Seasonality of the Urban Heat Island Effect in Madison, Wisconsin

Schatz, Jason; Kucharik, Christopher J.

doi:10.1175/jamc-d-14-0107.1

Cited by 122 publications

(118 citation statements)

References 58 publications

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“…These experimental results show that road snow clearing has a stronger effect on T min than on T max (not shown), which is consistent with the results of Schatz and Kucharik (2014). This result also indicates that the decrease in T max is attributable mainly to snow cover on roofs.…”

Section: Discussionsupporting

confidence: 88%

“…Therefore, snow cover in urban areas is of comparable importance to anthropogenic heat release when simulating the spatial air temperature contrast between urban and surrounding areas. Schatz and Kucharik (2014) reported snow depth effects on nocturnal surface air temperature through ground heat transfer change. To confirm the effect of snow depth and road snow clearing on urban surface air temperature, we conducted sensitivity experiments as the CL0, CL20, and NO_CL runs (Table 1).…”

Section: Discussionmentioning

confidence: 99%

“…Relationships between snow and urban heat islands have been explored in previous studies (Malevich and Klink 2011;Schatz and Kucharik 2014), and the following key results have been reported. 1) The effect of snow is smaller in rural areas than in urban areas because of dirty snow and relatively large snowfree areas such as walls and bare areas formed by snow melt in urban areas.…”

Section: Introductionmentioning

confidence: 99%

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Evaluating the Role of Snow Cover in Urban Canopy Layer on the Urban Heat Island in Sapporo, Japan with a Regional Climate Model

Mori

Sato

2015

Journal of the Meteorological Society of Japan

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Climate monitoring in urban areas is important because climate change in densely populated areas has a strong influence on society. The rate of long-term temperature increase in high-latitude snowy urban areas is relatively large due to global warming and urban heat islands. However, the influence of snow cover on urban heat islands is unclear. The purpose of this study is to assess the effect of snow cover in urban canopy layer on winter heat islands using a mesoscale atmospheric model coupled with an urban canopy model. Numerical experiments indicate that snow cover in urban areas serves to decrease surface air temperature, with a stronger decrease in daily maximum temperatures (0.4 -0.6°C) than daily minimum temperatures (0.1 -0.3°C). The increase in surface albedo is primarily responsible for the decrease in net shortwave radiation and sensible heat flux. In addition, increased evaporation causes a weakened sensible heat flux. The estimated snow cover effect during the day is comparable with the typical magnitude of anthropogenic heat release. In urban canopy layer, snow cover on roofs plays a significant role in reducing surface air temperature. Snow clearing on roads tends to increase nocturnal surface air temperature, especially in suburban areas because decreased snow depth increases ground heat transfer. These results indicate that snow cover in urban canopy layer reduces surface air temperature, resulting in weakened urban heat islands.

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Section: Discussionsupporting

confidence: 88%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Evaluating the Role of Snow Cover in Urban Canopy Layer on the Urban Heat Island in Sapporo, Japan with a Regional Climate Model

Mori

Sato

2015

Journal of the Meteorological Society of Japan

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“…The effect of the built-up environment manifests itself by impacting turbulent transport radiative heat exchange and hydrological processes, especially in urban canopies [36]. Schatz and Kucharik also demonstrated in their paper that the built-up environment was the primary driver of the spatial change in temperature patterns in the urban area [37]. They found that urban environments, together with their dark impervious surfaces and reduced vegetation cover, normally have large heat capacity and high thermal conductivity rates [34,[38][39][40][41][42].…”

Section: Discussionmentioning

confidence: 98%

Spatio-Temporal Modeling of the Urban Heat Island in the Phoenix Metropolitan Area: Land Use Change Implications

et al. 2016

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This study examines the spatial and temporal patterns of the surface urban heat island (SUHI) intensity in the Phoenix metropolitan area and the relationship with land use land cover (LULC) change between 2000 and 2014. The objective is to identify specific regions in Phoenix that have been increasingly heated and cooled to further understand how LULC change influences the SUHI intensity. The data employed include MODerate-resolution Imaging Spectroradiometer (MODIS) land surface temperature (LST) 8-day composite June imagery, and classified LULC maps generated using 2000 and 2014 Landsat imagery. Results show that the regions that experienced the most significant LST changes during the study period are primarily on the outskirts of the Phoenix metropolitan area for both daytime and nighttime. The conversion to urban, residential, and impervious surfaces from all other LULC types has been identified as the primary cause of the UHI effect in Phoenix. Vegetation cover has been shown to significantly lower LST for both daytime and nighttime due to its strong cooling effect by producing more latent heat flux and less sensible heat flux. We suggest that urban planners, decision-makers, and city managers formulate new policies and regulations that encourage residential, commercial, and industrial developers to include more vegetation when planning new construction.

