The microscopic property of magnetic vortices in the mixed state of a high-
quality CeRu2 crystal has been studied by muon spin rotation. We have found
that the spatial distribution of magnetic induction B(r) probed by muons i
s perfectly described by the London model for the triangular vortex lattice
with appropriate modifications to incorporate the high-field cutoff around
the vortex core and the effect of long-range defects in the vortex lattice
structure at lower fields. The vortex core radius is proportional to H(bet
a -1)/2 with beta similar or equal to0.53 (H being the magnetic field), whi
ch is in good agreement with the recently observed nonlinear field dependen
ce of the electronic specific heat coefficient gamma proportional toH(beta)
. In particular, the anomalous increase of magnetic penetration depth in ac
cordance with the peak effect in de magnetization (greater than or equal to
H*similar or equal to3 T at 2.0 K) has been confirmed; this cannot be expla
ined by the conventional pair-breaking effect due to magnetic field. In add
ition, the spontaneous enhancement of flux pinning, which is also associate
d with the peak effect, has been demonstrated microscopically. These result
s strongly suggest the onset of collective pinning induced by a new vortex
state having an anomalously enhanced quasiparticle density of states for H
greater than or equal toH*.