nach oben

Erschienen in:

2018 | OriginalPaper | Buchkapitel

The Long Road to Developing Agromining/Phytomining

verfasst von : Rufus L. Chaney, Alan J. M. Baker, Jean Louis Morel

Erschienen in: Agromining: Farming for Metals

Verlag: Springer International Publishing

Einloggen

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

search-config

KI-gestützte Suche

Aus

Abstract

The concept of phytomining is a natural extension of botanical prospecting and the study of metal biochemistry and biogeography of metal hyperaccumulator plants. Some elements may be phyto-extracted to remediate soils, but the recovered biomass would have little economic value (Cd, As, etc.) and disposal of the biomass would be a cost. A few elements may have sufficient economic value in phytomining biomass to support commercial practice (Ni, Co, Au). The development of phytomining requires (1) selection of high-biomass hyperaccumulator plant species; (2) evaluation of genetic diversity and breeding of improved strains with higher yields of the phytoextracted element; (3) development of agronomic practices to maximize economic return; and (4) development of methods to recover the phytomined element from the plant biomass. Plant species and methods for phytomining of soil Ni have been demonstrated for several species and locations (temperate and tropical climates). Production of Ni metal in an electric arc furnace smelter, and of Ni(NH₄)₂SO₄ using a hydrometallurgical method, have been demonstrated. Full commercial phytomining of Ni is beginning in Albania using Alyssum murale, and major trials in Malaysia are underway using Phyllanthus securinegioides. Variable prices of commodity metals add confusion to the development of commercial phytomining.

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

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

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

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

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

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

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

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Nächstes Kapitel Agronomy of ‘Metal Crops’ Used in Agromining

Aboudrar W, Schwartz C, Benizri E, Morel JL, Boularbah A (2007) Soil microbial diversity as affected by the rhizosphere of the hyperaccumulator Thlaspi caerulescens under natural conditions. Int J Phytoremediation 9:41–52CrossRef

Aboudrar W, Schwartz C, Morel JL, Boularbah A (2013) Effect of nickel-resistant rhizosphere bacteria on the uptake of nickel by the hyperaccumulator Noccaea caerulescens under controlled conditions. J Soils Sediments 13:501–507CrossRef

Anderson C, Moreno C, Meech J (2005) A field demonstration of gold phytoextraction technology. Miner Eng 18:385–392CrossRef

Angle JS, Linacre NA (2005) Metal phytoextraction—a survey of potential risks. Int J Phytoremediation 7:241–254CrossRef

Angle JS, Chaney RL, Baker AJM, Li Y, Reeves R, Volk V, Roseberg R, Brewer E, Burke S, Nelkin JP (2001) Developing commercial phytoextraction technologies: practical considerations. S Afr J Sci 97:619–623

Anonymous (1990) NEA dumps on science art. Science 250:1515

Anonymous (1994) Nickel farm. Discover Magazine, Sept Issue, p 19

Baker AJM (1981) Accumulators and excluders—strategies in the response of plants to heavy metals. J Plant Nutr 3:643–654CrossRef

Baker AJM, Brooks RR (1989) Terrestrial higher plants which hyperaccumulate metal elements—a review of their distribution, ecology, and phytochemistry. Biorecovery 1:81–126

Baker AJM, Brooks RR, Reeves RD (1988) Growing for gold and copper and zinc (plants that accumulate metals). New Sci 1603:44–48

Baker AJM, Reeves RD, Hajar ASM (1994) Heavy metal accumulation and tolerance in British populations of the metallophyte Thlaspi caerulescens J. & C. Presl (Brassicaceae). New Phytol 127:61–68CrossRef

Baker AJM, Morel JL, Schwartz C (1997) Des plantes pour dépolluer les friches industrielles. Biofutur 69:30–33CrossRef

Bani A (2009) Phytoextraction du Ni dans les sols ultramafiques d’Albanie. Thèse de Doctorat, Institut National Polytechnique de Lorraine, Nancy, France

Bani A, Echevarria G, Sulce S, Morel JL, Mullai A (2007) In-situ phytoextraction of Ni by a native population of Alyssum murale on an ultramafic site (Albania). Plant Soil 293:79–89CrossRef

