Sudden Aspen Decline: A Review of Pattern and Process in a Changing Climate
Abstract
:1. Introduction
2. Explaining Normal Patterns of Aspen Mortality versus SAD
3. Predisposing Factors to Sudden Aspen Decline
3.1. Succession, Forest Structure, and Conifer Competition
3.2. Edaphic and Topographic Conditions
4. Contributing Factors to Sudden Aspen Decline
4.1. Primary and Secondary Insects
4.2. Primary and Secondary Pathogens
5. Physiology of SAD
5.1. Proneness to Cavitation and Drought
5.2. Photosynthate Allocation and Carbon Storage
6. Landscape Level Change through Models and Remote Sensing
6.1. Climate Models and Changes in Aspen Range
6.2. Detecting Changes in SAD through Remote Sensing
7. Management Implications: Strategies for Mitigating SAD and Restoring Aspen Forests
7.1. Coppice Systems
7.2. Prescribed Fire
8. Conclusions
Author Contributions
Acknowledgments
Conflicts of Interest
References
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Characteristics of a Healthy Aspen Stand | Predisposing Factors | Inciting Factor | Contributing Factors | Characteristics of Affected Stands |
---|---|---|---|---|
Closed canopy Vigorous suckering Rapid growth Fine root mass growth Mixed-age stand (Values vary regionally) | Aspect (South or Southwest) Lower elevation Physiological maturity Low site index High stand density | Climate-induced drought | Bronze poplar borer (Agrilus liragus Barter and Brown 1949) Bark beetles (Trypophloeus populi, Hopkins 1915; Procryphalus mucronata, LeConte, 1879) Forest tent moth caterpillar (Malacosoma disstria Hübner, 1820) Cytospora canker (Cytospora chrysosperma, (Pers.:Fr) Fr) Armillaria root rot (Armillaria spp.) | Rapid die-off of previously healthy stands in 2–5 years Decreased photosynthesis Increased tree carbohydrate concentrations Decline in sap flow Smaller leaf area Decline in sap flow Root biomass decline Loss of hydraulic conductance Earlier leaf-shedding in autumn |
Author | Year | Methods | Key Findings | Terminology for SAD |
---|---|---|---|---|
Frey et al. | 2004 [7] | Review | Insect defoliation, drought, and thaw–freeze events appear to be the most likely factors initiating dieback in mature aspen stands. | Sudden dieback of mature plants |
Worrall et al. | 2008 [8] | Aerial surveys, Geospatial Analysis, and field observation. | Predisposing factors include stand maturation, low density, southern aspects, and low elevations. A major inciting factor was the recent, acute drought accompanied by high temperatures. Sites with poor regeneration and weak root systems may exhibit clonal death and long-term aspen forest cover loss. | SAD |
Worrall et al. | 2007 [53] | Used geographic information from the 2006 aerial survey on aspen damage, together with the aspen cover type. | Extreme drought with little regeneration after overstory loss incited rapid dieback of aspen in Southwest Colorado. Predisposing environmental and insect and/or pathenogenic damage also contributed. | SAD |
Evans | 2010 [54] | Regression analyses and a topographic analysis using zonal statistics were performed to determine climatic factors and landscape positions that correlated to aspen decline prevalence. | The most significant predictor of aspen decline was elevation, which was significantly greater in the live aspen for three of the five years. Drought weakens aspen, making it susceptible to future decline. | SAD |
Worrall et al. | 2010 [12] | To test the role of climate as an inciting factor for SAD, a landscape-scale climate model was used to compare the moisture status of declining and healthy aspen at the height of the warm drought in 2002. | Overstory age and diameter were not related to SAD severity. The severity of SAD was inversely and weakly related to the basal area, stem slenderness, and site index, and positively related to upper slope positions. | SAD |
Anderegg | 2012 [16] | Compared potted and naturally occurring aspen to conduct a water deprivation experiment. | Increased allocation to root non-structural carbohydrates is a direct response to drought in aspen and plays an important role in the die-off. | Wide-spread aspen die-off |
Marchetti et al. | 2011 [22] | Compared insects and diseases in 162 damaged and neighboring healthy plots to determine contributing factors and their ecological roles. | Cytospora canker, bronze poplar borer, and aspen bark beetles were the primary agents associated with crown loss and other factors related to SAD. Environmental stress may have increased host susceptibility. | SAD |
Michaelian et al. | 2011 [55] | Used plot-based, meteorological, and remote sensing measures to examine aspen die-off following an exceptionally severe drought. | Spatial variation in the percentage of dead biomass showed a moderately strong correlation with drought severity. | aspen mortality |
Morelli and Carr | 2011 [5] | Literature review | Complex, unpredictable future for aspen in the West, where increased drought, ozone, and insect outbreaks will vie with carbon dioxide fertilization and warmer soils, resulting in unknown cumulative effects. | SAD |
Hanna and Kulakowski | 2012 [44] | Tested the influence of climatic variability on aspen growth and mortality in northwestern Colorado and southern Wyoming using dendroecological methods. | Aspen growth was inhibited by warm temperatures, except at the highest elevations. Mortality frequency was associated with multiple years of drought. | aspen dieback |
