Investigation of the structure of the reaction center in photosynthetic systems by optical detection of triplet state magnetic resonance

By magnetic resonance es~criments on the phosphorescing triplet state of biacetyl in a 3-methytpentane glass the zero field splittings and the populating and depopulating rates of the individual triplet spin Ieveis have been me=ured. From these data an assignment of the zero field levels and mechani

A now method to obtain slow ~XSZXJC ODMR signals under othcrwisc impcdinz conditions is clcscribcd. 't'hc tcchnipuc is applied to identify the triplet state of DNA as thymino. 'The zero fictd splitting constants measured are I DI = (0.203 i 0.003) an-1 , and I El 7 (0.0123 t 0.0005) cm-l. From micro

The zero-lizld lluoresccnccdckctcd triplet state mpetlc reson3ncc spcctn hwc been obmincd for the pymchlorophyllidc a-apomyoglobm compln at 1 K The rnplct SICIIC zero-field sphltmgs Jnd spm sublevel dyn.mucs wcrc detcclcd on the rcsolwd features of the slrucrurcd lowtempcrzxture Iluoresccncc. Strucl

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.