Physique du bâtiment. Enveloppe du bâtiment. Matériaux poreux. Transport de masse et de chaleur. Bois. Modélisation. Milieu urbain. Déposition de la pluie. Rendement et dégradation.
Zhang C, Coasne B, Guyer R, Derome D, Carmeliet J. (2020). Moisture-Induced crossover in the thermodynamic and mechanical response of hydrophilic biopolymer, Cellulose, 27:89-99.
Zhou X, Desmarais G, Vontobel P, Carmeliet J, Derome D. (2020). Masonry brick-cement mortar interface resistance to water transport determined with neutron radiography and numerical modelling, J. Build. Phys., 44:251-271.
Chen M, Zhang C, Shomali A, Coasne B, Carmeliet J, Derome D. (2019). Wood-moisture relationships studied with molecular simulations - methodological guidelines, Forests, 10:628.
Chen M, Coasne B, Guyer R, Derome D, Carmeliet J. (2018). Role of hydrogen bonding in hysteresis observed in sorption-induced swelling of soft nanoporous polymers, Nature Communications, 9:3507.
Kubilay A, Derome D, Carmeliet J. (2018). Coupling of physical phenomena in urban microclimate: A model integrating air flow, wind-driven rain, radiation and transport in building materials, Urban Climate, 24:398-418.
Rafsanjani A, Stiefel M, Jefimovs K, Mokso R, Derome D, Carmeliet J. (2014). Hygroscopic swelling and shrinkage of latewood cell wall micropillars reveal ultrastructural anisotropy, J. Royal Society Interface, 11:20140126.
Kubilay A, Blocken B, Derome D, Carmeliet J. (2013). CFD simulation and validation of wind-driven rain on a building facade with an Eulerian multiphase model. Building and Environment 61: 69-81.
Patera A, Derome D, Griffa M, Carmeliet J (2013). Hysteresis in swelling and in sorption of wood tissue. Journal of Structural Biology, 182:226-234.
Derome, D., Griffa, M., Koebel, M., Carmeliet, J. (2011). “Hysteretic swelling of wood at cellular scale probed by phase contrast X-ray tomography”, J. Structural Biology, 173:180-190.