Bani A, Echevarria G, Mullaj A, Reeves R, Morel JL, Sulce S (2009) Nickel hyperaccumulation by Brassicaceae in serpentine soils of Albania and Northwestern Greece. Northeast Nat 16:385–404CrossRef

Bani A, Plavlova D, Echevarria G, Mullaj A, Reeves RD, Morel JL, Sulce S (2010) Nickel hyperaccumulation by the species of Alyssum and Thlaspi (Brassicaceae) from the ultramafic soils of the Balkans. Bot Serbica 34:3–14

Bani A, Imeri A, Echevarria G, Pavlova D, Reeves RD, Morel JL, Sulçe S (2013) Nickel hyperaccumulation in the serpentine flora of Albania. Fresen Environ Bull 22:1792–1801

Bani A, Echevarria G, Sulce S, Morel JL (2015a) Improving the agronomy of Alyssum murale for extensive phytomining: a five-year field study. Int J Phytoremediation 17:117–127CrossRef

Bani A, Echevarria G, Zhang X, Benizri E, Laubie B, Morel JL, Simonnot M-O (2015b) The effect of plant density in nickel-phytomining field experiments with Alyssum murale in Albania. Aust J Bot 63:72–77

Barbaroux R, Meunier N, Mercier G, Taillard V, Morel JL, Simonnot M-O, Blais JF (2009) Chemical leaching of nickel from the seeds of the metal hyperaccumulator plant Alyssum murale. Hydrometallurgy 100:10–14CrossRef

Barbaroux B, Mercier G, Blais JF, Morel JL, Simonnot M-O (2011) A new method for obtaining nickel metal from the hyperaccumulator plant Alyssum murale. Sep Sci Technol 83:57–65

Barbaroux R, Plasari E, Mercier G, Simonnot M-O, Morel JL, Blais JF (2012) A new process for nickel ammonium disulfate production from ash of the hyperaccumulating plant Alyssum murale. Sci Total Environ 423:111–119CrossRef

Blaylock MJ, Salt DE, Dushenkov S, Zakharova O, Gussman C, Kapulnik Y, Ensley BD, Raskin I (1997) Enhanced accumulation of Pb in Indian mustard by soil-applied chelating agents. Environ Sci Technol 31:860–865CrossRef

Broadhurst CL, Chaney RL (2016) Growth and metal accumulation of an Alyssum murale nickel hyperaccumulator ecotype co-cropped with Alyssum montanum and perennial ryegrass in serpentine soil. Front Plant Sci 7:451. doi:10.3389/fpls.2016.00451 CrossRef

Brooks RR, Lee J, Reeves RD, Jaffré T (1977) Detection of nickeliferous rocks by analysis of herbarium specimens of indicator plants. J Geochem Explor 7:49–57CrossRef

Brooks RR, Chambers MF, Nicks LJ, Robinson BH (1998) Phytomining. Trends Plant Sci 3:359–362CrossRef

Brooks R, Anderson C, Stewart R, Robinson B (1999) Phytomining: growing a crop of a metal. Biologist 46:201–205

Cannon HL (1960) Botanical prospecting for ore deposits. Science 132:591–598CrossRef

Chaîneau CH, Morel JL, Oudot J (1995) Microbiological degradation in soil microcosms of fuel oil hydrocarbons from drilling cuttings. Environ Sci Technol 29:1615–1621CrossRef

Chaîneau CH, Morel JL, Oudot J (2000) Biodegradation of fuel oil hydrocarbons in the rhizosphere of maize (Zea mays L.) J Environ Qual 29:569–578CrossRef

Chaney RL (1973) Crop and food chain effects of toxic elements in sludges and effluents. In: Proceedings of joint conference on recycling municipal sludges and effluents on land. National Association of State Universities and Land-Grant College, Washington, DC, pp 120–141

Chaney RL (1983a) Plant uptake of inorganic waste constituents. In: Parr JF, Marsh PB, Kla JM (eds) Land treatment of hazardous wastes. Noyes Data Corp, Park Ridge, NJ, pp 50–76

