Roughness Lengths for Momentum and Heat Derived from Outdoor Urban Scale Models

Kanda, Manabu; Kanega, Masahiko; Kawai, Tōru; Moriwaki, Ryo; Sugawara, Hirofumi

doi:10.1175/jam2500.1

Cited by 175 publications

(167 citation statements)

References 39 publications

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“…However, since the ratio of roughness length for momentum to heat is considerably larger over urbanized surfaces than vegetated ones (Voogt and Grimmond, 2000), a specific approach to the modelling of Z 0HR and Z 0HC needs to be taken for the SLUCM. The relation derived by Kanda et al (2007) using an outdoor scale model and evaluated against field data is chosen because it was developed specifically for urban conditions and has recently been applied to the Simple Urban Energy Balance Model for Mesoscale Simulations (SUMM), which is very similar to the SLUCM in its approach (Kanda et al, 2005;Kawai et al, 2009). It links the roughness length for heat to that for momentum using the roughness Reynolds number and an empirical constant a K (Table II, Eqs 24, 25).…”

Section: The Single-layer Urban Canopy Model In Wrfmentioning

confidence: 99%

“…It links the roughness length for heat to that for momentum using the roughness Reynolds number and an empirical constant a K (Table II, Eqs 24, 25). The formula is applied to both the roof surfaces and canyon space using the best-fit value of a K = 1.29 identified by Kanda et al (2007) as well as two distinct values of the roughness Reynolds number (Table II, Eq. 26).…”

Section: The Single-layer Urban Canopy Model In Wrfmentioning

confidence: 99%

“…In that sense they do not relate to any objectively measurable quantity and can only be determined with regard to a given experiment (e.g. Kanda et al (2007) found a K varied (1.24-1.41) depending on dataset in their study). Although not an input, coefficients α m and β m from MacDonald et al (1998) are in the same Table V.…”

Section: Optimization With Regard To Q * and Q Hmentioning

confidence: 99%

See 2 more Smart Citations

Trade-offs and responsiveness of the single-layer urban canopy parametrization in WRF: An offline evaluation using the MOSCEM optimization algorithm and field observations

Loridan

Grimmond

Grossman‐Clarke

et al. 2010

Q.J.R. Meteorol. Soc.

102

143

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For an increasing number of applications, mesoscale modelling systems now aim to better represent urban areas. The complexity of processes resolved by urban parametrization schemes varies with the application. The concept of fitness-forpurpose is therefore critical for both the choice of parametrizations and the way in which the scheme should be evaluated. A systematic and objective model response analysis procedure (Multiobjective Shuffled Complex Evolution Metropolis (MOSCEM) algorithm) is used to assess the fitness of the single-layer urban canopy parametrization implemented in the Weather Research and Forecasting (WRF) model. The scheme is evaluated regarding its ability to simulate observed surface energy fluxes and the sensitivity to input parameters. Recent amendments are described, focussing on features which improve its applicability to numerical weather prediction, such as a reduced and physically more meaningful list of input parameters. The study shows a high sensitivity of the scheme to parameters characterizing roof properties in contrast to a low response to road-related ones. Problems in partitioning of energy between turbulent sensible and latent heat fluxes are also emphasized. Some initial guidelines to prioritize efforts to obtain urban land-cover class characteristics in WRF are provided.

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Section: The Single-layer Urban Canopy Model In Wrfmentioning

confidence: 99%

Section: The Single-layer Urban Canopy Model In Wrfmentioning

confidence: 99%

Section: Optimization With Regard To Q * and Q Hmentioning

confidence: 99%

See 1 more Smart Citation

Trade-offs and responsiveness of the single-layer urban canopy parametrization in WRF: An offline evaluation using the MOSCEM optimization algorithm and field observations

Loridan

Grimmond

Grossman‐Clarke

et al. 2010

Q.J.R. Meteorol. Soc.

