Submitted / under review
[10] Ashley, A., Manthilake, G., Boulanger, M., Mookherjee, M., Bouhifd, A. (under review - Science Advances). Remote detection of the mobility of basaltic magma.
[9] Boulanger, M., Zhang C., France, L., Toussaint, A., Koepke J. (under revision - Contributions to Mineralogy and Petrology). Equilibrium and fractional crystallization of a tholeiitic magma at 0.2 GPa and implications for magmatic accretion at slow-spreading ridges.
Published
[8] Boulanger, M., Godard, M., Ildefonse, B., Bakouche*, M. A comparative study of mineral-melt interactions at Kane Megamullion and Atlantis Massif: Identifying universal processes building the slow-spreading lithosphere. Geochemistry, Geophysics, Geosystems, https://doi.org/10.1029/2023GC011409
[7] Boulanger, M., France, L. Cumulate formation and melt extraction from mush-dominated magma reservoirs: the “melt flush” process exemplified at mid-ocean ridges. Journal of Petrology, Invited contribution to Perspectives in Petrology. https://doi.org/10.1093/petrology/egad005
[6] Dhar, A., Ghosh, B., Bandyopadhyay, D., Morishita, T., Tamura, A., France, L., Nguyen, D.K., Boulanger, M., Koley, M., Roy, S., Chattopadhaya, S. (2022). The lower oceanic crust at ultraslow-spreading Southwest Indian Ridge: The inside story. Gondwana research. https://doi.org/10.1016/j.gr.2022.08.008
[5] Pieterek, B., Ciazela, J., Boulanger, M., Lazarov, M., Wegorzewski, A., Panczyk, M., Strauss, H., Dick, H.J.B., Muszynski, A., Koepke, J., Kuhn, T., Czupyt, Z., France, L. (2022). Sulfide enrichment along igneous layer boundaries in the lower oceanic crust: IODP Hole U1473A, Atlantis Bank, Southwest Indian Ridge. Geochimica et Cosmochimica Acta. https://doi.org/10.1016/j.gca.2022.01.004
[4] Boulanger, M., France, L., Ferrando, C., Ildefonse, B., Ghosh, B., Sanfilippo, A., Liu, C.-Z., Morishita, T., Koepke, J., Bruguier, O. (2021). Magma-mush interactions in the lower oceanic crust: Insights from Atlantis Bank layered series (Southwest Indian Ridge). JGR Solid Earth (Special issue: Ophiolites and Oceanic Lithosphere), https://doi.org/10.1029/2021JB022331
[3] Ferrando, C., France, L., Basch, V., Sanfilippo, A., Tribuzio, R., Boulanger, M. (2021). Grain size variations record segregation of residual melts in slow-spreading oceanic crust (Atlantis Bank; 57°E Southwest Indian Ridge). JGR Solid Earth. https://doi.org/10.1029/2020JB020997
[2] Boulanger, M., France, L., Deans, J., Ferrando, C., Lissenberg, C.J., von der Handt, A. (2020). Magma reservoir formation and evolution at a slow-spreading center (Atlantis Bank, Southwest Indian Ridge). Frontiers in Earth Science (Research Topic: Magma-Rock and Magma-Mush Interactions as Fundamental Processes of Magmatic Differentiation). https://doi.org/10.3389/feart.2020.554598
[1] Baudouin, C., France, L., Boulanger, M., Dalou, C., Devidal, J.-L. (2020). Trace element partitioning between clinopyroxene and alkaline magmas: role of M1 site on HREE enrichment in clinopyroxenes. Contributions to Mineralogy and Petrology. https://doi.org/10.1007/s00410-020-01680-6
Boulanger, M. (2021). Atlantis Bank et les systèmes magmatiques des dorsales à expansion lente. Géochronique n°159
Kelemen, P., Matter, J., Teagle, D., Coggon, J., The Oman Drilling Project Science Team, et al. Oman Drilling Project, Scientific Drilling in the Samail Ophiolite, Sultanate of Oman: Proceedings of the Oman Drilling Project. 2020, doi:10.14379/OmanDP.proc.2020
Boulanger, M. (2020). Le devenir des liquides au sein de la croûte océanique des dorsales à expansion lente : nouveaux apports de l’étude d’Atlantis Bank (dorsale Sud-Ouest Indienne). Manuscrit de thèse, Université de Lorraine, 262p.