Chaney RL (1983b) Potential effects of waste constituents on the food chain. In: Parr JF, Marsh PB, Kla JM (eds) Land treatment of hazardous wastes. Noyes Data Corp, Park Ridge, NJ, pp 152–240

Chaney RL (1993) Zinc phytotoxicity. In: Robson AD (ed) Zinc in soils and plants. Kluwer Academic, Dordrecht, pp 135–150CrossRef

Chaney RL, Hornick SB, Sikora LJ (1981a) Review and preliminary studies of industrial land treatment practices. In: Proceedings of seventh annual research symposium on land disposal of municipal solid and hazardous waste and resource recovery. EPA-600/9-81-002b, pp 200–212

Chaney RL, Kaufman DD, Hornick SB, Parr JF, Sikora LJ, Burge WD, Marsh PB, Willson GB, Fisher RH (1981b) Review of information relevant to land treatment of hazardous wastes. Report to US-EPA Solid and Hazardous Waste Research Division, 476 p

Chaney RL, Angle JS, Baker AJM, Li Y-M (1998) Method for phytomining of nickel, cobalt and other metals from soil. US Patent 5,711,784

Chaney RL, Brown SL, Li Y-M, Angle JS, Stuczynski TI, Daniels WL, Henry CL, Siebielec G, Malik M, Ryan JA, Compton H (2002) Progress in risk assessment for soil metals, and in-situ remediation and phytoextraction of metals from hazardous contaminated soils. In: Proceedings of US-EPA conference ‘Phytoremediation: state of the science’, 1–2 May 2000, Boston, MA

Chaney RL, Kukier U, Siebielec G (2003) Risk assessment for soil Ni, and remediation of soil-Ni phytotoxicity in situ or by phytoextraction. In: Proceedings of Sudbury-2003 (Mining and the Environment III), 27–31 May 2003. Laurentian University, Sudbury, ON, Canada, 43p

Chaney RL, Angle JS, Broadhurst CL, Peters CA, Tappero RV, Sparks DL (2007) Improved understanding of hyperaccumulation yields commercial phytoextraction and phytomining technologies. J Environ Qual 36:1429–1433CrossRef

Chaney RL, Baklanov IA (2017) Phytoremediation and phytomining: status and promise. Adv Bot Res 83:189–221

Chaney, RL, Baklanov IA, Ryan TC, Davis AP (2017) Effect of soil volume on Ni hyperaccumulation from serpentine soil by Alyssum corsicum. Int J Phytoremed (In press)

Chaney RL, Reeves RD, Baklanov IA, Centofanti T, Broadhurst CL, Baker AJM, Angle JS, van der Ent A, Roseberg RJ (2014) Phytoremediation and phytomining: using plants to remediate contaminated or mineralized environments, Chap. 15. In: Rajakaruna N, Boyd RS, Harris T (eds) Plant ecology and evolution in harsh environments. Nova Science, New York, pp 365–391

Chardot V, Massoura ST, Echevarria G, Reeves R, Morel JL (2005) Phytoextraction potential of the nickel hyperaccumulators Leptoplax emarginata and Bornmuellera tymphaea. Int J Phytoremediation 7:323–335CrossRef

Chardot-Jacques V, Calvaruso C, Simon B, Turpault MP, Echevarria G, Morel JL (2013) Chrysotile dissolution in the rhizosphere of the nickel hyperaccumulator Leptoplax emarginata. Environ Sci Technol 47:2612–2620CrossRef

De Kimpe C, Morel JL (2000) Urban soils: a growing concern. Soil Sci 165:31–40CrossRef

Deng THB, Cloquet C, Tang YT, Sterckeman T, Echevarria G, Estrade N, Morel JL, Qiu RL (2014) Nickel and zinc isotope fractionation in hyperaccumulating and nonaccumulating plants. Environ Sci Technol 48:11926–11933CrossRef

Deng THB, Tang YT, van der Ent A, Sterckeman T, Echevarria G, Morel JL, Qiu RL (2016) Nickel translocation via the phloem in the hyperaccumulator Noccaea caerulescens (Brassicaceae). Plant Soil 404:35–45CrossRef

