Polarization measurements in optically detected electron spin resonance of excited triplet states at zero field

An optically detected electron-electron double rosonnnce (EEDOR) experiment is demonstrated on the triplet state of pyrimidinc by using two concentric microwave heIiees. EEDOR extends the use of opticaL detection methods in olxcrving zero field (z.f.) transitions between z.f. levels thnf are either

UPon excitation of a single crystal of CSO in the visible, microwave transitions have been detected optically in zero field. The transitions derive from triplet states and their frequencies verify that these states are delocalized over more than one C6,, molecule, as Previously inferred from EPR exp

Optically detected magnetic resonance (ODMR) techniques are used to determine the orbital asQnment of the phosphorescent triplet state of p-benzoquinone in the condensed phase. The principal spin-orbit coupl% routes are discussed in terms of the observed spin-vibronic activity.

Electron spin echo envelope modulation (ESEEM) has been stud- imposed (3, 4). Since commercial pulsed EPR spectromeied at zero and low magnetic fields (B °100 G) by means of ters normally operate at X-band frequencies (8-10 GHz), optically detected magnetic resonance. Qualitative differences of the

Conventional microwave and optically detected ESR of l,l-naphthyridine in a durcne host sir@ crystal is reported.