Colin, S., Charles, N., Boulanger, M. (2016) - Gisements potentiels de sables verriers en Roumanie et Bulgarie. Etude bibliographique. Rapport final. BRGM/RC-66414-FR, 93 p.
Seminar 2025 - Geo-Ocean (Brest, France)
“Dynamics and evolution of oceanic crystal mushes: Experimental study of (dis)equilibrium magmatic processes at HP-HT”.
Solicited oral presentation - EGU General Assembly 2025
Session GMPV 2.2 - Deciphering the plutonic record at mid-ocean ridges: from crystal-scale processes to crustal-scale accretion
Seminar 2025 - LPG (Nantes, France)
“Understanding the dynamics of magmatic systems through the mineral record: Melt-mush reactions and differentiation at mid-ocean ridges”
Seminar Géosciences Marines 2025 - IPGP (Paris, France)
“Deciphering the mineral record at mid-ocean ridges: new perspectives on the dynamics of magmatic systems and their along-axis variability”
InterRidge France workshop 2023 - IPGP (Paris, France)
Invited ECR talk on "The dynamics of magmatic systems below mid-ocean ridges”
Seminar Magma Groupe 2021- ETH (Zürich, Switzerland, online)
Cumulate formation and melt extraction from mushy reservoirs: the “melt flush” model
[27] Boulanger, M., Médard, E., Laubier, M. (RST25). Evolution des mushes océaniques : expériences de déséquilibre en piston-cylindre à 200 MPa.
[26] Baudry, L.-L., Arbaret, L., Champallier, R., Précigout, J., Boulanger, M., Slodczyk, A. (EMPG25). Structure and mechanics of oceanic mafic mush: segregation of interstitial liquids and intracrystalline deformation.
[25] Boulanger, M., Médard, E., Laubier, M. (EMPG25). Crystal mush evolution in oceanic reservoirs: disequilibrium piston cylinder experiments at 300 MPa.
[24] Boulanger, M., et al. (EGU25 - invited). Deciphering the plutonic record at mid-ocean ridges: from crystal-scale processes to crustal-scale accretion. Session GMPV2.2
[23] Boulanger, M., Godard, M., Ildefonse, B., and Bakouche, M. (EGU24-7463). A comparative study of mineral-melt interactions at Kane Megamullion and Atlantis Massif: Identifying universal processes building the slow-spreading lithosphere.
[22] Boulanger, M., France, L. (Goldschmidt 2023). Consequences of melt-mush reactions on mush-dominated magma reservoirs: the melt flush process exemplified at mid-ocean ridges.
[21] Boulanger, M., Bakouche, M., Godard, M., Ildefonse, B. (Journées IODP France 2023). A comparative study of mineral-melt interactions at Kane Megamullion and Atlantis Massif: Identifying universal processes building the slow-spreading lithosphere.
[20] Boulanger, M., Médard, E., Zhang, C., France, L., Koepke, J. (EMPG 2023). The effect of mantle and mush assimilation on the crystallization path of MORB-type melts: IHPV and piston cylinder experiments at 200 and 250 MPa.
[19] Boulanger, M., France, L. (EGU 2022). Cumulate formation and melt extraction from mushy reservoirs: the "melt flush" model.
[18] Ferrando, C., Basch, V., Ildefonse, B., Deans, J., Sanfilippo, A., Tribuzio, R., Barou, F., Boulanger, M., France L. (Goldschmidt 2021). Microstructures of olivine gabbros from the Atlantis Bank OCC (57°E Southwest Indian Ridge) reveal compaction-driven melts extraction and accumulation in ultraslow-spread oceanic crust.
[17] Boulanger, M., France, L., Deans J, Ferrando, C., Lissenberg, J., and von der Handt, A. (EGU 2021). Formation and evolution of a magma reservoir at a slow-spreading center (Atlantis Bank, Southwest Indian Ridge).
