Increasing Solar Reflectivity of Building Envelope Materials to Mitigate Urban Heat Islands: State-of-the-Art Review
Abstract
:1. Introduction
2. UHI Causes and Effects
3. UHI Mitigation Strategies
4. Surface Solar Reflectivity
5. Cool Building Envelope Materials
6. Solar Reflectivity Measurements of Building Envelope Materials
7. Numerical Simulation of Building Envelope Materials
7.1. Building Simulations
7.2. Micro-Climate Simulations
7.3. Mesoscale Modeling
8. Concluding Remarks; Research Gap and Future Research Opportunities
- In comparison to studies focused only on roofs, there is still a need for more research that considers various factors such as building orientation, energy modeling for vertical surfaces, and envelope modeling, which limits understanding of their contribution to their overall potential for mitigating UHI effects. This gap necessitates more experimental and modeling studies that encompass the full range of surfaces that may be found within urban environments. An examination of the market scenario uncovers a noticeable scarcity of information regarding the application of cool materials for external walls in North America [87]. Cool materials predominantly find use on the rooftops of non-residential structures, with a lack of available market data. Looking at the corporate landscape, a thorough investigation has identified twenty companies located in Canada, the majority of which are small and medium enterprises (SMEs) specializing in manufacturing roofing products [87]. Reflective materials, phase-change materials, and coatings are prominently featured as the most frequently discussed options in North America;
- As temperature dynamics influence wind patterns, future investigations must account for these complicated relationships to provide a more accurate picture of the potential outcomes of cool material implementation. The complex interactions between changing temperatures and wind speed, potentially leading to reduced breezes, underscore the need for comprehensive assessments that consider multiple factors;
- The absence of extensive measured data from large-scale experimental sites and long-term weather records poses a challenge in fully recognizing the implications of cool material use. Obtaining such data is essential to comprehensively evaluate their efficacy and to inform practical applications. The need for large-scale testing poses a challenge in evaluating the practical applicability of cool materials. Rigorous real-world experiments are necessary to validate the potential of these materials on a broader scale and to ensure their reliability as passive UHI mitigation strategies. Finally, the interaction between humidity and the effects of cool materials remains an area of limited understanding. Incorporating humidity-related considerations into future studies will enhance the accuracy of predictions and the overall effectiveness of cool material strategies;
- Existing cool roof measurement and rating standards, like CRRC-1 [88], only address a 3-year aging process when assessing the impact on the reflective properties of materials. Further research is needed to examine the durability of these materials under natural exposure to real field tests more comprehensively, as durability plays a vital role in the material selection process for construction purposes.
- Create a comprehensive guideline that outlines the minimum prescriptive requirements for material solar reflectance index (SRI) based on the desired location. These standards can serve as a foundation for developing future building codes, making it easier to promote the widespread adoption of reflective materials and ensuring their consistent and effective use in various urban environments;
- Expand the focus beyond roofs to encompass vertical surfaces; this will promote a more complete understanding of the potential effects arising from the use of cool materials to reduce UHI effects;
- Develop a unified performance metric that allows for a direct comparison between different cool materials; the current set of performance indicators includes the Solar Reflectance Index, surface temperature, outdoor temperature, energy consumption, and glare from surfaces, whereas these performance indicators offer valuable insights, a comprehensive unit performance indicator would enable researchers, practitioners, and policymakers to effectively evaluate and rate various materials based on their overall effectiveness in mitigating the UHI effect;
- Modify existing indicators through the development of comprehensive evaluation criteria, such as surface and air temperature metrics; this would ensure a thorough understanding of how cool materials influence the urban environment; accurate and standardized measurements of these indicators would provide a clearer picture of the extent to which cool materials contribute to, and the efficacy of materials in, reducing the UHI effect and cooling the urban environment;
- Research into cool materials derived from natural sources is an ongoing endeavor within the field of material science. Future steps might involve utilizing different arrangements of these natural cool materials in the field of building engineering. Also, studies could focus on comparing the longevity, cost-effectiveness, and impact of these cool materials on building energy consumption and outdoor temperature.
