The paramagnetic spectral response of the intermediate-valence compound CeN
i has been studied by inelastic neutron scattering on isotopically (Ni-60)
enriched single-crystal and powder samples. At low temperature (T similar t
o 10 K), no magnetic intensity was found up to an energy E approximate to 1
5 meV, indicating a spin-gap-like response. The absence of detectable quasi
elastic scattering in high-resolution time-of-flight spectra provides clear
evidence for the formation of a singlet ground state due to electron corre
lations. The magnetic response measured at T = 11K on the single crystal co
nsists of (i) a broad structureless contribution, extending beyond 60 meV,
which is a characteristic feature of valence-fluctuating materials, and (ii
) two extra narrow peaks at about 18 and 34 meV, which exist for practicall
y all Q vectors investigated, and whose intensities vary as a function of b
oth the reduced q vector and the direction in reciprocal space. This behavi
or is quite unusual among intermetallic intermediate-valence compounds. It
implies that the mixed-valence state in CeNi cannot be described by a singl
e-ion Anderson model, and that magnetic correlations should be taken into a
ccount. The extra peaks are tentatively related to crystal-field interactio
ns, which are of the same order of magnitude here as the Kondo temperature.