Water-stained leaves: formation and application as a field indicator of wetland hydrology

• Published in: Wetlands (Wilmington, N.C.) Vol. 41; no. 8; p. 98
• Main Authors: Berkowitz, Jacob F., Pietroski, Jason P.
• Format: Journal Article
• Language: English
• Published: Dordrecht Springer Netherlands 01.12.2021; Springer Nature B.V
• Subjects: Anaerobic conditions; Anaerobic microorganisms; Applied Wetland Science; Biomedical and Life Sciences; Clean Water Act-US; Coastal Sciences; Color; Deionization; Ecology; Environmental Management; Experiments; Exposure; Freshwater & Marine Ecology; Hydrogeology; Hydrology; Laboratories; Landscape Ecology; Leaves; Life Sciences; Microorganisms; Morphology; Plant species; Ponding; Saturated soils; Sediments; Staining; Vegetation; Wetlands; United States > US; Field indicators; Hydrology; Wetland delineation; Sediment; Munsell color
• ISSN: 0277-5212; 1943-6246
• DOI: 10.1007/s13157-021-01498-3

Wetland delineations conducted in the United States utilize field indicators as proxy measures of the presence or absence of wetland hydrology. Water-stained leaves provide a practical, qualitative field indicator of wetland hydrology; however, the formation of water-stained leaves has not been elucidated. In response, leaves from six tree species were examined under five treatments to investigate the water-staining process and concomitant timeframes. Results indicate that leaf staining occurred within 14-21 days of continuous exposure to wetland waters and sediment under both laboratory and field conditions. Leaf staining was characterized by readily observable shifts in leaf color (i.e., decreasing Munsell hue, value, and chroma) causing the leaves to appear very dark or black. No color shifts associated with leaf staining occurred in treatments exposed to upland conditions. The timeframe associated with leaf staining corresponds with established wetland hydrology criteria requiring a minimum hydroperiod of 14 consecutive days of soil saturation, flooding, or ponding. Leaves exposed to wetland waters and sediment underwent color shifts significantly faster and to a greater extent than leaves inundated with deionized water, likely as a result of increased microbial abundance and the presence of anaerobic conditions in the simulated wetland treatments. Results suggest that water-stained leaves 1) are a useful and reliable wetland hydrology field indicator for wetland delineation purposes, 2) may provide a proxy measure of wetland hydroperiod, and 3) Munsell color measurements can help differentiate between leaves exposed to wetland and upland conditions.