Flavia Laureti scite author profile

Abstract:As urban overheating is increasing, there is a strong public interest towards mitigation strategies to enhance comfortable urban spaces, for their role in supporting urban metabolism and social life. The study presents an assessment of the existing thermal comfort and usage of San Silvestro Square in Rome during the summer, and performs the simulation of cooling strategies scenarios, to understand their mitigation potential for renovation projects. The first stage concerns a field analysis of the thermal and radiative environment on the 1st and 2nd of August 2014, including meteorological measurements and unobtrusive observations, to understand how people experience and respond to extreme microclimate conditions. In the second stage, the research proposes scenario simulations on the same day to examine the influence of cool colored materials, trees and vegetative surfaces on thermal comfort. The thermal comfort assessment was based on Physiologically Equivalent Temperature (PET), whereas microclimatic simulations were conducted with CFD calculations (ENVImet v.4.3.1). The first stage shows a strong relationship between lower PET values and attendance rate, depending on daily shading patterns. The second stage shows a relevant improvement of thermal comfort, with PET values of −12 • C comparing to the no-intervention scenario, associated with a combination of cool materials and trees.

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Climate Mitigation and Adaptation Strategies for Roofs and Pavements: A Case Study at Sapienza University Campus

Battisti

Laureti

Zinzi

et al. 2018

Sustainability

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The progressively emerging concept of urban resilience to climate change highlights the importance of mitigation and adaptation measures, and the need to integrate urban climatology in the design process, in order to better understand the multiple effects of combined green and cool technologies for the transition to climate responsive and thermally comfortable urban open spaces. This study focuses the attention on selected mitigation and adaptation technologies; two renovation scenarios were designed and modeled according to the minimal intervention criterion. The study pays attention to the effect on surface temperature and physiological equivalent temperature (PET) of vegetation and high albedo materials characterizing the horizontal boundaries of the site. The Sapienza University campus, a historical site in Rome, is taken as a case study. These results highlight the importance of treed open spaces and the combination of permeable green pavements associated with cool roofs as the most effective strategy for the mitigation of summer heatwaves and the improvement of outdoor thermal comfort.

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Plug&Play: Self-Sufficient Technological Devices for Outdoor Spaces to Mitigate the UHI Effect

Battisti

Laureti

Volpicelli

2019

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Flavia Laureti

Assessment and Mitigation Strategies to Counteract Overheating in Urban Historical Areas in Rome

Climate Mitigation and Adaptation Strategies for Roofs and Pavements: A Case Study at Sapienza University Campus

Plug&Play: Self-Sufficient Technological Devices for Outdoor Spaces to Mitigate the UHI Effect

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