Mountain pine beetle infestation impacts: modeling water and energy budgets at the hill‐slope scale

Mikkelson, Kristin M.; Maxwell, R. M.; Ferguson, Ian J.; Stednick, John D.; McCray, John E.; Sharp, Jonathan O.

doi:10.1002/eco.278

Cited by 71 publications

(78 citation statements)

References 42 publications

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“…Many previous studies have represented insect damage in DVLSMs or less comprehensive climate-driven terrestrial models (Randerson et al, 1996;Krinner et al, 2005;Seidl et al, 2008;Wolf et al, 2008;Albani et al, 2010;Schäfer et al, 2010;Edburg et al, 2011;Medvigy et al, 2012;Mikkelson et al, 2013b;Chen et al, 2015). To our knowledge, however, our study is the first to assess, over daily to centennial timescales, the impacts from insect damage on vegetation dynamics and the carbon, energy, and water cycles in an integrated way (see Sect.…”

Section: Discussionmentioning

confidence: 99%

“…Based on the empirical relationships of McNaughton et al (1989), the ORganizing Carbon and Hydrology in Dynamic EcosystEms (ORCHIDEE) DVLSM accounts for background leaf consumption by herbivores (not limited to insects), but the realism of the resulting impact on simulated tree mortality has been questioned by the authors themselves (Krinner et al, 2005). The effects of prescribed mortality due to mountain pine beetle (MPB; Dendroctonus ponderosae Hopkins) outbreaks in western US on coupled carbon-nitrogen dynamics (Edburg et al, 2011) and water and energy exchanges (Mikkelson et al, 2013b) have been studied in the Community Land Model (CLM) DVLSM. Medvigy et al (2012) used the Ecosystem Demography version 2 (ED2) DVLSM to simulate the impacts of defoliation by the gypsy moth (Lymantria dispar Linnaeus) on vegetation coexistence and carbon dynamics in the eastern US.…”

Section: -S Landry Et Al: Ibis-mimmentioning

confidence: 99%

“…Three of the four modelling studies (Wiedinmyer et al, 2012;Mikkelson et al, 2013b;Chen et al, 2015) indirectly forced the responses they obtained by directly reducing the total canopy conductance without accounting for the possible growth release of the surviving vegetation, while the fourth modelling study (included in the Mikkelson et al, 2013a, review) only computed the change in runoff and then assumed no change in soil moisture to estimate the change in evapotranspiration. The two satellite-based studies rest upon the highly parameterized MODIS evapotranspiration data set (Mu et al, 2011), which has not been developed and tested in the context of MPB-killed forests.…”

Section: Evaluation Of Performancementioning

confidence: 99%

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Implementation of a Marauding Insect Module (MIM, version 1.0) in the Integrated BIosphere Simulator (IBIS, version 2.6b4) dynamic vegetation–land surface model

et al. 2016

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Abstract. Insects defoliate and kill plants in many ecosystems worldwide. The consequences of these natural processes on terrestrial ecology and nutrient cycling are well established, and their potential climatic effects resulting from modified land-atmosphere exchanges of carbon, energy, and water are increasingly being recognized. We developed a Marauding Insect Module (MIM) to quantify, in the Integrated BIosphere Simulator (IBIS), the consequences of insect activity on biogeochemical and biogeophysical fluxes, also accounting for the effects of altered vegetation dynamics. MIM can simulate damage from three different insect functional types: (1) defoliators on broadleaf deciduous trees, (2) defoliators on needleleaf evergreen trees, and (3) bark beetles on needleleaf evergreen trees, with the resulting impacts being estimated by IBIS based on the new, insect-modified state of the vegetation. MIM further accounts for the physical presence and gradual fall of insect-killed dead standing trees. The design of MIM should facilitate the addition of other insect types besides the ones already included and could guide the development of similar modules for other process-based vegetation models. After describing IBIS-MIM, we illustrate the usefulness of the model by presenting results spanning daily to centennial timescales for vegetation dynamics and cycling of carbon, energy, and water in a simplified setting and for bark beetles only. More precisely, we simulated 100 % mortality events from the mountain pine beetle for three locations in western Canada. We then show that these simulated impacts agree with many previous studies based on field measurements, satellite data, or modelling. MIM and similar tools should therefore be of great value in assessing the wide array of impacts resulting from insect-induced plant damage in the Earth system.