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
Appendix A
No. | Cool Material | Year | Key Findings | Ref. |
---|---|---|---|---|
1 | Polyethylene alcohol plastic film + evaporative Aluminum. | 1974 | Surfaces with selective optical properties tailored to the atmospheric window between 8–13 μm can be created by applying affordable plastic materials to a metal surface. | [89] |
2 | PVF + Al + Substrate. | 1977 | Attainable temperatures and power levels can be achieved by employing selective surfaces that align with the atmospheric window. | [90] |
3 | TiO2 Paint + Al Plate. | 1978 | Oxides and carbonates of titanium, aluminum, calcium, and zinc are promising options for creating the needed white-black selective surface because they exhibit high reflectivity in the visible spectrum. | [91] |
4 | Poly Methylene film (340 mm) coated on an Aluminum base. | 1979 | The potential to enhance radiative cooling through the reversal of the greenhouse effect is explored, and certain experimental findings are presented. | [92] |
5 | SiO + the Aluminum substrate. | 1981 | can result in temperature variances of approximately 50 °C, with a cooling capacity of around 100 W/m2 | [93] |
6 | Silicon nitride film applied to aluminum substrates. | 1982 | An alternative method for radiative cooling involves utilizing selective infrared emission from flowing C2H+ gas confined within an IR-transparent enclosure. | [94] |
7 | Foil + reflective coatings and dyes from polyethylene or ethylene copolymers + a layer of absorbent pigments. | 1982 | The protective cover is designed for refrigerating devices and has selective optical properties, making it reflect sunlight diffusely on one side and absorb it on the other side. The cover’s reflectance on the sun-exposed side is high (above 0.6), and its transmittance in the solar spectrum is low (around 0.1). | [95] |
8 | Reflective aluminum plate, NH3, C2H4, C2H4O as gas plate. | 1984 | Radiative cooling can be harnessed to achieve lower temperatures, even during daylight hours. | [96] |
9 | The SiON film + Gas + Aluminum substrate. | 1984 | The combination can exhibit greater cooling capability than either of the individual gases, a significant finding for real-world applications. | [97] |
10 | MgO +LiF + Metal reflector. | 1984 | Magnesium oxide and lithium fluoride hold the potential for making radiators. By using a 1.1 mm thick layer of MgO ceramic, polished on one side and backed with a metal foil, they achieved favorable infrared optical properties. In a passive cooling test, the MgO radiator reached a temperature 22 °C lower than the surrounding air, making it 30 °C colder than a highly emissive nonselective radiator. | [98] |
11 | TiO2 white and black paint. | 1985 | Performance evaluations were conducted using three radiative cooling systems designed with surfaces made of aluminum, white TiO2 paint, and black paint coated with polyethylene. Comparable measurements were also taken with a fourth radiator featuring an uncovered black paint surface. | [99] |
12 | The Aluminum plate covers SiO2 + SiON | 1985 | Silicon dioxide and silicon nitride coatings were generated through Radio Frequency sputtering of silicon in the presence of either oxygen (O2) or nitrogen (N2). | [100] |
13 | The black radiation body is covered with a ZnS polyethylene film. | 1992 | The foil would reduce the solar heating burden on the material beneath it to a maximum of 43 W/m2 when the sun is directly overhead, and cooling would be effective for three hours in both the morning and evening. | [101] |
14 | White paint + Metal reflector. | 1993 | The incorporation of a BaSO4 extender into the paint dispersion resulted in an improvement in the cooling performance of the paint radiators. | [102] |
15 | Polyethylene foils containing ZnS, ZnSe, TiO2, ZrO2, and ZnO pigments. | 1995 | The temperature was slightly higher than the surrounding environment at noon, with a heating power of roughly 7.2 W/m2. Nevertheless, this foil demonstrated that cooling of a dark surface could be achieved for over 19 h daily in a dry region near the equator. The most effective ZnS pigments, with volume fractions reaching up to 0.15 at the surface of the black body emitter, were identified as the optimal choice. | [103] |
16 | SiO2 + SiON + Al + Glass. | 1995 | Silicon oxynitrides are particularly well suited for high emittance inside the atmospheric window. | [104] |
17 | Aluminum substrate, nitrogen oxide, and silica. | 1996 | The efficiency of silicon oxynitride material for radiative cooling applications is improved using multilayer structures. | [105] |
