Nighttime Cooling of an Urban Pond

Solcerová, Anna; Ven, F.H.M. Van de; Giesen, Nick van de

doi:10.3389/feart.2019.00156

Cited by 26 publications

(24 citation statements)

References 44 publications

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“…This proves to be particularly important if one desires to accurately represent the influence of blue spaces. A recent study suggests that during hot summer nights only a small part of the released heat from a waterbody is related to sensible heat (11%) (Solcerova et al, 2019). This finding underlines the need to extend research on the diurnal (especially night-time) energy balance of blue space in order to shed some light on its thermal behaviour and the potential to ameliorate the UHI.…”

Section: Blue Space -Atmosphere Dynamicsmentioning

confidence: 99%

A review of the impact of blue space on the urban microclimate

Ampatzidis

Kershaw

2020

Science of The Total Environment

121

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Section: Blue Space -Atmosphere Dynamicsmentioning

confidence: 99%

A review of the impact of blue space on the urban microclimate

Ampatzidis

Kershaw

2020

Science of The Total Environment

121

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“…The Penman method is a combination equation and is based on the two fundamental factors that determine evaporation, namely, available energy and atmospheric demand (see Table 1). The effect of these factors combined is captured by the turbulent transfer and energy balance equations for a wet surface (Brutsaert, 1982;Tanny et al, 2008;Moene and van Dam, 2014). Starting from the energy balance principle combined with the flux-gradient approach, the following form of Penman's equation is derived:…”

Section: Penmanmentioning

confidence: 99%

Evaporation from a large lowland reservoir – (dis)agreement between evaporation models from hourly to decadal timescales

Jansen

Teuling

2020

Hydrol. Earth Syst. Sci.

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Abstract. Accurate monitoring and prediction of surface evaporation become more crucial for adequate water management in a changing climate. Given the distinct differences between characteristics of a land surface and a water body, evaporation from water bodies requires a different parameterization in hydrological models. Here we compare six commonly used evaporation methods that are sensitive to different drivers of evaporation, brought about by a different choice of parameterization. We characterize the (dis)agreement between the methods at various temporal scales ranging from hourly to 10-yearly periods, and we evaluate how this reflects in differences in simulated water losses through evaporation of Lake IJssel in the Netherlands. At smaller timescales the methods correlate less (r=0.72) than at larger timescales (r=0.97). The disagreement at the hourly timescale results in distinct diurnal cycles of simulated evaporation for each method. Although the methods agree more at larger timescales (i.e. yearly and 10-yearly), there are still large differences in the projected evaporation trends, showing a positive trend to a more (i.e. Penman, De Bruin–Keijman, Makkink, and Hargreaves) or lesser extent (i.e. Granger–Hedstrom and FLake). The resulting discrepancy between the methods in simulated water losses of the Lake IJssel region due to evaporation ranges from −4 mm (Granger–Hedstrom) to −94 mm (Penman) between the methods. This difference emphasizes the importance and consequence of the evaporation method selection for water managers in their decision making.

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“…Physically, an urban pond acts as a heat absorber. Given the high thermal capacity of water, open water bodies store heat during the day and release it at night, mainly in the form of long-wave radiation [104] and latent heat fluxes. However, during warm summer days episodes, the water temperature can remain relatively hot during transition periods between seasons, maintaining a high UHI throughout the daily cycle [105], resulting in an unexpected effect.…”

Section: Effect Of Water Bodiesmentioning

confidence: 99%

Energetics of Urban Canopies: A Meteorological Perspective

Marciotto

Morais

2021

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The urban climatology consists not only of the urban canopy temperature but also of wind regime and boundary layer evolution among other secondary variables. The energetic input and response of urbanized areas is rather different to rural or forest areas. In this paper, we outline the physical characteristics of the urban canopy that make its energy balance depart from that of vegetated areas and change local climatology. Among the several canopy characteristics, we focus on the aspect ratio h/d and its effects. The literature and methods of retrieving meteorological quantities in urban areas are reviewed and a number of physical analyzes from conceptual or numerical models are presented. In particular, the existence of a maximum value for the urban heat island intensity is discussed comprehensively. Changes in the local flow and boundary layer evolution due to urbanization are also discussed. The presence of vegetation and water bodies in urban areas are reviewed. The main conclusions are as follows: for increasing h/d, the urban heat island intensity is likely to attain a peak around h/d≈4 and decrease for h/d>4; the temperature at the pedestrian level follows similar behavior; the urban boundary layer grows slowly, which in combination with low wind, can worsen pollution dispersion.

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Nighttime Cooling of an Urban Pond

Cited by 26 publications

References 44 publications

A review of the impact of blue space on the urban microclimate

A review of the impact of blue space on the urban microclimate

Evaporation from a large lowland reservoir – (dis)agreement between evaporation models from hourly to decadal timescales

Energetics of Urban Canopies: A Meteorological Perspective

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