Issue 6, 2024

Development of a sampling protocol for collecting leaf surface material for multiphase chemistry studies

Abstract

Plant leaves and water drops residing on them interact with atmospheric oxidants, impacting the deposition and emission of trace gases and mediating leaf damage from air pollution. Characterizing the chemical composition and reactivity of the water-soluble material on leaf surfaces is thus essential for improving our understanding of atmosphere-biosphere interactions. However, the limited knowledge of sources and nature of these chemicals challenges sampling decisions. This work investigates how sampling variables and environmental factors impact the quantity and composition of water-soluble material sampled from wet leaves and proposes a flexible protocol for its collection. The ratio of solvent volume-to-leaf area, the solvent-to-leaf contact time, and environmental parameters – including the occurrence of rain, plant location and its metabolism – drive solute concentration in leaf soaks. Despite minor variations, UV-vis absorption spectra of leaf soaks are comparable to authentic raindrops collected from the same tree and share features with microbial dissolved organic matter – including overall low aromaticity, low chromophore content, and low average molecular weight. In addition to guiding the development of a sampling protocol, our data corroborate recent hypotheses on the amount, origin, nature, and reactivity of water-soluble organics on wet leaves, providing new directions of research into this highly interdisciplinary topic.

Graphical abstract: Development of a sampling protocol for collecting leaf surface material for multiphase chemistry studies

Supplementary files

Article information

Article type
Paper
Submitted
08 2月 2024
Accepted
14 5月 2024
First published
14 5月 2024
This article is Open Access
Creative Commons BY license

Environ. Sci.: Processes Impacts, 2024,26, 1008-1021

Development of a sampling protocol for collecting leaf surface material for multiphase chemistry studies

R. Ossola, R. K. Rossell, M. Riches, C. Osburn and D. Farmer, Environ. Sci.: Processes Impacts, 2024, 26, 1008 DOI: 10.1039/D4EM00065J

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