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pPb

pPb denotes proton-lead collisions, a high-energy nuclear collision in which a single proton beam collides with a beam of lead nuclei. Studied in collider experiments at CERN and elsewhere, pPb provides insight into quantum chromodynamics in cold nuclear matter and serves as a baseline for heavier systems. The center-of-mass energy per nucleon pair, sqrt(s_NN), for pPb at the LHC has been 5.02 TeV, with explorations at other energies. The system is inherently asymmetric because the proton and the lead ion carry different numbers of nucleons and beam energies.

Experiments such as ALICE, ATLAS, CMS, and LHCb measure particle production, jets, heavy-flavor hadrons, and quarkonia

pPb data help calibrate theoretical models of QCD in nuclei and test ideas about gluon density, energy

in
pPb
collisions.
The
aim
is
to
understand
initial-state
effects
in
the
nucleus,
such
as
nuclear
parton
distribution
functions
and
saturation,
and
to
separate
them
from
final-state
effects
seen
in
PbPb
collisions.
Observables
include
the
nuclear
modification
factor
RpPb,
rapidity-dependent
yields,
and
collective-like
azimuthal
correlations
observed
in
high-multiplicity
events,
which
have
sparked
discussion
about
possible
hot-medium
behavior
in
small
systems.
loss
in
cold
nuclear
matter,
and
parton
energy
transport.
While
overall
signatures
of
a
quark-gluon
plasma
are
weaker
than
in
PbPb,
certain
measurements
show
flow-like
patterns
and
particle
production
asymmetries
that
challenge
simple
interpretations,
prompting
ongoing
theoretical
and
experimental
work.
Ongoing
and
planned
pPb
programs
continue
to
refine
measurements
across
energy,
rapidity,
and
event
activity,
contributing
to
a
consistent
picture
of
nuclear
effects
in
high-energy
collisions.