Sustained carbon uptake and storage following moderate disturbance in a Great Lakes forest

TitleSustained carbon uptake and storage following moderate disturbance in a Great Lakes forest
Publication TypeJournal Article
Year of Publication2013
AuthorsGough CM, Hardiman BS, Nave L, Bohrer G, Maurer KD, Vogel CS, Nadelhoffer KJ, Curtis PS
JournalEcological Applications
Volume23
Issue5
Pagination1205-1215
Date Published07/2013
Type of ArticlePI
Keywordsstructure-function
Abstract

Carbon (C) uptake rates in many forests are sustained, or decline only briefly, following disturbances that partially defoliate the canopy. The mechanisms supporting such functional 5 resistance to moderate forest disturbance are largely unknown. We used a large-scale experiment, in which >6,700 Populus (aspen) and Betula (birch) trees were stem girdled within a 39 ha area, to identify mechanisms sustaining C uptake through partial canopy defoliation. The Forest Accelerated Succession Experiment in northern Michigan, USA employs a suite of C cycling measurements within paired treatment and control meteorological flux tower footprints. 10 We found that enhancement of canopy light-use efficiency and maintenance of light absorption maintained net ecosystem production (NEP) and aboveground wood net primary production (NPP) when leaf area index (LAI) of the treatment forest temporarily declined by nearly half its maximum value. In the year following peak defoliation, redistribution of nitrogen (N) in the treatment forest from senescent early successional aspen and birch to non-girdled later 15 successional species facilitated the recovery of total LAI to pre-disturbance levels. Sustained canopy physiological competency following disturbance coincided with a downward shift in maximum canopy height, indicating that compensatory photosynthetic C uptake by undisturbed, later successional subdominant and subcanopy vegetation supported C uptake resistance to disturbance. These findings have implications for ecosystem management and modeling, 20 demonstrating that forests may tolerate considerable leaf area losses without diminishing rates of C uptake. We conclude that the resistance of C uptake to moderate disturbance depends not only on replacement of lost leaf area, but also on rapid compensatory photosynthetic C uptake during defoliation by emerging later successional species.

URLhttp://www.esajournals.org/doi/abs/10.1890/12-1554.1
DOI10.1890/12-1554.1