Du RJ, He EKI, Tang YT, PJ H, Ying RR, Morel JL, Qiu RL (2011) How phytohormone IAA and chelator EDTA affect lead uptake by Zn/Cd hyperaccumulator Picris divaricata? Int J Phytoremediation 13:1024–1036CrossRef

Durand A, Piutti S, Rue M, Morel JL, Echevarria G, Benizri E (2016) Improving nickel phytoextraction by co-cropping hyperaccumulator plants inoculated by plant growth promoting rhizobacteria. Plant Soil 399:179–192CrossRef

Echevarria G, Morel JL, Fardeau JC, Leclerc-Cessac E (1998) Assessment of phytoavailability of nickel in soils. J Environ Qual 27:1064–1070CrossRef

Ernst WHO (1974) Schwermetallvegetation der Erde. Fisher, Stuttgart Germany

Ernst WHO (1975) Physiology of heavy metal resistance in plants. In: Symposium proceedings, International conference on heavy metals in the environment Vol II (Part 1). University of Toronto, Toronto, Canada, pp 121–136.

Ernst WHO (1996) Bioavailability of heavy metals and decontamination of soils by plants. Appl Geochem 11:163–167CrossRef

Ernst WHO (2000) Commentary: Evolution of metal hyperaccumulation and phytoremediation hype. New Phytol 146:357–358CrossRef

Estrade N, Cloquet C, Echevarria G, Sterckeman T, Deng T, Tang YT, Morel JL (2015) Weathering and vegetation controls on nickel isotope fractionation in surface ultramafic environments (Albania). Earth Planet Sci Let 423:24–35CrossRef

Fardeau JC (1981) Cinétiques de dilution isotopique et phosphore assimilable des sols. Thèse Doc, Etat, Paris VI

Fardeau JC, Guiraud G, Hétier JM (1979) Etude au moyen de ¹⁵N, ³²P, ⁶⁵Zn, ¹⁰⁹Cd et ²⁰³Hg de quelques limites d’utilisation en agriculture de boues résiduaires. In: Alexandre D and Ott H (eds) First European symposium on treatment and use of sewage sludge, Cadarache, pp 383–390

Faucon M-P, Shutcha MN, Meerts P (2007) Revisiting copper and cobalt concentrations in supposed hyperaccumulators from SC Africa: influence of washing and metal concentrations in soil. Plant Soil 301:29–36CrossRef

Gérard E, Echevarria G, Sterckeman T, Morel JL (2001) Cadmium availability to three plant species varying in Cd accumulation pattern. J Environ Qual 29:1117–1123CrossRef

Harris AT, Naidoo K, Nokes J, Walker T, Orton F (2009) Indicative assessment of the feasibility of Ni and Au phytomining in Australia. J Clean Prod 17:194–200CrossRef

Huang JW, Cunningham SD (1996) Lead phytoextraction: species variation in lead uptake and translocation. New Phytol 134:75–84CrossRef

Iwamoto A (1999) Restoration of Cd-polluted paddy fields in the Jinzu River basin—Progress and prospects of the restoration project. In: Nogawa K, Kurachi M, Kasuya M (eds) Advances in the prevention of environmental cadmium pollution and countermeasures. Eiko Laboratory, Kanazawa, pp 179–183

Jaffré T, Schmid M (1974) Accumulation du nickel par une Rubiacée de Nouvelle Calédoniea: Psychotria douarrei (G. Beauvisage) Däniker. C R Acad Sci Paris 278:D1727–D1730

Jaffre T (1979) Accumulation due manganese par les Proteacees de Nouvelles-Caledonie. C R Acad Sci Paris Ser D 289:425–428

Jiang CA, QT W, Sterckeman T, Schwartz C, Sirguey C, Ouvrard S, Perriguey J, Morel JL (2010) Co-planting can phytoextract similar amounts of cadmium and zinc to mono-cropping from contaminated soils. Ecol Eng 36:391–395CrossRef

Jiang CA, QT W, Goudon R, Echevarria G, Morel JL (2015) Biomass and metal yield of co-cropped Alyssum murale and Lupinus albus. Aust J Bot 63:159–166

Kukier U, Chaney RL (2000) Remediating Ni-phytotoxicity of contaminated muck soil using limestone and hydrous iron oxide. Can J Soil Sci 80:581–593CrossRef

