Abstract
Abstract. The concept of disjunct eddy sampling (DES) for use in measuring ecosystem-level micrometeorological fluxes is re-examined. The governing equations are discussed as well as other practical considerations and guidelines concerning this sampling method as it is applied to either the disjunct eddy covariance (DEC) or disjunct eddy accumulation (DEA) techniques. A disjunct eddy sampling system was constructed that could either be combined with relatively slow sensors (response time of 2 to 40 s) to measure fluxes using DEC, or could also be used to accumulate samples in stable reservoirs for later laboratory analysis (DEA technique). Both the DEC and DEA modes of this sampler were tested against conventional eddy covariance (EC) for fluxes of either CO2 (DEC) or isoprene (DEA). Good agreement in both modes was observed relative to the EC systems. However, the uncertainty in a single DEA flux measurement was considerable (~40%) due to both the reduced statistical sampling and the analytical precision of the concentration difference measurements. We have also re-investigated the effects of nonzero mean vertical wind velocity on accumulation techniques as it relates to our DEA measurements. Despite the higher uncertainty, disjunct eddy sampling can provide an alternative technique to eddy covariance for determining ecosystem-level fluxes for species where fast sensors do not currently exist.
Highlights
Eddy covariance (EC) has gained acceptance as one of the most direct means of measuring ecosystem-level fluxes
In this paper we have re-examined the method of disjunct eddy sampling (DES) and its application towards measuring ecosystem-level fluxes
We have developed a sampler that can be used for disjunct eddy sampling in either a covariance (DEC) or accumulation (DEA) mode
Summary
Eddy covariance (EC) has gained acceptance as one of the most direct means of measuring ecosystem-level fluxes. The discontinuous nature of DES allows for tractable mass flow control for each sample and allows eddy accumulation to be a viable flux method (Disjunct Eddy Accumulation or DEA, Rinne et al, 2000). This provides a powerful alternative to both gradients or REA, as this is a direct flux technique (not reliant on similarity assumptions), can be used over a variety of canopies, and provides a method in which samples can be stored, transported and analyzed by a variety of slower methods. We show direct evaluation of this sampler versus eddy covariance measurements in both operating modes
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