M.,Phillips,C.I.,Speicher,J.A.,Barclift,D.J.,2006.Toxicity benchmarks for antimony,barium,and beryllium determined using reproduction endpoints for Folsomia candida,Eisenia fetida,and Enchytraeus crypticus.Environ.Toxicol.Chem.25,754-762.
Kuwae,M.,Tsugeki,N.K.,Agusa,T.,Toyoda,K.,Tani,Y.,Ueda,S.,et al.,2013.Sedimentary records of metal deposition in Japanese alpine lakes for the last 250 years:recent enrichment of airborne Sb and in in East Asia.Sci.Total Environ.442,189-197.
Lai,C.Y.,Wen,L.L.,Zhang,Y.,Luo,S.S.,Wang,Q.Y.,Luo,Y.H.,et al.,2016.Autotrophic antimonate bio-reduction using hydrogen as the electron donor.Water Res.88,467-474.
Laporte-Saumure,M.,Martel,R.,Mercier,G.,2011.Characterization and metal availability of copper,lead,antimony and zinc contamination at four Canadian small arms firing ranges.Environ.Technol.32,767-781.
Le,X.C.,2016.Professor William R.Cullen and arsenic chemistry.J.Environ.Sci.49,1-6.
Lehr,C.R.,Kashyap,D.R.,McDermott,T.R.,2007.New insights into microbial oxidation of antimony and arsenic.Appl.Environ.Microbiol.73,2386-2389.
Leng,Y.,Guo,W.,Su,S.,Yi,C.,Xing,L.,2012.Removal of antimony(III)from aqueous solution by graphene as an adsorbent.Chem.Eng.J.211-212(47),406-411.
Leuz,A.K.,Johnson,C.A.R.,2005.Oxidation of Sb(III)to Sb(V)by O-2and H2O2in aqueous solutions.Geochim.Cosmochim.Acta 69,1165-1172.
Leuz,A.K.,M?nch,H.,Johnson,C.A.,2006.Sorption of Sb(III)and Sb(V)to goethite:influence on Sb(III)oxidation and mobilization.Environ.Sci.Technol.40,7277-7282.
Levresse,G.,Lopez,G.,Tritlla,J.,Cardellach,L.E.,Carrillo,C.A.,Mascunano,S.E.,et al.,2012.Phytoavailability of antimony and heavy metals in arid regions:the case of the Wadley Sb district(San Luis,Potosi,Mexico).Sci.Total Environ.427,115-125.
Lewis,J.,Sjostrom,J.,Skyllberg,U.,Hagglund,L.,2010.Distribution,chemical speciation,and mobility of lead and antimony originating from small arms ammunition in a coarse-grained unsaturated surface sand.J.Environ.Qual.39,863-870.
Li,X.H.,Dou,X.M.,Li,J.Q.,2012.Antimony(V)removal from water by iron-zirconium bimetal oxide:performance and mechanism.J.Environ.Sci.24,1197-1203.
Li,P.,Lin,C.,Cheng,H.,Duan,X.,Lei,K.,2015a.Contamination and health risks of soil heavy metals around a lead/zinc smelter in southwestern China.Ecotoxicol.Environ.Saf.113,391-399.
Li,J.,Wang,Q.,Li,M.,Yang,B.,Shi,M.,Guo,W.,et al.,2015b.Proteomics and genetics for identification of a bacterial antimonite oxidase in agrobacterium tumefaciens.Environ.Sci.Technol.49,5980-5989.
Li,J.X.,Wang,Q.,Oremland,R.S.,Kulp,T.R.,Rensing,C.,Wang,G.J.,2016.Microbial antimony biogeochemistry:enzymes,regulation,and related metabolic pathways.Appl.Environ.Microbiol.82,5482-5495.
Li,J.,Wang,Q.,Zhang,S.,Qin,D.,Wang,G.,2013.Phylogenetic and genome analyses of antimony-oxidizing bacteria isolated from antimony mined soil.Int.Biodeterior.Biodegrad.76,76-80.
Li,J.,Wei,Y.,Zhao,L.,Zhang,J.,Shangguan,Y.,Li,F.,et al.,2014.Bioaccessibility of antimony and arsenic in highly polluted soils of the mine area and health risk assessment associated with oral ingestion exposure.Ecotoxicol.Environ.Saf.110,308-315.
Li,J.,Yang,B.,Shi,M.,Yuan,K.,Guo,W.,Li,M.,et al.,2017.Effects upon metabolic pathways and energy production by Sb(III)and As(III)/Sb(III)-oxidase gene aioA in Agrobacterium tumefaciens GW4.PLoS One 12(2),1-19.
Lin,Q.,Liu,E.,Zhang,E.,Nath,B.,Shen,J.,Yuan,H.,et al.,2018.Reconstruction of atmospheric trace metals pollution in Southwest China using sediments from a large and deep alpine lake:historical trends,sources and sediment focusing.Sci.Total Environment 613,331-341.
Lin,X.,Sun,Z.,Ma,J.,Zhao,L.,Qin,X.,Zhao,S.,et al.,2017.Toxicity differences of different forms of antimony to soil-dwelling springtail(Folsomia candida).J.Agro-Environ.Sci.36,657-664.
Liu,F.,Le,X.C.,McKnight-Whitford,A.,Xia,Y.,Wu,F.,Elswick,E.,et al.,2010.Antimony speciation and contamination of waters in the Xikuangshan antimony mining and smelting area,China.Environ.Geochem.Health 32,401-413.
Loppi,S.,Paoli,L.,2015.Comparison of the trace element content in transplants of the lichen Evernia prunastri and in bulk atmospheric deposition:a case study from a low polluted environment(C Italy).Biologia 70,460-466.
Mariet,A.L.,de Vaufleury,A.,Bégeot,C.,Walter-Simonnet,A.V.,Gimbert,F.,2016.Palaeo-pollution from mining activities in the Vosges Mountains:1000 years and still bioavailable.Environ.Pollut.214,575-584.
Marijic,V.F.,Dragun,Z.,Peric,M.S.,Kepcija,R.M.,Gulin,V.,Velki,M.,et al.,2016.Investigation of the soluble metals in tissue as biological response pattern to environmental pollutants(Gammarus fossarum example).Chemosphere 154,300-309.
Mariussen,E.,Johnsen,I.V.,Stromseng,A.E.,2017.Distribution and mobility of lead(Pb),copper(Cu),zinc(Zn),and antimony(Sb)from ammunition residues on shooting ranges for small arms located on mires.Environ.Sci.Pollut.Res.24,10182-10196.
Martin,R.,Dowling,K.,Pearce,D.C.,Florentine,S.,Mc Knight,S.,Stelcer,E.,et al.,2017.Trace metal content in inhalable particulate matter(PM2.5-10 and PM2.5)collected from historical mine waste deposits using a laboratory-based approach.Environ.Geochem.Health 39,549-563.
Martinez,A.M.,Echeberria,J.,2016.Towards a better understanding of the reaction between metal powders and the solid lubricant Sb2S3 in a low-metallic brake pad at high temperature.Wear348-349,27-42.
Mera,M.F.,Rubio,M.,Perez,C.A.,Galvan,V.,Germanier,A.,2015.SR mu XRF and XRD study of the spatial distribution and mineralogical composition of Pb and Sb species in weathering crust of corroded bullets of hunting fields.Microchem.J.119,114-122.
Miao,Y.Y.,Han,F.C.,Pan,B.C.,Niu,Y.J.,Nie,G.Z.,Lv,L.,2014.Antimony(V)removal from water by hydrated ferric oxides supported by calcite sand and polymeric anion exchanger.J.Environ.Sci.26,307-314.
Michalke,K.,Wickenheiser,E.B.,Mehring,M.,Hirner,A.V.,Hensel,R.,2000.Production of volatile derivatives of metal(loid)s by microflora involved in anaerobic digestion of sewage sludge.Appl.Environ.Microbiol.66,2791-2796.
Mishra,S.,Dwivedi,J.,Kumar,A.,Sankararamakrishnan,N.,2016.Removal of antimonite(Sb(III))and antimonate(Sb(V))using zerovalent iron decorated functionalized carbon nanotubes.RSC Adv.6,95865-95878.
Mitsunobu,S.,Harada,T.,Takahashi,Y.,2006.Comparison of antimony behavior with that of arsenic under various soil redox conditions.Environ.Sci.Technol.40,7270-7276.
Mitsunobu,S.,Muramatsu,C.,Watanabe,K.,Sakata,M.,2013.Behavior of antimony(V)during the transformation of ferrihydrite and its environmental implications.Environ.Sci.Technol.47,9660-9667.
Mitsunobu,S.,Takahashi,Y.,Sakai,Y.,2008.Abiotic reduction of antimony(V)by green rust(Fe-4(II)Fe-2(III)(OH)(12)SO4 center dot 3H(2)O).Chemosphere 70,942-947.
Mittal,V.K.,Bera,S.,Narasimhan,S.V.,Velmurugan,S.,2013.Adsorption behavior of antimony(III)oxyanions on magnetite surface in aqueous organic acid environment.Appl.Surf.Sci.266,272-279.
Mohammadpour,G.A.,Karbassi,A.R.,Baghvand,A.,2016.Origin and spatial distribution of metals in agricultural soils.Glob.J.Environ.Sci.Manag.2,145-156.
Nakamaru,Y.M.,Martín,P.F.J.,2017.Effect of soil organic matter on antimony bioavailability after the remediation process.Environ.Pollut.228,425.
Nannoni,F.,Protano,G.,2016.Chemical and biological methods to evaluate the availability of heavy metals in soils of the Siena urban area(Italy).Sci.Total Environ.568,1-10.
Nannoni,F.,Protano,G.,Riccobono,F.,2011.Uptake and bioaccumulation of heavy elements by two earthworm species from a smelter contaminated area in northern Kosovo.Soil Biol.Biochem.43,2359-2367.
Navarro,P.,Alguacil,F.J.,2002.Adsorption of antimony and arsenic from a copper electrorefining solution onto activated carbon.Hydrometallurgy 66,101-105.
Ngo,L.K.,Pinch,B.M.,Bennett,W.W.,Teasdale,P.R.,Jolley,D.F.,2016.Assessing the uptake of arsenic and antimony from contaminated soil by radish(Raphanus sativus)using DGT and selective extractions.Environ.Pollut.216,104-114.
Nguyen,V.K.,Choi,W.,Yu,J.,Lee,T.,2017.Microbial oxidation of antimonite and arsenite by bacteria isolated from antimony-contaminated soils.Int.J.Hydrog.Energy 42,27832-27842.
Ning,Z.P.,Xiao,T.F.,Xiao,E.Z.,2015.Antimony in the soil-plant system in an Sb mining/smelting area of Southwest China.Int.J.Phytorem.17,1081-1089.
Nishad,P.A.,Bhaskarapillai,A.,Velmurugan,S.,2014.Nano-titania-crosslinked chitosan composite as a superior sorbent for antimony(III)and(V).Carbohydr.Polym.108,169-175.
Okkenhaug,G.,Amstatter,K.,Bue,H.L.,Cornelissen,G.,Breedveld,G.D.,Henriksen,T.,et al.,2013.Antimony(Sb)contaminated shooting range soil:Sb mobility and immobilization by soil amendments.Environ.Sci.Technol.47,6431-6439.
Okkenhaug,G.,Gebhardt,K.A.G.,Amstaetter,K.,Bue,H.L.,Herzel,H.,Mariussen,E.,et al.,2016.Antimony(Sb)and lead(Pb)in contaminated shooting range soils:Sb and Pb mobility and immobilization by iron based sorbents,a field study.J.Hazard.Mater.307,336-343.
Okkenhaug,G.,Zhu,Y.G.,Luo,L.,Lei,M.,Li,X.,Mulder,J.,2011.Distribution,speciation and availability of antimony(Sb)in soils and terrestrial plants from an active Sb mining area.Environ.Pollut.159,2427-2434.
Oorts,K.,Smolders,E.,Degryse,F.,Buekers,J.,Gasco,G.,Cornelis,G.,et al.,2008.Solubility and toxicity of antimony trioxide(Sb2O3)in soil.Environ.Sci.Technol.42,4378-4383.
Osório,W.R.,Rosa,D.M.,Peixoto,L.C.,Garcia,A.,2011.Cell/dendrite transition and electrochemical corrosion of Pb-Sb alloys for lead-acid battery applications.J.Power Sources 196,6567-6572.
Pant,P.,Baker,S.J.,Goel,R.,Guttikunda,S.,Goel,A.,Shukla,A.,et al.,2016.Analysis of size-segregated winter season aerosol data from New Delhi,India.Atmos.Pollut.Res.7,100-109.
Payan,L.,Teresa,P.M.,Munoz,L.,Dolores,L.R.M.,Pacheco,R.,Ramos,N.,2017.Study of the influence of storage conditions on the quality and migration levels of antimony in polyethylene terephthalate-bottled water.Food Sci.Technol.Int.23,318-327.
Perez-Sirvent,C.,Martinez-Sanchez,M.J.,Martinez-Lopez,S.,Hernandez,C.M.,2011.Antimony distribution in soils and plants near an abandoned mining site.Microchem.J.97,52-56.
Phillips,M.A.,Canovas,A.,Wu,P.W.,Islas-Trejo,A.,Medrano,J.F.,Rice,R.H.,2016.Parallel responses of human epidermal keratinocytes to inorganic Sb-III and As-III.Environ.Chem.13,963-970.
Pierart,A.,Shahid,M.,Sejalon-Delmas,N.,Dumat,C.,2015.Antimony bioavailability:knowledge and research perspectives for sustainable agricultures.J.Hazard.Mater.289,219-234.
Ptak,C.,McBride,M.,2015.Organically complexed iron enhances bioavailability of antimony to maize(Zea mays)seedlings in organic soils.Environ.Toxicol.Chem.34,2732-2738.
Qi,C.,Liu,G.,Kang,Y.,Lam,P.K.S.,Chou,C.,2011a.Assessment and distribution of antimony in soils around three coal mines,Anhui,China.J.Air Waste Manag.61,850-857.
Qi,C.,Wu,F.,Deng,Q.,Liu,G.,Mo,C.,Liu,B.,et al.,2011b.Distribution and accumulation of antimony in plants in the super-large Sb deposit areas,China.Microchem.J.97,44-51.
Qiao,F.,Lei,K.,Li,Z.,Liu,Q.,Wei,Z.,An,L.,et al.,2018.Effects of storage temperature and time of antimony release from PETbottles into drinking water in China.Environ.Sci.Pollut.Res.Int.25(2),1388-1393.
