Comparison of slant open-path flux gradient and static closed chamber techniques to measure soil N2O emissions

Abstract

Improving direct field measurement techniques to quantify gas emissions from cropped agricultural fields is challenging. We compared nitrous oxide (N 2 O) emissions measured with static closed chambers to those from a newly developed aerodynamic flux gradient (FG) approach. Measurements were made at a vegetable farm following chicken manure application. The FG calculations were made with a single open-path Fourier transform infrared (OP-FTIR) spectrometer (height of 1.45 m) deployed in a slant-path configuration, sequentially aimed at retro reflectors at heights of 0.8 and 1.8m above ground. Hourly emissions were measured with the FG technique, but once a day between 10:00 and 13:00 with chambers. We compared the concurrent emission ratios (FG=chamber) of these two techniques and found N 2 O emission rates from a celery crop farm measured at midday by FG were statistically higher (1.22-1.40 times) than those from the chambers measured at the same time. Our results suggest the OP-FTIR slant-path FG configuration worked well in this study: It was sufficiently sensitive to detect the N 2 O gradients over our site, giving high temporal resolution N 2 O emissions corresponding to a large measurement footprint.