Kukier U, Chaney RL (2001) Amelioration of Ni phytotoxicity in muck and mineral soils. J Environ Qual 30:1949–1960CrossRef

Kukier U, Chaney RL (2004) In situ remediation of Ni-phytotoxicity for different plant species. J Plant Nutr 27:465–495CrossRef

Kukier U, Peters CA, Chaney RL, Angle JS, Roseberg RJ (2004) The effect of pH on metal accumulation in two Alyssum species. J Environ Qual 32:2090–2102CrossRef

Kumar PBAN, Dushenkov V, Motto H, Raskin I (1995) Phytoextraction: the use of plants to remove heavy metals from soils. Environ Sci Technol 29:1232–1238CrossRef

Larsen S (1952) The use of ³²P in studies on the uptake of phosphorus by plants. Plant Soil 4:1–10CrossRef

Leblanc M, Petit D, Deram A, Robinson BH, Brooks RR (1999) The phytomining and environmental significance of hyperaccumulation of thallium by Iberis intermedia from southern France. Econ Geol 94:109–114CrossRef

Li Y-M, Chaney RL, Brewer EP, Angle JS, Nelkin JP (2003a) Phytoextraction of nickel and cobalt by hyperaccumulator Alyssum species grown on nickel-contaminated soils. Environ Sci Technol 37:1463–1468CrossRef

Li Y-M, Chaney RL, Brewer E, Roseberg RJ, Angle JS, Baker AJM, Reeves RD, Nelkin J (2003b) Development of a technology for commercial phytoextraction of nickel: economic and technical considerations. Plant Soil 249:107–115CrossRef

Losfeld G, Escande V, Jaffré T, L’Huillier L, Grison C (2012) The chemical exploitation of nickel phytoextraction: an environmental, ecologic and economic opportunity for New Caledonia. Chemosphere 89:907–910CrossRef

Mench M, Morel JL, Guckert A (1986) Metal binding of high molecular weight soluble exudates from maize (Zea mays L.) roots. Biol Fertil Soils 3:165–169CrossRef

Miller RJ, Koeppe DE (1971) Accumulation and physiological effects of lead in corn. Trace Subst Environ Health 4:186–193

Minguzzi C, Vergnano O (1948) Il contenuto di nichel nelle ceneri di Alyssum bertolonii (Nickel content of the ash of Alyssum bertolonii) (in Italian). Atti della Societa Toscana Scienze Naturali, Pisa, Memorie Serie A 55:49–74

Montarges-Pelletier E, Chardot V, Echevarria G, Michot LJ, Bauer A, Morel JL (2008) Identification of nickel chelators in three hyperaccumulating plants: an XR spectroscopic study. Phytochemistry 69:1695–1709CrossRef

Morel JL (1977) Evolution des boues des stations d’épuration dans les sols. Thèse Docteur Ingénieur, Université de Nancy 1, Nancy, France

Morel JL (1985) Transfert sol-plante des métaux lourds: le rôle des mucilages racinaires. Thèse Doctorat d’Etat, Institut National Polytechnique de Lorraine, Nancy, France

Morel JL (1997) Bioavailability of trace elements to terrestrial plants, Chap 6. In: Tarradellas J, Bitton G, Rossel D (eds) Soil ecotoxicology. Lewis, CRC, Boca Raton, FL, pp 141–176

Morel JL (2012) In: Amouroux J, Blin E, Coquery M, Fontecave M, Goffé B, Guéritte F, Martin Ruel S, Monsan P, Morel JL, Rohmer M, Rupp-Dahlem C, Sanchez C, Soussana JF, Villenave E (eds) La phytoremédiation des sols contaminés: des plantes pour guérir… les sols. EDP Sciences, Collection Chimie et Nature, 300p. ISBN: 978-2-7598-0754-3

Morel JL (2013) Using plants to “micro-mine” metals. http://www.inra.fr/en/Scientists-Students/Biomass/All-the-news/Using-plants-to-micro-mine-metals

Morel JL, Guckert A (1984) Evolution en plein champ de la solubilité dans DTPA des métaux lourds du sol introduits par des épandages de boues urbaines chaulées. Agronomie 4:377–386CrossRef

