Eddy-covariance fluxes of CO2, CH4 and N2O in a drained peatland forest after clear-cutting

Rotation forestry based on clear-cut harvesting, site preparation, planting and intermediate thinnings is currently the dominant management approach in Fennoscandia. However, understanding of the greenhouse gas (GHG) emissions following clear-cutting remains limited, particularly in drained peatland...

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Bibliographic Details
Main Authors: Tikkasalo, Olli-Pekka, Peltola, Olli, Alekseychik, Pavel, Heikkinen, Juha, Launiainen, Samuli, Lehtonen, Aleksi, Li, Qian, Martínez-García, Eduardo, Peltoniemi, Mikko, Salovaara, Petri, Tuominen, Ville, Mäkipää, Raisa
Other Authors: Ilmatieteen laitos, Finnish Meteorological Institute, orcid:0000-0002-0612-128X
Format: Article in Journal/Newspaper
Language:English
Published: Copernicus Publications 2025
Subjects:
emissions
carbon dioxide
greenhouse gases
forests
peatlands
peatland forests
blogs
climate changes
atmosphere (earth)
machine learning
päästöt
hiilidioksidi
kasvihuonekaasut
metsät
turvemaat
suometsät
suot
ilmastonmuutokset
ilmakehä
koneoppiminen
Fennoscandia
Online Access:http://hdl.handle.net/10138/593712
Description
Summary:Rotation forestry based on clear-cut harvesting, site preparation, planting and intermediate thinnings is currently the dominant management approach in Fennoscandia. However, understanding of the greenhouse gas (GHG) emissions following clear-cutting remains limited, particularly in drained peatland forests. In this study, we report eddy-covariance-based (EC-based) net emissions of carbon dioxide (CO2), methane (CH4) and nitrous oxide (N2O) from a fertile drained boreal peatland forest 1 year after wood harvest. Our results show that, at an annual scale, the site was a net CO2 source. The CO2 emissions dominate the total annual GHG balance (23.3 t CO2 eq. ha−1 yr−1, 22.4–24.1 t CO2 eq. ha−1 yr−1, depending on the EC gap-filling method; 82.0 % of the total), while the role of N2O emissions (5.0 t CO2 eq. ha−1 yr−1, 4.9–5.1 t CO2 eq. ha−1 yr−1; 17.6 %) was also significant. The site was a weak CH4 source (0.1 t CO2 eq. ha−1 yr−1, 0.1–0.1 t CO2 eq. ha−1 yr−1; 0.4 %). A statistical model was developed to estimate surface-type-specific CH4 and N2O emissions. The model was based on the air temperature, soil moisture and contribution of specific surface types within the EC flux footprint. The surface types were classified using unoccupied aerial vehicle (UAV) spectral imaging and machine learning. Based on the statistical models, the highest surface-type-specific CH4 emissions occurred from plant-covered ditches and exposed peat, while the surfaces dominated by living trees, dead wood, litter and exposed peat were the main contributors to N2O emissions. Our study provides new insights into how CH4 and N2O fluxes are affected by surface-type variation across clear-cutting areas in forested boreal peatlands. Our findings highlight the need to integrate surface-type-specific flux modelling, EC-based data and chamber-based flux measurements to comprehend the GHG emissions following clear-cutting and regeneration. The results also strengthen the accumulated evidence that recently clear-cut peatland forests are significant ...

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