Agromining for nickel: A complete chain that optimizes ecosystem services rendered by ultramafic landscapes

G. Echevarria; A.J.M. Baker; A. Bani; E. Benizri; A. Van der Ent; V. Houzelot; P. Kidd; B. Laubie; J.L. Morel; M.N. Pons; M.O. Simonnot; X. Zhang

Agromining for nickel: A complete chain that optimizes ecosystem services rendered by ultramafic landscapes

G. Echevarria^*, A.J.M. Baker, A. Bani, E. Benizri, A. Van der Ent, V. Houzelot, P. Kidd, B. Laubie, J.L. Morel, M.N. Pons, M.O. Simonnot, X. Zhang

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Conference paper › Academic › peer-review

Abstract

Serpentine (i.e. ultramafic) outcrops in Europe cover more than 10,000 km² and have a low-fertility and low-productivity, making them unattractive for traditional agriculture. In general, these areas are slowly abandoned by local farmers, affected by strong rural exodus and landscapes undergo a process of closure. However, ultramafic landscapes have the potential to provide multiple ecosystem services that can contribute to Europe’s goals towards insuring food security, production of renewable raw materials and renewable energy. Phytomining (agromining) aims at cultivating metal hyperaccumulator plants that are able to accumulate Ni and other strategic elements from metal-rich soils and transport them to the shoots (>1%), which can then be harvested as a bio-ore. Such metal-rich biomass can be used to recover highly valuable metals, e.g. nickel (Ni) and also to produce energy (heat, electricity). Nickel agromining can thus offer an eco-efficient alternative to classical pyro- or hydrometallurgical processes without disturbing the soil cover and the geology from soils and rocks that would be considered as low grade ores or sterile material for conventional mining methods. Phytomining agroecosystems can lead to better soil resource efficiency and can offer a fully integrated, new agromining agriculture that could cover thousands of km² in Europe, benefit local communities with a sustainable rural development and provide a wide array of ecosystem services which will need to be optimised under a life cycle assessment methodology: 1. Production of bio-sourced metal products 2. Production of energy biomass 3. Restoration of soil fertility for conventional agriculture (Ni stress) 4. Limiting Ni intake by local populations and farmers 5. Use and conservation of local biodiversity (plant and soil fauna and microflora) as cultivated ecosystems 6. Store carbon in cultivated soils 7. Enhance pollination activity at landscape level. Nickel agromining could therefore change the economical balance in historically-disadvantaged ultramafic regions of Europe.

Original language	English
Title of host publication	IMPC 2016 - 28th International Mineral Processing Congress
Publisher	Canadian Institute of Mining, Metallurgy and Petroleum
ISBN (Electronic)	9781926872292
Publication status	Published - 2016
Externally published	Yes
Event	28th International Mineral Processing Congress, IMPC 2016 - Quebec City, Canada Duration: 11 Sept 2016 → 15 Sept 2016

Publication series

Name	IMPC 2016 - 28th International Mineral Processing Congress
Volume	2016-September

Conference/symposium

Conference/symposium	28th International Mineral Processing Congress, IMPC 2016
Country/Territory	Canada
City	Quebec City
Period	11/09/16 → 15/09/16

Keywords

Agroecology
Fuel crops
Hydrometallurgy
Hyperaccumulator plants
Life cycle assessment
Phytomining

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Cite this

Echevarria, G., Baker, A. J. M., Bani, A., Benizri, E., Van der Ent, A., Houzelot, V., Kidd, P., Laubie, B., Morel, J. L., Pons, M. N., Simonnot, M. O., & Zhang, X. (2016). Agromining for nickel: A complete chain that optimizes ecosystem services rendered by ultramafic landscapes. In IMPC 2016 - 28th International Mineral Processing Congress (IMPC 2016 - 28th International Mineral Processing Congress; Vol. 2016-September). Canadian Institute of Mining, Metallurgy and Petroleum.

