Page personnelle
Thibault Sterckeman

Docteur en Sciences Agronomiques, HDR

Ingénieur de Recherche, INRA

Adresse postale
2, avenue de la Forêt de Haye
TSA 40602
F-54518 Vandoeuvre-lès-Nancy cedex
tél. +33 (0)3 83 59 58 66
fax +33 (0)3 83 59 57 91
thibault.sterckeman@univ-lorraine.fr

RECHERCHE

Mécanismes de la phytoaccumulation des éléments en traces.
L’objectif est de développer un modèle de culture de phytoextraction. Pour cela, il convient de décrire le développement et la croissance de plantes hyperaccumulatrices de métaux ainsi que la dynamique des éléments en traces (ET) dans leurs organes au cours de la culture. Il convient également de modéliser le flux des ET dans la rhizosphère, en prenant en compte les facteurs liés au sol et à la plante. L’approche est basée sur la modélisation de culture et des transports réactifs, le traçage isotopique et les cultures expérimentales de plein champ et en milieu contrôlé (en terre et en hydroponie) ; elle se concentre sur un élément, le cadmium. Les modèles végétaux sont le tabouret calaminaire (Noccaea caerulescens), hyperaccumulateur de cadmium, de nickel et de zinc, ainsi que le maïs. Les sorties finalisées sont, outre des outils d’évaluation de la phyto-disponibilité, des modèles de conception et de pilotage des cultures de phytoextraction.


EXPERTISE ET VALORISATION

1. Normalisation des méthodes d’évaluation de la qualité des sols
Expert auprès de l’AFNOR depuis 1989, il a présidé la Commission X 31-C "Qualité des Sols – Méthodes chimiques" de 1993 à 2008 et participe aux travaux de l’ISO TC 190 "Qualité du Sol" et du CEN TC 345 "Caractérisation des sols".

2. Évaluation des risques liés à la contamination des sols par les éléments en traces
Il a participé à l’évaluation de la contamination des sols autours d’usines métallurgiques dans le Nord de la France ainsi qu’à l’élaboration, à la demande de l’ADEME et de l’APCA, d’un guide pour l’établissement des demandes de dérogation pour l’épandage de boues sur les parcelles naturellement riches en éléments en traces.


RÉSUMÉ DE CARRIÈRE

Ingénieur agronome de la Faculté des Sciences Agronomiques de Gembloux (Belgique), il est entré à l’INRA en 1988, pour diriger le Laboratoire d’Analyses des Sols d’Arras, Unité d’une quarantaine de personnes réalisant des analyses de roches, sols et solutions pour les chercheurs de l’Institut et des demandeurs extérieurs.
Outre la gestion de l’Unité, il a mené des recherches méthodologiques sur l’évaluation de la qualité des sols, en particulier sur l’appréciation des contaminations par les éléments en traces. Ceci l’a conduit à des investigations sur le fond pédo-géochimique et la phytodisponibilité des éléments en traces. Il a ainsi initié et coordonné la réalisation du Référentiel Pédo-Géochimique de la région Nord-Pas de Calais. Il a également travaillé au développement de méthodes physico-chimiques et isotopiques d’évaluation de la phytodisponibilité des éléments en traces.

En 2000, il a rejoint le Laboratoire Sols et Environnement pour y poursuivre ses recherches et préparer une thèse de doctorat soutenue en 2004 et une Habilitation à Diriger des Recherches obtenue en 2008. Il a animé l'équipe "Phytoremédiation des sols contaminés" de sa création en 2006 jusqu'en 2012.


PUBLICATIONS CHOISIES

Sirguey, C., Seznec, G., Mahevas, T., Echevarria, G., Gonneau, C., Sterckeman, T., 2018. Soil trace metal content does not affect the distribution of the hyperaccumulator Noccaea caerulescens in the Vosges Mountains (France). Plant and Soil, en ligne.

Sterckeman, T., Gossiaux, L., Guimont, S., Sirguey, C., Lin, Z., 2018. Cadmium mass balance in French soils under annual crops: Scenarios for the next century. Science of The Total Environment, 639 1440-1452.

Jacobs, A., De Brabandere, L., Drouet, T., Sterckeman, T., Noret, N., 2018. Phytoextraction of Cd and Zn with Noccaea caerulescens for urban soil remediation: influence of nitrogen fertilization and planting density. Ecological Engineering, 116, 178-187.

Deng, T., van der Ent, A., Tang, Y.-T., Sterckeman, T., Echevarria, G., Morel, J.-L., Qiu, R.-L., 2018. Nickel hyperaccumulation mechanisms: a review on the current state of knowledge. Plant and Soil, 423, 1-11.

