An electron capture detector is used in some gas chromatography systems.

Alvarez went on to study electron capture in gallium-67 and other nuclides.

Electron capture can be used in conjunction with chemical ionization.

This involves electron capture or positron decay of potassium-40 to argon-40.

This is also evident from phenomena like electron capture.

These may still reach a lower energy state, by the equivalent process of electron capture and neutrino emission.

Other sources may also include beta decay from cobalt-60 and electron capture from copper-60.

Double electron capture is a decay mode of atomic nucleus.

Electron capture is responsible for the remaining 4% of Ir decays.

The decay product resulting from electron capture is an isotope of copper.

The analyte concentration is thus proportional to the degree of electron capture.

It serves as a negative counter mode to Electron capture dissociation.

Its half-life is around 59 days and it decays by electron capture to an excited state of tellurium-125.

Inverse beta decay may also sometimes refer to the process normally called electron capture.

Possible sources include electron capture from copper-58 and EC + p from zinc-59.

This is electron capture, in which a nucleus absorbs an electron.

Electron capture in very dense parts of the infalling matter may produce additional neutrons.

There exist 35 naturally occurring isotopes that can undergo double electron capture.

Some common radioisotopes that decay by electron capture include:

The primary decay mode before the most abundant stable isotope V is electron capture.

Standards can be analyzed by gas chromatography with electron capture or mass spectrometric detection.

The Auger electrons can be applied in electron capture detectors for gas chromatography.

By changing the number of protons, electron capture transforms the nuclide into a new element.

Like all positron-emissing radioisotopes, F also has a probability to decay by electron capture.

Electron capture for almost all non-noble gas atoms involves the release of energy and thus are exothermic.