Morel JL, Mench M, Guckert A (1986) Measurement of Pb²⁺, Cu²⁺ and Cd²⁺ binding with mucilage exudates from maize (Zea mays L.) roots. Biol Fertil Soils 2:29–34CrossRef

Morel JL, Pierrat JC, Guckert A (1988) Effet et arrière-effet de l’épandage de boues urbaines conditionnées à la chaux et au chlorure ferrique sur la teneur en métaux lourds d’un maïs. Agronomie 8:107–113CrossRef

Moskvitch K (2014) Feature article, ‘Good to grow’. New Scientist, London, 22 Mar 2014, pp 47–49

Murakami M, Nakagawa F, Ae N, Ito M, Arao T (2009) Phytoextraction by rice capable of accumulating Cd at high levels: reduction of Cd content of rice grain. Environ Sci Technol 43:5878–5883CrossRef

Nicks LJ, Chambers MF (1995) Farming for metals. Mining Environ Manage 15–18 (Sept Issue)

Nicks LJ, Chambers MF (1998) A pioneering study of the potential of phytomining for nickel. In: Brooks RR (ed) Plants that hyperaccumulate heavy metals. CAB International, pp 313–326

Nkrumah PN, Baker AJM, Chaney RL, Erskine PD, Echevarria G, Morel JL, van der Ent A (2016) Current status and challenges in developing Ni phytomining: an agronomic perspective. Plant Soil 406:55–69CrossRef

Parr JF, Marsh PB, Kla JM (eds) (1983) Land treatment of hazardous wastes. Noyes Data Corp, Park Ridge, NJ

Perronnet K, Schwartz C, Gérard E, Morel JL (2000) Availability of cadmium and zinc accumulated in the leaves of Thlaspi caerulescens incorporated into soil. Plant Soil 227:257–263CrossRef

Perronnet K, Schwartz C, Morel JL (2003) Distribution of cadmium and zinc in the hyperaccumulator Thlaspi caerulescens grown on multicontaminated soil. Plant Soil 249:19–25CrossRef

Pilon-Smits E, Pilon M (2002) Phytoremediation of metals using transgenic plants. Crit Rev Plant Sci 21:439–456CrossRef

Rascio N (1977) Metal accumulation by some plants growing on zinc-mine dumps. Oikos 29:250–253CrossRef

Raskin I, Kumar PBAN, Dushenkov S (1994) Phytoremediation of metals. US Patent 5,364,451

Rees F, Germain C, Sterckeman T, Morel JL (2015) Plant growth and metal uptake by a non-hyperaccumulating species (Lolium perenne) and a Cd-Zn hyperaccumulator (Noccaea caerulescens) in contaminated soils amended with biochar. Plant Soil 395:57–73CrossRef

Rees F, Sterckeman T, Morel JL (2016) Root development of non-accumulating and hyperaccumulating plants in metal-contaminated soils amended with biochar. Chemosphere 182:1–196

Reeves RD, Brooks RR (1983) Hyperaccumulation of lead and zinc by two metallophytes from mining areas of central Europe. Environ Pollut A31:277–285CrossRef

Reeves RD, Brooks RR, Macfarlane RM (1981) Nickel uptake by California Streptanthus and Caulanthus with particular reference to the hyperaccumulator S. polygaloides Gray (Brassicaceae). Am J Bot 68:708–712CrossRef

Reeves R, Schwartz C, Morel JL, Edmondson J (2001) Distribution and metal-accumulating behavior of Thlaspi caerulescens and associated metallophytes in France. Int J Phytoremediation 3:145–172CrossRef

Robinson B, Ferandez J-E, Madejón P, Marañon T, Murillo JM, Green S, Clothier B (2003) Phytoextraction: an assessment of biogeochemical and economic viability. Plant Soil 249:117–125CrossRef

Robinson BH, Bañuelos G, Conesa HM, Evangelou MWH, Schulin R (2009) The phytomanagement of trace elements in soil. Crit Rev Plant Sci 28:240–266CrossRef

Rodrigues J, Houzelot V, Ferrari F, Echevarria G, Laubie B, Morel JL, Simonnot M-O, Pons MN (2016) Life cycle assessment of agromining chain highlights role of erosion control and bioenergy. J Clean Prod 139:770–778CrossRef

