AI Article Synopsis
- Inland lakes significantly influence water and greenhouse gas cycling, and this study assesses a flux-gradient system for measuring water vapor, CO2, and CH4 at the lake-air interface.
- Measurements demonstrate the system's precision, with a majority of gas fluxes exceeding measurement errors, confirming reliable data retrieval over a 620-day period.
- The flux-gradient method offers advantages like simultaneous gas measurement, minimal density corrections, good resolution for small CH4 fluxes, and noninvasive data collection, although enhancement is needed for accurate CO2 flux measurements in more lakes.
Article Abstract
Inland lakes play important roles in water and greenhouse gas cycling in the environment. This study aims to test the performance of a flux-gradient system for simultaneous measurement of the fluxes of water vapor, CO2, and CH4 at a lake-air interface. The concentration gradients over the water surface were measured with an analyzer based on the wavelength-scanned cavity ring-down spectroscopy technology, and the eddy diffusivity was measured with a sonic anemometer. Results of a zero-gradient test indicate a flux measurement precision of 4.8 W m(-2) for water vapor, 0.010 mg m(-2) s(-1) for CO2, and 0.029 μg m(-2) s(-1) for CH4. During the 620 day measurement period, 97%, 69%, and 67% of H2O, CO2, and CH4 hourly fluxes were higher in magnitude than the measurement precision, which confirms that the flux-gradient system had adequate precision for the measurement of the lake-air exchanges. This study illustrates four strengths of the flux-gradient method: (1) the ability to simultaneously measure the flux of H2O, CO2, and CH4; (2) negligibly small density corrections; (3) the ability to resolve small CH4 gradient and flux; and (4) continuous and noninvasive operation. The annual mean CH4 flux (1.8 g CH4 m(-2) year(-1)) at this hypereutrophic lake was close to the median value for inland lakes in the world (1.6 g CH4 m(-2) year(-1)). The system has adequate precision for CH4 flux for broad applications but requires further improvement to resolve small CO2 flux in many lakes.
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Article Synopsis
- Inland lakes significantly influence water and greenhouse gas cycling, and this study assesses a flux-gradient system for measuring water vapor, CO2, and CH4 at the lake-air interface.
- Measurements demonstrate the system's precision, with a majority of gas fluxes exceeding measurement errors, confirming reliable data retrieval over a 620-day period.
- The flux-gradient method offers advantages like simultaneous gas measurement, minimal density corrections, good resolution for small CH4 fluxes, and noninvasive data collection, although enhancement is needed for accurate CO2 flux measurements in more lakes.
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Phys Rev E Stat Nonlin Soft Matter Phys
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