Quan,S.X.,Yan,B.,Yang,F.,Li,N.,Xiao,X.M.,Fu,J.M.,2015.Spatial distribution of heavy metal contamination in soils near a primitive e-waste recycling site.Environ.Sci.Pollut.Res.22,1290-1298.
Quiroz,W.,Aguilar,L.,Barria,M.,Veneciano,J.,Martinez,D.,Bravo,M.,et al.,2013.Sb(V)and Sb(III)distribution in human erythrocytes:speciation methodology and the influence of temperature,time and anticoagulants.Talanta 115,902-910.
Quiroz,W.,Astudillo,F.,Bravo,M.,Cereceda-Balic,F.,Vidal,V.,Palomo-Marin,M.R.,et al.,2016.Antimony speciation in soils,sediments and volcanic ashes by microwave extraction and HPLC-HG-AFS detection.Microchem.J.129,111-116.
Quiroz,W.,De Gregori,I.,Basilio,P.,Bravo,M.,Pinto,M.,Gabriela,L.M.,2009.Heavy weight vehicle traffic and its relationship with antimony content in human blood.J.Environ.Monit.11,1051-1055.
Rafiei,B.,Khodaei,A.S.,Khodabakhsh,S.,Hashemi,M.,Nejad,M.B.,2010.Contamination assessment of lead,zinc,copper,cadmium,arsenic and antimony in Ahangaran mine soils,Malayer,west of Iran.Soil Sediment Contam.19,573-586.
Rakshit,S.,Sarkar,D.,Punamiya,P.,Datta,R.,2011.Antimony sorption at gibbsite-water interface.Chemosphere 84,480-483.
Rashedy,A.H.,Solimany,A.A.,Ismail,A.K.,Wahdan,M.H.,Saban,K.A.,2013.Histopathological and functional effects of antimony on the renal cortex of growing albino rat.Int.J.Clin.Exp.Pathol.6,1467-1480.
Reimann,C.,Matschullat,J.,Birke,M.,Salminen,R.,2010.Antimony in the environment:lessons from geochemical mapping.Appl.Geochem.25,175-198.
Ren,J.H.,Ma,L.Q.,Sun,H.J.,Cai,F.,Luo,J.,2014.Antimony uptake,translocation and speciation in rice plants exposed to antimonite and antimonate.Sci.Total Environ.475,83-89.
Ren,B.,Wang,C.,Ma,H.,Deng,R.,Zhang,P.,2016.Effect to rainfall on Sb release characteristics from smelting slag in rainy south China.Fresenius Environ.Bull.25,4908-4914.
Resongles,E.,Casiot,C.,Elbaz-Poulichet,F.,Freydier,R.,Bruneel,O.,Piot,C.,et al.,2013.Fate of Sb(V)and Sb(III)species along a gradient of pH and oxygen concentration in the Carnoules mine waters(southern France).Environ.Sci.Processes Impacts15,1536-1544.
Resongles,E.,Freydier,R.,Casiot,C.,Viers,J.,Chmeleff,J.,Elbaz-Poulichet,F.,2015.Antimony isotopic composition in river waters affected by ancient mining activity.Talanta 144,851-861.
Rocha,M.N.,Nogueira,P.M.,Demicheli,C.,de Oliveira,L.G.,da Silva,M.M.,Frezard,F.,et al.,2013.Cytotoxicity and in vitro antileishmanial activity of antimony(V),bismuth(V),and tin(IV)complexes of lapachol.Bioinorg.Chem.Appl.2013,1-7.
Rovira,J.,Nadal,M.,Schuhmacher,M.,Domingo,J.L.,2017.Trace elements in skin-contact clothes and migration to artificial sweat:risk assessment of human dermal exposure.Text.Res.J.87,726-738.
Rzetala,M.A.,Sgem,2015.Arsenic and antimony in bottom sediments of anthropogenic water bodies in the Silesian Upland(Southern Poland).Science and Technologies in Geology,Exploration and Mining,Sgem 2015 vol.I pp.45-52.
Sakata,M.,Asakura,K.,2009.Factors contributing to seasonal variations in wet deposition fluxes of trace elements at sites along Japan Sea coast.Atmos.Environ.43,3867-3875.
Sakata,M.,Asakura,K.,2011.Atmospheric dry deposition of trace elements at a site on Asian-continent side of Japan.Atmos.Environ.45,1075-1083.
Salam,M.A.,Mohamed,R.M.,2013.Removal of antimony(III)by multi-walled carbon nanotubes from model solution and environmental samples.Chem.Eng.Res.Des.91,1352-1360.
Sanchez-Hernandez,J.C.,2006.Earthworm biomarkers in ecological risk assessment.In:Ware,G.W.(Ed.),Reviews of Environmental Contamination and Toxicology.Vol.188,pp.85-126.
Sánchez-Martínez,M.,Pérez-Corona,T.,Cámara,C.,Madrid,Y.,2013.Migration of antimony from PET containers into regulated EU food simulants.Food Chem.141,816-822.
Sanchez-Rodas,D.,Alsioufi,L.,Sanchez De La Campa,A.M.,Gonzalez-Castanedo,Y.,2017.Antimony speciation as geochemical tracer for anthropogenic emissions of atmospheric particulate matter.J.Hazard.Mater.324,213-220.
Sanderson,P.,Naidu,R.,Bolan,N.,2014.Ecotoxicity of chemically stabilised metal(loid)s in shooting range soils.Ecotoxicol.Environ.Saf.100,201-208.
Sanderson,P.,Naidu,R.,Bolan,N.,2015.Effectiveness of chemical amendments for stabilisation of lead and antimony in risk-based land management of soils of shooting ranges.Environ.Sci.Pollut.Res.22,8942-8956.
Sar?,A.,?ahino?lu,G.,Tüzen,M.,2012.Antimony(III)adsorption from aqueous solution using raw perlite and Mn-modified perlite:equilibrium,thermodynamic,and kinetic studies.Ind.Eng.Chem.Res.51,6877-6886.
Schreck,E.,Dappe,V.,Sarret,G.,Sobanska,S.,Nowak,D.,Nowak,J.,et al.,2014.Foliar or root exposures to smelter particles:consequences for lead compartmentalization and speciation in plant leaves.Sci.Total Environ.476,667-676.
Schreck,E.,Foucault,Y.,Sarret,G.,Sobanska,S.,Cecillon,L.,Castrecrouelle,M.,et al.,2012.Metal and metalloid foliar uptake by various plant species exposed to atmospheric industrial fallout:mechanisms involved for lead.Sci.Total Environ.427(/428),253-262.
Serafimovska,J.M.,Arpadjan,S.,Stafilov,T.,Tsekova,K.,2013.Study of the antimony species distribution in industrially contaminated soils.J.Soils Sediments 13,294-303.
Sh,T.,Liu,C.Q.,Feng,C.,2012.Solubility,toxicity and sorption of antimony from smelter release.J.Geochem.Explor.118,14-18.
Shan,C.,Ma,Z.,Tong,M.,2014.Efficient removal of trace antimony(III)through adsorption by hematite modified magnetic nanoparticles.J.Hazard.Mater.268,229-236.
Sharifi,R.,Moore,F.,Keshavarzi,B.,2016.Mobility and chemical fate of arsenic and antimony in water and sediments of Sarouq River catchment,Takab geothermal field,Northwest Iran.J.Environ.Manag.170,136-144.
Shotyk,W.,Chen,B.,Krachler,M.,2005.Lithogenic,oceanic and anthropogenic sources of atmospheric Sb to a maritime blanket bog,Myrarnar,Faroe Islands.J.Environ.Monit.7,1148-1154.
Shtangeeva,I.,Bali,R.,Harris,A.,2011.Bioavailability and toxicity of antimony.J.Geochem.Explor.110,40-45.
Shtangeeva,I.,Singh,B.,Bali,R.,Ayrault,S.,Timofeev,S.,2014.Antimony accumulation in wheat seedlings grown in soil and water.Commun.Soil Sci.Plant Anal.45,968-983.
Shtangeeva,I.,Steinnes,E.,Lierhagen,S.,2012.Uptake of different forms of antimony by wheat and rye seedlings.Environ.Sci.Pollut.Res.19,502-509.
Song,J.,Yan,L.,Duan,J.,Jing,C.,2017.TiO2 crystal facet-dependent antimony adsorption and photocatalytic oxidation.J.Colloid Interface Sci.496,522-530.
Stefaniak,S.,Kmiecik,E.,Miszczak,E.,Szczepańska-Plewa,J.,Twardowska,I.,2015.Effect of weathering transformations of coal combustion residuals on trace elements mobility in view of the environmental safety and sustainability of their disposal and use.II.Element release.J.Environ.Manag.156,167-180.
Sud,D.,Mahajan,G.,Kaur,M.,2008.Agricultural waste material as potential adsorbent for sequestering heavy metal ions from aqueous solutions-a review.Bioresour.Technol.99,6017-6027.
Sun,Y.Z.,Liu,G.L.,Cai,Y.,2016a.Thiolated arsenicals in arsenic metabolism:occurrence,formation,and biological implications.J.Environ.Sci.49,59-73.
Sun,F.,Wu,F.,Liao,H.,Xing,B.,2011.Biosorption of antimony(V)by freshwater cyanobacteria Microcystis biomass:chemical modification and biosorption mechanisms.Chem.Eng.J.171,1082-1090.
Sun,W.,Xiao,E.,Dong,Y.,Tang,S.,Krumins,V.,Ning,Z.,et al.,2016b.Profiling microbial community in a watershed heavily contaminated by an active antimony(Sb)mine in Southwest China.Sci.Total Environ.550,297-308.
Sun,W.,Xiao,E.,Xiao,T.,Krumins,V.,Wang,Q.,Haggblom,M.,et al.,2017.Response of soil microbial communities to elevated antimony and arsenic contamination indicates the relationship between the innate microbiota and contaminant fractions.Environ.Sci.Technol.51(16),9165-9195.
Taiwo,A.M.,Beddows,D.C.S.,Shi,Z.B.,Harrison,R.M.,2014.Mass and number size distributions of particulate matter components:comparison of an industrial site and an urban background site.Sci.Total Environ.475,29-38.
Tandy,S.,Meier,N.,Schulin,R.,2017.Use of soil amendments to immobilize antimony and lead in moderately contaminated shooting range soils.J.Hazard.Mater.324,617-625.
Targan,?.,Tirtom,V.N.,Akku?,B.,2013.Removal of antimony(III)from aqueous solution by using grey and red Erzurum clay and application to the Gediz River sample.ISRN Anal.Chem.2013,1-8.
Tella,M.,Pokrovski,G.S.,2009.Antimony(III)complexing with O-bearing organic ligands in aqueous solution:an X-ray absorption fine structure spectroscopy and solubility study.Geochim.Cosmochim.Acta 73,268-290.
Terry,L.R.,Kulp,T.R.,Wiatrowski,H.,Miller,L.G.,Oremland,R.S.,2015.Microbiological oxidation of antimony(III)with oxygen or nitrate by bacteria isolated from contaminated mine sediments.Appl.Environ.Microbiol.81,8478-8488.
Thanabalasingam,P.,Pickering,W.F.,1990.Specific sorption of antimony(III)by the hydrous oxides of Mn,Fe,and Al.Water Air Soil Pollut.49,175-185.
Tian,X.,Wu,Y.,Hou,P.,Liang,S.,Qu,S.,Xu,M.,Zuo,T.,2017.Environmental impact and economic assessment of secondary lead production:comparison of main spent lead-acid battery recycling processes in China.J.Clean.Prod.144,142-148.
Tian,H.,Zhao,D.,Cheng,K.,Lu,L.,He,M.,Hao,J.,2012.Anthropogenic atmospheric emissions of antimony and its spatial distribution characteristics in China.Environ.Sci.Technol.46,3973-3980.
Tian,H.Z.,Zhao,D.,He,M.C.,Wang,Y.,Cheng,K.,2011.Temporal and spatial distribution of atmospheric antimony emission inventories from coal combustion in China.Environ.Pollut.159,1613-1619.
Tian,H.,Zhou,J.,Zhu,C.,Zhao,D.,Gao,J.,Hao,J.,et al.,2014.Acomprehensive global inventory of atmospheric antimony emissions from anthropogenic activities,1995-2010.Environ.Sci.Technol.48,10235-10241.
Tighe,M.,Lockwood,P.V.,Ashley,P.M.,Murison,R.D.,Wilson,S.C.,2013.The availability and mobility of arsenic and antimony in an acid sulfate soil pasture system.Sci.Total Environ.463,151-160.
Tisarum,R.,Lessl,J.T.,Dong,X.L.,de Oliveira,L.M.,Rathinasabapathi,B.,Ma,L.Q.,2014.Antimony uptake,efflux and speciation in arsenic hyperaccumulator Pteris vittata.Environ.Pollut.186,110-114.
Tisarum,R.,Ren,J.H.,Dong,X.,Chen,H.,Lessl,J.T.,Ma,L.Q.,2015.A new method for antimony speciation in plant biomass and nutrient media using anion exchange cartridge.Talanta 144,1171-1175.
Tschan,M.,Robinson,B.,Johnson,C.A.,Burgi,A.,Schulin,R.,2010.Antimony uptake and toxicity in sunflower and maize growing in Sb-III and Sb-V contaminated soil.Plant Soil334,235-245.
Tschan,M.,Robinson,B.H.,Nodari,M.,Schulin,R.,2009a.Antimony uptake by different plant species from nutrient solution,agar and soil.Environ.Chem.6,144-152.
Tschan,M.,Robinson,B.H.,Schulin,R.,2009b.Antimony in the soil-plant system-a review.Environ.Chem.6,106.
Turner,A.,Filella,M.,2017.Field-portable-XRF reveals the ubiquity of antimony in plastic consumer products.Sci.Total Environ.584,982-989.
Tuzen,M.,Sari,A.,2010.Biosorption of selenium from aqueous solution by green algae(Cladophora hutchinsiae)biomass:equilibrium,thermodynamic and kinetic studies.Chem.Eng.J.158,200-206.
Uluozlu,O.D.,Sari,A.,Tuzen,M.,2010.Biosorption of antimony from aqueous solution by lichen(Physcia tribacia)biomass.Chem.Eng.J.163,382-388.
Ungureanu,G.,Filote,C.,Santos,S.C.R.,Boaventura,R.A.R.,Volf,I.,Botelho,C.M.S.,2016.Antimony oxyanions uptake by green marine macroalgae.J.Environ.Chem.Eng.4,3441-3450.
