TY - JOUR
T1 - Quadrant Analysis of the Reynolds Shear Stress in a Two-Height Canopy
AU - Shig, Lior
AU - Babin, Valery
AU - Shnapp, Ron
AU - Fattal, Eyal
AU - Liberzon, Alex
AU - Bohbot-Raviv, Yardena
N1 - Publisher Copyright:
© 2023, The Author(s), under exclusive licence to Springer Nature B.V.
PY - 2023/6
Y1 - 2023/6
N2 - We study experimental data from a two-height roughness bed forming a top and bottom canopy sublayer of heights h and h/2, respectively. We focus on the double-averaged profiles of Reynolds stresses and the difference in contributions from sweep and ejection events, Δ S . The two-height roughness adds to the typical canopy–air interface at height h another, previously unexplored, inner-canopy interface at height h/2. We apply particle image velocimetry within and above the two-height canopy and obtain the flow statistics over a representative repeating cell area. A quadrant analysis of the turbulent velocity fields is used to explore Δ S . Our results show that, like in homogeneous dense canopies, ejections dominate the contribution to the measured shear stress (Δ S< 0) above 1.5h, while sweeps dominate below (Δ S> 0). In the two-height canopy roughness, Δ S peaks twice, right below the top and the bottom sublayer heights. We test how well the measured Δ S can be reproduced by the complete and incomplete cumulant expansion methods (CEM and ICEM), and further test a simplified gradient diffusion approach to the third-order velocity moments in the ICEM (ICEM-GD). We demonstrate that CEM and ICEM reproduce the measured Δ S fairly well above the canopy but over-estimate its values inside the canopy. It is also found that ICEM-GD captures the general shape of Δ S at heights dominated by ejections and reproduces the two peaks inside the canopy. But it fails above the canopy in the range h< z< 1.5 h . This failure uncovers the counter-gradient nature of the turbulent energy and shear stress flux associated with dense canopy flows.
AB - We study experimental data from a two-height roughness bed forming a top and bottom canopy sublayer of heights h and h/2, respectively. We focus on the double-averaged profiles of Reynolds stresses and the difference in contributions from sweep and ejection events, Δ S . The two-height roughness adds to the typical canopy–air interface at height h another, previously unexplored, inner-canopy interface at height h/2. We apply particle image velocimetry within and above the two-height canopy and obtain the flow statistics over a representative repeating cell area. A quadrant analysis of the turbulent velocity fields is used to explore Δ S . Our results show that, like in homogeneous dense canopies, ejections dominate the contribution to the measured shear stress (Δ S< 0) above 1.5h, while sweeps dominate below (Δ S> 0). In the two-height canopy roughness, Δ S peaks twice, right below the top and the bottom sublayer heights. We test how well the measured Δ S can be reproduced by the complete and incomplete cumulant expansion methods (CEM and ICEM), and further test a simplified gradient diffusion approach to the third-order velocity moments in the ICEM (ICEM-GD). We demonstrate that CEM and ICEM reproduce the measured Δ S fairly well above the canopy but over-estimate its values inside the canopy. It is also found that ICEM-GD captures the general shape of Δ S at heights dominated by ejections and reproduces the two peaks inside the canopy. But it fails above the canopy in the range h< z< 1.5 h . This failure uncovers the counter-gradient nature of the turbulent energy and shear stress flux associated with dense canopy flows.
KW - Canopy flow
KW - PIV
KW - Quadrant analysis
KW - Wind tunnel
UR - http://www.scopus.com/inward/record.url?scp=85153934710&partnerID=8YFLogxK
U2 - 10.1007/s10494-023-00421-6
DO - 10.1007/s10494-023-00421-6
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AN - SCOPUS:85153934710
SN - 1386-6184
VL - 111
SP - 35
EP - 57
JO - Flow, Turbulence and Combustion
JF - Flow, Turbulence and Combustion
IS - 1
ER -