C olumnar-to-E quiaxed T ransition in SOL idification Processing (CETSOL): a project of the E uropean S pace A gency (ESA) - M icrogravity A pplications P romotion (MAP) programme Ch.-A. Gandin 1,a , B. Billia 2 , G. Zimmermann 3 , D. J. Browne 4 , M.-D. Dupouy 5 , G. Guillemot 1 , H. Nguyen-Thi 2 , N. Mangelinck-Noël 2 , G. Reinhart 2 , L. Sturz 3 , S. Mc Fadden 4 , J. Banaszek 4 , Y. Fautrelle 5 , K. Zaidat 5 , A. Ciobanas 5 1 CEMEF, UMR CNRS-ENSMP 7635, Sophia Antipolis, F Formerly with LSG2M, UMR CNRS-INPL-UHP 7584, Nancy, F 2 L2MP, UMR CNRS-Université d'Aix-Marseille 6137, Marseille, F 3 ACCESS e.V., Aachen, D 4 University College Dublin, Dublin, IRL 5 EPM, UPR CNRS 9033, S t Martin d'Hères, F a Charles-Andre.Gandin@ensmp.fr Keywords : Solidification, metallic alloys, casting, grain structure, columnar-to-equiaxed transition, macrosegregation, microgravity Abstract. The main objective of the research project of the E uropean S pace A gency (ESA) - M icrogravity A pplication P romotion (MAP) programme entitled C olumnar-to-E quiaxed T ransition in SOL idification Processing (CETSOL) is the investigation of the formation of the transition from columnar to equiaxed macrostructure that takes place in casting. Indeed, grain structures observed in most casting processes of metallic alloys are the result of a competition between the growth of several arrays of dendrites that develop under constrained and unconstrained conditions, leading to the CET. A dramatic effect of buoyancy-driven flow on the transport of equiaxed crystals on earth is acknowledged. This leads to difficulties in conducting precise investigations of the origin of the formation of the equiaxed crystals and their interaction with the development of the columnar grain structure. Consequently, critical benchmark data to test fundamental theories of grain structure formation are required, that would benefit from microgravity investigations. Accordingly, the ESA-MAP CETSOL project has gathered together European groups with complementary skills to carry out experiments and to model the processes, in particular with a view to utilization of the reduced-gravity environment that will be afforded by the International Space Station (ISS) to get benchmark data. The ultimate objective of the research program is to significantly contribute to the improvement of integrated modelling of grain structure in industrially important castings. To reach this goal, the approach is devised to deepen the quantitative understanding of the basic physical principles that, from the microscopic to the macroscopic scales, govern microstructure formation in solidification processing under diffusive conditions and with fluid flow in the melt. Pertinent questions are attacked by well-defined model experiments on technical alloys and/or on model transparent systems, physical modelling at microstructure and mesoscopic scales (e.g. large columnar front or equiaxed crystals) and numerical simulation at all scales, up to the macroscopic scales of casting with integrated numerical models. Materials Science Forum Vol. 508 (2006) pp 393-404 Online available since 2006/Mar/15 at www.scientific.net © (2006) Trans Tech Publications, Switzerland doi:10.4028/www.scientific.net/MSF.508.393 All rights reserved. No part of contents of this paper may be reproduced or transmitted in any form or by any means without the written permission of TTP, www.ttp.net. (ID: 194.27.128.8, University of Newcastle, Callaghan, Australia-14/08/13,12:34:46)