@inproceedings{7551d76da625417aaac1177350d946da,

title = "Agromining for nickel: A complete chain that optimizes ecosystem services rendered by ultramafic landscapes",

abstract = "Serpentine (i.e. ultramafic) outcrops in Europe cover more than 10,000 km2 and have a low-fertility and low-productivity, making them unattractive for traditional agriculture. In general, these areas are slowly abandoned by local farmers, affected by strong rural exodus and landscapes undergo a process of closure. However, ultramafic landscapes have the potential to provide multiple ecosystem services that can contribute to Europe{\textquoteright}s goals towards insuring food security, production of renewable raw materials and renewable energy. Phytomining (agromining) aims at cultivating metal hyperaccumulator plants that are able to accumulate Ni and other strategic elements from metal-rich soils and transport them to the shoots (>1%), which can then be harvested as a bio-ore. Such metal-rich biomass can be used to recover highly valuable metals, e.g. nickel (Ni) and also to produce energy (heat, electricity). Nickel agromining can thus offer an eco-efficient alternative to classical pyro- or hydrometallurgical processes without disturbing the soil cover and the geology from soils and rocks that would be considered as low grade ores or sterile material for conventional mining methods. Phytomining agroecosystems can lead to better soil resource efficiency and can offer a fully integrated, new agromining agriculture that could cover thousands of km2 in Europe, benefit local communities with a sustainable rural development and provide a wide array of ecosystem services which will need to be optimised under a life cycle assessment methodology: 1. Production of bio-sourced metal products 2. Production of energy biomass 3. Restoration of soil fertility for conventional agriculture (Ni stress) 4. Limiting Ni intake by local populations and farmers 5. Use and conservation of local biodiversity (plant and soil fauna and microflora) as cultivated ecosystems 6. Store carbon in cultivated soils 7. Enhance pollination activity at landscape level. Nickel agromining could therefore change the economical balance in historically-disadvantaged ultramafic regions of Europe.",

keywords = "Agroecology, Fuel crops, Hydrometallurgy, Hyperaccumulator plants, Life cycle assessment, Phytomining",

author = "G. Echevarria and A.J.M. Baker and A. Bani and E. Benizri and {Van der Ent}, A. and V. Houzelot and P. Kidd and B. Laubie and J.L. Morel and M.N. Pons and M.O. Simonnot and X. Zhang",

year = "2016",

language = "English",

series = "IMPC 2016 - 28th International Mineral Processing Congress",

publisher = "Canadian Institute of Mining, Metallurgy and Petroleum",

booktitle = "IMPC 2016 - 28th International Mineral Processing Congress",

address = "Canada",

note = "28th International Mineral Processing Congress, IMPC 2016 ; Conference date: 11-09-2016 Through 15-09-2016",

}

Echevarria, G, Baker, AJM, Bani, A, Benizri, E, Van der Ent, A, Houzelot, V, Kidd, P, Laubie, B, Morel, JL, Pons, MN, Simonnot, MO & Zhang, X 2016, Agromining for nickel: A complete chain that optimizes ecosystem services rendered by ultramafic landscapes. in IMPC 2016 - 28th International Mineral Processing Congress. IMPC 2016 - 28th International Mineral Processing Congress, vol. 2016-September, Canadian Institute of Mining, Metallurgy and Petroleum, 28th International Mineral Processing Congress, IMPC 2016, Quebec City, Canada, 11/09/16.

Agromining for nickel: A complete chain that optimizes ecosystem services rendered by ultramafic landscapes. / Echevarria, G.; Baker, A.J.M.; Bani, A. et al.
IMPC 2016 - 28th International Mineral Processing Congress. Canadian Institute of Mining, Metallurgy and Petroleum, 2016. (IMPC 2016 - 28th International Mineral Processing Congress; Vol. 2016-September).

Research output: Chapter in Book/Report/Conference proceeding › Conference paper › Academic › peer-review

TY - GEN

T1 - Agromining for nickel

T2 - 28th International Mineral Processing Congress, IMPC 2016

AU - Echevarria, G.

AU - Baker, A.J.M.

AU - Bani, A.

AU - Benizri, E.

AU - Van der Ent, A.

AU - Houzelot, V.

AU - Kidd, P.

AU - Laubie, B.

AU - Morel, J.L.

AU - Pons, M.N.

AU - Simonnot, M.O.

AU - Zhang, X.