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Section: Discussionmentioning

confidence: 99%

Section: -S Landry Et Al: Ibis-mimmentioning

confidence: 99%

Section: Evaluation Of Performancementioning

confidence: 99%

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Implementation of a Marauding Insect Module (MIM, version 1.0) in the Integrated BIosphere Simulator (IBIS, version 2.6b4) dynamic vegetation–land surface model

et al. 2016

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“…Widespread tree mortality in mountain-pine-beetle-infested stands has been shown to result in earlier snowmelt, from increased canopy shortwave transmissions (Bewley et al, 2010;Pugh and Small, 2012), as well as increased stream flow, from a reduction in transpiration and canopy interception (Mikkelson et al, 2013). These changes could reduce water availability during the late growing season, exacerbating tree stress.…”

Section: Discussionmentioning

confidence: 99%

Albedo-induced radiative forcing from mountain pine beetle outbreaks in forests, south-central Rocky Mountains: magnitude, persistence, and relation to outbreak severity

et al. 2014

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Abstract. Mountain pine beetle (MPB) outbreaks in NorthAmerica are widespread and have potentially persistent impacts on forest albedo and associated radiative forcing. This study utilized multiple data sets, both current and historical, within lodgepole pine stands in the south-central Rocky Mountains to quantify the full radiative forcing impact of outbreak events for decades after outbreak (0-60 yr) and the role of outbreak severity in determining that impact. Change in annual albedo and radiative forcing peaked at 14-20 yr post-outbreak (0.06 ± 0.006 and −0.8 ± 0.1 W m −2 , respectively) and recovered to pre-outbreak levels by 30-40 yr post-outbreak. Change in albedo was significant in all four seasons, but strongest in winter with the increased visibility of snow (radiative cooling of −1.6 ± 0.2 W m −2 , −3.0 ± 0.4 W m −2 , and −1.6 ± 0.2 W m −2 for 2-13, 14-20 and 20-30 yr post-outbreak, respectively). Change in winter albedo and radiative forcing also increased with outbreak severity (percent tree mortality). Persistence of albedo effects are seen as a function of the growth rate and species composition of surviving trees, and the establishment and growth of both understory herbaceous vegetation and tree species, all of which may vary with outbreak severity. The establishment and persistence of deciduous trees was found to increase the temporal persistence of albedo effects. MPBinduced changes to radiative forcing may have feedbacks for regional temperature and the hydrological cycle, which could impact future MPB outbreaks dynamics.

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“…In turn, terrestrial hydrologic and biogeochemical cycles are altered, as these trees succumb to beetle infestation (2). Decreased canopy cover, increased soil moisture (3,4) and temperature (5) along with changing carbon inputs associated with needle fall, the cessation of rhizodeposition, and the decay of large quantities of woody debris (6) are all examples of observed shifts in beetle-killed forests.…”

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confidence: 99%

Rare Taxa Maintain Microbial Diversity and Contribute to Terrestrial Community Dynamics throughout Bark Beetle Infestation

Mikkelson

Bokman

Sharp

2016

Appl Environ Microbiol

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A global phenomenon of increasing bark beetle-induced tree mortality has heightened concerns regarding ecosystem response and biogeochemical implications. Here, we explore microbial dynamics under lodgepole pines through the analysis of bulk (16S rRNA gene) and potentially active (16S rRNA) communities to understand the terrestrial ecosystem responses that are associated with this form of large-scale tree mortality. We found that the relative abundances of bulk and potentially active taxa were correlated across taxonomic levels, but at lower levels, cladal differences became more apparent. Despite this correlation, there was a strong differentiation of community composition between bulk and potentially active taxa, with further clustering associated with the stages of tree mortality. Surprisingly, community clustering as a function of tree phase had limited correlation to soil water content and total nitrogen concentrations, which were the only two measured edaphic parameters to differ in association with tree phase. Bacterial clustering is more readily explained by the observed decrease in the abundance of active, rare microorganisms after tree death in conjunction with stable alpha diversity measurements. This enables the rare fraction of the terrestrial microbial community to maintain metabolic diversity by transitioning between metabolically active and dormant states during this ecosystem disturbance and contributes disproportionately to community dynamics and archived metabolic capabilities. These results suggest that analyzing bulk and potentially active communities after beetle infestation may be a more sensitive indicator of disruption than measuring local edaphic parameters. IMPORTANCEForests around the world are experiencing unprecedented mortality due to insect infestations that are fueled in part by a changing climate. While aboveground processes have been explored, changes at the terrestrial interface that are relevant to microbial biogeochemical cycling remain largely unknown. In this study, we investigated the changing bulk and potentially active microbial communities beneath healthy and beetle-killed trees. We found that, even though few edaphic parameters were altered from beetle infestation, the rare microbes were more likely to be active and fluctuate between dormancy and metabolic activity. This indicates that rare as opposed to abundant taxa contribute disproportionately to microbial community dynamics and presumably biogeochemical cycling within these types of perturbed ecosystems.

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Mountain pine beetle infestation impacts: modeling water and energy budgets at the hill‐slope scale

Cited by 71 publications

References 42 publications

Implementation of a Marauding Insect Module (MIM, version 1.0) in the Integrated BIosphere Simulator (IBIS, version 2.6b4) dynamic vegetation–land surface model

Implementation of a Marauding Insect Module (MIM, version 1.0) in the Integrated BIosphere Simulator (IBIS, version 2.6b4) dynamic vegetation–land surface model

Albedo-induced radiative forcing from mountain pine beetle outbreaks in forests, south-central Rocky Mountains: magnitude, persistence, and relation to outbreak severity

Rare Taxa Maintain Microbial Diversity and Contribute to Terrestrial Community Dynamics throughout Bark Beetle Infestation

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