Maintaining Pressure Equilibrium Inside and Outside the Chamber

Pressure equilibrium between air inside a soil CO2 flux chamber and the surrounding air outside the chamber must be maintained during the measurement if measured flux is to accurately represent the rate occurring naturally outside the chamber. A simple open vent tube connecting to the chamber often has been used to maintain the pressure equilibrium. This approach is effective only under calm conditions. Under windy conditions, negative pressure excursions occur as wind blows over the vent tube’s external open end because of the Venturi effect. This causes a mass flow of CO2 -rich air from the soil into the chamber, leading to a significant overestimation of soil CO2 flux. In fact, some researchers have recommended eliminating the vent tube after recognizing the potential problem from the Venturi effect.

LI-COR has developed a patent-pending vent design which has a tapered cross section (illustration). Conservation of mass requires the average air flow rate to drop as air enters the vent. According to Bernoulli’s equation, as the rate of air flow slows down, a major portion of the dynamic pressure is converted to static pressure, raising the static pressure with which the chamber equilibrates. The vent design is radially symmetric to eliminate sensitivity to wind direction. Data from field experiments on differential pressure measurements between air inside the chamber and the outside ambient air show that chambers equipped with this vent maintain the pressure of outside air under calm and windy conditions. LI-COR’s vent virtually eliminates the Venturi effect.

Xu, L., M. D. Furtaw, R. A. Madsen, R. L. Garcia, D. J. Anderson, and D. K. McDermitt (2006), On maintaining pressure equilibrium between a soil CO2 flux chamber and the ambient air, J. Geophys. Res., 111, D08S10, doi:10.1029/2005JD006435.

Chamber Drive Mechanisms

The different drive mechanisms controlling the opening and closing of the long-term chambers do not affect the measurements. Both chambers lower slowly onto the measurement collar to minimize pressure pulsations that change soil CO2 flux rates.

The vertical drive of the 8100-101 chamber may work better between and within crop rows by positioning the chamber to open and close without affecting adjacent plants.

The 8100-104 has six settings for the chamber’s open position. This gives researchers an advantage when placing the chamber under short plant canopies or other situations where these open positions may help to avoid terrain or other obstructions.

Baseplate Perforations

Structurally, the environmental impact of the 8100-101 and 8100-104 chambers is reduced with perforations in the baseplates to minimize disturbance of the environmental conditions surrounding the chambers. The perforations allow minimal perturbations to natural sunlight, precipitation, wind, etc., and they prevent a concentration gradient-induced impedance of CO2 flux from the soil, which can occur under a nonperforated, uniform plate.