Coherent Eddies Transporting Passive Scalars Through the Plant Canopy Revealed by Large-Eddy Simulations Using the Lattice Boltzmann Method

Watanabe Tsutomu; Takagi Marie; Shimoyama Kou; Kawashima Masayuki; Onodera Naoyuki; Inagaki Atsushi

Title	en Coherent Eddies Transporting Passive Scalars Through the Plant Canopy Revealed by Large-Eddy Simulations Using the Lattice Boltzmann Method
Creator	en Watanabe, Tsutomu en Takagi, Marie en Shimoyama, Kou NRID 1000050391115 en Kawashima, Masayuki NRID 1000010281833 en Onodera, Naoyuki en Inagaki, Atsushi
Accessrights	metadata only access
Rights	en The final publication is available at link.springer.com
Subject	Other en Double distribution function Other en Gram-Charlier distribution Other en Non-local transport Other en Scalar turbulence Other en Sweep and ejection NDC 450
Description	Abstract en A double-distribution-function lattice Boltzmann model for large-eddy simulations of a passive scalar field in a neutrally stratified turbulent flow is described. In simulations of the scalar turbulence within and above a homogeneous plant canopy, the model's performance is found to be comparable with that of a conventional large-eddy simulation model based on the Navier-Stokes equations and a scalar advection-diffusion equation in terms of the mean turbulence statistics, budgets of the second moments, power spectra, and spatial two-point correlation functions. For a top-down scalar, for which the plant canopy serves as a distributed sink, the variance and flux of the scalar near the canopy top are predominantly determined by sweep motions originating far above the canopy. These sweep motions, which have spatial scales much larger than the canopy height, penetrate deep inside the canopy and cause scalar sweep events near the canopy floor. By contrast, scalar ejection events near the canopy floor are induced by coherent eddies generated near the canopy top. The generation of such eddies is triggered by the downward approach of massive sweep motions to existing wide regions of weak ejective motions from inside to above the canopy. The non-local transport of scalars from above the canopy to the canopy floor, and vice versa, is driven by these eddies of different origins. Such non-local transport has significant implications for the scalar variance and flux budgets within and above the canopy, as well as the transport of scalars emitted from the underlying soils to the atmosphere.
Publisher	en Springer
Date	Issued2021-07-09
Language	eng
Resource Type	journal article
Version Type	NA
Identifier	HDL http://hdl.handle.net/2115/82362
Relation	isIdenticalTo DOI https://doi.org/10.1007/s10546-021-00633-1
Journal	PISSN 0006-8314 en Boundary-layer meteorology Volume Number181 Page Start39 Page End71
Oaidate	2023-07-26