Abstract
Second- and third-order turbulence closure models have met with mixed success when applied to the prediction of turbulent flows within and above plant canopies and model predictions are typically no better than those obtained using simpler two-equation \({(k-\varepsilon)}\) models. This is because the local gradient diffusion approximation (a crucial model requirement) cannot represent accurately turbulent transport that is dominated by the presence of ejections and sweeps whose length scales are comparable with the canopy height. To make progress, turbulent transport must be treated without approximation, as in Lagrangian probability density function (PDF) models. This study is the first to develop and to validate a PDF model of horizontally-homogeneous canopy flow. The model relies upon a prescribed length-scale that has been used elsewhere in the modelling of turbulent flows. Model predictions compare favourably with measurements of neutrally stratified turbulent flows within and above canopies of mature corn and forested eucalypt trees.
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References
Andreopoulos J, Bradshaw P (1981) Measurements of turbulence structure in the boundary layer on a rough surface. Boundary-Layer Meteorol 20: 201–213
Ayotte KW, Finnigan JF, Raupach MR (1999) A second-order closure for neutrally stratified vegetative canopy flows. Boundary-Layer Meteorol 90: 189–216
Brunet Y, Finnigan JJ, Raupach MR (1994) A wind tunnel study of air flow in waving wheat: single point velocity statistics. Boundary-Layer Meterol 70: 95–132
Deardorff JW (1978) Closure of second- and third-moment rate equations for diffusion in homogeneous. Phys Fluids 21: 525–530
Delarue BJ, Pope SB (1997) Application of PDF methods to compressible turbulent flows. Phys Fluids 9: 704–2715
den Hartog G, Shaw RH (1975) A field study of atmospheric exchange processes within a vegetative canopy. In: De Vries DA, Afgan NH (eds) Heat and mass transfer in the biosphere. Wiley, New York, pp 299–309
Dreeben TD, Pope SB (1998) Probability density function Monte Carlo simulation of near-wall turbulent flows. J Fluid Mech 357: 141–166
Finnigan J (2000) Turbulence in plant canopies. Annu Rev Fluid Mech 32: 519–571
Flesch TK, Wilson JD (1992) A two-dimensional trajectory-simulation model for non-Gaussian inhomogeneous turbulence within plant canopies. Boundary-Layer Meteorol 61: 349–374
Jenny P, Muradoglu M, Liu K, Pope SB, Caughey DA (2001) PDF simulations of a bluff-body stabilized flow. J Comput Phys 169: 1–23
Katul GG, Albertson JD (1998) An investigation of higher-order closure models for a forested canopy. Boundary-Layer Meteorol 89: 47–74
Katul GG, Chang W-H (1999) Principal length scales in second-order closure models for canopy turbulence. J Appl Meteorol 38: 1631–1643
Katul GG, Mahrt L, Poggi D, Sanz C (2004) One- and two-equation models for canopy turbulence. Boundary-Layer Meteorol 133: 81–109
Meyers TP, Baldocchi DD (1991) The budgets of turbulent kinetic energy and Reynolds stress within and above deciduous forest. Agric For Meteorol 53: 207–222
Meyers T, Paw U KT (1986) Testing of a higher-order closure model for modeling airflow within and above plant canopies. Boundary-Layer Meteorol 37: 297–311
Minier J-P, Pozorski J (1995) Analysis of a PDF model in a mixing layer case. In: Proceedings of tenth symposium on turbulent shear flows, pp 26.25–26.30
Mölder M, Klemedtsson L, Lindroth A (2004) Turbulence characteristics and dispersion in a forest-tests of Thomson’s random flight model. Agric For Meteorol 127: 203–222
Mulhearn PJ, Finnigan JJ (1978) Turbulent flow over a very rough random surface. Boundary-Layer Meteorol 15: 109–132
