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renormalization

Renormalization is a collection of techniques in quantum field theory and statistical physics that aims to remove or absorb infinities or scale dependence into redefined parameters so that predictions for physical quantities are finite and regulator-independent.

In perturbative quantum field theory, calculations often produce ultraviolet divergences. Renormalization introduces counterterms and renormalization constants

Renormalization group concepts describe how a theory changes with energy scale. Couplings become scale-dependent, known as

Fixed points of the renormalization group flow correspond to scale-invariant theories and determine critical behavior and

In quantum field theory, renormalizability means a finite set of parameters suffices to absorb divergences; nonrenormalizable

Applications include critical phenomena, phase transitions, lattice gauge theory, and the understanding of asymptotic freedom in

to
relate
bare
parameters
to
renormalized
ones
measured
at
a
chosen
momentum
scale.
Physical
observables
are
required
to
be
independent
of
the
regulator
and
of
the
specific
regularization
scheme
used.
running
couplings,
and
are
governed
by
beta
functions.
Wilson’s
approach
interprets
renormalization
as
coarse-graining:
integrating
out
short-distance
degrees
of
freedom,
rescaling
to
restore
the
cutoff,
and
following
the
flow
in
parameter
space.
This
flow
captures
how
theories
evolve
when
viewed
at
different
resolutions.
universality
classes
in
statistical
mechanics
and
phase
transitions.
terms
are
suppressed
at
low
energies
and
can
be
organized
within
effective
field
theories,
which
describe
physics
up
to
a
given
cutoff.
quantum
chromodynamics.
While
intermediate
steps
depend
on
the
renormalization
scheme
and
regulator,
physical
predictions
remain
scheme-independent.