W. Fudickar et al., Fluorescence quenching and size selective heterodimerization of a porphyrin adsorbed to gold and embedded in rigid membrane gaps, J AM CHEM S, 121(41), 1999, pp. 9539-9545
Octaanionic meso-tetra(3,5-dicarboxylatophenyl) porphyrin 1 was adsorbed to
gold electrodes at pH 12 and stayed there after repeated washing with 10(-
2) M KOH. The fluorescence on sputtered gold surfaces amounted to 10% of th
e intensity observed on an organic subphase. Addition of 10(-6) M aqueous s
olutions of the manganese(III) complexes of an isomer mixture of tetracatio
nic beta-tetraethyl-beta'-tetrakis (1-methyl-4-pyridinium)- and meso-4-(1-m
ethyl-4-pyridinium)phenyl porphyrins 2 and 4 at pH 12 quenched the fluoresc
ence quantitatively. Visible spectroscopy proved that the amount of porphyr
in 1 on the gold surface had not changed. The octaanionic porphyrin 1 was t
hen embedded in a membrane by self-assembly of a bolaamphiphile containing
two secondary amide groups. Two hydrogen bond chains rigidify such a monola
yer. The emission of porphyrin 1 remained after the self-assembly process.
1 was now localized on the bottom of a rigid membrane gap. Its fluorescence
was again quantitatively quenched by the tetracationic manganese(III) porp
hyrinate 2, which fit in with the membrane gap. A larger manganese(III) por
phyrin with a phenyl spacer between the porphyrin and methyl pyridinium rin
gs could not enter, and no quenching was observed. The same experiment with
a more fluid membrane made of octadecanethiol showed no such discriminatin
g effect. The entrapment of 1,2 trans-cyclohexanediol within the "immobile"
water volume of the membrane gap is also reported. Water-soluble compounds
have thus been separated within a 2 nm(3) water volume from bulk water. So
far, the membrane pores with a porphyrin bottom resemble natural enzyme cl
efts.