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Publication Date
2025-5
First Advisor
Jessica Gersony
Document Type
Honors Project
Degree Name
Bachelor of Arts
Department
Biological Sciences
Keywords
Xylem, drought, plant physiology, tree mortality, optical vulnerability, red maple, white ash, Acer rubrum, Fraxinus americana, vascular tissue, embolism, cavitation, northeast, northeastern forest, climate change
Abstract
As climate change intensifies the frequency and severity of droughts, understanding how tree species respond to water stress has become increasingly important for forest conservation and management. This study uses the optical vulnerability (OV) method as a tool for assessing xylem embolism resistance and drought tolerance in two temperate tree species with contrasting wood anatomies: Acer rubrum (red maple; diffuse porous) and Fraxinus americana (white ash; ring porous). Using dehydration experiments and OV imaging of leaves, species-specific vulnerability curves were generated to quantify percent loss of conductivity (PLC) in relation to increasing water stress, including determination of water potential at which 50% of veins had embolized (P50) and a plant would be unlikely to recover. Results highlighted significant differences in dehydration dynamics and embolism thresholds for the two tree species: diffuse porous A. rubrum exhibited slower dehydration rates but reached critical embolism thresholds at less negative water potentials (P50 = -2.06 MPa), while ring porous F. americana dehydrated rapidly yet maintained hydraulic function under more extreme drought conditions (P50 = -3.36 MPa). These findings provide new insight into how xylem structure influences drought response. The results underscore a trade-off between hydraulic safety and efficiency shaped by wood porosity, with implications for predicting species resilience under future climate scenarios.
Rights
©2025 Avery Maltz. Access limited to the Smith College community and other researchers while on campus. Smith College community members also may access from off-campus using a Smith College log-in. Other off-campus researchers may request a copy through Interlibrary Loan for personal use.
Language
English
Recommended Citation
Maltz, Avery, "Using the Optical Vulnerability method to further our understanding of drought resistance in Acer rubrum and Fraxinus americana" (2025). Honors Project, Smith College, Northampton, MA.
https://scholarworks.smith.edu/theses/2724
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Comments
41 pages: color illustrations. Includes bibliographical references (pages 38-41).