Evolution of ecosystem-scale surface energy fluxes of a newly constructed boreal upland-fen watershed

Obligatory mine reclamation efforts in the Athabasca oil sands region require leased land to be returned to pre-disturbance function. This entails the re-establishment of key ecosystem services such as carbon sequestration and water and nutrient cycling. Surface-atmosphere exchanges of energy, heat and moisture are critical to ecohydrological processes and feedbacks that govern ecosystem functionality. Eddy covariance and remote sensing measurements were used to examine the temporal changes in energy partitioning of a reclaimed fen-upland watershed during the initial seven years post-construction (2013-2019). Surface conditions evolved from bare ground to robustly vegetated plant communities, altering albedo, surface roughness and plant-mediated shading. Initially in the fen, due to near-surface water table, high soil moisture content and the low albedo (0.09) of bare, wet peat, energy was predominantly partitioned to latent heat (QE) and exhibited a high degree of decoupled surface-atmosphere conditions (surface-atmosphere decoupling factor (& omega;) of 0.49). As the fen plant community developed and stabilized, QE remained the dominant energy flux, but a larger proportion of available energy was partitioned to sensible heat flux (QH). Plant establishment altered the biophysical surface through sheltering and shading affecting ground heat flux and supressing surface evaporative losses. Moreover, plant-mediated water loss through stomatal controls resulted in an increase in surface-atmosphere coupling (& omega; = 0.32), particularly during drier periods. In the drier upland, plant emergence and establishment was slower than in the fen. Initially, bare ground in the upland resulted in higher albedo (0.20-0.25), and QE and QH were similar. Once understory and tree species matured, QE increased with seasonal trends that mirrored plant phenology. Unlike the fen, the upland continually exhibited a higher degree of surface-atmosphere coupling (& omega; ranging between 0.23 and 0.3). By year seven (2019) energy fluxes and intra-and inter-seasonal trends at the constructed watershed were comparable to natural and post-disturbance boreal landscapes indicating the system is evolving towards a functional, reclaimed ecosystem.

Automated summary

Obligatory mine reclamation efforts in the Athabasca oil sands region require the restoration of key ecosystem services, such as carbon sequestration and water and nutrient cycling. A study used eddy covariance and remote sensing measurements to analyze the changes in energy partitioning of a reclaimed fen-upland watershed over seven years. The results showed that surface conditions evolved from bare ground to robustly vegetated plant communities, altering energy fluxes and surface-atmosphere coupling.