Add to ORKGResonance energy transfer is a spectroscopic process whose relevance in all major areas of science is reflected both by a wide prevalence of the effect, and through numerous technical applications. It is an optical near field mechanism which effects a transportation of electronic excitation between physically distinct atomic or molecular components, based on transition dipole dipole coupling. In this chapter a comprehensive survey of the process is presented, beginning with an outline of the history and highlighting the early contributions of Perrin and Förster. A review of the photophysics behind resonance energy transfer follows, and then a discussion of some prominent applications of resonance energy transfer. Particular emphasis is give...
At distances beyond wavefunction overlap, and typically running up to 100 Å, the migration of electr...
Forster resonance energy transfer (FRET) is a photophysical process in which an electronically excit...
Electronically excited molecules interact with their neighbors differently from their ground-state c...
Resonance energy transfer, also known as Förster- or fluorescence- resonance energy transfer, or ele...
Resonance energy transfer (RET), the transport of electronic energy from one atom or molecule to ano...
Resonanceenergy transfer (RET) is the principal mechanism for the intermolecular or intramolecular r...
Resonance energy transfer is the primary mechanism for the migration of electronic excitation in the...
The process of laser-assisted resonance-energy transfer (LARET) is described and analyzed within the...
Understanding the molecular basics of recognition events in chemistry is crucial for a wide range of...
Theodor Förster (1910–1974) developed a phenomenological theory of nonradiative resonance ...
The process of radiationless energy transfer from a chromophore in an excited electronic state (the ...
Resonance energy transfer involving two identical donors and one acceptor is modelled by quantum ele...
Because of the sensitivity of the rate of Coulomb interaction induced long range resonance energy tr...
Resonance energy transfer (RET) is a complex phenomenon where energy is transferred between two non-...
A general theory is developed to identify the influence of local dipole fields on fluorescence and i...
At distances beyond wavefunction overlap, and typically running up to 100 Å, the migration of electr...
Forster resonance energy transfer (FRET) is a photophysical process in which an electronically excit...
Electronically excited molecules interact with their neighbors differently from their ground-state c...
Resonance energy transfer, also known as Förster- or fluorescence- resonance energy transfer, or ele...
Resonance energy transfer (RET), the transport of electronic energy from one atom or molecule to ano...
Resonanceenergy transfer (RET) is the principal mechanism for the intermolecular or intramolecular r...
Resonance energy transfer is the primary mechanism for the migration of electronic excitation in the...
The process of laser-assisted resonance-energy transfer (LARET) is described and analyzed within the...
Understanding the molecular basics of recognition events in chemistry is crucial for a wide range of...
Theodor Förster (1910–1974) developed a phenomenological theory of nonradiative resonance ...
The process of radiationless energy transfer from a chromophore in an excited electronic state (the ...
Resonance energy transfer involving two identical donors and one acceptor is modelled by quantum ele...
Because of the sensitivity of the rate of Coulomb interaction induced long range resonance energy tr...
Resonance energy transfer (RET) is a complex phenomenon where energy is transferred between two non-...
A general theory is developed to identify the influence of local dipole fields on fluorescence and i...
At distances beyond wavefunction overlap, and typically running up to 100 Å, the migration of electr...
Forster resonance energy transfer (FRET) is a photophysical process in which an electronically excit...
Electronically excited molecules interact with their neighbors differently from their ground-state c...