Abstract
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.
Highlights
Boreal peatlands store at least 500 pg of soil carbon due to the incomplete decomposition of plant litter inputs resulting from a combination of low temperature and watersaturated soils
Since evaporation at the Sphagnum surface depends on the atmospheric water vapor deficit, moss–atmosphere conductance, and available water pool which depends on capillary wicking of water up to the surface, we developed a relationship between measured soil water content at depth and surface Sphagnum water content
Main effect sensitivities are shown for eight model output quantities of interest: total site gross primary productivity (GPP), gross primary production (GPP) for the moss plant functional types (PFTs) only (GPP_moss), total site net primary productivity (NPP), NPP for the moss PFT only (NPP_moss), total site vegetation transpiration (QVEGT), evaporation from the moss surface (QVEG_moss), net ecosystem exchange (NEE), and site total vegetation carbon (TOTVEGC) (Fig. 2)
Summary
Boreal peatlands store at least 500 pg of soil carbon due to the incomplete decomposition of plant litter inputs resulting from a combination of low temperature and watersaturated soils Because of this capacity to store carbon, boreal peatlands have played a critical role in regulating the global climate since the onset of the Holocene (Frolking and Roulet, 2007; Yu et al, 2010). Functioning as a keystone species of boreal peatlands, Sphagnum mosses strongly influence the nutrient, carbon, and water cycles of peatland ecosystems (Nilsson and Wardle, 2005; Cornelissen et al, 2007; Lindo and Gonzalez, 2010; Turetsky et al, 2010, 2012) and exert a substantial impact on ecosystem net carbon balance (Clymo and Hayward; 1982; Gorham, 1991; Wieder, 2006; Weston et el., 2015; Walker et al, 2017; Griffiths et al, 2018)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
