My Account: Log In | Join | Renew
Search
Author
Title
Vol.
Issue
Year
1st Page

Abstract

 

This article in SSSAJ

  1. Vol. 42 No. 6, p. 913-918
     
    Received: Aug 31, 1977
    Published: Nov, 1978


 View
 Download
 Alerts
 Permissions
 Share

doi:10.2136/sssaj1978.03615995004200060017x

Nitrate Reduction to Ammonium in Anaerobic Soil1

  1. R. J. Buresh and
  2. W. H. Patrick2

Abstract

Abstract

Knowledge regarding the pathway and soil conditions necessary for NO3- Conversion to NH4+ and organic N, a process which conserves soil N, is limited. The influence of rice straw (2.5 mg C/g soil), methanol (1.0 mg C/g soil), and glucose (1.0 mg C/g soil) on the fate of 100 µg/g 15N-labelled NO3--N was studied in Crowley silt loam. The fraction of the added NO3--N in the NO3-, N2, NH4+, and organic N forms was determined after 4-day incubations under an Ar atmosphere at 30°C. In glucose-amended soil 9 and 19% of the applied NO3--N was recovered as NH4+-N and organic N, respectively. A 1-day preincubation with glucose (0.5 mg C/g soil) before the 4-day incubation with added NO3- and glucose increased labelled NH4+-N and organic N recovery to 36 and 34% of the added NO3--N, respectively. The corresponding values for rice straw- and methanol-treated soil and soil containing no added energy source were each less than 5%.

Nitrate-N reduction to NH4+-N increased to 20.5% after a 4-day incubation when soil with no C amendment was incubated under Ar for 20 days before NO3- addition. The redox potential was −260 mV upon NO3- addition

Transformation of significant amounts of NO3- to NH4+ and organic N required intensely reduced soil conditions. The reaction was apparently not suppressed by NH4+. Evidence indicated that NO3- was reduced to NH4+ by a nonassimilatory pathway in which NO3- functioned as a terminal electron acceptor.

  Please view the pdf by using the Full Text (PDF) link under 'View' to the left.

Copyright © . Soil Science Society of America