Short‐term carbon emissions: Effect of various tree harvesting, transport, and tillage methods under a eucalyptus plantation

Eucalyptus forests stand out for their potential to sequestrate atmospheric CO2 in soil organic matter throughout their growth. Our study evaluated the harvesting and tillage effect in eucalyptus plantations to the soil CO2, 13C–CO2, and CH4 fluxes. This study was carried out in a eucalyptus plantat...

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Bibliographic Details
Published in:Land degradation & development 2018-11, Vol.29 (11), p.3995-4004
Main Authors: Fialho, Ricardo Cardoso, Silva Teixeira, Rafael, Teixeira, Ana Paula Mendes, Silva, Ivo Ribeiro
Format: Article
Language:English
Subjects:
13C
Carbon dioxide
C–CH4
C–CO2
Design of experiments
eucalypt harvest residue
Eucalyptus
Experimental design
Fluxes
Harvesting
Methane
Organic carbon
Organic matter
Organic soils
Pasture
Plantations
Soil density
Soil moisture
soil organic carbon
Soil organic matter
Tillage
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Summary:Eucalyptus forests stand out for their potential to sequestrate atmospheric CO2 in soil organic matter throughout their growth. Our study evaluated the harvesting and tillage effect in eucalyptus plantations to the soil CO2, 13C–CO2, and CH4 fluxes. This study was carried out in a eucalyptus plantation, on Typic Haplustox soil. The study used stands cultivated with eucalyptus at the end of the first rotation (7 years), established over degraded pastures. The effect of harvesting was assessed through comparisons of samples taken before and after harvesting with Feller + Skidder (F + S) and Harvester + Forwarder (H + F) methods and separate samples of plant rows (R) and plant interrows (IR). The effect of tillage was assessed through comparisons of R and IR samples taken before and after subsoiling tillage in areas harvested with F + S and H + F methods. A nested experimental design was used with eight replicates. The harvest operation (F + S and H + F methods) in eucalyptus plantations increased soil CO2 fluxes, which were primarily derived from eucalyptus materials (‘new C’). The F + S harvesting method resulted in the highest soil density and soil moisture reduction in the IR. The tillage operation (subsoiling) resulted in higher soil CO2 fluxes in eucalyptus plantations harvest with F + S and H + F methods. However, the H + F method preserved the older soil organic carbon (40.8% in R and 50.4% IR of C4–CO2). The soil in the eucalyptus plantations showed soil CH4 influxes, and the harvest and tillage (subsoiling) operations did not negatively affect the net soil CH4 influx in the studied eucalyptus plantations.
ISSN:1085-3278
1099-145X
DOI:10.1002/ldr.3161