Schneider, A., Lin, Z., Sterckeman, T., Nguyen, C., 2018. Comparison between numeric and approximate analytic solutions for the prediction of soil metal uptake by roots. Example of cadmium. Science of the Total Environment, 619–620, 1194–1205.

Gonneau, C., Noret, N., Godé, C., Kitt, J., Sirguey, C., Sterckeman, T., Koch, M., Pauwels, M., 2017. Design and validation of sixteen single nucleotide polymorphism to investigate plastid DNA sequence variation in Noccaea caerulescens (Brassicaceae). Conservation Genetics Resources, 9, 67-71.

Sterckeman, T., Cazes, Y., Gonneau, C., Sirguey, C., 2017. Phenotyping 60 populations of Noccaea caerulescens provides a broader knowledge of variation in traits of interest for phytoextraction. Plant and Soil, 418, 523-540.

Jacobs, A., Drouet, T., Sterckeman, T., Noret, N., 2017. Phytoremediation of urban soils contaminated with trace metals using Noccaea caerulescens: comparing non-metallicolous populations to the metallicolous ‘Ganges’ in field trials. Environmental Science and Pollution Research, 24, 8176–8188.

Gonneau, C., Noret, N., Godé, C., Frérot, H., Sirguey, C., Sterckeman, T., Pauwels, M., 2017. Demographic history of the trace metal hyperaccumulator Noccaea caerulescens (J. Presl and C. Presl) F. K. Mey. in Western Europe. Molecular Ecology, 29, 904-922.

Tang, Y.-T., Cloquet, C., Deng, T.-H.-B., Sterckeman, T., Echevarria, G., Yang, W.-J., Morel, J.-L., Qiu, R.-L., 2016. Zinc isotope fractionation in the hyperaccumulator Noccaea caerulescens and the non-accumulating plant Thlaspi arvense at low and high Zn supply. Environmental Science and Technology, 50, 8020-8027.

Cornu, J.Y., Bakoto, R., Bonnard, O., Bussière, S., Coriou, C., Sirguey, C., Sterckeman, T., Thunot, S., Visse, M.I., Nguyen, C., 2016. Cadmium uptake and partitioning during the vegetative growth of sunflower exposed to low Cd2+ concentrations in hydroponics. Plant and Soil, 404, 263-275.

Deng, T., Tang, Y.-T., van der Ent, A., Sterckeman, T., Echevarria, G., Morel, J.-L., Qiu, R.-L., 2016. Nickel translocation via the phloem in the hyperaccumulator Noccaea caerulescens (Brassicaceae). Plant and Soil, 404, 35-45.

Dupuy, J., Leglize, P., Vincent, Q., Zelko, I., Mustin, C., Ouvrard, S., Sterckeman, T, 2016. Effect and localization of phenanthrene in maize roots. Chemosphere, en ligne.

Lin, Z., Schneider, A., Sterckeman, T., Nguyen, C., 2016. Ranking of mechanisms governing the phytoavailability of cadmium in agricultural soils using a mechanistic model. Plant Soil, 399, 89-107.

Rees, F., Sterckeman, T., Morel, J.L., 2016. Root development of non-accumulating and hyperaccumulating plants in metal-contaminated soils amended with biochar. Chemosphere, 142, 48-55.

Estrade, N., Cloquet, C., Echevarria, G., Sterckeman, T., Deng, T., Tang, Y.-T., Morel, J.-L., 2015. Weathering and vegetation controls on nickel isotope fractionation in surface ultramafic environments (Albania). Earth and Planetary Science Letters, 423, 24-35.

Sterckeman, T., Goderniaux, M., Sirguey, C., Cornu, J.-Y., Nguyen, C., 2015. Do roots or shoots control cadmium accumulation in the hyperaccumulator Noccaea caerulescens? Plant and Soil, 392, 87-99.

Rees, F., Germain, C., Sterckeman, T., Morel, J.L., 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 and Soil, 395, 57-73.

Dupuy, J, Ouvrard, S, Leglize, P, Sterckeman, T, 2015. Morphological and physiological responses of maize (Zea mays) exposed to sand contaminated by phenanthrene. Chemosphere 124, 110-115.

Ferret, C., Cornu, J.-Y., Elhabiri, M., Sterckeman, T., Braud, A., Jezequel, K., Lollier, M., Lebeau., T., Schalk, I. J, Geoffroy, V. A., 2015. Effect of pyoverdine supply on cadmium and nickel complexation and phytoavailability in hydroponics. Environmental Science and Pollution Research, 22, 2106-2116.

