Growth responses of Sphagnum hollows to a growing season lengthening manipulation in Alaskan Arctic tundra

Genet, Hélène; Oberbauer, Steven F.; Colby, S. J.; Staudhammer, Christina L.; Starr, Gregory

doi:10.1007/s00300-012-1236-x

Cited by 11 publications

(8 citation statements)

References 49 publications

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“…We thus used the T gs , the arithmetic average temperature of the months above 0 • C, as the growth temperature for the whole plant of Sphagnum. In fact, Sphagnum growth during the months of freezing temperature does occur if snow cover was thick and persistent enough to insulate Sphagnum from winter frost (Dorrepaal et al, 2004;Genet et al, 2013), as snow cover shading is not is not a major limiting factor for Sphagnum growth (Clymo and Hayward, 1982;Küttim et al, 2020). That being said, biomass production of Sphagnum during freezing months is much reduced.…”

Section: Uncertainty In Constraining the Time Span Of Precipitation Imentioning

confidence: 99%

“…However, the cumulative temperature-such that is defined as growing degree days above zero in bioclimatic studies (Charman et al, 2013)-might be a more accurate measure of the total warmth Sphagnum have experienced. Studies found that Sphagnum productivity at a given site is enhanced during the warmest season (Krebs et al, 2016;Küttim et al, 2020), although a few studies suggested that Sphagnum growth could be limited by summer desiccation stress and photoinhibition (Lindholm, 1990;Dorrepaal et al, 2004;Genet et al, 2013). Certainly, there is a tendency that T gs would underestimate the mass-weighted growth temperature for the whole plant of Sphagnum.…”

Section: Uncertainty In Constraining the Time Span Of Precipitation Imentioning

confidence: 99%

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Temperature-Dependent Oxygen Isotope Fractionation in Plant Cellulose Biosynthesis Revealed by a Global Dataset of Peat Mosses

Xia

2020

Front. Earth Sci.

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The oxygen isotope composition (δ 18 O) of plant cellulose has been widely used to study ecohydrological processes of ecosystems as well as to reconstruct past climate conditions in terrestrial climate archives. These applications are grounded on a key assumption that the biochemical fractionation during cellulose synthesis is a constant around +27 and is not affected by environmental factors. Here we revisit the influence of temperature on biochemical fractionation factor during cellulose synthesis using a global compilation of Sphagnum cellulose δ 18 O data. Sphagnum (peat mosses) are known for inhabiting waterlogged peatlands and possessing unique physiological strategy in that their cellulose δ 18 O could closely reflect growing-season precipitation δ 18 O. Although within-site cellulose δ 18 O variability shows a median standard deviation of 0.7-0.8 resulting from different degrees of evaporative enrichment of 18 O in metabolic leaf water, this evaporative enrichment should be a small quantity due to the external capillary "water buffer" in Sphagnum mosses. Using site-specific minimum cellulose δ 18 O data that most likely reflect the signal of unevaporated source water, we show that the apparent enrichment factor between cellulose and precipitation δ 18 O increases with decreasing air temperature. In particular, the apparent enrichment factor could reach values as high as +32 when growth temperature is below 5 • C. This observational dataset extends the support for the temperature-dependent oxygen isotope fractionation in plant cellulose synthesis previously demonstrated in laboratory experiment, with implications for paleoclimate and plant physiology studies that employ cellulose δ 18 O measurements, particularly in alpine regions.

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Section: Uncertainty In Constraining the Time Span Of Precipitation Imentioning

confidence: 99%

Section: Uncertainty In Constraining the Time Span Of Precipitation Imentioning

confidence: 99%

Temperature-Dependent Oxygen Isotope Fractionation in Plant Cellulose Biosynthesis Revealed by a Global Dataset of Peat Mosses

Xia

2020

Front. Earth Sci.

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“…In the southern-most parts of this region, more precipitation will arrive in liquid form and be available earlier in the season for hydropower generation, rather than stored in the snowpack until spring melt. In the Far North, ET is a relatively small portion of the hydrologic budget and precipitation dominates (Kane et al, 1990), though ET will increase as the growing season continues to lengthen as it has in recent decades (Genet et al, 2013;Olchev and Novenko, 2011;Zeng et al, 2011). Other aspects of the supply side, which include groundwater storage and glacier storage, will be addressed in the next section on regional complexity.…”

Section: Climate Change Impacts On Hydropower Supply and Demandmentioning

confidence: 99%

Planning for climate change impacts on hydropower in the Far North

Cherry

Knapp

Trainor

et al. 2017

Hydrol. Earth Syst. Sci.

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Abstract. Unlike much of the contiguous United States, new hydropower development continues in the Far North, where climate models project precipitation will likely increase over the next century. Regional complexities in the Arctic and subArctic, such as glacier recession and permafrost thaw, however, introduce uncertainties about the hydrologic responses to climate change that impact water resource management. This work reviews hydroclimate changes in the Far North and their impacts on hydropower; it provides a template for application of current techniques for prediction and estimating uncertainty, and it describes best practices for integrating science into management and decision-making. The growing number of studies on hydrologic impacts suggests that information resulting from climate change science has matured enough that it can and should be integrated into hydropower scoping, design, and management. Continuing to ignore the best available information in lieu of status quo planning is likely to prove costly to society in the long term.

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Section: Climate Change Impacts On Hydropower Supply and Demandmentioning

confidence: 99%

Planning for climate change impacts on hydropower in the Far North

Cherry¹,

Knapp²,

Trainor³

et al. 2016

Preprint

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Abstract. Unlike much of the contiguous United States, new hydropower development continues in the Far North, where climate models project precipitation will likely increase over the next century. Regional complexities in the Arctic and sub-Arctic, such as glacier recession and permafrost thaw, however, introduce uncertainties about the hydrologic responses to climate change that impact water resource management. This work reviews hydroclimate changes in the Far North and their impacts on hydropower; it provides a template for application of current techniques for prediction and estimating uncertainty, and it describes best practices for integrating science into management and decision-making. The growing number of hydrologic impacts studies suggests that information resulting from climate change science has matured enough that it can and should be integrated into hydropower scoping, design, and management. Continuing to ignore the best-available information in lieu of status quo planning is likely to prove costly to society in the long term.

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Growth responses of Sphagnum hollows to a growing season lengthening manipulation in Alaskan Arctic tundra

Cited by 11 publications

References 49 publications

Temperature-Dependent Oxygen Isotope Fractionation in Plant Cellulose Biosynthesis Revealed by a Global Dataset of Peat Mosses

Temperature-Dependent Oxygen Isotope Fractionation in Plant Cellulose Biosynthesis Revealed by a Global Dataset of Peat Mosses

Planning for climate change impacts on hydropower in the Far North

Planning for climate change impacts on hydropower in the Far North

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