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[1]  Wang B., Zeyen N.,Wilson S., Funk R., Turvey C.C. 2024. Quantifying the potential for mineral carbonation of processed kimberlite with the Rietveld-PONKCS method. American Mineralogist doi:

[2] Lockhart J., Power I.M., Paulo C., Stubbs A., Zeyen N., Wilson S., Steele-MacInnis M., Caldwell R., Gunning C. 2024 Weathering and cementation of historic kimberlite residues from South Africa: Implications for residue stabilization and CO2 sequestration, Science of the Total environment 959:177094, doi:

[3] Raudsepp M.J., Wilson S., Zeyen N., Arizaleta M.L., and Power I.M., 2024. Magnesite everywhere: Formation of carbonates in the alkaline lakes and playas of the Cariboo Plateau, British Columbia, Canada. Chemical Geology 648:121951, doi:

[4] Wang B., ´Ü±ð²â±ð²ÔÌý±·., Wilson S.A., Honda-McNeil M., von Gunten K., Alessi D., Jones T., Hamilton J., Paterson D., Southam G. 2024. Migration of transition metals and potential for carbon mineralization during acid leaching of processed kimberlite from Venetia diamond mine, South Africa, Applied Geochemistry, 105986, doi:

[5]  Carlos P., Power I.M., Zeyen N., Wang B., Wilson S. 2023. Geochemical modeling of CO2 sequestration in ultramafic mine wastes from Australia, Canada, and South Africa: Implications for carbon accounting and monitoring. Applied Geochemistry 152:105630, doi:

[6]  Stubbs A.R., Power I.M., Paulo C., Wang B., Zeyen N., Wilson S., Mervine E., Gunning C. 2023. Impact of wet-dry cycles on enhanced rock weathering of brucite, wollastonite, serpentinite and kimberlite: Implications for carbon verification. Chemical Geology 637:121674, doi:

[7]  Zhu B., Wilson, S.A. Raudsepp, M.J. Vessey, C.J., Zeyen N., Riechelmann S., Safarimohsenabad S., Snihur K.N., Wang B., Paulo C., Power I.M., Rostron B.J. Alessi, D.S. 2022. Accelerating mineral carbonation with hydraulic fracturing flowback and produced water as a feedstock for carbon dioxide removal. Applied Geochemistry 143:105380, doi:

°Ú8±ÕÌý Zeyen N., Wang B., Wilson S. A., Paulo C., Stubbs A.R., Power I., Steele-Maclnnis M., Lanzirotti A., Newville M., Paterson D.J., Hamilton J.L., Jones T.R., Turvey C.C., Dipple G., Southam G. 2022. Cation exchange in smectites as a new approach to mineral carbonation: characterization of the highly reactive clay fraction from the Venetia and Gahcho Kué diamond mines. Frontiers in Climate, 4:913632, doi:

[9]  Zhu B., Wilson S.A., Zeyen N., Raudsepp M.J., Wang B., Rostron B.J., Snihur K.N., von Gunten K., Harrison A.L., Alessi D.S. 2022. Hydraulic fracturing flowback and produced water as a feedstock for carbon dioxide removal or emissions reduction via mineral carbonation. Applied Geochemistry 142:105345, doi:

[10]  Marin-Carbonne J., Decraene M.-N., Havas R., Remusat L., Pasquier V., Alléon J., Zeyen N., Bouton A., Bernard S., Escrig S., Olivier N., Vennin E., Meibom A., Benzerara K., Thomazo C. 2022. Early precipitated micropyrite in microbialites: a time capsule of microbial sulfur cycling. Geochemical Perspective Letters, 21, 7-12, doi:

[11]  Stubbs R. A., Paulo C., Power I. M., Wang B., Zeyen N., Wilson S.A. 2022. Direct measurement of CO₂ drawdown in mine residues: Implications for enhanced rock weathering as a negative emission technology. International Journal of Greenhouse Gas Control, 113, 103554, doi:

°Ú12±ÕÌý Zeyen N., Benzerara K., Beyssac O., Daval D., Muller E., Thomazo C., Tavera R., Lopez-Garcia P., Moreira D.,Duprat E. 2021.Integrative analysis of the mineralogical and chemical composition of modern microbialites from ten Mexican lakes: what do we learn about their formation? Geochemica Cosmochemica Acta, 305, 148-184, doi:

[13]   C., PowerI., Stubbs A., Wang B., Zeyen N., Wilson S.A. 2021. Evaluating feedstocks for carbon dioxide removal by enhanced rock weathering and CO₂ mineralization. Applied Geochemistry, 129:104955. doi:

[14] Zeyen N., Benzerara K., Menguy N., Brest J., Templeton A.S., Webb S.M., Gérard E., Moreira D., López-García P., Tavera R., and Morin G. 2019. Fe bearing phases in modern lacustrine microbialites from Mexico. Geochemica Cosmochemica Acta, 253, 201:230. doi:

°Ú15±ÕÌýÌý Zeyen N. and Benzerara K. 2018. Modern and Fossil Stromatolites.In Importance of prokaryotes in the functioning and evolution of the present and past geosphere and biosphere, Prokaryotes and evolution, Bertrand J.-C., Normand P., Ollivier B., Sime-Ngando T. (eds), Springer. doi:

[16]   Stetten L., Mangeret A., Brest J., Seder-Colomina M., Le Pape P., Ikogou M., Zeyen N., Thouvenot A., Julien A., Alcade G., Reyss J.-L., Bombled B., Rabouille C., Olivi, L., Proux O., Cazala C., Morin G. 2018. Geochemical control on the reduction of U(VI) to mononuclear U(IV) species in lacustrine sediments. Geochimica Cosmochemica Acta, 222, 171-186. doi:

°Ú17±ÕÌýÌý Zeyen N., Benzerara K., Li J., Groleau A., Balan E., Robert J-L., Estève I., Tavera R., Moreira D., López-García P. 2015. Formation of low-T hydrated silicates in modern microbialites from Mexico and implications for microbial fossilization. Frontiers in Earth Science, 3:64. doi:

[18]   Iniesto M., Zeyen N., López-Archilla A.I., Bernard S., Buscalioni A.D., Guerrero M.C., Benzerara K. 2015. Preservation in microbial mats: mineralization by a talc-like phase of a fish embedded in a microbial sarcophagus. Frontiers in Earth Science, 3:51. doi:

[19]   Saghaï A., Zivanovic Y., Zeyen N.,Moreira D., Benzerara K., Deschamps P., Bertolino P., Ragon M., Tavera R., López-Archilla A.I., López-García P. 2015. Metagenome-based diversity analyses suggest a significant contribution of non-cyanobacterial lineages to carbonate precipitation in modern microbialites. Frontiers in Microbiology, 6:797. doi: