Soil management affects carbon dynamics and yield in a Mediterranean peach orchard

► We examined the effect of 7-year of sustainable practices on carbon reserves. ► Changed management practices increased soil and litter carbon reserves (and yield). ► We report the seasonal pattern of CO2 soil emission in a peach orchard. ► The distance from row affects CO2 soil emission rate. ► Sp...

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Bibliographic Details
Published in:Agriculture, ecosystems & environment ecosystems & environment, 2012-10, Vol.161, p.46-54
Main Authors: Montanaro, Giuseppe, Dichio, Bartolomeo, Briccoli Bati, Caterina, Xiloyannis, Cristos
Format: Article
Language:English
Subjects:
aboveground biomass
Agronomy. Soil science and plant productions
Biological and medical sciences
carbon
carbon dioxide
Carbon inputs
carbon markets
CO2 flux
crop yield
dead wood
emissions
field experimentation
Fundamental and applied biological sciences. Psychology
General agroecology
General agroecology. Agricultural and farming systems. Agricultural development. Rural area planning. Landscaping
General agronomy. Plant production
Generalities. Agricultural and farming systems. Agricultural development
microbial activity
orchards
peaches
pruning
roots
Seasonal pattern
Soil carbon reserves
Soil management
soil water content
Spatial variability
temporal variation
tillage
topography
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Summary:► We examined the effect of 7-year of sustainable practices on carbon reserves. ► Changed management practices increased soil and litter carbon reserves (and yield). ► We report the seasonal pattern of CO2 soil emission in a peach orchard. ► The distance from row affects CO2 soil emission rate. ► Spatial variability of CO2 emissions shows that these concentrate along the row. A field trial was conducted over a seven-year period, in Mediterranean peach orchard. The aims were (i) to explore the effects of alternative soil-management practices (Amng) on soil and litter carbon (C) reserves, (ii) to monitor the seasonal and (iii) spatial variations of soil CO2 flushes. The alternative management included no tillage, retention of all aboveground biomass and application of imported organic amendments (15tha−1y−1 fresh weigh). Locally conventional management (Lmng) served as the control: i.e. tillage, mineral fertilisation, removal of prunings. The mean total annual C inputs were 4.2 and 2.4tha−1 in Amng and Lmng, respectively. Spatial and temporal variations in CO2 soil emissions over a 20m2 plot (×2) were assessed (Li-6400, LI-COR, USA) on the assumption that root topography and microbial activity declined systematically with distance from the row line. Under Amng practices soil C significantly increased up to 1.78% against 1.38% at Lmng block. The C stored as litter and dead wood in Amng, was 16-times that in Lmng. On a whole-season basis, CO2 losses were 20% higher in Amng than in Lmng. Soil CO2 emissions were mostly from the in-row, with the inter-row emissions being lower, especially due to reduced soil-water content during the drier months. It is concluded that despite a higher CO2 soil emissions, alternative management techniques will partially offset atmospheric CO2 rise through increased soil C reserves, and that spatial variability of emissions must be taken into account if the accuracy of estimates of large-scale emissions are to be improved.
ISSN:0167-8809
1873-2305
DOI:10.1016/j.agee.2012.07.020