isotopic$41133$ - significado y definición. Qué es isotopic$41133$
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Qué (quién) es isotopic$41133$ - definición

RELATIVE PROPORTION OF AN ISOTOPE AS FOUND IN NATURE; ABUNDANCE OF ISOTOPES OF A CHEMICAL ELEMENT AS NATURALLY FOUND ON A PLANET
Isotopic abundances; Isotopic Abundances; Natural isotopic abundance; Isotopic abundance; Isotope abundance; Isotopic ratio
  • Relative abundance of elements in the Earth's upper crust.

Isotopic labeling         
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  • Determining the percent of isotope labeling throughout a reaction. If a 50% labeled and 50% unlabeled metabolite is split in the manner shown, the expected percent of each outcome can be found. The blue circles indicate a labeled atom, while a white circle indicates an unlabeled atom.
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TECHNIQUE TO FOLLOW REACTIONS BY USING ATOMIC ISOTOPES
Isotopic Tracer; Isotopic tracer; Radioisotopic labelling; Radioisotopic labeling; Tracer element; Tracer Element; Isotopic label; Deuterium labeling; Isotopic labelling; Isotope labeling; Deuterated; Isotope scrambling; Radioactive marker; Radio labelling; Deuterium-labelling; Isotopic indicator; Isotonic label; Radiolabelled; Deuterium labelling; Radio-labeled; Singly labelled; Isotope affinity tags
Isotopic labeling (or isotopic labelling) is a technique used to track the passage of an isotope (an atom with a detectable variation in neutron count) through a reaction, metabolic pathway, or cell. The reactant is 'labeled' by replacing specific atoms by their isotope.
deuterated         
  • pmid=12785789}}</ref>
  • Determining the percent of isotope labeling throughout a reaction. If a 50% labeled and 50% unlabeled metabolite is split in the manner shown, the expected percent of each outcome can be found. The blue circles indicate a labeled atom, while a white circle indicates an unlabeled atom.
  • pmid=12753973 }}</ref>
TECHNIQUE TO FOLLOW REACTIONS BY USING ATOMIC ISOTOPES
Isotopic Tracer; Isotopic tracer; Radioisotopic labelling; Radioisotopic labeling; Tracer element; Tracer Element; Isotopic label; Deuterium labeling; Isotopic labelling; Isotope labeling; Deuterated; Isotope scrambling; Radioactive marker; Radio labelling; Deuterium-labelling; Isotopic indicator; Isotonic label; Radiolabelled; Deuterium labelling; Radio-labeled; Singly labelled; Isotope affinity tags
['dju:t?re?t?d]
(also deuteriated dju:'t??r?e?t?d)
¦ adjective Chemistry (of a compound) in which the ordinary isotope of hydrogen has been replaced with deuterium.
Derivatives
deuteration noun
Isotopomers         
ISOMER THAT IS AN ISOTOPE
Isotopic isomer; Isotopomers
Isotopomers or isotopic isomers are isomers with isotopic atoms, having the same number of each isotope of each element but differing in their positions. The result is that the molecules are either constitutional isomers or stereoisomers solely based on isotopic location.

Wikipedia

Natural abundance

In physics, natural abundance (NA) refers to the abundance of isotopes of a chemical element as naturally found on a planet. The relative atomic mass (a weighted average, weighted by mole-fraction abundance figures) of these isotopes is the atomic weight listed for the element in the periodic table. The abundance of an isotope varies from planet to planet, and even from place to place on the Earth, but remains relatively constant in time (on a short-term scale).

As an example, uranium has three naturally occurring isotopes: 238U, 235U, and 234U. Their respective natural mole-fraction abundances are 99.2739–99.2752%, 0.7198–0.7202%, and 0.0050–0.0059%. For example, if 100,000 uranium atoms were analyzed, one would expect to find approximately 99,274 238U atoms, approximately 720 235U atoms, and very few (most likely 5 or 6) 234U atoms. This is because 238U is much more stable than 235U or 234U, as the half-life of each isotope reveals: 4.468 × 109 years for 238U compared with 7.038 × 108 years for 235U and 245,500 years for 234U.

Exactly because the different uranium isotopes have different half-lives, when the Earth was younger, the isotopic composition of uranium was different. As an example, 1.7×109 years ago the NA of 235U was 3.1% compared with today's 0.7%, and that allowed a natural nuclear fission reactor to form, something that cannot happen today.

However, the natural abundance of a given isotope is also affected by the probability of its creation in nucleosynthesis (as in the case of samarium; radioactive 147Sm and 148Sm are much more abundant than stable 144Sm) and by production of a given isotope as a daughter of natural radioactive isotopes (as in the case of radiogenic isotopes of lead).