Abstract
Abstract. Climate change in the Arctic is leading to shifts in vegetation communities, permafrost degradation and alteration of tundra surface–atmosphere energy and carbon (C) fluxes, among other changes. However, year-round C and energy flux measurements at high-latitude sites remain rare. This poses a challenge for evaluating the impacts of climate change on Arctic tundra ecosystems and for developing and evaluating process-based models, which may be used to predict regional and global energy and C feedbacks to the climate system. Our study used 14 years of seasonal eddy covariance (EC) measurements of carbon dioxide (CO2), water and energy fluxes, and winter soil chamber CO2 flux measurements at a dwarf-shrub tundra site underlain by continuous permafrost in Canada’s Southern Arctic ecozone to evaluate the incorporation of shrub plant functional types (PFTs) in the Canadian Land Surface Scheme Including Biogeochemical Cycles (CLASSIC), the land surface component of the Canadian Earth System Model. In addition to new PFTs, a modification of the efficiency with which water evaporates from the ground surface was applied. This modification addressed a high ground evaporation bias that reduced model performance when soils became very dry, limited heat flow into the ground, and reduced plant productivity through water stress effects. Compared to the grass and tree PFTs previously used by CLASSIC to represent the vegetation in Arctic permafrost-affected regions, simulations with the new shrub PFTs better capture the physical and biogeochemical impact of shrubs on the magnitude and seasonality of energy and CO2 fluxes at the dwarf-shrub tundra evaluation site. The revised model, however, tends to overestimate gross primary productivity, particularly in spring, and overestimated late-winter CO2 emissions. On average, annual net ecosystem CO2 exchange was positive for all simulations, suggesting this site was a net CO2 source of 18 ± 4 g C m−2 yr−1 using shrub PFTs, 15 ± 6 g C m−2 yr−1 using grass PFTs, and 25 ± 5 g C m−2 yr−1 using tree PFTs. These results highlight the importance of using appropriate PFTs in process-based models to simulate current and future Arctic surface–atmosphere interactions.
Highlights
The terrestrial carbon (C) cycle of the Arctic is changing as the region warms at more than twice the rate of the rest of the world (IPCC, 2014; Post et al, 2019)
In order to further improve the representation of Arctic surface–atmosphere interactions in Canadian Land Surface Scheme Including Biogeochemical Cycles (CLASSIC), we evaluate new dwarf deciduous and evergreen shrubs and sedge plant functional types (PFTs) parameterizations with eddy covariance (EC)-based observations of CO2 and energy fluxes at an erect dwarf-shrub tundra site in Canada’s Southern Arctic
We address an evaporation (E) bias discovered in CLASSIC, which has important implications for appropriately simulating energy flux feedbacks and water-stress impacts on growing season photosynthesis
Summary
The terrestrial carbon (C) cycle of the Arctic is changing as the region warms at more than twice the rate of the rest of the world (IPCC, 2014; Post et al, 2019). A significant positive climate feedback effect is possible if even a small proportion of the approximately 1035 ± 150 Pg C stored in the top 3 m of Arctic soils (Hugelius et al, 2014) is transferred to the atmosphere (Chapin et al, 2005; Schuur et al, 2009; Hayes et al, 2014). Longer growing seasons and Arctic “greening” associated, in part, with northward migration of the tree line and shrub expansion are linked to increased growing season carbon dioxide (CO2) uptake (Belshe et al, 2013a; Abbott et al, 2016; Myers-Smith et al, 2011)
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