Abstract
This research study aimed to investigate the influences of angular-selective retro-reflective (AS-RR) and retro-reflective (RR) materials on the urban equivalent albedo (αeq). Full ray tracing solar analyses were conducted through the Monte Carlo-based numerical model validated in a previous work. Different geometry scenarios with different patterns of urban density were modelled. AS-RR and RR materials were alternately applied to the street and to the most irradiated façade. AS-RR materials were proposed to enhance the αeq of the urban environment particularly during summer. Solar analyses were reiterated for three latitudes (i.e., Oslo, Milan, Cairo). RR pavements and façades were capable of increasing the αeq throughout the year. However, implementing an angular-selective behavior allowed for a reduction of the mitigation potential of RR materials during the winter season. In their best application, RR and AS-RR materials enabled higher αeq in summer (122%) with negligible effects during the winter (7%). Finally, the study highlighted the need for exploiting numerical models capable of conducting full ray tracing solar analyses when investigating materials whose optical properties depend on the angle of incidence of the sunrays (such as RR materials).
Highlights
Urban overheating results from a synergistic combination of local and global climate change phenomena
The results from the solar analyses carried out for the reference case demonstrated that the highest αeq values were typically observed for the UC scenarios characterized by a low-density pattern
The results highlighted that RR and angular-selective retro-reflective (AS-RR) materials show different impacts depending on the surfaces to which they are applied
Summary
Urban overheating results from a synergistic combination of local and global climate change phenomena. The most documented issue associated with that is the urban heat island (UHI) effect. This is caused by a lack of permeable and vegetated surfaces, the materials used in the built environment, anthropogenic heat, worsened ventilation within urban canopies, and higher pollutants concentration in the atmosphere [1,2,3,4]. Anti-cyclonic conditions related to low wind speed, and clear sky were found to strongly contribute to increased UHI magnitude. Whereas, precipitation decreases this due to the increment of the thermal admittance of rural areas [10]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
