Unusual magneto-elastic forces stabilize the insulating ferromagnetic state of manganites: the La(0.8)Ca(0.2)MnO(3) case

The ferromagnetic and insulating state observed in La$_{1-x}$Ca$_{x}$MnO$_3$, 0.125$<$x$<$0.2, is characterized by structural and magnetic anomalies below T$_C$, similar to those observed in the x$_{Sr}$$\approx$1/8. A neutron scattering study of the superlattice {\bf Q$_0$}= (0,0,1+/4)$_{cub}$ peak, and of the magnetic excitations are reported in the x$_{Ca}$=0.2 sample. The occurrence of this superstructure is associated with the observation of a gap in the spin dynamics, at a {\bf q$_0$} wave-vector ({\bf q$_0$}={\bf Q$_0$}-$\tau$) with the same modulus $|${\bf q$_0$}$|$ in all directions, which divides the dispersion into two regimes. For $|${\bf q}$|$$<$$|${\bf q$_0$}$|$ the dispersion is splitted into two or three curves. For $|${\bf q}$|$$>$$|${\bf q$_0$}$|$, magnetic excitations lock on acoustic and optic phonon energies, revealing a new kind of magneto-vibrational coupling. We suggest an analysis in terms of two distinct magnetic couplings, associated with two ferromagnetic media involved into a collective state.