Abstract

We present and interpret long‐term measurements of the chemically and radiatively important trace gas nitrous oxide (N 2 O) obtained during the Atmospheric Lifetime Experiment (ALE) and its successor the Global Atmospheric Gases Experiment (GAGE). The ALE/GAGE data for N 2 O comprise over 110,000 individual calibrated real‐time air analyses carried out over a 10‐year (July 1978–June 1988) time period. These measurements indicate that the average concentration in the northern hemisphere is persistently 0.75±0.16 ppbv higher than in the southern hemisphere and that the global average linear trend in N 2 O lies in the range from 0.25 to 0.31% yr −1 , with the latter result contingent on certain assumptions about the long‐term stability of the calibration gases used in the experiment. Interpretation of the data, using inverse theory and a 9‐box (grid) model of the global atmosphere, indicates that the N 2 O surface emissions into the 90°N–30°N, 30°N–0°, 0°–30°S, and 30°S–90°S semihemispheres account for about 22–34, 32–39, 20–29 and 11–15% of the global total emissions, respectively. The measured trends and latitudinal distributions are consistent with the hypothesis that stratospheric photodissociation is the major atmospheric sink for N 2 O, but they do not support the hypothesis that the temporal N 2 O increase is caused solely by increases in anthropogenic N 2 O emissions associated with fossil fuel combustion. Instead, the cause for the N 2 O trend appears to be a combination of a growing tropical source (probably resulting from tropical land disturbance) and a growing northern mid‐latitude source (probably resulting from a combination of fertilizer use and fossil fuel combustion). The exact combination of these sources which best fits the data depends on the assumed tropospheric‐stratospheric exchange rates for N 2 O in the northern hemisphere relative to the southern hemisphere. Accepting a theoretically‐calculated N 2 O lifetime of 166±16 years due to stratospheric destruction only, we deduce from the ALE/GAGE data a 10‐year average global N 2 O emission rate of (20.5±2.4) × 10 12 g N 2 O yr −1 , but with significant year‐to‐year variations in emissions associated perhaps with year‐to‐year variations in tropical land disturbance.