Abstract
An understanding of the effect of fertility management on soil surface fluxes of CO2, N2O, and CH4 is essential in evaluating C sequestration measures that attempt to increase the amount of crop residue returned to the soil through increased fertilizer inputs. In this study, soil surface CO2 flux was measured over a 27‐mo sampling period in continuous maize (Zea mays L.) plots managed under either an intensive fertility regime (M2) or recommended best management (M1). Flux was significantly higher in the M2 treatment on only 2 d during the first growing season. Annual estimates of soil surface CO2 flux, based on a modified exponential equation that incorporates leaf area index (LAI) to predict temporal changes in soil respiration, averaged 11550 kg C ha−1 yr−1 for both treatments (approximately 31.64 kg C ha−1 d−1 on average). Within row soil surface CO2 flux was, on average, 64% higher than between row flux. Plant population did not significantly affect measured soil surface CO2 flux. While fertility management had no significant effect on CH4 flux, N2O flux as measured on 3 d during the 2000 growing season was significantly higher in the M2 treatment. In 2001, no significant differences in N2O flux were observed, possibly due to changes in N management and irrigation method. Electrical conductivity measured during the 2000 and 2001 growing seasons was significantly higher in the M2 treatment while pH measured during the 2001 season was significantly lower for M2.
Highlights
That the fertilizer treatment was significant for only 1 out of 19 sampling dates
On July 7, soil temperature was significantly lower in the high plant population (P3) plant population than in either the medium plant population (P2) or low plant population (P1) plant populations (p ϭ 0.04 and 0.009, respectively)
leaf area index (LAI) was considerably higher in the P3 plant population (5.2 Ϯ 0.4) than in the P2 (3.6 Ϯ 0.2) and P1 (2.7 Ϯ 0.9) plant populations
Summary
That the fertilizer treatment was significant for only 1 out of 19 sampling dates. we know of no studies that have compared soil surface CO2 flux in maize receiving standard recommended N levels and those receiving intensive levels designed to achieve maximum yield potential and increase crop residue. In addition to CO2, increasing levels of atmospheric N2O and CH4 are of particular concern due to their considerably higher global warming potentials (GWP) relative to CO2. Nitrous oxide is produced when plant-available N forms are subjected to the bacterial processes of denitrification and nitrification (Firestone and Davidson, 1989), and various studies have shown that N2O emission from agricultural soil is significantly increased by application of synthetic N fertilizers (Linn and Doran, 1984; Bronson and Mosier, 1993). Global N2O emissions from row-crop agriculture are assumed to be the greatest contributor to global N2O flux (Robertson, 1993), with cultivated soils comprising 27% of the total N2O-N added from all known sources (Beauchamp, 1997). Few studies have examined the effect of fertilizer application on CH4 uptake by cultivated soils. This article is a U.S government work, and is not subject to copyright in the United States
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