PY - 2016

Y1 - 2016

N2 - Serpentine (i.e. ultramafic) outcrops in Europe cover more than 10,000 km2 and have a low-fertility and low-productivity, making them unattractive for traditional agriculture. In general, these areas are slowly abandoned by local farmers, affected by strong rural exodus and landscapes undergo a process of closure. However, ultramafic landscapes have the potential to provide multiple ecosystem services that can contribute to Europe’s goals towards insuring food security, production of renewable raw materials and renewable energy. Phytomining (agromining) aims at cultivating metal hyperaccumulator plants that are able to accumulate Ni and other strategic elements from metal-rich soils and transport them to the shoots (>1%), which can then be harvested as a bio-ore. Such metal-rich biomass can be used to recover highly valuable metals, e.g. nickel (Ni) and also to produce energy (heat, electricity). Nickel agromining can thus offer an eco-efficient alternative to classical pyro- or hydrometallurgical processes without disturbing the soil cover and the geology from soils and rocks that would be considered as low grade ores or sterile material for conventional mining methods. Phytomining agroecosystems can lead to better soil resource efficiency and can offer a fully integrated, new agromining agriculture that could cover thousands of km2 in Europe, benefit local communities with a sustainable rural development and provide a wide array of ecosystem services which will need to be optimised under a life cycle assessment methodology: 1. Production of bio-sourced metal products 2. Production of energy biomass 3. Restoration of soil fertility for conventional agriculture (Ni stress) 4. Limiting Ni intake by local populations and farmers 5. Use and conservation of local biodiversity (plant and soil fauna and microflora) as cultivated ecosystems 6. Store carbon in cultivated soils 7. Enhance pollination activity at landscape level. Nickel agromining could therefore change the economical balance in historically-disadvantaged ultramafic regions of Europe.

AB - Serpentine (i.e. ultramafic) outcrops in Europe cover more than 10,000 km2 and have a low-fertility and low-productivity, making them unattractive for traditional agriculture. In general, these areas are slowly abandoned by local farmers, affected by strong rural exodus and landscapes undergo a process of closure. However, ultramafic landscapes have the potential to provide multiple ecosystem services that can contribute to Europe’s goals towards insuring food security, production of renewable raw materials and renewable energy. Phytomining (agromining) aims at cultivating metal hyperaccumulator plants that are able to accumulate Ni and other strategic elements from metal-rich soils and transport them to the shoots (>1%), which can then be harvested as a bio-ore. Such metal-rich biomass can be used to recover highly valuable metals, e.g. nickel (Ni) and also to produce energy (heat, electricity). Nickel agromining can thus offer an eco-efficient alternative to classical pyro- or hydrometallurgical processes without disturbing the soil cover and the geology from soils and rocks that would be considered as low grade ores or sterile material for conventional mining methods. Phytomining agroecosystems can lead to better soil resource efficiency and can offer a fully integrated, new agromining agriculture that could cover thousands of km2 in Europe, benefit local communities with a sustainable rural development and provide a wide array of ecosystem services which will need to be optimised under a life cycle assessment methodology: 1. Production of bio-sourced metal products 2. Production of energy biomass 3. Restoration of soil fertility for conventional agriculture (Ni stress) 4. Limiting Ni intake by local populations and farmers 5. Use and conservation of local biodiversity (plant and soil fauna and microflora) as cultivated ecosystems 6. Store carbon in cultivated soils 7. Enhance pollination activity at landscape level. Nickel agromining could therefore change the economical balance in historically-disadvantaged ultramafic regions of Europe.

KW - Agroecology

KW - Fuel crops

KW - Hydrometallurgy

KW - Hyperaccumulator plants

KW - Life cycle assessment

KW - Phytomining

M3 - Conference paper

AN - SCOPUS:85048376976

T3 - IMPC 2016 - 28th International Mineral Processing Congress

BT - IMPC 2016 - 28th International Mineral Processing Congress

PB - Canadian Institute of Mining, Metallurgy and Petroleum

Y2 - 11 September 2016 through 15 September 2016

ER -

Echevarria G, Baker AJM, Bani A, Benizri E, Van der Ent A, Houzelot V et al. Agromining for nickel: A complete chain that optimizes ecosystem services rendered by ultramafic landscapes. In IMPC 2016 - 28th International Mineral Processing Congress. Canadian Institute of Mining, Metallurgy and Petroleum. 2016. (IMPC 2016 - 28th International Mineral Processing Congress).

Agromining for nickel: A complete chain that optimizes ecosystem services rendered by ultramafic landscapes

Abstract

Publication series

Conference/symposium

Keywords

UN SDGs

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