Huang and Anderegg | 2012 [56] | Combined field measures, remote sensing and a digital elevation model in SAD affected areas in southwest Colorado. | SAD clustered on south-facing slopes due to relatively drier and warmer conditions, but no apparent spatial gradient was found for elevation and slope. | SAD |
Zegler et al. | 2012 [29] | Collected data from a random sample of 48 aspen sites to determine the relationship of predisposing site and stand factors and contributing agents to tree mortality. | Relative conifer basal area and density, the incidence of canker disease and wood-boring insects, and slope were significantly associated with regeneration mortality. | aspen decline, aspen mortality |
Anderegg et al. | 2013 [18] | Drew upon multiple sources of climate data to characterize the drought that triggered aspen mortality. | High 2002 summer temperature and low shallow soil moisture were associated with the spatial patterns of aspen mortality. | Widespread aspen forest mortality |
Anderegg et al. | 2013 [17] | Tested whether accumulated hydraulic damage can predict the probability of tree survival over 2 years. | Hydraulic damage persisted and increased in dying trees over multiple years and exhibited few signs of repair. | SAD |
Kulakowski et al. | 2013 [24] | Literature review | Future aspen trends will depend on the net result of direct (drought) and indirect (forest fires, bark beetle outbreaks) effects of altered climate. | Major aspen decline |
Worrall et al. | 2013 [9] | Range-wide bioclimate model characterizing climatic controls of aspen distribution. | Researchers expect a substantial loss of suitable habitat within the current distribution. | SAD |
Anderegg et al. | 2014 [19] | Monitored quaking aspen trees over two growing seasons, including a severe summer drought. | SAD-affected trees exhibited lower whole-tree hydraulic conductance and assimilation than healthy trees. | SAD |
Bell et al. | 2014 [21] | Examined the relation of mortality index to forest structure and climate in the Rocky Mountains and intermountain west. | Drought mortality may be influenced by stand development, inter-species competition, and vulnerabilities of large trees to drought. | SAD |
Ireland et al. | 2014 [20] | Tree-ring investigation of growth patterns and mortality | The initial growth rate was not associated with a longer lifespan. Younger trees with lower recent growth and more abrupt growth have an increased risk of mortality. | SAD, widespread dieback of aspen forests |
Bell et al. | 2015 [57] | Modeled disease prevalence in live aspen stems and survival rates near the species’ southern range limit. | Mortality depends on tree size, allometry, competition, summer temperature, summer precipitation. | Mortality of diseased trees |
Dudley et al. | 2015a [46] | Surveyed aspen stands with various mortality levels in CO and WY | Cankers, bark beetles, and wood borers were the most common damage agents. | SAD, aspen mortality |
Dudley et al. | 2015b [47] | Analyzed a series of increment cores | Found a relationship between tree growth and annual precipitation but not summer precipitation. | SAD |
Krasnow and Stephens | 2015 [58] | Compared regeneration dynamics of pre-fire stand composition to post-fire aspen regeneration. | Greater disturbance severity increased sprout density. Live conifer and/or dead aspen basal area prior to fire disturbance reduced sprout density. | SAD |
Shepperd et al. | 2015 [23] | Clearfelled half of stands to compare with uncut half. | It is possible to successfully regenerate SAD-affected stands, provided that treatment occurs before the majority of the aspen are dead. | SAD |
Worrall et al. | 2015 [59] | Diseased aspen stands were paired with a neighboring healthy aspen plot. | Diseased plots had much more recent damage than healthy plots. | SAD |
Bretfeld et al. | 2016 [32] | Sampled 89 plots in the Colorado front range from 305 plots sampled in 1972–1973. | 22 plots no longer contained aspen. Upslope shifts suggest climate-related responses and migrations. | SAD |
Blodgett et al. | 2017 [60] | Researchers measured and tagged mature trees and sapling density. | No significant tree mortality events have occurred. | SAD |
Rice et al. | 2017 [61] | Literature review | A dynamic spatial and temporal response to climate change is expected. | Sudden aspen mortality |
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Singer, J.A.; Turnbull, R.; Foster, M.; Bettigole, C.; Frey, B.R.; Downey, M.C.; Covey, K.R.; Ashton, M.S. Sudden Aspen Decline: A Review of Pattern and Process in a Changing Climate. Forests 2019, 10, 671. https://doi.org/10.3390/f10080671
Singer JA, Turnbull R, Foster M, Bettigole C, Frey BR, Downey MC, Covey KR, Ashton MS. Sudden Aspen Decline: A Review of Pattern and Process in a Changing Climate. Forests. 2019; 10(8):671. https://doi.org/10.3390/f10080671
Chicago/Turabian StyleSinger, Jack A., Rob Turnbull, Mark Foster, Charles Bettigole, Brent R. Frey, Michelle C. Downey, Kristofer R. Covey, and Mark S. Ashton. 2019. "Sudden Aspen Decline: A Review of Pattern and Process in a Changing Climate" Forests 10, no. 8: 671. https://doi.org/10.3390/f10080671
APA StyleSinger, J. A., Turnbull, R., Foster, M., Bettigole, C., Frey, B. R., Downey, M. C., Covey, K. R., & Ashton, M. S. (2019). Sudden Aspen Decline: A Review of Pattern and Process in a Changing Climate. Forests, 10(8), 671. https://doi.org/10.3390/f10080671