Indole in aqueous solution is photoionized near threshold following single photon absorption from a
femtosecond laser pulse at 260 nm. Transient absorption measurements are performed using a white-light
continuum probe pulse. Excited state absorption of neutral indole molecules is characterized accurately in
1-propanol where photoexcitation at 260 nm does not lead to photoionization. The presence of 0.75 M carbon
tetrachloride in a solution of indole/1-propanol leads to the formation of indole radical cations on a picosecond
time scale. While solvated electrons are formed in aqueous indole within our time resolution of 200 fs,
measurements of the transient absorbance out to 100 ps are flat and indicate that geminate recombination is
insignificant on this time scale. This result contrasts sharply with the geminate recombination dynamics observed
following the photoionization of neat water. This indicates that the bimolecular reaction between indole radical
cations and solvated electrons is considerably slower than the diffusion limit. We suggest that geminate
recombination arising from solute photoionization in polar solvents may be slower than previously thought.
High-efficiency light-driven hydrogen evolution from water was demonstrated by using poly(phenyleneethynylene) bearing negatively charged, [G3] poly(benzyl ether) dendrimeric side groups 3(L4) as photosensitizer. Three-dimensional wrapping of the conjugated backbone suppressed self-quenching of the photoexcited state, while methyl viologen (MV(2+)), a positively charged electron acceptor, was trapped on its negatively charged surface, to form a spatially separated donor-acceptor supramolecular complex. Studies with time-resolved fluorescence spectroscopy showed that the quenching rate constant (k(q) = 1.2 x 10(15) M(-1) s(-1)) is much greater than diffusion control rate constants. Upon excitation of 3(L4) in the presence of a mixture of MV(2+), triethanolamine (TEOA; sacrificial electron donor), and a colloidal PVA-Pt, hydrogen evolution took place with an overall efficiency of 13%, 1 order of magnitude better than precedent examples. Comparative studies with several reference sensitizers showed that spatial isolation of the conjugated backbone and its long-range pi-electronic conjugation, along with electrostatic interactions on the exterior surface, play important roles in achieving the efficient photosensitized water reduction.
Laser flash photolysis (LFP) of perfluorophenyl azide
and perfluoro-4-biphenyl azide produces the
corresponding singlet nitrenes which were detected by their transient
absorptions at 330 and 350 nm,
respectively. The absolute rate constants of the fundamental
processes that consume the singlet nitrenes
(intersystem crossing, k
isc, rearrangement,
k
R; reaction with pyridine,
k
pyr) were determined by monitoring
the
decay of the singlet nitrene and by the growth of its reaction products
(ketenimine, triplet nitrene, or pyridine
ylide). In the case of singlet 4-perfluorobiphenylnitrene in
CH2Cl2
k
isc =
(2.2 ± 0.1) × 106 s-1,
k
R =
1013.2±0.2
exp[−(9400 ± 400)/RT]
s-1, and k
pyr =
109.06±0.15 exp[−(2400
± 200)/RT] M-1
s-1. In the case of singlet
perfluorophenylnitrene in CH2Cl2
k
isc = (1.05 ± 0.05) × 107
s-1, k
R =
1013.8±0.3 exp[−(8800 ±
400)/RT] s-1,
and k
pyr =
109.00±0.13 exp[−(1600
± 160)/RT] M-1
s-1.
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