excitation energy

Excitation energy can be deposited in air by a number of different mechanisms:

This distribution is determined by the atomic excitation energies, and the local temperature.

I think the Z axis is excitation energy density.

Typical rotational excitation energies are on the order of a few cm.

This excitation energy transfer process is given by the reaction equations:

The excitation energy is obtained from recombination of oxidized and reduced species.

For quantitative good energy differences (excitation energies) one has to be careful in selecting the references.

Collisions with other atoms or molecules absorb the excitation energy and prevent emission.

The excitation energy is transformed into heat.

These excitation energies and inter-dot interactions are all functions of the applied field F.

Each of these internal degrees of freedom are assumed to be frozen out due to their relatively high excitation energy.

Eventually this excitation energy will exit somehow.

By this it is possible to calculate energy differences (excitation energies) with CI methods.

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

"On resonance transfer of excitation energy between aromatic aminoacids in proteins."

Hf has the highest excitation energy of any comparably long-lived isomer.

Much of current research in nuclear physics relates to the study of nuclei under extreme conditions such as high spin and excitation energy.

From this last equation it is possible to derive the excitation energies of the system, as these are simply the poles of the response function.

The most studied biochemical protective mechanism is non-photochemical quenching of excitation energy.

That is, if the excitation energy is 500 cm, then about 9 percent of the molecules are thermally excited at room temperature.

It has a nuclear isomer (or metastable state) with a remarkably low excitation energy of 7.6 eV.

Excitation energy transfer increases the population of the neon 2s and 3s levels manyfold.

A Coulomb explosion is a mechanism for coupling electronic excitation energy from intense electromagnetic fields into atomic motion.

This is sometimes observed as the creation of an island of inversion or in the reduction of excitation energy gaps above the traditional magic numbers.

The table below provides cross-sections and excitation energies for cold fusion reactions producing rutherfordium isotopes directly.