Soil carbon, nitrogen and phosphorus changes under sugarcane expansion in Brazil

Historical data of land use change (LUC) indicated that the sugarcane expansion has mainly displaced pasture areas in Central–Southern Brazil, globally the largest producer, and that those pastures were prior established over native forests in the Cerrado biome. We sampled 3 chronosequences of land...

Full description

Saved in:
Bibliographic Details
Published in:The Science of the total environment 2015-05, Vol.515-516, p.30-38
Main Authors: Franco, André L.C., Cherubin, Maurício R., Pavinato, Paulo S., Cerri, Carlos E.P., Six, Johan, Davies, Christian A., Cerri, Carlos C.
Format: Article
Language:English
Subjects:
Agriculture
Bioenergy
Brazil
Carbon
Carbon - analysis
Crops
Crops, Agricultural - growth & development
Ecosystem
Environmental Monitoring
Environmental sustainability
Ethanol
Ethyl alcohol
Land use
Land use change
Nitrogen - analysis
Phosphorus - analysis
Pools
Saccharum - growth & development
Soil (material)
Soil - chemistry
Soil organic matter
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Historical data of land use change (LUC) indicated that the sugarcane expansion has mainly displaced pasture areas in Central–Southern Brazil, globally the largest producer, and that those pastures were prior established over native forests in the Cerrado biome. We sampled 3 chronosequences of land use comprising native vegetation (NV), pasture (PA), and sugarcane crop (SC) in the sugarcane expansion region to assess the effects of LUC on soil carbon, nitrogen, and labile phosphorus pools. Thirty years after conversion of NV to PA, we found significant losses of original soil organic matter (SOM) from NV, while insufficient new organic matter was introduced from tropical grasses into soil to offset the losses, reflecting in a net C emission of 0.4Mgha−1yr−1. These findings added to decreases in 15N signal indicated that labile portions of SOM are preserved under PA. Afterwards, in the firsts five years after LUC from PA to SC, sparse variations were found in SOM levels. After more than 20years of sugarcane crop, however, there were losses of 40 and 35% of C and N stocks, respectively, resulting in a rate of C emission of 1.3Mgha−1yr−1 totally caused by the respiration of SOM from C4-cycle plants. In addition, conversion of pastures to sugarcane mostly increased 15N signal, indicating an accumulation of more recalcitrant SOM under sugarcane. The microbe- and plant-available P showed site-specific responses to LUC as a function of different P-input managements, with the biological pool mostly accounting for more than 50% of the labile P in both anthropic land uses. With the projections of 6.4Mha of land required by 2021 for sugarcane expansion in Brazil to achieve ethanol's demand, this explanatory approach to the responses of SOM to LUC will contribute for an accurate assessment of the CO2 balance of sugarcane ethanol. •An explanatory approach to the responses of soil C, N and P to sugarcane expansion is provided.•Conversion of pasture to sugarcane produces a net C emission of 1.3Mgha−1yr−1 in 20years.•C emission is caused by the respiration of SOM from C4-cycle plants.•15N signal mostly increased, indicating an accumulation of recalcitrant SOM under sugarcane.•Biological pool accounting for more than 50% of the soil labile P in both land uses
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2015.02.025