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“…For coastal environments, the enhanced UHI thermal gradient has been associated with the earlier onset of the sea breeze, followed by stagnation over the urban environment as the sea breeze is perturbed by the UHI circulation (Melas et al 2000;Khan and Simpson 2001;Lemonsu et al 2006b;Freitas et al 2007). Furthermore, enhanced convergence, vertical motion and aerosols concentrations from the UHI has been documented in association with increased cloud formation (Tsunematsu and Kai 2004;Schatz and Kucharik 2014), convective precipitation rates (Dixon and Mote 2003;Ryu et al 2015) and storm initiation (Rozoff et al 2003;Shem and Shepherd 2009). Continuing growth of the near-coastal urban landscape (Small and Nicolls 2003) highlights that UHI processes are increasingly a significant component of the coastal PBL.…”

Section: Planetary Boundary Layer Circulations and Convergence Zonesmentioning

confidence: 99%

The coastal convective interactions experiment

Soderholm¹

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Prediction of convective storm environments relies principally upon the broad-scale meteorology (e.g., synoptic boundaries and air masses) in contrast to local-scale (2 -20 km) processes within the planetary boundary layer (PBL). Diurnal heating of the Earth's heterogeneous surface at these finer scales forces circulations (e.g., sea breezes, valley winds, urban heat island circulations) which have been related to trends in the meteorological and climatological activity of storms; however, a quantitative understanding of their interactions with deep convection is limited. This is especially true for physical settings which support a variety of PBL circulations that challenge our understanding of ii Detailed analysis of the CCIE climatology datasets provided an understanding of SEQ hailstorms across a range of spatiotemporal scales. At the inter-annual time scale, the ElNiño Southern Oscillation (ENSO) was shown to have a statistically significant relationship with both hailstorm and sea breeze frequency in SEQ. Synoptic scale southeasterly changes that were found to couple with sea breezes provide the most favourable environment for hailstorms, particularly for southwest SEQ. At the mesoscale, hail development within convective cells was found to be most frequent within the inland limb of maritime air masses on sea breeze days. It was concluded, that the maritime sea breeze air is potentially favourable for convection after modification through inland propagation and the associated entrainment of sensible heat.Investigation of the CCIE field campaign datasets show that diurnal modification of the coastal PBL by near-surface and boundary layer processes provide favourable preconditioning for convective storms. This includes: (1) early sea breeze onset for the city of Brisbane due an urban heat island enhanced land-sea thermal contrast, (2) significant afternoon warming and moistening above the sea breeze attributed to the advection of the inland convective boundary layer coastward under prevailing westerly flow, and (3) substantial variations in near-surface moisture likely associated with topography and landuse. For the 27 November 2014 Brisbane case study hailstorm event, which caused damages exceeding $1.5 billion AUD, these diurnal preconditioning processes are shown to be favourable for the development of a mesoscale convective environment capable of supporting large hailstone growth. The multicell-HP supercell storm mode identified for this event and previous similar events in SEQ is hypothesised to be more sensitive to variations in near-surface and boundary layer instability. This is in contrast to contemporary supercell storms, highlighting the importance of PBL observations for developing an understanding of convective storms in subtropical coastal environments.In summary, this thesis provides a substantial and original contribution towards understanding of subtropical coastal storm environments. The integration of meteorological and climatological datasets from the CCIE provided a wealth of evi...

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Seasonality of the Urban Heat Island Effect in Madison, Wisconsin

Cited by 122 publications

References 58 publications

Evaluating the Role of Snow Cover in Urban Canopy Layer on the Urban Heat Island in Sapporo, Japan with a Regional Climate Model

Evaluating the Role of Snow Cover in Urban Canopy Layer on the Urban Heat Island in Sapporo, Japan with a Regional Climate Model

Spatio-Temporal Modeling of the Urban Heat Island in the Phoenix Metropolitan Area: Land Use Change Implications

The coastal convective interactions experiment

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