Ungureanu,G.,Santos,S.,Boaventura,R.,Botelho,C.,2015.Arsenic and antimony in water and wastewater:overview of removal techniques with special reference to latest advances in adsorption.J.Environ.Manag.151,326-342.
Ungureanu,G.,Santos,S.C.R.,Volf,I.,Boaventura,R.A.R.,Botelho,C.M.S.,2017.Biosorption of antimony oxyanions by brown seaweeds:batch and column studies.J.Environ.Chem.Eng.5,3463-3471.
Uppal,J.S.,Shuai,Q.,Li,Z.,Le,X.C.,2017.Arsenic biotransformation and an arsenite S-adenosylmethionine methyltransferase in plankton.J.Environ.Sci.61,118-121.
Van Khanh,N.,Lee,J.U.,2014.Isolation and characterization of antimony-reducing bacteria from sediments collected in the vicinity of an antimony factory.Geomicrobiol J.31,855-861.
Van Vleek,B.,Amarasiriwardena,D.,Xing,B.,2011.Investigation of distribution of soil antimony using sequential extraction and antimony complexed to soil-derived humic acids molar mass fractions extracted from various depths in a shooting range soil.Microchem.J.97,68-73.
Varrica,D.,Bardelli,F.,Dongarrà,G.,Tamburo,E.,2013.Speciation of Sb in airborne particulate matter,vehicle brake linings,and brake pad wear residues.Atmos.Environ.64,18-24.
Verbinnen,B.,Block,C.,Lievens,P.,Van Brecht,A.,Vandecasteele,C.,2013.Simultaneous removal of molybdenum,antimony and selenium oxyanions from wastewater by adsorption on supported magnetite.Waste Biomass Valoriz.4,635-645.
Wan,X.M.,Tandy,S.,Hockmann,K.,Schulin,R.,2013a.Changes in Sb speciation with waterlogging of shooting range soils and impacts on plant uptake.Environ.Pollut.172,53-60.
Wan,X.M.,Tandy,S.,Hockmann,K.,Schulin,R.,2013b.Effects of waterlogging on the solubility and redox state of Sb in a shooting range soil and its uptake by grasses:a tank experiment.Plant Soil 371,155-166.
Wang,Y.,Chai,L.,Yang,Z.,Mubarak,H.,Xiao,R.,Tang,C.,2017.Subcellular distribution and chemical forms of antimony in Ficus tikoua.Int.J.Phytoremediation 19,97-103.
Wang,H.,Chen,F.,Mu,S.,Zhang,D.,Pan,X.,Lee,D.J.,Chang,J.S.,2013.Removal of antimony(Sb(V))from Sb mine drainage:biological sulfate reduction and sulfide oxidation-precipitation.Bioresour.Technol.146,799-802.
Wang,X.,He,M.,Lin,C.,Gao,Y.,Zheng,L.,2012a.Antimony(III)oxidation and antimony(V)adsorption reactions on synthetic manganite.Chem.Erde-Geochem.72,41-47.
Wang,Q.,He,M.,Wang,Y.,2011b.Influence of combined pollution of antimony and arsenic on culturable soil microbial populations and enzyme activities.Ecotoxicology20,9-19.
Wang,X.,He,M.,Xi,J.,Lu,X.,2011a.Antimony distribution and mobility in rivers around the world's largest antimony mine of Xikuangshan,Hunan Province,China.Microchem.J.97,4-11.
Wang,X.,He,M.,Xi,J.,Lu,X.,Xie,J.,2010a.Antimony,arsenic and other toxic elements in the topsoil of an antimony mine area.In:Xu,Jianming,Huang,Pan Ming(Eds.),Molecular Environmental Soil Science at the Interfaces in the Earth's Critical Zone.Zhejiang University Press,Hangzhou and Springer-Verlag Berlin Heidelberg2010.
Wang,X.,He,M.,Xie,J.,Xi,J.,Lu,X.,2010b.Heavy metal pollution of the world largest antimony mine-affected agricultural soils in Hunan province(China).J.Soils Sediments 10,827-837.
Wang,Q.Q.,Ma,Y.L.,Tan,J.H.,Zheng,N.J.,Duan,J.C.,Sun,Y.L.,et al.,2015.Characteristics of size-fractionated atmospheric metals and water-soluble metals in two typical episodes in Beijing.Atmos.Environ.119,294-303.
Wang,X.,Yu,T.,Li,C.,et al.,2012b.The adsorption of Sb(III)in aqueous by KMnO4-modified activated carbon.J.Zhejiang Univ.(Eng.Sci.)46,2028-2034.
Wang,D.,Zhu,F.Q.,Wang,Q.,Rensing,C.,Yu,P.,Gong,J.,et al.,2016.Disrupting ROS-protection mechanism allows hydrogen peroxide to accumulate and oxidize Sb(III)to Sb(V)in Pseudomonas stutzeri TS44.BMC Microbiol.16,1-11.
Wang,N.,Zhang,S.,He,M.,2018.Bacterial community profile of contaminated soils in a typical antimony mining site.Environ.Sci.Pollut.Res.25,141-152.
Warnken,J.,Ohlsson,R.,Welsh,D.T.,Teasdale,P.R.,Chelsky,A.,Bennett,W.W.,2017.Antimony and arsenic exhibit contrasting spatial distributions in the sediment and vegetation of a contaminated wetland.Chemosphere 180,388-395.
Wei,Y.,Chen,Z.P.,Wu,F.C.,Hou,H.,Li,J.N.,Shangguan,Y.X.,et al.,2015b.Molecular diversity of arbuscular mycorrhizal fungi at a large-scale antimony mining area in southern China.J.Environ.Sci.29,18-26.
Wei,C.,Ge,Z.,Chu,W.,Feng,R.,2015a.Speciation of antimony and arsenic in the soils and plants in an old antimony mine.Environ.Exp.Bot.109,31-39.
Wei,Y.,Su,Q.,Sun,Z.,Shen,Y.,Li,J.,Zhu,X.,et al.,2016.The role of arbuscular mycorrhizal fungi in plant uptake,fractions,and speciation of antimony.Appl.Soil Ecol.107,244-250.
Wen,B.,Zhou,J.W.,Zhou,A.G.,Liu,C.F.,Li,L.G.,2018.A review of antimony(Sb)isotopes analytical methods and application in environmental systems.Int.Biodeterior.Biodegrad.128,109-116.
Willis,S.S.,Haque,S.E.,Johannesson,K.H.,2011.Arsenic and antimony in groundwater flow systems:a comparative study.Aquat.Geochem.17,775-807.
Wilson,S.C.,Lockwood,P.V.,Ashley,P.M.,Tighe,M.,2010.The chemistry and behaviour of antimony in the soil environment with comparisons to arsenic:a critical review.Environ.Pollut.158,1169-1181.
Wu,C.C.,Chen,Y.C.,2017.Assessment of industrial antimony exposure and immunologic function for workers in Taiwan.Int.J.Environ.Res.Public Health 14(7),689.
Wu,Q.H.,Feng,R.W.,Guo,J.K.,Wang,R.G.,Xu,Y.M.,Fan,Z.L.,et al.,2017b.Interactions between selenite and different forms of antimony and their effects on root morphology of paddy rice.Plant Soil 413,231-242.
Wu,Z.,He,M.,Guo,X.,Zhou,R.,2010.Removal of antimony(III)and antimony(V)from drinking water by ferric chloride coagulation:competing ion effect and the mechanism analysis.Sep.Purif.Technol.76,184-190.
Wu,D.,Purnomo,B.J.,Sun,S.,2017a.As and Sb speciation in relation with physico-chemical characteristics of hydrothermal waters in Java and Bali.J.Geochem.Explor.173,85-91.
Wu,X.D.,Song,J.M.,Li,X.G.,Yuan,H.M.,Li,N.,2011.Behaviors of dissolved antimony in the Yangtze River estuary and its adjacent waters.J.Environ.Monit.13,2292-2303.
Wu,F.,Sun,F.,Wu,S.,Yan,Y.,Xing,B.,2012.Removal of antimony(III)from aqueous solution by freshwater cyanobacteria Microcystis biomass.Chem.Eng.J.183,172-179.
Xi,J.,He,M.,2013.Removal of Sb(III)and Sb(V)from aqueous media by goethite.Water Qual.Res.J.Can.48,223-231.
Xi,J.,He,M.,Lin,C.,2011.Adsorption of antimony(III)and antimony(V)on bentonite:kinetics,thermodynamics and anion competition.Microchem.J.97,85-91.
Xi,J.,He,M.,Wang,K.,Zhang,G.,2013.Adsorption of antimony(III)on goethite in the presence of competitive anions.J.Geochem.Explor.132,201-208.
Xiao,E.Z.,Krumins,V.,Tang,S.,Xiao,T.F.,Ning,Z.P.,Lan,X.L.,et al.,2016.Correlating microbial community profiles with geochemical conditions in a watershed heavily contaminated by an antimony tailing pond.Environ.Pollut.215,141-153.
Xu,Y.H.,Ohki,A.,Maeda,S.,2001.Adsorption and removal of antimony from aqueous solution by an activated alumina.Toxicol.Environ.Chem.80,133-144.
Xu,W.,Wang,H.,Liu,R.,Zhao,X.,Qu,J.,2011a.The mechanism of antimony(III)removal and its reactions on the surfaces of Fe-Mn binary oxide.J.Colloid Interface Sci.363,320-326.
Xu,L.,Wu,F.,Zheng,J.,Xie,Q.,Li,H.,Liao,H.,et al.,2011b.Sediment records of Sb and Pb stable isotopic ratios in Lake Qinghai.Microchem.J.97,25-29.
Xue,L.,Ren,H.D.,Li,S.,Gao,M.,Shi,S.Q.,Chang,E.M.,et al.,2015.Comparative proteomic analysis in Miscanthus sinensis exposed to antimony stress.Environ.Pollut.201,150-160.
Yan,L.,Hu,S.,Jing,C.Y.,2016.Recent progress of arsenic adsorption on TiO2in the presence of coexisting ions:a review.J.Environ.Sci.49,74-85.
Yan,L.,Song,J.Y.,Chan,T.S.,Jing,C.Y.,2017.Insights into antimony adsorption on{001}TiO2:XAFS and DFT study.Environ.Sci.Technol.51,6335-6341.
Yang,H.,He,M.,2015.Speciation of antimony in soils and sediments by liquid chromatography-hydride generationatomic fluorescence spectrometry.Anal.Lett.48,1941-1953.
Yang,H.,Lu,X.,He,M.,2018.Effect of organic matter on mobilization of antimony from nanocrystalline titanium dioxide.Environ.Technol.39(12),1515-1521.
Y?lmaz,H.,2015.Characterization and comparison of leaching behaviors of fly ash samples from three different power plants in Turkey.Fuel Process.Technol.137,240-249.
Yuan,Y.,Xiang,M.,Liu,C.,Theng,B.K.G.,2017.Geochemical characteristics of heavy metal contamination induced by a sudden wastewater discharge from a smelter.J.Geochem.Explor.176,33-41.
Zhang,L.,Lin,Q.,Guo,X.J.,Verpoort,F.,2011.Sorption behavior of florisil for the removal of antimony ions from aqueous solutions.Water Sci.Technol.63,2114-2122.
Zhang,S.,Jiang,X.,Liu,B.,Lv,G.,Jin,Y.,Yan,J.,2017a.Co-combustion of bituminous coal and pickling sludge in a drop tube furnace:thermodynamic study and experimental data on the distribution of Cr,Ni,Mn,As,Cu,Sb,Pb,Cd,Zn,and Sn.Energy Fuel 31,3019-3028.
Zhang,G.,Ouyang,X.,Li,H.,Fu,Z.,Chen,J.,2016.Bioremoval of antimony from contaminated waters by a mixed batch culture of sulfate-reducing bacteria.Int.Biodeterior.Biodegrad.115,148-155.
Zhang,L.,Yang,Q.,Wang,S.,Li,W.,Jiang,S.,Liu,Y.,2017b.Influence of silicon treatment on antimony uptake and translocation in rice genotypes with different radial oxygen loss.Ecotoxicol.Environ.Saf.144,572-577.
Zhou,J.,Nyirenda,M.T.,Xie,L.,Li,Y.,Zhou,B.,Zhu,Y.,et al.,2017.Mine waste acidic potential and distribution of antimony and arsenic in waters of the Xikuangshan mine,China.Appl.Geochem.77,52-61.
Zhou,J.R.,Tian,H.Z.,Zhu,C.Y.,Hao,J.M.,Gao,J.J.,Wang,Y.,et al.,2015.Future trends of global atmospheric antimony emissions from anthropogenic activities until 2050.Atmos.Environ.120,385-392.
Zhu,J.,Wu,F.C.,Pan,X.L.,Guo,J.Y.,Wen,D.S.,2011.Removal of antimony from antimony mine flotation wastewater by electrocoagulation with aluminum electrodes.J.Environ.Sci.23,1066-1071.
Alderton,D.,Serafimovski,T.,Burns,L.,Tasev,G.,2014.Distribution and mobility of arsenic and antimony at mine sites in fry Macedonia.Carpath.J.Earth Environ.9,43-56.
Alphazan,T.,Florian,P.,Thieuleux,C.,2017.Ethoxy and silsesquioxane derivatives of antimony as dopant precursors:unravelling the structure and thermal stability of surface species on SiO2.Phys.Chem.Chem.Phys.19,8595-8601.
Alvarez-Ayuso,E.,Otones,V.,Murciego,A.,Garcia-Sanchez,A.,Santa,R.I.,2012.Antimony,arsenic and lead distribution in soils and plants of an agricultural area impacted by former mining activities.Sci.Total Environ.439,35-43.
Amarasiriwardena,D.,Wu,F.,2011.Antimony:emerging toxic contaminant in the environment.Microchem.J.97,1-3.
An,Y.J.,Kim,M.,2009.Effect of antimony on the microbial growth and the activities of soil enzymes.Chemosphere 74,654-659.
An,Y.J.,Yang,C.Y.,2009.Fridericia peregrinabunda(Enchytraeidae)as a new test species for soil toxicity assessment.Chemosphere77,325-329.
Anawar,H.M.,Freitas,M.C.,Canha,N.,Santa-Regina,I.,2011.Arsenic,antimony,and other trace element contamination in a mine tailings affected area and uptake by tolerant plant species.Environ.Geochem.Health 33,353-362.
Anayurt,R.A.,Sari,A.,Tuzen,M.,2009.Equilibrium,thermodynamic and kinetic studies on biosorption of Pb(II)and Cd(II)from aqueous solution by macrofungus(Lactarius scrobiculatus)biomass.Chem.Eng.J.151,255-261.
