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isotoperesolution

Isotoperesolution refers to the ability of a measurement system to distinguish between peaks or signals arising from different isotopes of an element. In mass spectrometry and related analytical techniques, isotopic resolution means that peaks corresponding to isotopes with different masses can be spatially or temporally separated and accurately measured. Achieving isotoperesolution requires sufficient mass resolving power and precise mass calibration, particularly when isotopes differ by small mass differences.

In practice, resolution is often expressed as the mass resolving power, m/Δm, where Δm is the smallest

Applications of isotoperesolution span several fields. In proteomics and metabolomics, it enables accurate isotope-labeling experiments (for

Limitations include peak overlap from different species, low natural abundance of minor isotopes, instrumental noise, and

mass
difference
that
can
be
resolved
at
mass
m.
Isotopic
resolution
is
more
challenging
for
light
elements
with
small
mass
gaps
between
isotopes
and
at
higher
masses,
where
peaks
become
crowded.
Instruments
designed
for
high-resolution
measurements—such
as
Fourier-transform
ion
cyclotron
resonance
(FT-ICR)
mass
spectrometers,
Orbitrap
analyzers,
and
high-resolution
time-of-flight
(TOF)
systems—are
commonly
employed
when
isotopic
distinctions
are
critical.
Resolution
is
influenced
by
factors
including
instrument
design,
calibration,
scan
rate,
signal-to-noise,
and
sample
complexity.
example,
SILAC)
and
precise
quantification
of
isotopologues.
In
geochemistry
and
environmental
science,
it
supports
isotopic
ratio
measurements
and
the
determination
of
elemental
compositions.
Isotope-resolved
data
also
aid
in
studying
reaction
mechanisms,
tracing
chemical
pathways,
and
improving
the
accuracy
of
quantitative
analyses.
limited
dynamic
range
in
complex
mixtures.