General information
            
            
                
                
                
                    
                        Organisation
                    
                    The French Alternative Energies and Atomic Energy Commission (CEA) is a key player in research, development and innovation in four main areas :
• defence and security,
• nuclear energy (fission and fusion),
• technological research for industry,
• fundamental research in the physical sciences and life sciences.
Drawing on its widely acknowledged expertise, and thanks to its 16000 technicians, engineers, researchers and staff, the CEA actively participates in collaborative projects with a large number of academic and industrial partners.
The CEA is established in ten centers spread throughout France
  
                
                
                    
                        Reference
                    
                    SL-DRF-26-0372  
                
        
                
                
                
                
             
	Direction
DRF
Thesis topic details
	Category
Condensed Matter Physics, chemistry, nanosciences
	Thesis topics
New concepts for cold neutron reflectors
	Contract
Thèse
	Job description
	The CEA and the CNRS have launched an initiative to design a new neutron source using low-energy proton accelerators, the ICONE project [1]. The goal is to build a facility that will provide an instrumental suite of about ten spectrometers available to the French and European scientific community. Neutron scattering experiments require thermal and cold neutrons. The design of the moderator is therefore a crucial component of the project to maximize the source's performance.
One avenue for improving the moderator performances is to enhance the efficiency of the reflector, and more specifically, the cold neutron reflector. In this study, we propose to investigate the specific scattering properties of cold neutrons on nanostructured materials. Indeed, cold neutrons have long wavelengths (> 0.4 nm) and can therefore be coherently scattered by nanostructured materials. Scattering efficiency is not only amplified by coherent scattering effects, but it is potentially possible to direct this scattering if the reflecting material is anisotropic. This control over the scattering direction can further increase the moderator's brightness.
The first part of the work will consist of identifying the most promising nanostructured materials and modeling their cold neutron reflectivity performance. In a second step, these materials will be shaped and their properties characterized using neutron scattering devices at neutron scattering facilities such as the ILL in Grenoble or the PSI in Switzerland.
 
	University / doctoral school
Ondes et Matière (EDOM)
Paris-Saclay
Thesis topic location
	Site
Saclay
Requester
	Position start date
01/10/2025
	Person to be contacted by the applicant
OTT Frédéric  Frederic.Ott@cea.fr
 Frederic.Ott@cea.fr
CEA
DRF/IRAMIS/LLB/INFRA
Laboratoire Léon Brillouin CEA/CNRS
CEA Saclay
91191 Gif sur Yvette
 01 69 08 61 21
 01 69 08 61 21
	Tutor / Responsible thesis director
OTT Frédéric  Frederic.Ott@cea.fr
 Frederic.Ott@cea.fr
CEA
DRF/IRAMIS/LLB/INFRA
Laboratoire Léon Brillouin CEA/CNRS
CEA Saclay
91191 Gif sur Yvette
 01 69 08 61 21
 01 69 08 61 21
	En savoir plus
https://iramis.cea.fr/llb/infra/
https://iramis.cea.fr/llb/
icone-neutron.fr