Anderson,C.G.,2012.The metallurgy of antimony.Chem.Erde-Geochem.72,3-8.
Andreae,M.O.,Asmode,J.F.,Foster,P.,Vantdack,L.,1981.Determination of anitmony(III),antimony(V),and methylantimony species in natural-waters by atomic-absorption spectrometry with hydride generation.Anal.Chem.53,1766-1771.
Andreae,M.O.,Froelich,P.N.,1984.Arsenic,antimony,and germanium biogeochemistry in the Baltic Sea.Tellus B 36,101-117.
Andrewes,P.,Cullen,W.R.,Polishchuk,E.,2000.Antimony biomethylation by Scopulariopsis brevicaulis:characterization of intermediates and the methyl donor.Chemosphere 41,1717-1725.
Andrewes,P.,Cullen,W.R.,Polishchuk,E.,Reimer,K.J.,2001.Antimony biomethylation by the wood rotting fungus Phaeolus schweinitzii.Appl.Organomet.Chem.15,473-480.
Anjum,A.,Datta,M.,2012.Adsorptive removal of antimony(III)using modified montmorillonite:a study on sorption kinetics.J.Anal.Sci.Meth.Instrum.02,167-175.
Armiento,G.,Nardi,E.,Lucci,F.,De Cassan,M.,Della,V.G.,Santini,C.,et al.,2017.Antimony and arsenic distribution in a catchment affected by past mining activities:influence of extreme weather events.Rend.Lincei-Sci.Fis.28,303-315.
Asaoka,S.,Takahashi,Y.,Araki,Y.,Tanimizu,M.,2012.Comparison of antimony and arsenic behavior in an Ichinokawa River water-sediment system.Chem.Geol.334,1-8.
Baceva,K.,Stafilov,T.,Matevski,V.,2015.Distribution and mobility of toxic metals in Thymus alsarensis Ronniger in the Allchar As-Sb-T1 mine,Republic of Macedonia.Plant Biosyst.149,884-893.
Baek,Y.W.,An,Y.J.,2011.Microbial toxicity of metal oxide nanoparticles(CuO,NiO,ZnO,and Sb2O3)to Escherichia coli,Bacillus subtilis,and Streptococcus aureus.Sci.Total Environ.409,1603-1608.
Baek,Y.W.,Lee,W.M.,Jeong,S.W.,An,Y.J.,2014.Ecological effects of soil antimony on the crop plant growth and earthworm activity.Environ.Earth Sci.71,895-900.
Baeza,M.,Ren,J.,Krishnamurthy,S.,Vaughan,T.C.,2010.Spatial distribution of antimony and arsenic levels in Manadas creek,an urban tributary of the Rio Grande in Laredo,Texas.Arch.Environ.Contam.Toxicol.58,299-314.
Bagherifam,S.,Lakzian,A.,Fotovat,A.,Khorasani,R.,Komarneni,S.,2014.In situ stabilization of As and Sb with naturally occurring Mn,Al and Fe oxides in a calcareous soil:bioaccessibility,bioavailability and speciation studies.J.Hazard.Mater.273,247.
Bai,Y.,Jefferson,W.A.,Liang,J.,Yang,T.,Qu,J.,2017.Antimony oxidation and adsorption by in-situ formed biogenic Mn oxide and Fe-Mn oxides.J.Environ.Sci.54,126-134.
Basu,A.,Saha,D.,Saha,R.,Ghosh,T.,Saha,B.,2014.A review on sources,toxicity and remediation technologies for removing arsenic from drinking water.Res.Chem.Intermed.40,447-485.
Beaudon,E.,Gabrielli,P.,Sierra-Hernandez,M.R.,Wegner,A.,Thompson,L.G.,2017.Central Tibetan Plateau atmospheric trace metals contamination:a 500-year record from the Puruogangri ice core.Sci.Total Environ.601,1349-1363.
Belzile,N.,Chen,Y.W.,Filella,M.,2011.Human exposure to antimony:I.Sources and intake.Crit.Rev.Environ.Sci.Technol.41,1309-1373.
Belzile,N.,Chen,Y.W.,Wang,Z.J.,2001.Oxidation of antimony(III)by amorphous iron and manganese oxyhydroxides.Chem.Geol.174,379-387.
Biver,M.,Shotyk,W.,2012.Experimental study of the kinetics of ligand-promoted dissolution of stibnite(Sb2S3).Chem.Geol.294,165-172.
Boamponsem,L.K.,Adam,J.I.,Dampare,S.B.,Nyarko,B.J.B.,Essumang,D.K.,2010.Assessment of atmospheric heavy metal deposition in the Tarkwa gold mining area of Ghana using epiphytic lichens.Nucl.Instrum.Methods Phys.Res.Sect.BBeam Interact.Mater.Atoms 268,1492-1501.
Borcinov,R.A.,Jamieson,H.,Lalinsk-Volekov,B.,Majzlan,J.,Stevko,M.,Chovan,M.,2017.Mineralogical controls on antimony and arsenic mobility during tetrahedrite-tennantite weathering at historic mine sites Spania Dolina-Piesky and Lubietova-Svatodusna,Slovakia.Am.Mineral.102,1091-1100.
Briki,M.,Zhu,Y.,Gao,Y.,Shao,M.,Ding,H.,Ji,H.,2017.Distribution and health risk assessment to heavy metals near smelting and mining areas of Hezhang,China.Environ.Monit.Assess.189,458.
Bullough,F.,Weiss,D.J.,Dubbin,W.E.,Coles,B.J.,Barrott,J.,Sengupta,A.K.,2010.Evidence of competitive adsorption of Sb(III)and As(III)on activated alumina.Ind.Eng.Chem.Res.49,2521-2524.
Buschmann,J.,Canonica,S.,Sigg,L.,2005.Photoinduced oxidation of antimony(III)in the presence of humic acid.Environ.Sci.Technol.39,5335-5341.
Cai,Y.,Mi,Y.,Zhang,H.,2016b.Kinetic modeling of antimony(III)oxidation and sorption in soils.J.Hazard.Mater.316,102-109.
Cai,F.,Ren,J.,Tao,S.,Wang,X.,2016a.Uptake,translocation and transformation of antimony in rice(Oryza sativa L.)seedlings.Environ.Pollut.209,169-176.
Canepari,S.,Marconi,E.,Astolfi,M.L.,Perrino,C.,2010.Relevance of Sb(III),Sb(V),and Sb-containing nano-particles in urban atmospheric particulate matter.Anal.Bioanal.Chem.397,2533-2542.
Carneado,S.,Hernández-Nataren,E.,López-Sánchez,J.F.,Sahuquillo,A.,2015.Migration of antimony from polyethylene terephthalate used in mineral water bottles.Food Chem.166,544-550.
Carneado,S.,Lopez-Sanchez,J.F.,Sahuquillo,A.,Klontzas,E.,Froudakis,G.E.,Pergantis,S.A.,2017.Antimony speciation in spirits stored in PET bottles:identification of a novel antimony complex.J.Anal.Atom.Spectrom.32,1109-1118.
Carvalho,P.C.S.,Neiva,A.M.R.,Silva,M.M.V.G.,2010.Geochemistry of waters close to abandoned As-Au and Sb-Au mines from Valongo,northern Portugal.Geochim.Cosmochim.Acta 74,A146.
Chapa-Martínez,C.A.,Hinojosa-Reyes,L.,Hernández-Ramírez,A.,Ruiz-Ruiz,E.,Maya-Trevi?o,L.,Guzmán-Mar,J.L.,2016.An evaluation of the migration of antimony from polyethylene terephthalate(PET)plastic used for bottled drinking water.Sci.Total Environ.565,511-518.
Chen,J.,Liu,G.,Kang,Y.,Wu,B.,Sun,R.,Zhou,C.,et al.,2013.Atmospheric emissions of F,As,Se,Hg,and Sb from coal-fired power and heat generation in China.Chemosphere 90,1925-1932.
Chen,Z.,Wei,Y.,Zhao,D.,Shangguan,Y.,Hou,H.,Zeng,Q.,2015.Effect of arbuscular mycorrhizal fungi on antimony uptake and antioxidative responses of Medicago sativa in antimony polluted soil.J.Agro-Environ.Sci.34,1053-1059.
Cidu,R.,Biddau,R.,Dore,E.,Vacca,A.,Marini,L.,2014.Antimony in the soil-water-plant system at the Su Suergiu abandoned mine(Sardinia,Italy):strategies to mitigate contamination.Sci.Total Environ.497,319-331.
Coelho,D.R.,Miranda,E.S.,Saint'Pierre,T.D.,Roma,P.F.J.,2014.Tissue distribution of residual antimony in rats treated with multiple doses of meglumine antimoniate.Mem.Inst.Oswaldo Cruz 109,420-427.
Cohen,S.M.,Chowdhury,A.,Arnold,L.L.,2016.Inorganic arsenic:a non-genotoxic carcinogen.J.Environ.Sci.49,28-37.
Corrales,I.,Barcelo,J.,Bech,J.,Poschenrieder,C.,2014.Antimony accumulation and toxicity tolerance mechanisms in Trifolium species.J.Geochem.Explor.147,167-172.
Courtin-Nomade,A.,Rakotoarisoa,O.,Bril,H.,Grybos,M.,Forestier,L.,Foucher,F.,et al.,2012.Weathering of Sb-rich mining and smelting residues:insight in solid speciation and soil bacteria toxicity.Chem.Erde-Geochem.72,29-39.
Craig,P.J.,Jenkins,R.O.,Dewick,R.,Miller,D.P.,1999.Trimethylantimony generation by Scopulariopsis brevicaulis during aerobic growth.Sci.Total Environ.229,83-88.
Cullen,W.R.,Liu,Q.,Lu,X.,McKnight-Whitford,A.,Peng,H.,Popowich,A.,et al.,2016.Methylated and thiolated arsenic species for environmental and health research-a review on synthesis and characterization.J.Environ.Sci.49,7-27.
Cutter,G.A.,Cutter,L.S.,Featherstone,A.M.,Lohrenz,S.E.,2001.Antimony and arsenic biogeochemistry in the western Atlantic Ocean.Deep-Sea Res.II Top.Stud.Oceanogr.48,2895-2915.
Czégény,Z.,Jakab,E.,Blazsó,M.,Bhaskar,T.,Sakata,Y.,2012.Thermal decomposition of polymer mixtures of PVC,PET and ABS containing brominated flame retardant:formation of chlorinated and brominated organic compounds.J.Anal.Appl.Pyrolysis 96,69-77.
Dai,C.,Zhou,Z.,Zhou,X.,Zhang,Y.,2014.Removal of Sb(III)and Sb(V)from aqueous solutions using nZVI.Water Air Soil Pollut.225,1-12.
Das,S.K.,Das,A.R.,Guha,A.K.,2007.A study on the adsorption mechanism of mercury on Aspergillus versicolor biomass.Environ.Sci.Technol.41,8281-8287.
Das,R.,Khezri,B.,Srivastava,B.,Datta,S.,Sikdar,P.K.,Webster,R.D.,et al.,2015.Trace element composition of PM2.5and PM10from Kolkata-a heavily polluted Indian metropolis.Atoms.Pollut.Res.6,742-750.
Day,B.M.,Coles,M.P.,Hitchcock,P.B.,2012.Neutral and anionic antimony(III)species supported by a bicyclic guanidinate.Eur.J.Inorg.Chem.2012(5),841-846.
De Gregori,I.,Quiroz,W.,Pinochet,H.,Pannier,F.,Potin-Gautier,M.,2007.Speciation analysis of antimony in marine biota by HPLC-(UV)-HG-AFS:extraction procedures and stability of antimony species.Talanta 73,458-465.
Ding,Y.Z.,Wang,R.G.,Guo,J.K.,Wu,F.C.,Xu,Y.M.,Feng,R.W.,2015a.The effect of selenium on the subcellular distribution of antimony to regulate the toxicity of antimony in paddy rice.Environ.Sci.Pollut.Res.22,5111-5123.
Ding,W.,Wang,Y.J.,Yu,Y.T.,Zhang,X.Z.,Li,J.J.,Wu,F.,2015b.Photooxidation of arsenic(III)to arsenic(V)on the surface of kaolinite clay.J.Environ.Sci.36,29-37.
Do Hur,S.,Soyol-Erdene,T.O.,Hwang,H.J.,Han,C.,Gabrielli,P.,Barbante,C.,et al.,2013.Climate-related variations in atmospheric Sb and Tl in the EPICA Dome C ice(East Antarctica)during the past 800,000 years.Glob.Biogeochem.Cycles 27,930-940.
Dordevic,D.,Stortini,A.M.,Relic,D.,Mihajlidi-Zelic,A.,Huremovic,J.,Barbante,C.,et al.,2014.Trace elements in size-segregated urban aerosol in relation to the anthropogenic emission sources and the resuspension.Environ.Sci.Pollut.Res.21,10949-10959.
Dousova,B.,Buzek,F.,Herzogova,L.,Machovic,V.,Lhotka,M.,2015.Effect of organic matter on arsenic(V)and antimony(V)adsorption in soils.Eur.J.Soil Sci.66,74-82.
Duan,L.Q.,Song,J.M.,Li,X.G.,Yuan,H.M.,2010.The behaviors and sources of dissolved arsenic and antimony in Bohai Bay.Cont.Shelf Res.30,1522-1534.
Duan,L.Q.,Song,J.M.,Yuan,H.M.,Li,X.G.,Li,N.,Ma,J.K.,2014.Distribution,chemical speciation and source of trace elements in surface sediments of the Changjiang Estuary.Environ.Earth Sci.72,3193-3204.
Duester,L.,Diaz-Bone,R.A.,Kosters,J.,Hirner,A.V.,2005.Methylated arsenic,antimony and tin species in soils.J.Environ.Monit.7,1186-1193.
Duester,L.,van der Geest,H.G.,Moelleken,S.,Hirner,A.V.,Kueppers,K.,2011.Comparative phytotoxicity of methylated and inorganic arsenic-and antimony species to Lemna minor,Wolffia arrhiza and Selenastrum capricornutum.Microchem.J.97,30-37.
Dupont,D.,Arnout,S.,Jones,P.T.,Binnemans,K.,2016.Antimony recovery from end-of-life products and industrial process residues:a critical review.J.Sustain.Metall.2,79-103.
El Shanawany,S.,Foda,N.,Hashad,D.I.,Salama,N.,Sobh,Z.,2017.The potential DNA toxic changes among workers exposed to antimony trioxide.Environ.Sci.Pollut.Res.24,12455-12461.
