Excited state kinetics of anthracene-bridge-aniline intramolecular exciplexes.

We report on the synthesis and characterization of fluorescent halogen substituted anthracene-bridge-aniline (ABA) supermolecules that undergo structural reorganization on photoexcitation to form transient complexes. The syntheses were achieved in high yields on a large scale and the molecular structures were confirmed by single crystal X-ray diffraction. The photophysics of the ABA supermolecules were investigated using steady state and time resolved optical spectroscopy. Despite the presence of heavy atoms the series of ABA molecules have high quantum yields of fluorescence from both a locally excited anthracene state (LE) and an excited state complex (exciplex, EP) in non-polar solvents. The kinetics of the excited state processes were established in decalin from the time-resolved emission, and was shown to be strongly influenced by an electron-transfer state (ET). For quantitative studies of the excited state dynamics, the presence of this state required the development of a numerical three-excited-state kinetic model to replace the commonly used two-excited-state model. The experimental results shows that the reaction rates are strongly influenced both by substituents and solvent, illustrating the importance of including all relevant states in the kinetic modeling. Ultimately it is established that the excited state dynamics can conveniently be followed by optical methods, and the applicability of the system as a model system in time-resolved X-ray scattering experiments is discussed.

Structure of a short-lived excited state trinuclear Ag-Pt-Pt complex in aqueous solution by time resolved X-ray scattering.

The present communication describes the identification and structural characterization of a photo-induced transient trinuclear Ag-Pt-Pt complex, in which a pronounced internal structural change of the excited-state PtPOP moiety is observed upon complexation with the Ag ion.

Oligodeoxynucleotides containing alpha-L-ribo configured LNA-type C-aryl nucleotides.

Synthesis of 2[prime or minute]-O,4[prime or minute]-C-methylene-[small alpha]-l-ribofuranosyl derivatives containing phenyl and 1-pyrenyl aglycons, i.e., novel [small alpha]-l-ribo configured LNA-type C-aryl nucleosides, has been accomplished. Key synthetic steps included stereoselective Grignard reactions on tetrahydrofuran aldehyde, configurational inversion of the resulting alcohol into alcohol, and concomitant Mitsonobu cyclization furnishing the desired bicyclic furanosyl skeleton with a locked conformation. The phosphoramidite derivatives and were used for automated synthesis of 9-mer DNA and [small alpha]-L-LNA oligonucleotides containing the [small alpha]-L-LNA-type C-aryl monomers ([small alpha]L)Ph(L) and ([small alpha]L)Py(L) containing a phenyl and pyrenyl aglycon, respectively. Thermal denaturation studies showed universal base pairing behavior for the pyrenyl monomer ([small alpha]L)Py(L) when incorporated into a DNA or an [small alpha]-L-LNA oligonucleotide.