[16] France, L., Boulanger, M. (EGU 2021). A new perspective on cumulate formation and melt extraction from mushy reservoirs: the "melt flush" model.
[15] France, L., Boulanger, M. (AGU 2020). Cumulate formation and melt extraction from mushy reservoirs: the “melt flush” model.
[14] Ferrando, C., France, L., Basch, V., Sanfilippo, A., Ildefonse, B., Tribuzio, R., Boulanger, M., Barou F. (AGU 2020). Compaction of crystal mush bodies aids extraction and accumulation of reactive melts throughout the ultraslow-spread oceanic crust at the Atlantis Bank OCC (SWIR): insights from grain-size variations in olivine gabbro.
[13] France, L., Ferrando, C., Basch, V., Sanfilippo, A., Boulanger, M., Tribuzio, R. & Deloule, E. (Goldschmidt 2020). Segregation of Migrating Reacted Melts Through the Ultraslow-Spreading Lower Oceanic Crust.
[12] Boulanger, M., France, L., Deans, J., Ferrando, C., Lissenberg, C.J., von der Handt, A. (AGU 2020). Magma reservoir formation and evolution at a slow-spreading center (Atlantis Bank, Southwest Indian Ridge).
[11] Baudouin, C., France, L., Boulanger, M., Dalou, C., Devidal, J.-L. (AGU 2020). Quantification of intraplate volcanism magmatic processes: New partition coefficients between minerals & alkaline melts.
[10] Boulanger, M., France, L., Deans, J., Ferrando, C. (Goldschmidt 2019). Emplacement and evolution of a mushy magma reservoir in the slow-spread lower oceanic crust.
[9] Ferrando, C., France, L., Boulanger, M. & Deloule, E. (Goldschmidt 2019). Record of Segregated Magma Modified by Reactive Porous Flow in Ultraslow-Spreading Oceanic Crust.
[8] Mollex, G., France, L., Boulanger, M. & Devidal, J.-L. (Goldschmidt 2019). Oldoinyo Lengai Natrocarbonatites Derive from Classical Calciocarbonatites: A Melt Inclusion Approach.
[7] Baudouin, C., France, L., Boulanger, M., Dalou, C. & Devidal, J.-L. (Goldschmidt2019). New Constraints on Trace Element Partitioning between Minerals & Alkaline Melts.
[6] Ciazela, J., Pieterek, B., Boulanger, M., Dick, H.J.B., France, L., Grabowska, M., Koepke, J., Kuhn, T., Muszynski, A., Strauss, H., and Wegorzewski, A. (EGU 2019). Sulfide differentiation at the lower oceanic crust with high magma supply: fractional crystallization and melt-rock reaction (IODP Hole U1473A, Atlantis Bank).
[5] Boulanger, M., France, L., Ferrando, C., Ildefonse, B. et al. (Goldschmidt 2019). Melt migration and interactions in the lower oceanic crust: insights from Atlantis Bank interlayered series at IODP Hole U1473A (Southwest Indian Ridge)
[4] France, L., Ferrando, C., Boulanger, M. (EGU 2019). Olivine gabbros from IODP Hole U1473A (SWIR, 57◦E): Record of reactive porous flow through ultraslow-spreading oceanic crust?
[3] Baudouin, C., France, L., Boulanger, M., Dalou, C. & Devidal, J.-L. (Goldschmidt 2018). Trace Element Partitioning between Clinopyroxene and Alkaline Magmas.
[2] Boulanger, M., France, L., Ildefonse, B., Ghosh, B., Sanfilippo, A., Liu, C., Morishita, T., Koepke, J. (Goldschmidt 2018 - 244). Origin of the Interlayered Series at Atlantis Bank (SWIR): New Insights on Lower Oceanic Crust Accretion Processes.
[1] France, L., Boulanger, M., Mollex, G. & Devidal, J.-L. (Goldschmidt 2017). Oldoinyo Lengai Natrocarbonatite Derives from Classical Calciocarbonatite.