Ettler,V.,Tejnecky,V.,Mihaljevic,M.,Sebek,O.,Zuna,M.,Vanek,A.,2010.Antimony mobility in lead smelter-polluted soils.Geoderma 155,409-418.
Evangelou,M.W.H.,Hockmann,K.,Pokharel,R.,Jakob,A.,Schulin,R.,2012.Accumulation of Sb,Pb,Cu,Zn and Cd by various plants species on two different relocated military shooting range soils.J.Environ.Manag.108,102-107.
Fae Gomes,G.M.,Mendes,T.F.,Wada,K.,2011.Reduction in toxicity and generation of slag in secondary lead process.J.Clean.Prod.19,1096-1103.
Fan,J.,Wang,Y.,2016.Atmospheric emissions of As,Sb,and Se from coal combustion in Shandong province,2005-2014.Pol.J.Environ.Stud.25,2339-2347.
Fan,J.X.,Wang,Y.J.,Fan,T.T.,Cui,X.D.,Zhou,D.M.,2014.Photo-induced oxidation of Sb(III)on goethite.Chemosphere 95,295.
Fan,J.X.,Wang,Y.J.,Fan,T.T.,Dang,F.,Zhou,D.M.,2016.Effect of aqueous Fe(II)on Sb(V)sorption on soil and goethite.Chemosphere 147,44-51.
Fawcett,S.E.,Jamieson,H.E.,2011.The distinction between ore processing and post-depositional transformation on the speciation of arsenic and antimony in mine waste and sediment.Chem.Geol.283,109-118.
Fawcett,S.E.,Jamieson,H.E.,Nordstrom,D.K.,Mccleskey,R.B.,2015.Arsenic and antimony geochemistry of mine wastes,associated waters and sediments at the Giant Mine,Yellowknife,Northwest Territories,Canada.Appl.Geochem.62,3-17.
Feng,R.,Liao,G.,Guo,J.,Wang,R.,Xu,Y.,Ding,Y.,et al.,2016.Responses of root growth and antioxidative systems of paddy rice exposed to antimony and selenium.Environ.Exp.Bot.122,29-38.
Feng,R.,Wei,C.,Tu,S.,Ding,Y.,Wang,R.,Guo,J.,2013.The uptake and detoxification of antimony by plants:a review.Environ.Exp.Bot.96,28-34.
Filella,M.,2010.Alkyl derivatives of antimony in the environment.Met.Ions Life Sci.7,267-301.
Filella,M.,Belzile,N.,Chen,Y.W.,2002a.Antimony in the environment:a review focused on natural waters I.Occurrence.Earth-Sci.Rev.57,125-176.
Filella,M.,Belzile,N.,Chen,Y.W.,2002b.Antimony in the environment:a review focused on natural waters II.Relevant solution chemistry.Earth-Sci.Rev.59,265-285.
Filella,M.,Belzile,N.,Chen,Y.W.,2012.Human exposure to antimony.II.Contents in some human tissues often used in biomonitoring(hair,nails,teeth).Crit.Rev.Environ.Sci.Technol.42,1058-1115.
Filella,M.,Belzile,N.,Chen,Y.W.,2013a.Human exposure to antimony.III.Contents in some human excreted biofluids(urine,milk,saliva).Crit.Rev.Environ.Sci.Technol.43,162-214.
Filella,M.,Belzile,N.,Chen,Y.W.,2013b.Human exposure to antimony.IV.Contents in human blood.Crit.Rev.Environ.Sci.Technol.43,2071-2105.
Filella,M.,Belzile,N.,Lett,M.C.,2007.Antimony in the environment:a review focused on natural waters.III.Microbiota relevant interactions.Earth-Sci.Rev.80,195-217.
Flakova,R.,Zenisova,Z.,Sracek,O.,Krcmar,D.,Ondrejkova,I.,Chovan,M.,et al.,2012.The behavior of arsenic and antimony at Pezinok mining site,southwestern part of the Slovak Republic.Environ.Earth Sci.66,1043-1057.
Fort,M.,Grimalt,J.O.,Querol,X.,Casas,M.,Sunyer,J.,2016.Evaluation of atmospheric inputs as possible sources of antimony in pregnant women from urban areas.Sci.Total Environ.544,391-399.
Foucault,Y.,Leveque,T.,Xiong,T.,Schreck,E.,Austruy,A.,Shahid,M.,et al.,2013.Green manure plants for remediation of soils polluted by metals and metalloids:ecotoxicity and human bioavailability assessment.Chemosphere 93,1430-1435.
Fu,Z.,Wu,F.,Amarasiriwardena,D.,Mo,C.,Liu,B.,Zhu,J.,et al.,2010.Antimony,arsenic and mercury in the aquatic environment and fish in a large antimony mining area in Hunan,China.Sci.Total Environ.408,3403-3410.
Fu,Z.,Wu,F.,Mo,C.,Liu,B.,Zhu,J.,Deng,Q.,et al.,2011.Bioaccumulation of antimony,arsenic,and mercury in the vicinities of a large antimony mine,China.Microchem.J.97,12-19.
Fu,L.,Shozugawa,K.,Matsuo,M.,2018.Oxidation of antimony(III)in soil by manganese(IV)oxide using X-ray absorption fine structure.J.Environ.Sci.https://doi.org/10.1016/j.jes.2018.01.003.
Gadd,G.M.,2009.Biosorption:critical review of scientific rationale,environmental importance and significance for pollution treatment.J.Chem.Technol.Biotechnol.84,13-28.
Gaga,E.O.,Dogeroglu,T.,Ozden,O.,Ari,A.,Yay,O.D.,Altug,H.,et al.,2012.Evaluation of air quality by passive and active sampling in an urban city in Turkey:current status and spatial analysis of air pollution exposure.Environ.Sci.Pollut.Res.19,3579-3596.
Gandois,L.,Tipping,E.,Dumat,C.,Probst,A.,2010.Canopy influence on trace metal atmospheric inputs on forest ecosystems:speciation in throughfall.Atmos.Environ.44,824-833.
Gao,B.,Lu,J.,Zhou,H.D.,Yin,S.H.,Hao,H.,2012.The distribution,accumulation and potential source of seldom monitored trace elements in sediments of Beijiang River,South China.Water Sci.Technol.65,2118-2124.
Gebel,T.,1997.Arsenic and antimony:comparative approach on mechanistic toxicology.Chem.Biol.Interact.107,131-144.
Gil-Diaz,T.,Schafer,J.,Pougnet,F.,Abdou,M.,Dutruch,L.,Eyrolle-Boyer,F.,et al.,2016.Distribution and geochemical behaviour of antimony in the Gironde estuary:a first qualitative approach to regional nuclear accident scenarios.Mar.Chem.185,65-73.
Goyenechepatino,D.A.,Valderrama,L.,Walker,J.,Saravia,N.G.,2008.Antimony resistance and trypanothione in experimentally selected and clinical strains of Leishmania panamensis.Antimicrob.Agents Chemother.52,4503-4506.
Guillamot,F.,Calvert,V.,Millot,M.V.,Criquet,S.,2014.Does antimony affect microbial respiration in Mediterranean soils?A microcosm experiment.Pedobiologia 57,119-121.
Guo,X.,Wang,K.,He,M.,Liu,Z.,Yang,H.,Li,S.,2014.Antimony smelting process generating solid wastes and dust:characterization and leaching behaviors.J.Environ.Sci.26,1549-1556.
Guo,X.,Wu,Z.,He,M.,2009.Removal of antimony(V)and antimony(III)from drinking water by coagulation-flocculation-sedimentation(CFS).Water Res.43,4327-4335.
Guo,Y.Q.,Xue,X.M.,Yan,Y.,Zhu,Y.G.,Yang,G.D.,Ye,J.,2016.Arsenic methylation by an arsenite S-adenosylmethionine methyltransferase from Spirulina platensis.J.Environ.Sci.49,162-168.
Hamamura,N.,Fukushima,K.,Itai,T.,2013.Identification of antimony-and arsenic-oxidizing bacteria associated with antimony mine tailing.Microbes Environ.28,257-263.
Han,Y.,Zhang,F.,Wang,Q.,Zheng,S.,Guo,W.,Feng,L.,et al.,2016.Flavihumibacter stibioxidans sp nov.,an antimony-oxidizing bacterium isolated from antimony mine soil.Int.J.Syst.Evol.Microbiol.66,4676-4680.
Hartmann,L.M.,Craig,P.J.,Jenkins,R.O.,2003.Influence of arsenic on antimony methylation by the aerobic yeast Cryptococcus humicolus.Arch.Microbiol.180,347-352.
He,M.,Wan,H.,2004.Distribution,speciation,toxicity and bioavailability of antimony in the environment.Prog.Chem.16,131-135.
He,M.,Wang,X.,Wu,F.,Fu,Z.,2012.Antimony pollution in China.Sci.Total Environ.421,41-50.
He,M.,Xie,N.,Yu,W.,Yang,R.,1992.Antimony in the environment.Environ.Prot.2,44.
He,M.,Yang,J.,1999.Effects of different forms of antimony on rice during the period of germination and growth and antimony concentration in rice tissue.Sci.Total Environ.243,149-155.
Herath,I.,Vithanage,M.,Bundschuh,J.,2017.Antimony as a global dilemma:geochemistry,mobility,fate and transport.Environ.Pollut.223,545-559.
Hiller,E.,Lalinska,B.,Chovan,M.,Jurkovic,L.,Klimko,T.,Jankular,M.,et al.,2012.Arsenic and antimony contamination of waters,stream sediments and soils in the vicinity of abandoned antimony mines in the Western Carpathians,Slovakia.Appl.Geochem.27,598-614.
Hockmann,K.,Lenz,M.,Tandy,S.,Nachtegaal,M.,Janousch,M.,Schulin,R.,2014.Release of antimony from contaminated soil induced by redox changes.J.Hazard.Mater.275,215-221.
Hong,S.,Soyol-Erdene,T.O.,Hwang,H.J.,Hong,S.B.,Do Hur,S.,Motoyama,H.,2012.Evidence of global-scale As,Mo,Sb,and Tl atmospheric pollution in the Antarctic snow.Environ.Sci.Technol.46,11550-11557.
Hu,X.,Guo,X.,He,M.,Li,S.,2016.pH-dependent release characteristics of antimony and arsenic from typical antimony-bearing ores.J.Environ.Sci.44,171-179.
Hu,X.,He,M.,2017.Organic ligand-induced dissolution kinetics of antimony trioxide.J.Environ.Sci.56,87-94.
Hu,X.,He,M.,Kong,L.,2015a.Photopromoted oxidative dissolution of stibnite.Appl.Geochem.61,53-61.
Hu,X.,He,M.,Li,S.,2015b.Antimony leaching release from brake pads:effect of p H,temperature and organic acids.J.Environ.Sci.29,11-17.
Hu,X.,He,M.,Li,S.,Guo,X.,2017.The leaching characteristics and changes in the leached layer of antimony-bearing ores from China.J.Geochem.Explor.176,76-84.
Hu,X.,Kong,L.,He,M.,2014.Kinetics and mechanism of photopromoted oxidative dissolution of antimony trioxide.Environ.Sci.Technol.48,14266-14272.
Huang,Y.,Chen,Z.,Liu,W.,2012.Influence of iron plaque and cultivars on antimony uptake by and translocation in rice(Oryza sativa L.)seedlings exposed to Sb(III)or Sb(V).Plant Soil 352,41-49.
Iijima,A.,2010.Clarification of the predominant emission sources of antimony in airborne particulate matter and estimation of their impacts on the atmosphere.Bunseki Kagaku 59,151-152.
Iijima,A.,Sato,K.,Ikeda,T.,Sato,H.,Kozawa,K.,Furuta,N.,2010.Concentration distributions of dissolved Sb(III)and Sb(V)species in size-classified inhalable airborne particulate matter.J.Anal.At.Spectrom.25,356-363.
Iqbal,M.,Saeed,A.,Edyvean,R.G.J.,2013.Bioremoval of antimony(III)from contaminated water using several plant wastes:optimization of batch and dynamic flow conditions for sorption by green bean husk(Vigna radiata).Chem.Eng.J.225,192-201.
Jablonska-Czapla,M.,Szopa,S.,Zerzucha,P.,Lyko,A.,Michalski,R.,2015.Chemometric and environmental assessment of arsenic,antimony,and chromium speciation form occurrence in a water reservoir subjected to thermal anthropopressure.Environ.Sci.Pollut.Res.22,15731-15744.
Jain,A.,Raven,K.P.,Loeppert,R.H.,1999.Arsenite and arsenate adsorption on ferrihydrite:surface charge reduction and net OH-release stoichiometry.Environ.Sci.Technol.33,1179-1184.
Jenkins,R.O.,Craig,P.J.,Goessler,W.,Miller,D.,Ostah,N.,Irgolic,K.J.,1998.Biomethylation of inorganic antimony compounds by an aerobic fungus:Scopulariopsis brevicaulis.Environ.Sci.Technol.32,882-885.
Jenkins,R.O.,Forster,S.N.,Craig,P.J.,2002.Formation of methylantimony species by an aerobic prokaryote:Flavobacterium sp.Arch.Microbiol.178,274-278.
Kalantzi,I.,Mylona,K.,Sofoulaki,K.,Tsapakis,M.,Pergantis,S.A.,2017.Arsenic speciation in fish from Greek coastal areas.J.Environ.Sci.56,300-312.
Kameda,T.,Honda,M.,Yoshioka,T.,2011.Removal of antimonate ions and simultaneous formation of a brandholzite-like compound from magnesium-aluminum oxide.Sep.Purif.Technol.80,235-239.
Kameda,T.,Yagihashi,N.,Grause,G.,Yoshioka,T.,2009.Preparation of Fe-Al layered double hydroxide and its application in Sb removal.Fresenius Environ.Bull.18,1006-1010.
Kappen,P.,Ferrando-Miguel,G.,Reichman,S.M.,Innes,L.,Welter,E.,Pigram,P.J.,2017.Antimony leaching and chemical species analyses in an industrial solid waste:surface and bulk speciation using To F-SIMS and XANES.J.Hazard.Mater.329,131-140.
Khalid,N.,Ahmad,S.,Toheed,A.,Ahmed,J.,2000.Potential of rice husks for antimony removal.Appl.Radiat.Isot.52,31-38.
