Control of Excited-State Proton-Coupled Electron Transfer
by Ultrafast Pump-Push-Probe Spectroscopy in Heptazine-Phenol Complexes:
Implications for Photochemical Water Oxidation
posted on 2020-03-17, 12:05authored byKathryn
L. Corp, Emily J. Rabe, Xiang Huang, Johannes Ehrmaier, Mitchell E. Kaiser, Andrzej L. Sobolewski, Wolfgang Domcke, Cody W. Schlenker
We demonstrate chemical
tuning and laser-driven control of intermolecular
H atom abstraction from protic solvent molecules. Using multipulse
ultrafast pump-push-probe transient absorption (TA) spectroscopy,
we monitor hydrogen abstraction by a functionalized heptazine (Hz)
from substituted phenols in condensed-phase hydrogen-bonded complexes.
Hz is the monomer unit of the ubiquitous organic polymeric photocatalyst
graphitic carbon nitride (g-C3N4). Previously,
we reported that the Hz derivative 2,5,8-tris(4-methoxyphenyl)-1,3,5,6,7,9,9b-heptaazaphenalene (TAHz) can photochemically abstract
H atoms from water, in addition to exhibiting photocatalytic activity
for H2 evolution matching that of g-C3N4 in aqueous suspensions. In the present work, we combine ultrafast
multipulse TA spectroscopy with predictive wave function-based ab
initio electronic-structure calculations to explore the role of mixed nπ*/ππ* upper excited states in directing
H atom abstraction from hydroxylic compounds. We use an ultraviolet
(365 nm) laser pulse to photoexcite TAHz to a bright upper excited
state, and, after a relaxation period of roughly 6 ps, we use a near-infrared
(NIR) (1150 nm) pulse to “push” the chromophore from
the long-lived S1 state to a higher-lying excited state.
When phenol is present, the NIR push induces a persistent decrease
(ΔΔOD) in the S1 TA signal magnitude, indicating
an impulsively driven change in photochemical branching ratios. In
the presence of substituted phenols with electron-donating moieties,
the magnitude of ΔΔOD diminishes markedly due to the increased
excited-state reactivity of these complexes that accompanies the cathodic
shift in phenol oxidation potential. In the latter case, H atom abstraction
proceeds unaided by additional energy from the push pulse. These results
reveal new insight into branching mechanisms among unreactive locally
excited states and reactive intermolecular charge-transfer states.
They also suggest molecular design strategies for functionalizing
aza-aromatics to drive important photoreactions, such as H atom abstraction
from water. More generally, this study demonstrates an avidly desired
achievement in the field of photochemistry, rationally redirecting
excited-state reactivity with light.