Laporte, M.A., Sterckeman, T., Dauguet, S., Denaix, L., Nguyen, C., 2015. Variability in cadmium and zinc shoot concentration in 14 cultivars of sunflower (Helianthus annuus L.) as related to metal uptake and partitioning. Environmental and Experimental Botany, 109, 45-53.

Deng, T., Cloquet, Tang, Y.-T., C., Sterckeman, T., Echevarria, G., Estrade, N., Morel, J.-L., Qiu, R.-L., 2014. Nickel and zinc isotope fractionation in hyperaccumulating and non-accumulating plants. Environmental Science and Technology, 48, 11926?11933.

Gonneau, C., Genevois, N., Frérot, H., Sirguey, C., Sterckeman, T., 2014. Variation of trace metal accumulation, major nutrient uptake and growth parameters and their correlations in 22 populations of Noccaea caerulescens. Plant and Soil, 384, 271–287.

Lin, Z., Schneider, A., Nguyen, C., Sterckeman, T., 2014. Can ligand addition to soil enhance Cd phytoextraction? A mechanistic model study. Environmental Science and Pollution Research, 21, 12811–12826.

Lucisine, P., Echevarria, G., Sterckeman, T., Vallance, J., Rey, P., Benizri, E., 2014. Effect of hyperaccumulating plant cover composition and rhizosphere-associated bacteria on the efficiency of nickel extraction from soil. Applied Soil Ecology, 81, 30-36.

Ferret, C., Sterckeman, T; Cornu, J.-Y., Gangloff, S., Schalk, I. J, Geoffroy, V. A., 2014. Siderophore-promoted dissolution of smectite by fluorescent Pseudomonas. Environmental Microbiology Reports, 6, 459–467.

Custos, J.M., Moyne, C., Treillon, T., Sterckeman, T., 2014. Contribution of Cd-EDTA complexes to cadmium uptake by maize: a modelling approach. Plant and Soil, 374, 497-512.

Laporte, M.A., Denaix, L., Pagès, L., Sterckeman, T., Flenet, F., Dauguet, S., Nguyen, C., 2013. Longitudinal variation in cadmium influx in intact first order lateral roots of sunflower (Helianthus annuus L). Plant and Soil, 372, 581-595.

Lovy, L., Latt, D., Sterckeman, T., 2013. Cadmium uptake and partitioning in the hyperaccumulator Noccaea caerulescens exposed to constant Cd concentrations throughout complete growth cycles. Plant and Soil, 362, 345-354.

Raous, S., Echevarria, G., Sterckeman, T., Hanna, K. , Thomas F., Martins, E.S., Becquer, T., 2013. Potentially-toxic metals in ultramafic mining materials: identification of the main bearing and reactive phases. Geoderma, 192, 111-119.

Tang, Y.T., Cloquet, C., Sterckeman, T., Echevarria, G., Carignan, J., Qiu, R.L., Morel, J.L., 2012. Fractionation of stable zinc isotopes in the field-grown zinc hyperaccumulator Noccaea caerulescens and the zinc-tolerant plant Silene vulgaris. Environmental Science & Technology, 46, 9972?9979.

Zelko, I., Lux, A., Sterckeman, T., Martinka, M., Kollarova, K., Liskova, D., 2012. An easy method for cutting and fluorescent staining of thin roots. Annals of Botany, 110, 475-478.

Sterckeman, T., Redjala, T., Morel, J.L., 2011. Influence of exposure solution composition and of plant cadmium content on root cadmium short-term uptake. Environmental and Experimental Botany, 74, 131-139.

Redjala, T., Zelko, I., Sterckeman, T., Legué, V., Lux, A., 2011. Relationship between root structure and root cadmium uptake in maize. Environmental and Experimental Botany, 71, 241-248.

Redjala, T., Sterckeman, T., Morel, J.L., 2010. Determination of the different components of cadmium short-term uptake by roots. Journal of Plant Nutrition and Soil Science, 173, 935-945.

Raous, S., Becquer, T., Garnier, J., de Sousa Martins, É., Echevarria, G., Sterckeman, T., 2010. Mobility of metals in nickel mine spoil materials. Applied Geochemistry, 25, 1746-1755.

Bourennane, H., Douay, F., Sterckeman, T. Villanneau, E., Ciesielski, H., King, D., Baize, D. 2010. Mapping of anthropogenic trace elements inputs in agricultural topsoil from Northern France using enrichment factors. Geoderma, 157, 165-174.

Jiang, C-A, Wu, Q-T, Sterckeman, T., Schwartz, C., Sirguey, C., Ouvrard, S., Perriguey, J., Morel, J.L., 2010. Co-planting can phytoextract similar amounts of cadmium and zinc to mono-cropping from contaminated soils. Ecological Engineering, 36: 391-395.

