Journal
JOURNAL OF AGRICULTURAL METEOROLOGY
Volume 78, Issue 1, Pages 41-45Publisher
SOC AGRICULTURAL METEOROLOGY JAPAN
DOI: 10.2480/agrmet.D-21-00033
Keywords
Bubbling frequency; CH 4 flux; High time resolution; Measurement time; Portable gas analyzer
Funding
- JSPS KAKENHI [JP19K22921, JP19H03096, JP20J40189, JPNP18016]
- New Energy and Industrial Technology Development Organization (NEDO) [JPNP18016]
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A modified closed-chamber method was developed to estimate CH4 emissions from rice paddies. The study found that the estimated flux was sensitive to time length with short closure times but became less sensitive with longer closure. The minimum time length required for accurate flux measurement varied depending on the frequency of bubbling events.
A modified closed-chamber method for estimating total, plant-mediated, and bubbling (ebullition) emissions of CH4 from rice paddies has been developed to use high-time-resolution CH4 concentration data (-1 Hz) obtained by a spectroscopic mobile gas analyzer. Here we aimed at determining an appropriate minimum time length of chamber closure for accurate flux measurement by investigating 3255 datasets obtained from a 2-year field survey. To investigate the minimum time length for each chamber measurement, we generated a series of datasets from each measurement: by setting the hypothetical termination time of the chamber closure ahead in 1-min intervals, we obtained various chamber CH4 concentration time series with different durations of chamber closure, and separately estimated CH4 emissions via rice plants and bubbling from each. The estimated flux was sensitive to time length with short closure times, but became less sensitive with longer closure. We defined the minimum time length at which the difference in estimated flux between adjacent time windows was small enough ( 10% of plant-mediated emission). The estimated minimum time length differed from one measurement to another, but 10 min was sufficient for 99% of cases. Detailed analysis showed a positive correlation between minimum time length and frequency of bubbling events; the time length needed to be longer as bubbling events became more frequent. From this relationship, we computed the appropriate chamber-duration time as a function of bubbling frequency. In the absence of ebullition, 4-5 min was sufficient, but as the bubbling frequency increased to 2.5 times per minute 15-20 min was necessary for accurate pathway-dependent flux measurements.
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