Kim,Y.H.,Wyrzykowska-Ceradini,B.,Touati,A.,Krantz,Q.T.,Dye,J.A.,Linak,W.P.,et al.,2015.Characterization of size-fractionated airborne particles inside an electronic waste recycling facility and acute toxicity testing in mice.Environ.Sci.Technol.49,11543-11550.
Kolbe,F.,Weiss,H.,Morgenstern,P.,Wennrich,R.,Lorenz,W.,Schurk,K.,et al.,2011.Sorption of aqueous antimony and arsenic species onto akaganeite.J.Colloid Interface Sci.357,460-465.
Kong,L.,He,M.,2016.Mechanisms of Sb(III)photooxidation by the excitation of organic Fe(III)complexes.Environ.Sci.Technol.50,6974-6982.
Kong,L.,He,M.,Hu,X.,2016.Rapid photooxidation of Sb(III)in the presence of different Fe(III)species.Geochim.Cosmochim.Acta 180,214-226.
Kong,L.,Hu,X.,He,M.,2015.Mechanisms of Sb(III)oxidation by pyrite-induced hydroxyl radicals and hydrogen peroxide.Environ.Sci.Technol.49,3499-3505.
Krachler,M.,Zheng,J.,Koerner,R.,Zdanowicz,C.,Fisher,D.,Shotyk,W.,2005.Increasing atmospheric antimony contamination in the northern hemisphere:snow and ice evidence from Devon Island,Arctic Canada.J.Environ.Monit.7,1169-1176.
Kulp,T.R.,Miller,L.G.,Braiotta,F.,Webb,S.M.,Kocar,B.D.,Blum,J.S.,et al.,2014.Microbiological reduction of Sb(V)in anoxic freshwater sediments.Environ.Sci.Technol.48,218-226.
Kuperman,R.G.,Checkai,R.T.,Simini,M.,Phillips,C.I.,Speicher,J.A.,Barclift,D.J.,2006.Toxicity benchmarks for antimony,barium,and beryllium determined using reproduction endpoints for Folsomia candida,Eisenia fetida,and Enchytraeus crypticus.Environ.Toxicol.Chem.25,754-762.
Kuwae,M.,Tsugeki,N.K.,Agusa,T.,Toyoda,K.,Tani,Y.,Ueda,S.,et al.,2013.Sedimentary records of metal deposition in Japanese alpine lakes for the last 250 years:recent enrichment of airborne Sb and in in East Asia.Sci.Total Environ.442,189-197.
Lai,C.Y.,Wen,L.L.,Zhang,Y.,Luo,S.S.,Wang,Q.Y.,Luo,Y.H.,et al.,2016.Autotrophic antimonate bio-reduction using hydrogen as the electron donor.Water Res.88,467-474.
Laporte-Saumure,M.,Martel,R.,Mercier,G.,2011.Characterization and metal availability of copper,lead,antimony and zinc contamination at four Canadian small arms firing ranges.Environ.Technol.32,767-781.
Le,X.C.,2016.Professor William R.Cullen and arsenic chemistry.J.Environ.Sci.49,1-6.
Lehr,C.R.,Kashyap,D.R.,McDermott,T.R.,2007.New insights into microbial oxidation of antimony and arsenic.Appl.Environ.Microbiol.73,2386-2389.
Leng,Y.,Guo,W.,Su,S.,Yi,C.,Xing,L.,2012.Removal of antimony(III)from aqueous solution by graphene as an adsorbent.Chem.Eng.J.211-212(47),406-411.
Leuz,A.K.,Johnson,C.A.R.,2005.Oxidation of Sb(III)to Sb(V)by O-2and H2O2in aqueous solutions.Geochim.Cosmochim.Acta 69,1165-1172.
Leuz,A.K.,M?nch,H.,Johnson,C.A.,2006.Sorption of Sb(III)and Sb(V)to goethite:influence on Sb(III)oxidation and mobilization.Environ.Sci.Technol.40,7277-7282.
Levresse,G.,Lopez,G.,Tritlla,J.,Cardellach,L.E.,Carrillo,C.A.,Mascunano,S.E.,et al.,2012.Phytoavailability of antimony and heavy metals in arid regions:the case of the Wadley Sb district(San Luis,Potosi,Mexico).Sci.Total Environ.427,115-125.
Lewis,J.,Sjostrom,J.,Skyllberg,U.,Hagglund,L.,2010.Distribution,chemical speciation,and mobility of lead and antimony originating from small arms ammunition in a coarse-grained unsaturated surface sand.J.Environ.Qual.39,863-870.
Li,X.H.,Dou,X.M.,Li,J.Q.,2012.Antimony(V)removal from water by iron-zirconium bimetal oxide:performance and mechanism.J.Environ.Sci.24,1197-1203.
Li,P.,Lin,C.,Cheng,H.,Duan,X.,Lei,K.,2015a.Contamination and health risks of soil heavy metals around a lead/zinc smelter in southwestern China.Ecotoxicol.Environ.Saf.113,391-399.
Li,J.,Wang,Q.,Li,M.,Yang,B.,Shi,M.,Guo,W.,et al.,2015b.Proteomics and genetics for identification of a bacterial antimonite oxidase in agrobacterium tumefaciens.Environ.Sci.Technol.49,5980-5989.
Li,J.X.,Wang,Q.,Oremland,R.S.,Kulp,T.R.,Rensing,C.,Wang,G.J.,2016.Microbial antimony biogeochemistry:enzymes,regulation,and related metabolic pathways.Appl.Environ.Microbiol.82,5482-5495.
Li,J.,Wang,Q.,Zhang,S.,Qin,D.,Wang,G.,2013.Phylogenetic and genome analyses of antimony-oxidizing bacteria isolated from antimony mined soil.Int.Biodeterior.Biodegrad.76,76-80.
Li,J.,Wei,Y.,Zhao,L.,Zhang,J.,Shangguan,Y.,Li,F.,et al.,2014.Bioaccessibility of antimony and arsenic in highly polluted soils of the mine area and health risk assessment associated with oral ingestion exposure.Ecotoxicol.Environ.Saf.110,308-315.
Li,J.,Yang,B.,Shi,M.,Yuan,K.,Guo,W.,Li,M.,et al.,2017.Effects upon metabolic pathways and energy production by Sb(III)and As(III)/Sb(III)-oxidase gene aioA in Agrobacterium tumefaciens GW4.PLoS One 12(2),1-19.
Lin,Q.,Liu,E.,Zhang,E.,Nath,B.,Shen,J.,Yuan,H.,et al.,2018.Reconstruction of atmospheric trace metals pollution in Southwest China using sediments from a large and deep alpine lake:historical trends,sources and sediment focusing.Sci.Total Environment 613,331-341.
Lin,X.,Sun,Z.,Ma,J.,Zhao,L.,Qin,X.,Zhao,S.,et al.,2017.Toxicity differences of different forms of antimony to soil-dwelling springtail(Folsomia candida).J.Agro-Environ.Sci.36,657-664.
Liu,F.,Le,X.C.,McKnight-Whitford,A.,Xia,Y.,Wu,F.,Elswick,E.,et al.,2010.Antimony speciation and contamination of waters in the Xikuangshan antimony mining and smelting area,China.Environ.Geochem.Health 32,401-413.
Loppi,S.,Paoli,L.,2015.Comparison of the trace element content in transplants of the lichen Evernia prunastri and in bulk atmospheric deposition:a case study from a low polluted environment(C Italy).Biologia 70,460-466.
Mariet,A.L.,de Vaufleury,A.,Bégeot,C.,Walter-Simonnet,A.V.,Gimbert,F.,2016.Palaeo-pollution from mining activities in the Vosges Mountains:1000 years and still bioavailable.Environ.Pollut.214,575-584.
Marijic,V.F.,Dragun,Z.,Peric,M.S.,Kepcija,R.M.,Gulin,V.,Velki,M.,et al.,2016.Investigation of the soluble metals in tissue as biological response pattern to environmental pollutants(Gammarus fossarum example).Chemosphere 154,300-309.
Mariussen,E.,Johnsen,I.V.,Stromseng,A.E.,2017.Distribution and mobility of lead(Pb),copper(Cu),zinc(Zn),and antimony(Sb)from ammunition residues on shooting ranges for small arms located on mires.Environ.Sci.Pollut.Res.24,10182-10196.
Martin,R.,Dowling,K.,Pearce,D.C.,Florentine,S.,Mc Knight,S.,Stelcer,E.,et al.,2017.Trace metal content in inhalable particulate matter(PM2.5-10 and PM2.5)collected from historical mine waste deposits using a laboratory-based approach.Environ.Geochem.Health 39,549-563.
Martinez,A.M.,Echeberria,J.,2016.Towards a better understanding of the reaction between metal powders and the solid lubricant Sb2S3 in a low-metallic brake pad at high temperature.Wear348-349,27-42.
Mera,M.F.,Rubio,M.,Perez,C.A.,Galvan,V.,Germanier,A.,2015.SR mu XRF and XRD study of the spatial distribution and mineralogical composition of Pb and Sb species in weathering crust of corroded bullets of hunting fields.Microchem.J.119,114-122.
Miao,Y.Y.,Han,F.C.,Pan,B.C.,Niu,Y.J.,Nie,G.Z.,Lv,L.,2014.Antimony(V)removal from water by hydrated ferric oxides supported by calcite sand and polymeric anion exchanger.J.Environ.Sci.26,307-314.
Michalke,K.,Wickenheiser,E.B.,Mehring,M.,Hirner,A.V.,Hensel,R.,2000.Production of volatile derivatives of metal(loid)s by microflora involved in anaerobic digestion of sewage sludge.Appl.Environ.Microbiol.66,2791-2796.
Mishra,S.,Dwivedi,J.,Kumar,A.,Sankararamakrishnan,N.,2016.Removal of antimonite(Sb(III))and antimonate(Sb(V))using zerovalent iron decorated functionalized carbon nanotubes.RSC Adv.6,95865-95878.
Mitsunobu,S.,Harada,T.,Takahashi,Y.,2006.Comparison of antimony behavior with that of arsenic under various soil redox conditions.Environ.Sci.Technol.40,7270-7276.
Mitsunobu,S.,Muramatsu,C.,Watanabe,K.,Sakata,M.,2013.Behavior of antimony(V)during the transformation of ferrihydrite and its environmental implications.Environ.Sci.Technol.47,9660-9667.
Mitsunobu,S.,Takahashi,Y.,Sakai,Y.,2008.Abiotic reduction of antimony(V)by green rust(Fe-4(II)Fe-2(III)(OH)(12)SO4 center dot 3H(2)O).Chemosphere 70,942-947.
Mittal,V.K.,Bera,S.,Narasimhan,S.V.,Velmurugan,S.,2013.Adsorption behavior of antimony(III)oxyanions on magnetite surface in aqueous organic acid environment.Appl.Surf.Sci.266,272-279.
Mohammadpour,G.A.,Karbassi,A.R.,Baghvand,A.,2016.Origin and spatial distribution of metals in agricultural soils.Glob.J.Environ.Sci.Manag.2,145-156.
Nakamaru,Y.M.,Martín,P.F.J.,2017.Effect of soil organic matter on antimony bioavailability after the remediation process.Environ.Pollut.228,425.
Nannoni,F.,Protano,G.,2016.Chemical and biological methods to evaluate the availability of heavy metals in soils of the Siena urban area(Italy).Sci.Total Environ.568,1-10.
Nannoni,F.,Protano,G.,Riccobono,F.,2011.Uptake and bioaccumulation of heavy elements by two earthworm species from a smelter contaminated area in northern Kosovo.Soil Biol.Biochem.43,2359-2367.
Navarro,P.,Alguacil,F.J.,2002.Adsorption of antimony and arsenic from a copper electrorefining solution onto activated carbon.Hydrometallurgy 66,101-105.
Ngo,L.K.,Pinch,B.M.,Bennett,W.W.,Teasdale,P.R.,Jolley,D.F.,2016.Assessing the uptake of arsenic and antimony from contaminated soil by radish(Raphanus sativus)using DGT and selective extractions.Environ.Pollut.216,104-114.
Nguyen,V.K.,Choi,W.,Yu,J.,Lee,T.,2017.Microbial oxidation of antimonite and arsenite by bacteria isolated from antimony-contaminated soils.Int.J.Hydrog.Energy 42,27832-27842.
Ning,Z.P.,Xiao,T.F.,Xiao,E.Z.,2015.Antimony in the soil-plant system in an Sb mining/smelting area of Southwest China.Int.J.Phytorem.17,1081-1089.
Nishad,P.A.,Bhaskarapillai,A.,Velmurugan,S.,2014.Nano-titania-crosslinked chitosan composite as a superior sorbent for antimony(III)and(V).Carbohydr.Polym.108,169-175.
Okkenhaug,G.,Amstatter,K.,Bue,H.L.,Cornelissen,G.,Breedveld,G.D.,Henriksen,T.,et al.,2013.Antimony(Sb)contaminated shooting range soil:Sb mobility and immobilization by soil amendments.Environ.Sci.Technol.47,6431-6439.
Okkenhaug,G.,Gebhardt,K.A.G.,Amstaetter,K.,Bue,H.L.,Herzel,H.,Mariussen,E.,et al.,2016.Antimony(Sb)and lead(Pb)in contaminated shooting range soils:Sb and Pb mobility and immobilization by iron based sorbents,a field study.J.Hazard.Mater.307,336-343.
Okkenhaug,G.,Zhu,Y.G.,Luo,L.,Lei,M.,Li,X.,Mulder,J.,2011.Distribution,speciation and availability of antimony(Sb)in soils and terrestrial plants from an active Sb mining area.Environ.Pollut.159,2427-2434.
Oorts,K.,Smolders,E.,Degryse,F.,Buekers,J.,Gasco,G.,Cornelis,G.,et al.,2008.Solubility and toxicity of antimony trioxide(Sb2O3)in soil.Environ.Sci.Technol.42,4378-4383.
Osório,W.R.,Rosa,D.M.,Peixoto,L.C.,Garcia,A.,2011.Cell/dendrite transition and electrochemical corrosion of Pb-Sb alloys for lead-acid battery applications.J.Power Sources 196,6567-6572.
Pant,P.,Baker,S.J.,Goel,R.,Guttikunda,S.,Goel,A.,Shukla,A.,et al.,2016.Analysis of size-segregated winter season aerosol data from New Delhi,India.Atmos.Pollut.Res.7,100-109.
Payan,L.,Teresa,P.M.,Munoz,L.,Dolores,L.R.M.,Pacheco,R.,Ramos,N.,2017.Study of the influence of storage conditions on the quality and migration levels of antimony in polyethylene terephthalate-bottled water.Food Sci.Technol.Int.23,318-327.