Redjala, T., Sterckeman, T., Skiker, S., Echevarria, G., 2010. Contribution of apoplast and symplast to short term nickel uptake by maize and Leptoplax emarginata roots, Environmental and Experimental Botany, 68: 99-106.

Blossfeld, S., Perriguey, J., Sterckeman, T., Morel, J.L., Lösch, R., 2010. Rhizosphere pH dynamics in trace-metal-contaminated soils, monitored with planar pH optodes. Plant and Soil, 330, 173-184.

Sterckeman, T., Carignan, J., Srayeddin, I., Baize, D., Cloquet, 2009. Availability of soil cadmium using stable and radioactive isotope dilution. Geoderma, 153: 372-378.

Redjala, T., Sterckeman, T., Morel, J.L., 2009. Cadmium uptake by roots: contribution of apoplast and of high- and low-affinity membrane transport systems. Environmental and Experimental Botany, 67:235-242.

Perriguey, J., Sterckeman T., Morel, J. L., 2008. Effect of rhizosphere and plant related factors on the cadmium uptake by maize (Zea mays L.). Environmental and Experimental Botany, 63: 333-341.

Sterckeman, T., Douay, F., Baize, D., Fourrier, H., Proix, N., Schvartz, C., 2006. Trace elements in soils developed in sedimentary materials from northern France. Geoderma, 136: 912-929.

Cloquet C., Carignan J., Libourel G., Sterckeman T ., Perdrix E., 2006. Tracing source pollution in soils using cadmium and lead isotopes. Environmental Science and Technology, 40:2525-2530.

Sterckeman, T.
, Douay, F., Baize, D., Fourrier, H., Proix, N., Schwartz, C. and Carignan, J., 2005. Trace element distribution in soils developed in loess deposits from Northern France. European Journal of Soil Science, 57: 392-410.

Sterckeman, T., Duquene, L., Perriguey, J. and Morel, J.L., 2005. Quantifying the effect of rhizosphere processes on the availability of soil cadmium and zinc. Plant and Soil, 276: 335-345.

Sterckeman, T., Douay, F., Baize, D., Fourrier, H., Proix, N. and Schwartz, C., 2004. Factors affecting trace element concentrations in soils developed in recent marine deposits from northern France. Applied Geochemistry, 19: 89-103.

Sterckeman, T., Perriguey, J., Caël, M., Schwartz, C. and Morel, J.L., 2004. Applying a mechanistic model to cadmium uptake by Zea mays and Thlaspi caerulescens: Consequences for the assessment of the soil quantity and capacity factors. Plant and Soil, 262(1-2): 289-302.

Sterckeman, T., Douay, F., Proix, N., Fourrier, H. and Perdrix, E., 2002. Assessment of the contamination of cultivated soils by eighteen trace elements around smelters in the North of France. Water, Air, and Soil Pollution, 135: 173-194.

Baize, D. and Sterckeman, T., 2001. Of the necessity of knowledge of the natural pedo-geochemical background content in the evaluation of the contamination of soils by trace elements. The Science of the Total Environment, 264: 127-139.

Sterckeman, T., Douay , F., Proix, N. and Fourrier, H., 2000. Vertical distribution of Cd, Pb and Zn in soils near smelters in the North of France. Environmental Pollution, 107: 377-389.

Gérard, E., Echevarria, G., Sterckeman, T. and Morel, J.L., 2000. Cadmium availability to three plant species varying in cadmium accumulation pattern. Journal of Environmental Quality, 29: 1117-1123.

Lebourg, A., Sterckeman, T., Ciesielski, H. and Proix, N., 1998. Trace metal speciation in three unbuffered salt solutions used to assess their bioavailability in soil. Journal of Environmental Quality, 27: 584-590.

Tremel, A., Masson, P., Sterckeman, T., Baize, D., Mench, M., 1997. Thallium in French agrosystems - I. Thallium contents in arable soils. Environmental Pollution, 95, 293-302.

Lebourg, A., Sterckeman, T., Ciesielski, H. and Proix, N., 1996. Intérêt de différents réactifs d'extraction chimique pour l'évaluation de la biodisponibilité des métaux en traces des sols. Agronomie, 16: 201-205.

Lebourg, A., Sterckeman, T., Ciesielski, H., Proix, N. and Gomez, A., 1996. Estimation of soil trace metal bioavailability using unbuffered salt solutions: degree of saturation of polluted soil extracts. Environmental Technology, 19: 243-252.