Nakagawa H, Nezu I (1977) Prediction of the contributions to the Reynolds stress from bursting events in open channel flows. J Fluid Mech 80: 99–128
Naot D, Shavit A, Wolfshtein M (1970) Interactions between components of the turbulent velocity correlation tensor due to pressure fluctuations. Israel J Technol 8: 259–269
Nathan R, Katul GG, Horn HS, Thomas SM, Oren R, Avissar R, Pacala SW, Levin SA (2002) Mechanisms of long-distance dispersal of seeds by wind. Nature 418: 409–413
Pinard JDJ-P, Wilson JD (2001) First- and second-order closure models for wind in a plant canopy. J Appl Meteorol 40: 1762–1768
Pope SB (1985) PDF methods for turbulent reactive flows. Prog Energy Combust Sci 11: 119–192
Pope SB (1994) On the relationship between stochastic Lagrangian models of turbulence and second-moment closures. Phys Fluids 6: 973–985
Raupach MR (1981) Conditional statistics of Reynolds stress in rough-wall and smooth-wall turbulent boundary-layers. J Fluid Mech 108: 363–382
Raupach MR, Thom AS (1981) Turbulence in and above plant canopies. Annu Rev Fluid Mech 13: 97–129
Raupach MR, Coppin PA, Legg BJ (1986) Experiments on scalar dispersion within a model plant canopy. Part 1: The turbulence structure. Boundary-Layer Meteorol 35: 21–52
Raupach MR, Finnigan JJ, Brunet Y (1996) Coherent eddies and turbulence in vegetation canopies: the mixing-layer analogy. Boundary-Layer Meteorol 78: 351–382
Rotta JC (1951) Statistiche theorie nichthomogener turbulenz. Z Phys 129: 547–572
Seginer I (1972) Interrelationship between leaf density and mixing length within plant canopies. J Meteorol Soc Jpn 50: 585–586
Shaw RH, Patton EG (2003) Canopy element influences on resolved- and subgrid-scale energy within a large-eddy simulation. Agric For Meteorol 15: 5–17
Shaw RH, Schumann U (1992) Large-eddy simulation of turbulent flow above and within a forest. Boundary-Layer Meteorol 61: 47–64
Shaw RH, Seginer I (1987) Calculation of velocity skewness in real and artificial canopies. Boundary-Layer Meterol 39: 315–332
Shaw RH, Den Hartog G, King KM, Thurtell GW (1974) Measurements of mean flow and three-dimensional turbulence intensity within a mature corn canopy. Agric Meteorol 13: 419–425
Speziale CG, Sarkar S, Gatski TB (1991) Modelling the pressure–strain correlation in turbulence. An invariant dynamical systems approach. J Fluid Mech 227: 245–272
Squires KD, Eaton JK (1991) Measurements of particle dispersion obtained from direct numerical simulations of isotropic turbulence. J Fluid Mech 226: 1–35
Thom AS (1972) Momentum mass and heat-exchange of vegetation. Q J Roy Meteorol Soc 98: 124–134
Thomson DJ (1987) Criteria for the selection of stochastic models of particle trajectories in turbulent flows. J Fluid Mech 180: 529–556
Waclawczyk M, Pozorski J, Minier J-P (2004) Probability density function computation of turbulent flows with a new near-wall model. Phys Fluids 16: 1410–1422
Wilson JD (1988) A second-order closure model for flow through vegetation. Boundary-Layer Meteorol 42: 317–392
Wilson JD, Sawford BL (1996) Review of Lagrangian stochastic models for trajectories in the turbulent atmosphere. Boundary-Layer Meteorol 78: 191–210
Wilson NR, Shaw RH (1977) A higher order closure model for canopy flow. J Appl Meteorol 16: 1197–1205
Wilson JD, Ward DP, Thurtell GW, Kidd GE (1982) Statistics of atmospheric turbulence within and above a corn canopy. Boundary-Layer Meteorol 24: 495–519
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Reynolds, A.M. Development and Validation of a Lagrangian Probability Density Function Model of Horizontally-Homogeneous Turbulence Within and Above Plant Canopies. Boundary-Layer Meteorol 142, 193–205 (2012). https://doi.org/10.1007/s10546-011-9666-5
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DOI: https://doi.org/10.1007/s10546-011-9666-5