Vascular plant species response to warming and elevated carbon dioxide in a boreal peatland

McPartland, Mara Y.; Montgomery, Rebecca; Hanson, P. J.; Phillips, Jana R.; Kolka, Randy; Palik, Brian

doi:10.1088/1748-9326/abc4fb

Cited by 41 publications

(37 citation statements)

References 58 publications

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“…It is our hope that our study has shed some light on what may occur as we now transition from the Holocene to the Anthropocene. We realize that a myriad of other factors in addition to temperature will affect peatland carbon storage including water table changes (Roulet et al, 1993), fires (Flanagan et al, 2020;Turetsky et al, 2015), and vegetation changes such as increasing shrubification and Sphagnum loss (Malhotra et al, 2020;McPartland et al, 2020;Norby et al, 2019). In addition, peat may be buried under mineral soils with changing climate and thus preserved for periods of time on the order of hundreds of thousands of years (Treat et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

Latitude, Elevation, and Mean Annual Temperature Predict Peat Organic Matter Chemistry at a Global Scale

Verbeke

Lamit

Lilleskov

et al. 2022

Global Biogeochemical Cycles

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Peatlands contain a significant fraction of global soil carbon, but how these reservoirs will respond to the changing climate is still relatively unknown. A global picture of the variations in peat organic matter chemistry will aid our ability to gauge peatland soil response to climate. The goal of this research is to test the hypotheses that (a) peat carbohydrate content, an indicator of soil organic matter reactivity, will increase with latitude and decrease with mean annual temperatures, (b) while peat aromatic content, an indicator of recalcitrance, will vary inversely, and (c) elevation will have a similar effect to latitude. We used Fourier Transform Infrared Spectroscopy to examine variations in the organic matter functional groups of 1034 peat samples collected from 10 to 20, 30–40, and 60–70 cm depths at 165 individual sites across a latitudinal gradient of 79°N–65°S and from elevations of 0–4,773 m. Carbohydrate contents of high latitude peat were significantly greater than peat originating near the equator, while aromatic content showed the opposite trend. For peat from similar latitudes but different elevations, the carbohydrate content was greater and aromatic content was lower at higher elevations. Higher carbohydrate content at higher latitudes indicates a greater potential for mineralization, whereas the chemical composition of low latitude peat is consistent with their apparent relative stability in the face of warmer temperatures. The combination of low carbohydrates and high aromatics at warmer locations near the equator suggests the mineralization of high latitude peat until reaching recalcitrance under a new temperature regime.

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Section: Discussionmentioning

confidence: 99%

Latitude, Elevation, and Mean Annual Temperature Predict Peat Organic Matter Chemistry at a Global Scale

Verbeke

Lamit

Lilleskov

et al. 2022

Global Biogeochemical Cycles

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“…Preliminary isotopic measurements imply that a significant fraction of carbon assimilated by the moss may come from subsurface-respired CO 2 (i.e., CO 2 with older 14 C signatures predating bomb carbon that can only be sourced from deeper peat; Hanson et al, 2017). However, the observed elevated CO 2 response is smaller than simulated (Hanson et al, 2020). Understanding the drivers of elevated CO2 response or lack thereof is a key topic for future work.…”

Section: Predicted Warming and Elevated Co 2 Concentration Response Uncertaintiesmentioning

confidence: 97%

“…Norby et al (2019) investigated different Sphagnum species at the same site and reported there was no support for the hypothesis that species more adapted to dry conditions (e.g., S. magellanicum and Polytrichum mainly on hummocks) would be more resistant to the stress and would increase in dominance, and both hummock and hollow Sphagnum decline with warming despite the differences between them. This declining trend may be in part due to increased shading from the shrub layer which expands with warming (McPartland et al, 2020).…”

Section: Predicted Warming and Elevated Co 2 Concentration Response Uncertaintiesmentioning

confidence: 99%

Extending a land-surface model with <i>Sphagnum</i> moss to simulate responses of a northern temperate bog to whole ecosystem warming and elevated CO<sub>2</sub>

et al. 2021

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Abstract. Mosses need to be incorporated into Earth system models to better simulate peatland functional dynamics under the changing environment. Sphagnum mosses are strong determinants of nutrient, carbon, and water cycling in peatland ecosystems. However, most land-surface models do not include Sphagnum or other mosses as represented plant functional types (PFTs), thereby limiting predictive assessment of peatland responses to environmental change. In this study, we introduce a moss PFT into the land model component (ELM) of the Energy Exascale Earth System Model (E3SM) by developing water content dynamics and nonvascular photosynthetic processes for moss. The model was parameterized and independently evaluated against observations from an ombrotrophic forested bog as part of the Spruce and Peatland Responses Under Changing Environments (SPRUCE) project. The inclusion of a Sphagnum PFT with some Sphagnum-specific processes in ELM allows it to capture the observed seasonal dynamics of Sphagnum gross primary production (GPP) albeit with an underestimate of peak GPP. The model simulated a reasonable annual net primary production (NPP) for moss but with less interannual variation than observed, and it reproduced aboveground biomass for tree PFTs and stem biomass for shrubs. Different species showed highly variable warming responses under both ambient and elevated atmospheric CO2 concentrations, and elevated CO2 altered the warming response direction for the peatland ecosystem. Microtopography is critical: Sphagnum mosses on hummocks and hollows were simulated to show opposite warming responses (NPP decreasing with warming on hummocks but increasing in hollows), and hummock Sphagnum was modeled to have a strong dependence on water table height. The inclusion of this new moss PFT in global ELM simulations may provide a useful foundation for the investigation of northern peatland carbon exchange, enhancing the predictive capacity of carbon dynamics across the regional and global scales.