Perez-Sirvent,C.,Martinez-Sanchez,M.J.,Martinez-Lopez,S.,Hernandez,C.M.,2011.Antimony distribution in soils and plants near an abandoned mining site.Microchem.J.97,52-56.
Phillips,M.A.,Canovas,A.,Wu,P.W.,Islas-Trejo,A.,Medrano,J.F.,Rice,R.H.,2016.Parallel responses of human epidermal keratinocytes to inorganic Sb-III and As-III.Environ.Chem.13,963-970.
Pierart,A.,Shahid,M.,Sejalon-Delmas,N.,Dumat,C.,2015.Antimony bioavailability:knowledge and research perspectives for sustainable agricultures.J.Hazard.Mater.289,219-234.
Ptak,C.,McBride,M.,2015.Organically complexed iron enhances bioavailability of antimony to maize(Zea mays)seedlings in organic soils.Environ.Toxicol.Chem.34,2732-2738.
Qi,C.,Liu,G.,Kang,Y.,Lam,P.K.S.,Chou,C.,2011a.Assessment and distribution of antimony in soils around three coal mines,Anhui,China.J.Air Waste Manag.61,850-857.
Qi,C.,Wu,F.,Deng,Q.,Liu,G.,Mo,C.,Liu,B.,et al.,2011b.Distribution and accumulation of antimony in plants in the super-large Sb deposit areas,China.Microchem.J.97,44-51.
Qiao,F.,Lei,K.,Li,Z.,Liu,Q.,Wei,Z.,An,L.,et al.,2018.Effects of storage temperature and time of antimony release from PETbottles into drinking water in China.Environ.Sci.Pollut.Res.Int.25(2),1388-1393.
Quan,S.X.,Yan,B.,Yang,F.,Li,N.,Xiao,X.M.,Fu,J.M.,2015.Spatial distribution of heavy metal contamination in soils near a primitive e-waste recycling site.Environ.Sci.Pollut.Res.22,1290-1298.
Quiroz,W.,Aguilar,L.,Barria,M.,Veneciano,J.,Martinez,D.,Bravo,M.,et al.,2013.Sb(V)and Sb(III)distribution in human erythrocytes:speciation methodology and the influence of temperature,time and anticoagulants.Talanta 115,902-910.
Quiroz,W.,Astudillo,F.,Bravo,M.,Cereceda-Balic,F.,Vidal,V.,Palomo-Marin,M.R.,et al.,2016.Antimony speciation in soils,sediments and volcanic ashes by microwave extraction and HPLC-HG-AFS detection.Microchem.J.129,111-116.
Quiroz,W.,De Gregori,I.,Basilio,P.,Bravo,M.,Pinto,M.,Gabriela,L.M.,2009.Heavy weight vehicle traffic and its relationship with antimony content in human blood.J.Environ.Monit.11,1051-1055.
Rafiei,B.,Khodaei,A.S.,Khodabakhsh,S.,Hashemi,M.,Nejad,M.B.,2010.Contamination assessment of lead,zinc,copper,cadmium,arsenic and antimony in Ahangaran mine soils,Malayer,west of Iran.Soil Sediment Contam.19,573-586.
Rakshit,S.,Sarkar,D.,Punamiya,P.,Datta,R.,2011.Antimony sorption at gibbsite-water interface.Chemosphere 84,480-483.
Rashedy,A.H.,Solimany,A.A.,Ismail,A.K.,Wahdan,M.H.,Saban,K.A.,2013.Histopathological and functional effects of antimony on the renal cortex of growing albino rat.Int.J.Clin.Exp.Pathol.6,1467-1480.
Reimann,C.,Matschullat,J.,Birke,M.,Salminen,R.,2010.Antimony in the environment:lessons from geochemical mapping.Appl.Geochem.25,175-198.
Ren,J.H.,Ma,L.Q.,Sun,H.J.,Cai,F.,Luo,J.,2014.Antimony uptake,translocation and speciation in rice plants exposed to antimonite and antimonate.Sci.Total Environ.475,83-89.
Ren,B.,Wang,C.,Ma,H.,Deng,R.,Zhang,P.,2016.Effect to rainfall on Sb release characteristics from smelting slag in rainy south China.Fresenius Environ.Bull.25,4908-4914.
Resongles,E.,Casiot,C.,Elbaz-Poulichet,F.,Freydier,R.,Bruneel,O.,Piot,C.,et al.,2013.Fate of Sb(V)and Sb(III)species along a gradient of pH and oxygen concentration in the Carnoules mine waters(southern France).Environ.Sci.Processes Impacts15,1536-1544.
Resongles,E.,Freydier,R.,Casiot,C.,Viers,J.,Chmeleff,J.,Elbaz-Poulichet,F.,2015.Antimony isotopic composition in river waters affected by ancient mining activity.Talanta 144,851-861.
Rocha,M.N.,Nogueira,P.M.,Demicheli,C.,de Oliveira,L.G.,da Silva,M.M.,Frezard,F.,et al.,2013.Cytotoxicity and in vitro antileishmanial activity of antimony(V),bismuth(V),and tin(IV)complexes of lapachol.Bioinorg.Chem.Appl.2013,1-7.
Rovira,J.,Nadal,M.,Schuhmacher,M.,Domingo,J.L.,2017.Trace elements in skin-contact clothes and migration to artificial sweat:risk assessment of human dermal exposure.Text.Res.J.87,726-738.
Rzetala,M.A.,Sgem,2015.Arsenic and antimony in bottom sediments of anthropogenic water bodies in the Silesian Upland(Southern Poland).Science and Technologies in Geology,Exploration and Mining,Sgem 2015 vol.I pp.45-52.
Sakata,M.,Asakura,K.,2009.Factors contributing to seasonal variations in wet deposition fluxes of trace elements at sites along Japan Sea coast.Atmos.Environ.43,3867-3875.
Sakata,M.,Asakura,K.,2011.Atmospheric dry deposition of trace elements at a site on Asian-continent side of Japan.Atmos.Environ.45,1075-1083.
Salam,M.A.,Mohamed,R.M.,2013.Removal of antimony(III)by multi-walled carbon nanotubes from model solution and environmental samples.Chem.Eng.Res.Des.91,1352-1360.
Sanchez-Hernandez,J.C.,2006.Earthworm biomarkers in ecological risk assessment.In:Ware,G.W.(Ed.),Reviews of Environmental Contamination and Toxicology.Vol.188,pp.85-126.
Sánchez-Martínez,M.,Pérez-Corona,T.,Cámara,C.,Madrid,Y.,2013.Migration of antimony from PET containers into regulated EU food simulants.Food Chem.141,816-822.
Sanchez-Rodas,D.,Alsioufi,L.,Sanchez De La Campa,A.M.,Gonzalez-Castanedo,Y.,2017.Antimony speciation as geochemical tracer for anthropogenic emissions of atmospheric particulate matter.J.Hazard.Mater.324,213-220.
Sanderson,P.,Naidu,R.,Bolan,N.,2014.Ecotoxicity of chemically stabilised metal(loid)s in shooting range soils.Ecotoxicol.Environ.Saf.100,201-208.
Sanderson,P.,Naidu,R.,Bolan,N.,2015.Effectiveness of chemical amendments for stabilisation of lead and antimony in risk-based land management of soils of shooting ranges.Environ.Sci.Pollut.Res.22,8942-8956.
Sar?,A.,?ahino?lu,G.,Tüzen,M.,2012.Antimony(III)adsorption from aqueous solution using raw perlite and Mn-modified perlite:equilibrium,thermodynamic,and kinetic studies.Ind.Eng.Chem.Res.51,6877-6886.
Schreck,E.,Dappe,V.,Sarret,G.,Sobanska,S.,Nowak,D.,Nowak,J.,et al.,2014.Foliar or root exposures to smelter particles:consequences for lead compartmentalization and speciation in plant leaves.Sci.Total Environ.476,667-676.
Schreck,E.,Foucault,Y.,Sarret,G.,Sobanska,S.,Cecillon,L.,Castrecrouelle,M.,et al.,2012.Metal and metalloid foliar uptake by various plant species exposed to atmospheric industrial fallout:mechanisms involved for lead.Sci.Total Environ.427(/428),253-262.
Serafimovska,J.M.,Arpadjan,S.,Stafilov,T.,Tsekova,K.,2013.Study of the antimony species distribution in industrially contaminated soils.J.Soils Sediments 13,294-303.
Sh,T.,Liu,C.Q.,Feng,C.,2012.Solubility,toxicity and sorption of antimony from smelter release.J.Geochem.Explor.118,14-18.
Shan,C.,Ma,Z.,Tong,M.,2014.Efficient removal of trace antimony(III)through adsorption by hematite modified magnetic nanoparticles.J.Hazard.Mater.268,229-236.
Sharifi,R.,Moore,F.,Keshavarzi,B.,2016.Mobility and chemical fate of arsenic and antimony in water and sediments of Sarouq River catchment,Takab geothermal field,Northwest Iran.J.Environ.Manag.170,136-144.
Shotyk,W.,Chen,B.,Krachler,M.,2005.Lithogenic,oceanic and anthropogenic sources of atmospheric Sb to a maritime blanket bog,Myrarnar,Faroe Islands.J.Environ.Monit.7,1148-1154.
Shtangeeva,I.,Bali,R.,Harris,A.,2011.Bioavailability and toxicity of antimony.J.Geochem.Explor.110,40-45.
Shtangeeva,I.,Singh,B.,Bali,R.,Ayrault,S.,Timofeev,S.,2014.Antimony accumulation in wheat seedlings grown in soil and water.Commun.Soil Sci.Plant Anal.45,968-983.
Shtangeeva,I.,Steinnes,E.,Lierhagen,S.,2012.Uptake of different forms of antimony by wheat and rye seedlings.Environ.Sci.Pollut.Res.19,502-509.
Song,J.,Yan,L.,Duan,J.,Jing,C.,2017.TiO2 crystal facet-dependent antimony adsorption and photocatalytic oxidation.J.Colloid Interface Sci.496,522-530.
Stefaniak,S.,Kmiecik,E.,Miszczak,E.,Szczepańska-Plewa,J.,Twardowska,I.,2015.Effect of weathering transformations of coal combustion residuals on trace elements mobility in view of the environmental safety and sustainability of their disposal and use.II.Element release.J.Environ.Manag.156,167-180.
Sud,D.,Mahajan,G.,Kaur,M.,2008.Agricultural waste material as potential adsorbent for sequestering heavy metal ions from aqueous solutions-a review.Bioresour.Technol.99,6017-6027.
Sun,Y.Z.,Liu,G.L.,Cai,Y.,2016a.Thiolated arsenicals in arsenic metabolism:occurrence,formation,and biological implications.J.Environ.Sci.49,59-73.
Sun,F.,Wu,F.,Liao,H.,Xing,B.,2011.Biosorption of antimony(V)by freshwater cyanobacteria Microcystis biomass:chemical modification and biosorption mechanisms.Chem.Eng.J.171,1082-1090.
Sun,W.,Xiao,E.,Dong,Y.,Tang,S.,Krumins,V.,Ning,Z.,et al.,2016b.Profiling microbial community in a watershed heavily contaminated by an active antimony(Sb)mine in Southwest China.Sci.Total Environ.550,297-308.
Sun,W.,Xiao,E.,Xiao,T.,Krumins,V.,Wang,Q.,Haggblom,M.,et al.,2017.Response of soil microbial communities to elevated antimony and arsenic contamination indicates the relationship between the innate microbiota and contaminant fractions.Environ.Sci.Technol.51(16),9165-9195.
Taiwo,A.M.,Beddows,D.C.S.,Shi,Z.B.,Harrison,R.M.,2014.Mass and number size distributions of particulate matter components:comparison of an industrial site and an urban background site.Sci.Total Environ.475,29-38.
Tandy,S.,Meier,N.,Schulin,R.,2017.Use of soil amendments to immobilize antimony and lead in moderately contaminated shooting range soils.J.Hazard.Mater.324,617-625.
Targan,?.,Tirtom,V.N.,Akku?,B.,2013.Removal of antimony(III)from aqueous solution by using grey and red Erzurum clay and application to the Gediz River sample.ISRN Anal.Chem.2013,1-8.
Tella,M.,Pokrovski,G.S.,2009.Antimony(III)complexing with O-bearing organic ligands in aqueous solution:an X-ray absorption fine structure spectroscopy and solubility study.Geochim.Cosmochim.Acta 73,268-290.
Terry,L.R.,Kulp,T.R.,Wiatrowski,H.,Miller,L.G.,Oremland,R.S.,2015.Microbiological oxidation of antimony(III)with oxygen or nitrate by bacteria isolated from contaminated mine sediments.Appl.Environ.Microbiol.81,8478-8488.
Thanabalasingam,P.,Pickering,W.F.,1990.Specific sorption of antimony(III)by the hydrous oxides of Mn,Fe,and Al.Water Air Soil Pollut.49,175-185.
Tian,X.,Wu,Y.,Hou,P.,Liang,S.,Qu,S.,Xu,M.,Zuo,T.,2017.Environmental impact and economic assessment of secondary lead production:comparison of main spent lead-acid battery recycling processes in China.J.Clean.Prod.144,142-148.
Tian,H.,Zhao,D.,Cheng,K.,Lu,L.,He,M.,Hao,J.,2012.Anthropogenic atmospheric emissions of antimony and its spatial distribution characteristics in China.Environ.Sci.Technol.46,3973-3980.
Tian,H.Z.,Zhao,D.,He,M.C.,Wang,Y.,Cheng,K.,2011.Temporal and spatial distribution of atmospheric antimony emission inventories from coal combustion in China.Environ.Pollut.159,1613-1619.
Tian,H.,Zhou,J.,Zhu,C.,Zhao,D.,Gao,J.,Hao,J.,et al.,2014.Acomprehensive global inventory of atmospheric antimony emissions from anthropogenic activities,1995-2010.Environ.Sci.Technol.48,10235-10241.
Tighe,M.,Lockwood,P.V.,Ashley,P.M.,Murison,R.D.,Wilson,S.C.,2013.The availability and mobility of arsenic and antimony in an acid sulfate soil pasture system.Sci.Total Environ.463,151-160.
Tisarum,R.,Lessl,J.T.,Dong,X.L.,de Oliveira,L.M.,Rathinasabapathi,B.,Ma,L.Q.,2014.Antimony uptake,efflux and speciation in arsenic hyperaccumulator Pteris vittata.Environ.Pollut.186,110-114.
