Abstract
We present neutron inelastic scattering measurements of the full three-dimensional spin-wave dispersion in
the multiferroic material BiFeO3 for temperatures from 5K to 700K. Despite the presence of strong electromagnetic
coupling, the magnetic excitations behave like conventional magnons over all parts of the Brillouin
zone. At low temperature the spin-waves are well-defined coherent modes, described by a classical model for
a G-type antiferromagnet. A softening of the spin-wave velocity and broadening in energy is already present
at room temperature, which is well below the N´eel temperature TN ∼ 640K, and increases on heating. In
addition, a strong hybridization of the Fe 3d and O 2p states is found to modify the distribution of the spin-wave
spectral weight significantly, which implies that the spins are not restricted to the Fe atomic sites as previously
believed.