Ruttens A, Boulet J, Weyens N, Smeets K, Adriaensen K, Meers E, Van Slycken S, Tack F, Meiresonne L, Thewys T, Witters N, Carleer R, Dupae J, Vangronsveld J (2011) Short rotation coppice culture of willows and poplars as energy crops on metal contaminated agricultural soils. Int J Phytoremediation 13(Suppl 1):194–207

Saison C, Schwartz C, Morel JL (2004) Hyperaccumulation of metals by Thlaspi caerulescens as affected by root development and Cd-Zn/Ca-Mg interactions. Int J Phytoremediation 6:49–61CrossRef

Schwartz C (1997) Phytoextraction des métaux des sols pollués par la plante hyperaccumulatrice Thlaspi caerulescens. Thèse de Doctorat, Institut National Polytechnique de Lorraine, Nancy, France

Schwartz C, Morel JL, Saumier S, Whiting SN, Baker AJM (1999) Root development of the Zn-hyperaccumulator plant Thlaspi caerulescens as affected by metal origin, content and localization in soil. Plant Soil 208:103–115CrossRef

Schwartz C, Guimont S, Saison C, Perronnet K, Morel JL (2001a) Phytoextraction of Cd and Zn by the hyperaccumulator Thlaspi caerulescens as affected by plant size and origin. S Afr J Sci 97:561–564

Schwartz C, Perronnet K, Gérard E, Morel JL (2001b) Measurement of in situ phytoextraction of zinc by spontaneous metallophytes growing on a former smelter site. Sci Total Environ 279:215–221CrossRef

Schwartz C, Echevarria G, Morel JL (2003) Phytoextraction of cadmium with Thlaspi caerulescens. Plant Soil 249:27–35CrossRef

Schwartz C, Sirguey C, Peronny S, Reeves RD, Bourgaud F, Morel JL (2006) Testing of outstanding individuals of Thlaspi caerulescens for Cd phytoextraction. Int J Phytoremediation 8:339–357CrossRef

Shallari S (1997) Biodisponibilité du nickel du sol pour l’hyperaccumulateur Alyssum murale . Thèse de Doctorat, Institut National Polytechnique de Lorraine, Nancy, France

Shallari S, Schwartz C, Hasko A, Morel JL (1998) Heavy metals in soils and plants of serpentine and industrial sites of Albania. Sci Total Environ 209:133–142CrossRef

Shallari S, Echevarria G, Schwartz C, Morel JL (2001) Availability of nickel in soils for the hyperaccumulator Alyssum murale (Waldst. & Kit.). S Afr J Sci 97:568–570

Siebielec G, Chaney RL, Kukier U (2007) Liming to remediate Ni contaminated soils with diverse properties and a wide range of Ni concentration. Plant Soil 299:117–130CrossRef

Simmons RW, Chaney RL, Angle JS, Kruatrachue M, Klinphoklap S, Reeves RD, Bellamy P (2015) Towards practical cadmium phytoextraction with Noccaea caerulescens. Int J Phytoremediation 17:191–199CrossRef

Sinaj S, Mächler F, Frossard E (1999) Assessment of isotopically exchangeable zinc in polluted soils and non polluted soils. Soil Sci Soc Am J 63:1618–1625CrossRef

Sirguey C, Schwartz C, Morel JL (2006) Response of Thlaspi caerulescens to nitrogen, phosphorus and sulfur fertilisation. Int J Phytoremediation 8:149–161CrossRef

Sterckeman T, Douay F, Proix N, Fourrier H (2000) Vertical distribution of Cd, Pb and Zn in soils near smelters in the North of France. Environ Pollut 107:377–389CrossRef

Sterckeman T, Perriguey J, Cael M, Schwartz C, Morel JL (2004) Applying a mechanistic model to cadmium uptake by Zea mays and Thlaspi caerulescens: consequence on the assessment of the soil quantity and capacity factors. Plant Soil 262:289–302CrossRef

