Photochemistry of aqueous pyruvic acid

The study of organic chemistry in atmospheric aerosols and cloud formation is of interest in predictions of air quality and climate change. It is now known that aqueous phase chemistry is important in the formation of secondary organic aerosols. Here, the photoreactivity of pyruvic acid (PA; CH ₃COC...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2013-07, Vol.110 (29), p.11714-11719
Main Authors: Griffith, Elizabeth C., Carpenter, Barry K., Shoemaker, Richard K., Vaida, Veronica
Format: Article
Language:English
Subjects:
Acetic Acid - chemistry
Acetoin - chemistry
Aerosols
Aerosols - chemistry
Aqueous chemistry
Aqueous solutions
Atmosphere - chemistry
Atmospheric chemistry
Atmospherics
Decarboxylation
Lactic Acid - chemistry
Light
Magnetic Resonance Spectroscopy
Mass Spectrometry
Molecular Structure
Molecules
Oligomers
Organic chemistry
Photochemistry
Photochemistry - methods
Photolysis
Physical Sciences
Pyruvic Acid - chemistry
Ultraviolet radiation
Vapor phases
Water - chemistry
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Summary:The study of organic chemistry in atmospheric aerosols and cloud formation is of interest in predictions of air quality and climate change. It is now known that aqueous phase chemistry is important in the formation of secondary organic aerosols. Here, the photoreactivity of pyruvic acid (PA; CH ₃COCOOH) is investigated in aqueous environments characteristic of atmospheric aerosols. PA is currently used as a proxy for α-dicarbonyls in atmospheric models and is abundant in both the gas phase and the aqueous phase (atmospheric aerosols, fog, and clouds) in the atmosphere. The photoreactivity of PA in these phases, however, is very different, thus prompting the need for a mechanistic understanding of its reactivity in different environments. Although the decarboxylation of aqueous phase PA through UV excitation has been studied for many years, its mechanism and products remain controversial. In this work, photolysis of aqueous PA is shown to produce acetoin (CH ₃CHOHCOCH ₃), lactic acid (CH ₃CHOHCOOH), acetic acid (CH ₃COOH), and oligomers, illustrating the progression from a three-carbon molecule to four-carbon and even six-carbon molecules through direct photolysis. These products are detected using vibrational and electronic spectroscopy, NMR, and MS, and a reaction mechanism is presented accounting for all products detected. The relevance of sunlight-initiated PA chemistry in aqueous environments is then discussed in the context of processes occurring on atmospheric aerosols.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1303206110