Differential controls by climate and physiology over the emission rates of biogenic volatile organic compounds from mature trees in a semi-arid pine forest

Drought has the potential to influence the emission of biogenic volatile organic compounds (BVOCs) from forests and thus affect the oxidative capacity of the atmosphere. Our understanding of these influences is limited, in part, by a lack of field observations on mature trees and the small number of...

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Bibliographic Details
Published in:Oecologia 2016-02, Vol.180 (2), p.345-358
Main Authors: Eller, Allyson S. D, Young, Lindsay L, Trowbridge, Amy M, Monson, Russell K
Format: Article
Language:English
Subjects:
acetaldehyde
acetone
Atmosphere - chemistry
Biomedical and Life Sciences
Carbon dioxide
Climate
Conductance
Coniferous forests
Drought
Droughts
Ecology
Emissions
Emissions (Pollution)
Forests
Hydrology/Water Resources
Interception
leaves
Life Sciences
methanol
Monoterpenes
Monoterpenes - analysis
Monoterpenes - metabolism
monsoon season
Organic compounds
Photosynthesis
Photosynthesis - physiology
Physiological aspects
PHYSIOLOGICAL ECOLOGY - ORIGINAL RESEARCH
Physiology
Phytochemistry
Pine trees
Pinus - metabolism
Pinus - physiology
Pinus ponderosa
Plant Leaves - anatomy & histology
Plant Leaves - physiology
Plant Sciences
sap flow
Seasons
stomatal conductance
Summer
Temperature
Throughfall
trees
VOCs
Volatile organic compounds
Volatile Organic Compounds - analysis
Volatile Organic Compounds - metabolism
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Summary:Drought has the potential to influence the emission of biogenic volatile organic compounds (BVOCs) from forests and thus affect the oxidative capacity of the atmosphere. Our understanding of these influences is limited, in part, by a lack of field observations on mature trees and the small number of BVOCs monitored. We studied 50- to 60-year-old Pinus ponderosa trees in a semi-arid forest that experience early summer drought followed by late-summer monsoon rains, and observed emissions for five BVOCs—monoterpenes, methylbutenol, methanol, acetaldehyde and acetone. We also constructed a throughfall-interception experiment to create “wetter” and “drier” plots. Generally, trees in drier plots exhibited reduced sap flow, photosynthesis, and stomatal conductances, while BVOC emission rates were unaffected by the artificial drought treatments. During the natural, early summer drought, a physiological threshold appeared to be crossed when photosynthesis ≅2 μmol m⁻² s⁻¹ and conductance ≅0.02 mol m⁻² s⁻¹. Below this threshold, BVOC emissions are correlated with leaf physiology (photosynthesis and conductance) while BVOC emissions are not correlated with other physicochemical factors (e.g., compound volatility and tissue BVOC concentration) that have been shown in past studies to influence emissions. The proportional loss of C to BVOC emission was highest during the drought primarily due to reduced CO₂ assimilation. It appears that seasonal drought changes the relations among BVOC emissions, photosynthesis and conductance. When drought is relaxed, BVOC emission rates are explained mostly by seasonal temperature, but when seasonal drought is maximal, photosynthesis and conductance—the physiological processes which best explain BVOC emission rates—decline, possibly indicating a more direct role of physiology in controlling BVOC emission.
ISSN:0029-8549
1432-1939
DOI:10.1007/s00442-015-3474-4