posted on 2016-05-12, 00:00authored byLiora Bliumkin, Rudraksha Dutta Majumdar, Ronald Soong, Antonio Adamo, Jonathan
P. D. Abbatt, Ran Zhao, Eric Reiner, André J. Simpson
Photochemistry
is a key environmental process directly linked to
the fate, source, and toxicity of pollutants in the environment. This
study explores two approaches for integrating light sources with nuclear
magnetic resonance (NMR) spectroscopy: sample irradiation using a
“sunlight simulator” outside the magnet versus direct
irradiation of the sample inside the magnet. To assess their applicability,
the in situ NMR photoreactors were applied to a series of environmental
systems: an atmospheric pollutant (p-nitrophenol),
crude oil extracts, and groundwater. The study successfully illustrates
that environmentally relevant aqueous photochemical processes can
be monitored in situ and in real time using NMR spectroscopy. A range
of intermediates and degradation products were identified and matched
to the literature. Preliminary measurements of half-lives were also
obtained from kinetic curves. The sunlight simulator was shown to
be the most suitable model to explore environmental photolytic processes
in situ. Other light sources with more intense UV output hold potential
for evaluating UV as a remediation alternative in areas such as wastewater
treatment plants or oil spills. Finally, the ability to analyze the
photolytic fate of trace chemicals at natural abundance in groundwater,
using a cryogenic probe, demonstrates the viability of NMR spectroscopy
as a powerful and complementary technique for environmental applications
in general.