Sommellier L, Morel JL, Morel C, Wiart J, Fardeau JC (1996) La valeur phosphatée des boues résiduaires des stations d’épuration urbaines. In: Ademe (ed) Collection Valorisation agricole des boues d’épuration. ISBN 2-86817-151-6

Tang YT, Cloquet C, Sterckeman T, Echevarria G, Carignan J, Qiu R, Morel JL (2012a) Fractionation of stable zinc isotopes in the field-grown zinc hyperaccumulator Noccaea caerulescens and the zinc-tolerant plant Silene vulgaris. Environ Sci Technol 46:9972–9979

Tang YT, Deng THB, QH W, Wang SZ, Qiu RL, Wei ZB, Guo XF, QT W, Lei M, Chen TB, Echevarria G, Sterckeman T, Simonnot M-O, Morel JL (2012b) Designing cropping systems for metal-contaminated sites: a review. Pedosphere 22:470–488CrossRef

Tang L, Ying RR, Jiang D, Zeng XW, Morel JL, Tang YT, Qiu RL (2013) Impaired leaf CO₂ diffusion mediates Cd-induced inhibition of photosynthesis in the Zn/Cd hyperaccumulator Picris divaricata. Plant Physiol Biochem 73:70–76CrossRef

Tang YT, Cloquet C, Deng THB, Sterckeman T, Echevarria G, Yang WJ, Morel JL, Qiu RL (2016) Zinc isotope fractionation in the hyperaccumulator Noccaea caerulescens and the nonaccumulating plant Thlaspi arvense at low and high Zn supply. Environ Sci Technol 50:8020–8027CrossRef

van der Ent A, Baker AJM, Van Balgooy MMJ, Tjoa A (2013) Ultramafic nickel laterites in Indonesia (Sulawesi, Halmahera): mining, nickel hyperaccumulators and opportunities for phytomining. J Geochem Explor 128:72–79CrossRef

Van der Ent A, Baker AJM, Reeves RD, Chaney RL, Anderson C, Meech J, Erskine PD, Simonnot M-O, Vaughan J, Morel JL, Echevarria G, Fogliani B, Mulligan D (2015) ‘Agromining’: farming for metals in the future? Environ Sci Technol 49(8):4773–4780CrossRef

Vaughan J, Riggio J, Chen J, Pen H, Harris HH, van der Ent A (2017) Characterisation and hydrometallurgical processing of nickel from tropical agromined bio-ore. Hydrometallurgy 169:346–355CrossRef

Wang AS, Angle JS, Chaney RL, Delorme TA, Reeves RD (2006) Soil pH effects on uptake of Cd and Zn by Thlaspi caerulescens. Plant Soil 281:325–337CrossRef

Wild H (1970) Geobotanical anomalies in Rhodesia. 3. The vegetation of nickel-bearing soils. Kirkia 7(Suppl):1–62

Wu QT, Deng JC, Long XX, Morel JL, Schwartz C (2006) Selection of appropriate organic additives for enhancing Zn and Cd phytoextraction by hyperaccumulators. J Environ Sci China 18:1113–1118CrossRef

Wu QT, Hei L, Wong JWC, Schwartz C, Morel JL (2007) Co-cropping for phyto-separation of zinc and potassium from sewage sludge. Chemosphere 60:1954–1960CrossRef

Ying RR, Qiu RL, Tang YT, PJ H, Qiu H, Chen HR, Shi TH, Morel JL (2010) Cadmium tolerance of carbon assimilation enzymes and chloroplast in Zn/Cd hyperaccumulator Picris divaricata. J Plant Physiol 167:81–87CrossRef

Zhang X, Houzelot V, Bani A, Morel JL, Echevarria G, Simonnot M-O (2014) Selection and combustion of Ni-hyperaccumulators for the phytomining process. Int J Phytoremediation 16:1058–1072CrossRef

Titel: The Long Road to Developing Agromining/Phytomining
verfasst von: Rufus L. Chaney
Alan J. M. Baker
Jean Louis Morel
Verlag: Springer International Publishing
Buch: Agromining: Farming for Metals
Print ISBN: 978-3-319-61898-2

Electronic ISBN: 978-3-319-61899-9

Copyright-Jahr: 2018
DOI: https://doi.org/10.1007/978-3-319-61899-9_1