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This article in SSSAJ

  1. Vol. 70 No. 2, p. 367-377
    Received: Apr 4, 2005

    * Corresponding author(s): jmclain@uswcl.ars.ag.gov
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Moisture Controls on Trace Gas Fluxes in Semiarid Riparian Soils

  1. Jean E.T. McLain *a and
  2. Dean A. Martensb
  1. a USDA-ARS, U.S. Water Conservation Lab., 4331 East Broadway Rd., Phoenix, AZ 85040
    b Dean A. Martens (deceased), USDA-ARS, Southwest Watershed Research Center, 2000 East Allen Rd., Tucson, AZ 85719


Variability in seasonal soil moisture (SM) and temperature (T) can alter ecosystem/atmosphere exchange of the trace gases carbon dioxide (CO2), nitrous oxide (N2O), and methane (CH4). This study reports the impact of year-round SM status on trace gas fluxes in three semiarid vegetation zones, mesquite (30 g organic C kg−1 soil), open/forb (6 g organic C kg−1 soil), and sacaton (18 g organic C kg−1 soil) from July 2002–September 2003 in southeastern Arizona. Carbon dioxide and N2O emissions were highly dependent on available SM and T. During the heavy rains of the 2002 monsoon (238 mm total rainfall), large differences in soil C content did not correlate with variations in CO2 production, as efflux averaged 235.6 ± 39.5 mg CO2 m−2 h−1 over all sites. In 2003, limited monsoon rain (95 mm total rainfall) reduced CO2 emissions by 19% (mesquite), 40% (open), and 30% (sacaton), compared with 2002. Nitrous oxide emissions averaged 21.1 ± 13.4 (mesquite), 2.1 ± 4.4 (open), and 3.9 ± 5.2 μg N2O m−2 h−1 (sacaton) during the 2002 monsoon. Limited monsoon 2003 rainfall reduced N2O emissions by 47% in the mesquite, but N2O production increased in the open (55%) and sacaton (5%) sites. Following a dry winter and spring 2002 (15 mm total rainfall), premonsoon CH4 consumption at all sites was close to zero, but following monsoon moisture input, the CH4 sink averaged 26.1 ± 6.3 μg CH4 m−2 h−1 through April 2003. Laboratory incubations showed potentials for CH4 oxidation from 0 to 45 cm, suggesting that as the soil surface dried, CH4 oxidation activity shifted downward in the sandy soils. Predicted climate change shifts in annual precipitation from one dominated by summer monsoon rainfall to one with higher winter precipitation may reduce soil CO2 and N2O emissions while promoting CH4 oxidation rates in semiarid riparian soils of the Southwest, potentially acting as a negative feedback for future global warming.

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