Tisarum,R.,Ren,J.H.,Dong,X.,Chen,H.,Lessl,J.T.,Ma,L.Q.,2015.A new method for antimony speciation in plant biomass and nutrient media using anion exchange cartridge.Talanta 144,1171-1175.
Tschan,M.,Robinson,B.,Johnson,C.A.,Burgi,A.,Schulin,R.,2010.Antimony uptake and toxicity in sunflower and maize growing in Sb-III and Sb-V contaminated soil.Plant Soil334,235-245.
Tschan,M.,Robinson,B.H.,Nodari,M.,Schulin,R.,2009a.Antimony uptake by different plant species from nutrient solution,agar and soil.Environ.Chem.6,144-152.
Tschan,M.,Robinson,B.H.,Schulin,R.,2009b.Antimony in the soil-plant system-a review.Environ.Chem.6,106.
Turner,A.,Filella,M.,2017.Field-portable-XRF reveals the ubiquity of antimony in plastic consumer products.Sci.Total Environ.584,982-989.
Tuzen,M.,Sari,A.,2010.Biosorption of selenium from aqueous solution by green algae(Cladophora hutchinsiae)biomass:equilibrium,thermodynamic and kinetic studies.Chem.Eng.J.158,200-206.
Uluozlu,O.D.,Sari,A.,Tuzen,M.,2010.Biosorption of antimony from aqueous solution by lichen(Physcia tribacia)biomass.Chem.Eng.J.163,382-388.
Ungureanu,G.,Filote,C.,Santos,S.C.R.,Boaventura,R.A.R.,Volf,I.,Botelho,C.M.S.,2016.Antimony oxyanions uptake by green marine macroalgae.J.Environ.Chem.Eng.4,3441-3450.
Ungureanu,G.,Santos,S.,Boaventura,R.,Botelho,C.,2015.Arsenic and antimony in water and wastewater:overview of removal techniques with special reference to latest advances in adsorption.J.Environ.Manag.151,326-342.
Ungureanu,G.,Santos,S.C.R.,Volf,I.,Boaventura,R.A.R.,Botelho,C.M.S.,2017.Biosorption of antimony oxyanions by brown seaweeds:batch and column studies.J.Environ.Chem.Eng.5,3463-3471.
Uppal,J.S.,Shuai,Q.,Li,Z.,Le,X.C.,2017.Arsenic biotransformation and an arsenite S-adenosylmethionine methyltransferase in plankton.J.Environ.Sci.61,118-121.
Van Khanh,N.,Lee,J.U.,2014.Isolation and characterization of antimony-reducing bacteria from sediments collected in the vicinity of an antimony factory.Geomicrobiol J.31,855-861.
Van Vleek,B.,Amarasiriwardena,D.,Xing,B.,2011.Investigation of distribution of soil antimony using sequential extraction and antimony complexed to soil-derived humic acids molar mass fractions extracted from various depths in a shooting range soil.Microchem.J.97,68-73.
Varrica,D.,Bardelli,F.,Dongarrà,G.,Tamburo,E.,2013.Speciation of Sb in airborne particulate matter,vehicle brake linings,and brake pad wear residues.Atmos.Environ.64,18-24.
Verbinnen,B.,Block,C.,Lievens,P.,Van Brecht,A.,Vandecasteele,C.,2013.Simultaneous removal of molybdenum,antimony and selenium oxyanions from wastewater by adsorption on supported magnetite.Waste Biomass Valoriz.4,635-645.
Wan,X.M.,Tandy,S.,Hockmann,K.,Schulin,R.,2013a.Changes in Sb speciation with waterlogging of shooting range soils and impacts on plant uptake.Environ.Pollut.172,53-60.
Wan,X.M.,Tandy,S.,Hockmann,K.,Schulin,R.,2013b.Effects of waterlogging on the solubility and redox state of Sb in a shooting range soil and its uptake by grasses:a tank experiment.Plant Soil 371,155-166.
Wang,Y.,Chai,L.,Yang,Z.,Mubarak,H.,Xiao,R.,Tang,C.,2017.Subcellular distribution and chemical forms of antimony in Ficus tikoua.Int.J.Phytoremediation 19,97-103.
Wang,H.,Chen,F.,Mu,S.,Zhang,D.,Pan,X.,Lee,D.J.,Chang,J.S.,2013.Removal of antimony(Sb(V))from Sb mine drainage:biological sulfate reduction and sulfide oxidation-precipitation.Bioresour.Technol.146,799-802.
Wang,X.,He,M.,Lin,C.,Gao,Y.,Zheng,L.,2012a.Antimony(III)oxidation and antimony(V)adsorption reactions on synthetic manganite.Chem.Erde-Geochem.72,41-47.
Wang,Q.,He,M.,Wang,Y.,2011b.Influence of combined pollution of antimony and arsenic on culturable soil microbial populations and enzyme activities.Ecotoxicology20,9-19.
Wang,X.,He,M.,Xi,J.,Lu,X.,2011a.Antimony distribution and mobility in rivers around the world's largest antimony mine of Xikuangshan,Hunan Province,China.Microchem.J.97,4-11.
Wang,X.,He,M.,Xi,J.,Lu,X.,Xie,J.,2010a.Antimony,arsenic and other toxic elements in the topsoil of an antimony mine area.In:Xu,Jianming,Huang,Pan Ming(Eds.),Molecular Environmental Soil Science at the Interfaces in the Earth's Critical Zone.Zhejiang University Press,Hangzhou and Springer-Verlag Berlin Heidelberg2010.
Wang,X.,He,M.,Xie,J.,Xi,J.,Lu,X.,2010b.Heavy metal pollution of the world largest antimony mine-affected agricultural soils in Hunan province(China).J.Soils Sediments 10,827-837.
Wang,Q.Q.,Ma,Y.L.,Tan,J.H.,Zheng,N.J.,Duan,J.C.,Sun,Y.L.,et al.,2015.Characteristics of size-fractionated atmospheric metals and water-soluble metals in two typical episodes in Beijing.Atmos.Environ.119,294-303.
Wang,X.,Yu,T.,Li,C.,et al.,2012b.The adsorption of Sb(III)in aqueous by KMnO4-modified activated carbon.J.Zhejiang Univ.(Eng.Sci.)46,2028-2034.
Wang,D.,Zhu,F.Q.,Wang,Q.,Rensing,C.,Yu,P.,Gong,J.,et al.,2016.Disrupting ROS-protection mechanism allows hydrogen peroxide to accumulate and oxidize Sb(III)to Sb(V)in Pseudomonas stutzeri TS44.BMC Microbiol.16,1-11.
Wang,N.,Zhang,S.,He,M.,2018.Bacterial community profile of contaminated soils in a typical antimony mining site.Environ.Sci.Pollut.Res.25,141-152.
Warnken,J.,Ohlsson,R.,Welsh,D.T.,Teasdale,P.R.,Chelsky,A.,Bennett,W.W.,2017.Antimony and arsenic exhibit contrasting spatial distributions in the sediment and vegetation of a contaminated wetland.Chemosphere 180,388-395.
Wei,Y.,Chen,Z.P.,Wu,F.C.,Hou,H.,Li,J.N.,Shangguan,Y.X.,et al.,2015b.Molecular diversity of arbuscular mycorrhizal fungi at a large-scale antimony mining area in southern China.J.Environ.Sci.29,18-26.
Wei,C.,Ge,Z.,Chu,W.,Feng,R.,2015a.Speciation of antimony and arsenic in the soils and plants in an old antimony mine.Environ.Exp.Bot.109,31-39.
Wei,Y.,Su,Q.,Sun,Z.,Shen,Y.,Li,J.,Zhu,X.,et al.,2016.The role of arbuscular mycorrhizal fungi in plant uptake,fractions,and speciation of antimony.Appl.Soil Ecol.107,244-250.
Wen,B.,Zhou,J.W.,Zhou,A.G.,Liu,C.F.,Li,L.G.,2018.A review of antimony(Sb)isotopes analytical methods and application in environmental systems.Int.Biodeterior.Biodegrad.128,109-116.
Willis,S.S.,Haque,S.E.,Johannesson,K.H.,2011.Arsenic and antimony in groundwater flow systems:a comparative study.Aquat.Geochem.17,775-807.
Wilson,S.C.,Lockwood,P.V.,Ashley,P.M.,Tighe,M.,2010.The chemistry and behaviour of antimony in the soil environment with comparisons to arsenic:a critical review.Environ.Pollut.158,1169-1181.
Wu,C.C.,Chen,Y.C.,2017.Assessment of industrial antimony exposure and immunologic function for workers in Taiwan.Int.J.Environ.Res.Public Health 14(7),689.
Wu,Q.H.,Feng,R.W.,Guo,J.K.,Wang,R.G.,Xu,Y.M.,Fan,Z.L.,et al.,2017b.Interactions between selenite and different forms of antimony and their effects on root morphology of paddy rice.Plant Soil 413,231-242.
Wu,Z.,He,M.,Guo,X.,Zhou,R.,2010.Removal of antimony(III)and antimony(V)from drinking water by ferric chloride coagulation:competing ion effect and the mechanism analysis.Sep.Purif.Technol.76,184-190.
Wu,D.,Purnomo,B.J.,Sun,S.,2017a.As and Sb speciation in relation with physico-chemical characteristics of hydrothermal waters in Java and Bali.J.Geochem.Explor.173,85-91.
Wu,X.D.,Song,J.M.,Li,X.G.,Yuan,H.M.,Li,N.,2011.Behaviors of dissolved antimony in the Yangtze River estuary and its adjacent waters.J.Environ.Monit.13,2292-2303.
Wu,F.,Sun,F.,Wu,S.,Yan,Y.,Xing,B.,2012.Removal of antimony(III)from aqueous solution by freshwater cyanobacteria Microcystis biomass.Chem.Eng.J.183,172-179.
Xi,J.,He,M.,2013.Removal of Sb(III)and Sb(V)from aqueous media by goethite.Water Qual.Res.J.Can.48,223-231.
Xi,J.,He,M.,Lin,C.,2011.Adsorption of antimony(III)and antimony(V)on bentonite:kinetics,thermodynamics and anion competition.Microchem.J.97,85-91.
Xi,J.,He,M.,Wang,K.,Zhang,G.,2013.Adsorption of antimony(III)on goethite in the presence of competitive anions.J.Geochem.Explor.132,201-208.
Xiao,E.Z.,Krumins,V.,Tang,S.,Xiao,T.F.,Ning,Z.P.,Lan,X.L.,et al.,2016.Correlating microbial community profiles with geochemical conditions in a watershed heavily contaminated by an antimony tailing pond.Environ.Pollut.215,141-153.
Xu,Y.H.,Ohki,A.,Maeda,S.,2001.Adsorption and removal of antimony from aqueous solution by an activated alumina.Toxicol.Environ.Chem.80,133-144.
Xu,W.,Wang,H.,Liu,R.,Zhao,X.,Qu,J.,2011a.The mechanism of antimony(III)removal and its reactions on the surfaces of Fe-Mn binary oxide.J.Colloid Interface Sci.363,320-326.
Xu,L.,Wu,F.,Zheng,J.,Xie,Q.,Li,H.,Liao,H.,et al.,2011b.Sediment records of Sb and Pb stable isotopic ratios in Lake Qinghai.Microchem.J.97,25-29.
Xue,L.,Ren,H.D.,Li,S.,Gao,M.,Shi,S.Q.,Chang,E.M.,et al.,2015.Comparative proteomic analysis in Miscanthus sinensis exposed to antimony stress.Environ.Pollut.201,150-160.
Yan,L.,Hu,S.,Jing,C.Y.,2016.Recent progress of arsenic adsorption on TiO2in the presence of coexisting ions:a review.J.Environ.Sci.49,74-85.
Yan,L.,Song,J.Y.,Chan,T.S.,Jing,C.Y.,2017.Insights into antimony adsorption on{001}TiO2:XAFS and DFT study.Environ.Sci.Technol.51,6335-6341.
Yang,H.,He,M.,2015.Speciation of antimony in soils and sediments by liquid chromatography-hydride generationatomic fluorescence spectrometry.Anal.Lett.48,1941-1953.
Yang,H.,Lu,X.,He,M.,2018.Effect of organic matter on mobilization of antimony from nanocrystalline titanium dioxide.Environ.Technol.39(12),1515-1521.
Y?lmaz,H.,2015.Characterization and comparison of leaching behaviors of fly ash samples from three different power plants in Turkey.Fuel Process.Technol.137,240-249.
Yuan,Y.,Xiang,M.,Liu,C.,Theng,B.K.G.,2017.Geochemical characteristics of heavy metal contamination induced by a sudden wastewater discharge from a smelter.J.Geochem.Explor.176,33-41.
Zhang,L.,Lin,Q.,Guo,X.J.,Verpoort,F.,2011.Sorption behavior of florisil for the removal of antimony ions from aqueous solutions.Water Sci.Technol.63,2114-2122.
Zhang,S.,Jiang,X.,Liu,B.,Lv,G.,Jin,Y.,Yan,J.,2017a.Co-combustion of bituminous coal and pickling sludge in a drop tube furnace:thermodynamic study and experimental data on the distribution of Cr,Ni,Mn,As,Cu,Sb,Pb,Cd,Zn,and Sn.Energy Fuel 31,3019-3028.
Zhang,G.,Ouyang,X.,Li,H.,Fu,Z.,Chen,J.,2016.Bioremoval of antimony from contaminated waters by a mixed batch culture of sulfate-reducing bacteria.Int.Biodeterior.Biodegrad.115,148-155.
Zhang,L.,Yang,Q.,Wang,S.,Li,W.,Jiang,S.,Liu,Y.,2017b.Influence of silicon treatment on antimony uptake and translocation in rice genotypes with different radial oxygen loss.Ecotoxicol.Environ.Saf.144,572-577.
Zhou,J.,Nyirenda,M.T.,Xie,L.,Li,Y.,Zhou,B.,Zhu,Y.,et al.,2017.Mine waste acidic potential and distribution of antimony and arsenic in waters of the Xikuangshan mine,China.Appl.Geochem.77,52-61.
Zhou,J.R.,Tian,H.Z.,Zhu,C.Y.,Hao,J.M.,Gao,J.J.,Wang,Y.,et al.,2015.Future trends of global atmospheric antimony emissions from anthropogenic activities until 2050.Atmos.Environ.120,385-392.
Zhu,J.,Wu,F.C.,Pan,X.L.,Guo,J.Y.,Wen,D.S.,2011.Removal of antimony from antimony mine flotation wastewater by electrocoagulation with aluminum electrodes.J.Environ.Sci.23,1066-1071.
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