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“…In that study water potential of the shrubs was more variable but also indicated midday water stress for some plants, especially Chamaedaphne calyculata (−1.5 to −2.0 MPa) and Rhododendron groenlandicum (previously Ledum groenlandicum ; −1.4 to −1.9 MPa), while Kalmia polifolia and Vaccinium angustifolium peaked higher (−1.2 to −1.6 MPa). Along with the Sphagnum moss groundcover, the species‐specific responses of this community to drier or hotter conditions will shape southern boreal peatland composition (McPartland et al, 2020; Norby et al, 2019) and productivity (Hanson, Griffiths, et al, 2020) in the future.…”

Section: Introductionmentioning

confidence: 99%

“…Increased productivity by some species may lead to decline of other species, such as exhibited by shrub expansion under whole ecosystem warming (McPartland et al, 2019) at the expense of Sphagnum spp. (Norby et al, 2019) and forbs (McPartland et al, 2020). Thus, knowledge of species‐specific responses to peatland warming and the underlying mechanisms is necessary to assess the trajectory of peatland ecosystems in the future.…”

Section: Introductionmentioning

confidence: 99%

Divergent species‐specific impacts of whole ecosystem warming and elevated CO₂on vegetation water relations in an ombrotrophic peatland

Warren

Jensen

Ward

et al. 2021

Global Change Biology

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Boreal peatland forests have relatively low species diversity and thus impacts of climate change on one or more dominant species could shift ecosystem function. Despite abundant soil water availability, shallowly rooted vascular plants within peatlands may not be able to meet foliar demand for water under drought or heat events that increase vapor pressure deficits while reducing near surface water availability, although concurrent increases in atmospheric CO2 could buffer resultant hydraulic stress. We assessed plant water relations of co‐occurring shrub (primarily Rhododendron groenlandicum and Chamaedaphne calyculata) and tree (Picea mariana and Larix laricina) species prior to, and in response to whole ecosystem warming (0 to +9°C) and elevated CO2 using 12.8‐m diameter open‐top enclosures installed within an ombrotrophic bog. Water relations (water potential [Ψ], turgor loss point, foliar and root hydraulic conductivity) were assessed prior to treatment initiation, then Ψ and peak sap flow (trees only) assessed after 1 or 2 years of treatments. Under the higher temperature treatments, L. laricina Ψ exceeded its turgor loss point, increased its peak sap flow, and was not able to recover Ψ overnight. In contrast, P. mariana operated below its turgor loss point and maintained constant Ψ and sap flow across warming treatments. Similarly, C. calyculata Ψ stress increased with temperature while R. groenlandicum Ψ remained at pretreatment levels. The more anisohydric behavior of L. laricina and C. calyculata may provide greater net C uptake with warming, while the more conservative P. mariana and R. groenlandicum maintained greater hydraulic safety. These latter species also responded to elevated CO2 by reduced Ψ stress, which may also help limit hydraulic failure during periods of extreme drought or heat in the future. Along with Sphagnum moss, the species‐specific responses of peatland vascular communities to drier or hotter conditions will shape boreal peatland composition and function in the future.

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Vascular plant species response to warming and elevated carbon dioxide in a boreal peatland

Cited by 41 publications

References 58 publications

Latitude, Elevation, and Mean Annual Temperature Predict Peat Organic Matter Chemistry at a Global Scale

Latitude, Elevation, and Mean Annual Temperature Predict Peat Organic Matter Chemistry at a Global Scale

Extending a land-surface model with <i>Sphagnum</i> moss to simulate responses of a northern temperate bog to whole ecosystem warming and elevated CO<sub>2</sub>

Divergent species‐specific impacts of whole ecosystem warming and elevated CO₂on vegetation water relations in an ombrotrophic peatland

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Vascular plant species response to warming and elevated carbon dioxide in a boreal peatland

Cited by 41 publications

References 58 publications

Latitude, Elevation, and Mean Annual Temperature Predict Peat Organic Matter Chemistry at a Global Scale

Latitude, Elevation, and Mean Annual Temperature Predict Peat Organic Matter Chemistry at a Global Scale

Extending a land-surface model with &lt;i&gt;Sphagnum&lt;/i&gt; moss to simulate responses of a northern temperate bog to whole ecosystem warming and elevated CO&lt;sub&gt;2&lt;/sub&gt;

Divergent species‐specific impacts of whole ecosystem warming and elevated CO2on vegetation water relations in an ombrotrophic peatland

Contact Info

Product

Resources

About

Extending a land-surface model with <i>Sphagnum</i> moss to simulate responses of a northern temperate bog to whole ecosystem warming and elevated CO<sub>2</sub>

Divergent species‐specific impacts of whole ecosystem warming and elevated CO₂on vegetation water relations in an ombrotrophic peatland