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Scalar Similarity for Relaxed Eddy Accumulation Methods

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Abstract

The relaxed eddy accumulation (REA) method allows the measurement of trace gas fluxes when no fast sensors are available for eddy covariance measurements. The flux parameterisation used in REA is based on the assumption of scalar similarity, i.e., similarity of the turbulent exchange of two scalar quantities. In this study changes in scalar similarity between carbon dioxide, sonic temperature and water vapour were assessed using scalar correlation coefficients and spectral analysis. The influence on REA measurements was assessed by simulation. The evaluation is based on observations over grassland, irrigated cotton plantation and spruce forest.

Scalar similarity between carbon dioxide, sonic temperature and water vapour showed a distinct diurnal pattern and change within the day. Poor scalar similarity was found to be linked to dissimilarities in the energy contained in the low frequency part of the turbulent spectra ( < 0.01 Hz).

The simulations of REA showed significant change in b-factors throughout the diurnal course. The b-factor is part of the REA parameterisation scheme and describes a relation between the concentration difference and the vertical flux of a trace gas. The diurnal course of b-factors for carbon dioxide, sonic temperature and water vapour matched well. Relative flux errors induced in REA by varying scalar similarity were generally below  ± 10%. Systematic underestimation of the flux of up to  − 40% was found for the use of REA applying a hyperbolic deadband (HREA). This underestimation was related to poor scalar similarity between the scalar of interest and the scalar used as proxy for the deadband definition.

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Author notes

  1. Johannes Ruppert

    Present address: Environmental Measuring Department, Verein Deutscher Zementwerke e.V. (VDZ), Research Institute of the Cement Industry, Duesseldorf, Germany

  2. Christoph Thomas

    Present address: Department of Forest Science, Oregon State University, Corvallis, OR, U.S.A.

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  1. Department of Micrometeorology, University of Bayreuth, Universitätsstrasse 30, D-95440, Bayreuth, Germany

    Johannes Ruppert, Christoph Thomas & Thomas Foken

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  1. Johannes Ruppert
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Correspondence to Johannes Ruppert.

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Ruppert, J., Thomas, C. & Foken, T. Scalar Similarity for Relaxed Eddy Accumulation Methods. Boundary-Layer Meteorol 120, 39–63 (2006). https://doi.org/10.1007/s10546-005-9043-3

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