internal conversion

Internal conversion energies are well below the main energy levels.

This occurs by means of a process called "ultrafast internal conversion".

Internal conversion coefficients can be looked up from tables, but this is time-consuming.

Several natural molecules perform a very fast internal conversion.

K line is a term used in Internal conversion electron spectroscopy.

Melanin is also a molecule with extremely fast internal conversion.

Internal conversion is a transition from a higher to a lower electronic state in a molecule or atom.

There are theoretical calculations that can be used to derive internal conversion coefficients.

Its internal conversion has been carried out to make as little alteration as possible to the 1906-08 phase of the building.

Also, no neutrino is emitted during internal conversion.

The internal conversion coefficient may be empirically determined by the following formula:

Internal conversions usually take place on a time scale of a few to tens of femtoseconds.

In applications that make use of bimolecular electron transfer the internal conversion is undesirable.

They were able to detect a new isomer, Sg, decaying by internal conversion into the ground state.

The transformation of excitation energy into harmless heat occurs via a photochemical process called internal conversion.

The internal conversion process competes with gamma decay.

The nucleus will eventually relax to its ground state through the emission of gamma rays or internal conversion electrons.

In DNA, this internal conversion is extremely fast-and therefore efficient.

Internal conversion electrons accompanying slow neutron capture in Gd.

Internal conversion coefficients are observed to increase for increasing atomic number (Z) and decreasing gamma-ray energy.

This should not be confused with the internal conversion process, in which no gamma ray photon is produced as an intermediate particle.

This process is known as internal conversion (IC).

The internal conversion and Auger electrons cause little damage outside the cell which contains the isotope atom.

Like internal conversion electrons, Auger electrons also emerge in a sharp energy peak.

Computer programs have been developed (see the BrIcc Program) which will present internal conversion coefficients quickly and easily.