Stability Dependence of Canopy Flows Observed in a Larch Forest

Forest energy, water, and mass budgets are particularly important for better understanding global climate change due to the extensive distribution of forests over land. To evaluate such budgets accurately using numerical models, it is crucial to understand turbulent motion near the canopy, which contributes largely to vertical transfer between a forest and the atmosphere. Despite advances in our understanding of the canopy flow, few studies have examined the continuous spectral behavior over a wide stability range. The dependence on atmospheric stability of flow characteristics was investigated in a larch forest in Japan. Micrometeorological measurements of three-dimensional wind velocity and air temperature were taken at two heights above the forest, namely 1.7 and 1.2 times the mean canopy height h. Under near-neutral and stable conditions, the observed turbulence statistics suggest that the flow was likely to be that of the atmospheric surface layer (ASL) at 1.7h, and of the roughness sublayer (RSL) at 1.2h. However, in turbulence spectra, canopy-induced large coherent motions appeared clearly at both heights. Even under strongly stable conditions, the large-scale motions were retained at 1.2h, whereas they were overwhelmed by small-scale motions at 1.7h. This phenomenon was probably due to the enhanced contribution of the ASL turbulence associated with nocturnal decay of the RSL depth, because the small-scale motions appeared at frequencies close to the peak frequencies of well-known ASL spectra. This result supports the relatively recent concept that canopy flow is a superimposition of coherent motions and the ASL turbulence. The large-scale motions were retained in temperature spectra over a wider region of stability compared to streamwise wind spectra, suggesting that a canopy effect extended higher up for temperature than wind. The streamwise spacing of dominant eddies according to the plane mixing-layer analogy was only valid in a narrow range at near neutral, and it was stabilized at nearly half its value under stable conditions.