• Électronique et optique du futur › Nanomagnétisme et oxydes : spintronique, matériaux multiferroïques et nouveaux capteurs magnétiques
• Institut Rayonnement Matière de Saclay • IRAMIS: Saclay Institute of Matter and Radiation • UMR 3680 - Laboratory of Condensed Matter Physics (SPEC) • UMR 3680 - Service de Physique de l'Etat Condensé (SPEC)
• Laboratoire Nano-Magnétisme et Oxydes (LNO)
Figure 1. Illustration of the interplay between strain, magnetization and electric polarization. After N. A. Spaldin and M. Fiebig, Science 309 (2005) 391
The development of highly controllable oxide thin films growth and lithography techniques makes it possible to realize genuine materials stacking and nanostructures dedicated to spintronics applications like magnetic tunnel junctions, spin filters and more recently multiferroics. A renewed interest on ferroelectric materials has emerged for the development of nonvolatile random access memories and multiferroic materials. In multiferroics several ferroic orders can coexist and be eventually coupled, as for example ferroelectric, ferroelastic and/or ferro- (or antiferro-) magnetic long-range orders. The multiferroics class of materials has commonly been extended to anti-ferroics which show antiferromagnetic and antiferroelectric behaviors. Unfortunately, single phase multiferroics with ordering temperatures above 300 K are very seldom and artificial multiferroics are actively sought after. Defining and tailoring new operational multiferroic materials has, in recent years, emerged as an important topic in modern spintronics driven by numerous potential applications and fundamental physics issues such as the coupling between ferroelectric and magnetic orders and domain structures. This opens exciting new perspectives like the control of the magnetic state of an individual device by an electric field (and/or the control of the ferroelectric state by a magnetic field).
Artificial multiferroics can be realized following several routes: (i) doping a ferroelectric material with ferromagnetic ions, (ii) co-deposition and thermal treatments taking advantage of phase separation thermodynamics, (iii) the combination of ferroelectric and ferromagnetic materials in multilayered or nanostructured systems. The coupling between ferroelectricity and magnetism through interface bonding has been predicted theoretically for ferromagnetic/ferroelectric interfaces and was indeed observed in some systems. Additional magnetic exchange coupling using antiferromagnetic layer and strain coupling can be exploited as well.
The functioning principle of multiferroics dedicated to spintronics relies on a subtle interplay between structural strain, magnetization and electric polarization (figure 1). A fundamental understanding of multiferroic materials necessarily needs to address all these properties at the same time which requires the elaboration of single crystalline multiferroic model samples and experimental techniques or tools able to address each every aspect.
The laboratory has acquired expertise in growing epitaxial oxide thin films by atomic oxygen plasma assisted molecular beam epitaxy (AO-MBE). In particular of the ferroelectric perovskite barium titanate (BaTiO3) and ferrimagnetic spinel ferrites (ex. CoFe2O4) thin films, the former is an excellent and well-known ferroelectric material that displays remnant electric polarization higher than bulk crystals and the later class of materials presents a wide range of magnetic properties at room temperature.
In addition to classical laboratory characterizations, the model multiferroics materials are studied within a wide range of pertinent additional synchrotron radiation techniques allowing to access the structure (X-ray diffraction and absorption), the element specific or average magnetic properties (magnetic dichroism, spectromicroscopy) and electrical and magnetic domain structure (spectromicroscopy) that allows determining the electronic and crystalline structures as well as the ferroic orders.
"Croissance épitaxiale d’hétérostructures CoFe2O4 / BaTiO3 pour l’analyse de couplages magnéto-électriques " (Thomas Aghavnian), 2013-2016, supervisors: A. Barbier, R. Belkhou
"Films ultraminces épitaxiés de MnFe2O4, CoFe2O4 et NiFe2O4 pour le filtrage de spin à température ambiante", 2008-2011, (Sylvia Matzen) supervisor: J.-B. Moussy
"Propriétés et couplage d’échange dans le système modèle : Co/a-Fe2O3 (0001)" (Odile Bezencenet), 2005-2008, supervisor: A. Barbier
“Croissance de films multiferroïques artificiels de structure pérovskite” (Thomas Aghavnian), 2012; supervisor: A. Barbier
“Croissance et structure de films de BaTiO3“, (Amélie Joly), 2009; supervisor: A. Barbier
Aghavnian T., Moussy J.-B., Stanescu D., Belkhou R., Jedrecy N., Magnan H., Ohresser P., Arrio M.-A., Sainctavit Ph., Barbier A., “Determination of the cation site distribution of the spinel in multiferroic CoFe2O4 / BaTiO3 layers by X-ray photoelectron spectroscopy”, Journal of Electron Spectroscopy and Related Phenomena, 202 16-21 (2015)
Barbier A., Aghavnian T., Badjeck V., Mocuta C., Stanescu D., Magnan H., Rountree C. L., Belkhou R., Ohresser P., Jedrecy N., “Antiferromagnetic long range spin ordering in Fe and NiFe2 doped BaTiO3 multiferroic layers”, Physical Review B 91, 035417 (2015)
Jedrecy, N., Bardeleben H. J., Badjeck V., Demaille D., Stanescu D., Magnan H., Barbier A., “Strong magnetoelectric coupling in multiferroic Co/BaTiO3 thin films”, Physical Review B, 88, 121409 (2013)
C. Mocuta, A. Barbier, S. Stanescu, S. Matzen, J.-B. Moussy and E. Ziegler, X-ray diffraction imaging of metal-oxide epitaxial tunnel junctions made by optical lithography: use of focused and unfocused X-ray beams, J. Synchrotron Rad. 20 (2013) 355-365
Barbier A., Mocuta C., Stanescu D., Jegou P., Jedrecy N., Magnan H., “Surface composition of BaTiO3 /SrTiO3(001) films grown by atomic oxygen plasma assisted molecular beam epitaxy”, Journal of Applied Physics, 112, 114116 (2012)
S. Matzen, J.-B.Moussy, R. Mattana, F. Petroff, C. Gatel, B. Warot-Fonrose, J.C. Cezar, A. Barbier, M.-A. Arrio and Ph. Sainctavit,"Restoration of bulk magnetic properties by strain engineering in epitaxial CoFe2O4(001) ultrathin films", Appl. Phys. Lett. 99, 052514 (2011).
Odile Bezencenet, Daniel Bonamy, Rachid Belkhou, Philippe Ohresser, Antoine Barbier, "Origin and tailoring of the antiferromagnetic domain structure in a-Fe2O3 thin films unraveled by statistical analysis of dichroic spectromicroscopy (x-ray photoemission electron microscopy) images", Phys. Rev. Lett. 106, 107201 (2011)
Magnan H., Bezencenet O., Stanescu D., Belkhou R., Barbier A., “Beyond the Magnetic Domain Matching in Magnetic Exchange Coupling”, Physical Review Letters, 105, 9, 097204 (2010)
O. Bezencenet, H. Magnan, C. Mocuta, E. Fonda, S. Stanescu, P. Ohresser, R. Belkhou, and A. Barbier, “Multiscale investigation of the structure and morphology of the Co/Fe2O3(0001) interface”, Phys. Rev. B 81, 085419 (2010)