102

143

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“…The aerodynamic roughness length is assumed to be the building height divided by 10. The roughness length for scalar quantities is calculated following Kanda et al (2007).…”

Section: Model Set-upmentioning

confidence: 99%

Parametrisation of the variety of human behaviour related to building energy consumption in the Town Energy Balance (SURFEX-TEB v. 8.2)

et al. 2017

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Abstract. The anthropogenic heat flux can be an important part of the urban surface energy balance. Some of it is due to energy consumption inside buildings, which depends on building use and human behaviour, both of which are very heterogeneous in most urban areas. Urban canopy parametrisations (UCP), such as the Town Energy Balance (TEB), parametrise the effect of the buildings on the urban surface energy balance. They contain a simple building energy model. However, the variety of building use and human behaviour at grid point scale has not yet been represented in state of the art UCPs. In this study, we describe how we enhance the Town Energy Balance in order to take fractional building use and human behaviour into account. We describe how we parametrise different behaviours and initialise the model for applications in France. We evaluate the spatio-temporal variability of the simulated building energy consumption for the city of Toulouse. We show that a more detailed description of building use and human behaviour enhances the simulation results. The model developments lay the groundwork for simulations of coupled urban climate and building energy consumption which are relevant for both the urban climate and the climate change mitigation and adaptation communities.

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“…1 The variation with surface roughness Reynolds number of the boundary-layer resistance factor kB −1 = ln(z 0 /z 0T ), as determined for the case of heat transfer and as reported by G&H. The solid circles (•) represent the average results from datasets originally available to G&H. Two additional averages are plotted, both discussed below: black up-pointing triangle daytime results obtained over natural fallow in Zimbabwe, and black down-pointing triangle the average of daytime measurements made over grazed pasture in Alabama. The curves drawn are due to, (1) Zhang et al (2001), (2) Owen and Thomson (1963), (3) Brutsaert (1975), and (4) Kanda et al (2007). Curve (5) has been created using random numbers kB −1 decreases uniformly from a maximum value of about 2 at Re * = 10 2 to about zero at Re * = 10 5 , much as might be concluded from Fig.…”

Section: Introductionmentioning

confidence: 99%

On the Relevance of ln(z0/z0T) = kB-1

Hicks

Pendergrass

Baker

et al. 2017

Boundary-Layer Meteorol

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The assumption that the roughness Reynolds number (Re * ) can be used as a basis for quantifying the boundary-layer property kB −1 (= ln(z 0 /z 0T )) as in some modern numerical models is questioned. While Re * is a useful property in studies of pipe flow, it appears to have only marginal applicability in the case of treeless terrain, as studied in the two experimental situations presented here. For both the daytime and night-time cases there appears to be little correlation between kB −1 and Re * . For daytime, the present studies indicate that the assumption kB −1 ≈ 2 is acceptable, while for night-time, the scatter involved in relating kB −1 to Re * suggests there is little reason to assume a direct relationship. However, while the scatter affecting all of the night-time results is large, there remains a significant correlation between the heat and momentum fluxes upon which an alternative methodology for describing bulk air-surface exchange at night could be constructed. The friction coefficient (C f ) and the turbulent Stanton number (St * ) are discussed as possible alternatives for describing bulk properties of the air layer adjacent to the surface. While describing the surface roughness in terms of the friction coefficient provides an attractive simplification relative to the conventional methodologies based on roughness length and stability considerations, use of the Stanton number shares many of uncertainties that affect kB −1 . The transitions at dawn and dusk remain demanding situations to address.

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Roughness Lengths for Momentum and Heat Derived from Outdoor Urban Scale Models

Cited by 175 publications

References 39 publications

Trade-offs and responsiveness of the single-layer urban canopy parametrization in WRF: An offline evaluation using the MOSCEM optimization algorithm and field observations

Trade-offs and responsiveness of the single-layer urban canopy parametrization in WRF: An offline evaluation using the MOSCEM optimization algorithm and field observations

Parametrisation of the variety of human behaviour related to building energy consumption in the Town Energy Balance (SURFEX-TEB v. 8.2)

On the Relevance of ln(z0/z0T) = kB-1

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