18 | Aluminum substrate, tantalum dioxide, and tungsten. | 1998 | The Spectral selective radiating material can attain a stable surface temperature determined by the transition temperature of the film. | [106] |
19 | SiO+VWO2+Black Substrate. | 1998 | The choice between overcoating and sandwiching the silver islands within a medium can have a significant effect on the system’s tunability. | [106] |
20 | Aluminum substrate and silicon dioxide. | 2007 | The research focused on creating Si2N2O nanowires through a Si nitridation process, with the addition of carbon playing a crucial role. The resulting Si2N2O nanowires exhibited a consistent and intense green emission at 540 nm in their photoluminescence spectrum. | [107] |
21 | Polyethylene foil + Aluminum foil + silicon dioxide and silicon carbide. | 2010 | Using a combination of SiC and SiO2 nanoparticles, effective and cost-efficient cooling is achieved within a feasible cooling system setup. | [108] |
22 | TiO2 + MgF2 | 2013 | The structure functions as a wide-spectrum mirror for sunlight and emits significantly in the mid-infrared range, falling within the atmospheric transparency window. This results in a net cooling power exceeding 100 W/m2 at room temperature. | [109] |
23 | Polyethylene Terephthalate+ silver substrate. | 2015 | It has been observed to be 11 degrees Celsius cooler than a nearby commercial white cool roof. This effect is achieved using carefully selected polymers and a thin silver film, resulting in exceptional values of around 100% for both reflecting solar radiation and emitting thermal energy in the infrared spectrum, specifically between 7.9 and 13 μm wavelengths. | [110] |
24 | Silver substrate + amorphous silicon and silicon nitride. | 2016 | An average cooling of 37 °C compared to the surrounding air temperature over a 24 h day/night cycle was attained, with the most substantial cooling, reaching up to 42 °C, occurring when the experimental configuration containing the emitter is subjected to the highest levels of solar radiation. | [111] |
25 | Metal-methyl cone nanostructure consisting of aluminum and palladium. | 2017 | Over 90% of the incoming solar radiation can be effectively reflected, and the typical emissivity within the atmospheric transparency window exceeds 0.9 in most directions. It is projected that a daytime net cooling power of over 100W/m2 will be achieved at room temperature. This cooling capacity remains effective even when accounting for substantial conduction and convection heat transfer. | [112] |
26 | Phosphorus + silicon cubes + Silver | 2017 | This approach employs common materials and manufacturing methods, making it suitable for scalable production and integration with silicon photonics. This innovation holds promise for efficient, energy-saving applications in passive cooling and thermodynamic control. | [113] |
27 | Polyethylene + ZnO. | 2017 | The TiO2+SiO2 coating exhibits a reflectivity of 90.7% within the solar spectrum, and its emittance in the “sky window” is 90.11%. In theory, this coating has the potential to achieve a cooling effect of around 17 °C below the surrounding temperature during nighttime and approximately 5 °C below the ambient temperature when exposed to direct sunlight. | [114] |
28 | SiO2 + SiN + Al2O3 + TiO2 + HfO2 and SiO2. | 2017 | Applying this photonic cooler to a solar panel can lower the cell temperature by over 5.7 °C. | [115] |
29 | TiO2 + Carbon particles + Substrate. | 2017 | By incorporating nanoparticles, the coating achieves favorable radiative properties, offering spectral selectivity for effective daytime cooling. | [112] |
30 | Silver + polyethylene layer +SiO2 | 2017 | It provides an average radiative cooling capacity exceeding 110 W/m2 throughout a continuous 72 h cycle of day and night measurements, with the peak cooling power around noon reaching 93 W/m2 under direct solar irradiance of over 900 W/m2. Additionally, there was a notable increase in nighttime radiative cooling compared to daytime. | [116] |
31 | PDMS + Sio2+Ag | 2017 | A polymer-coated fused silica mirror, which serves as a near-perfect blackbody in the mid-infrared and an excellent reflector in the solar spectrum, accomplishes radiative cooling below the surrounding air temperature both during direct sunlight (8.2 °C) and at nighttime (8.4 °C). | [117] |
32 | SiO2 + TiO2 + Alumina on a silver substrate. | 2017 | The addition of an Al2O3 film, which selectively absorbs in the 8–13 μm range while being transparent to visible and near-infrared light, can improve the effectiveness of radiative cooling within standard coating designs. | [118] |
33 | SiO2+TiO2+Al + Ag + Substrate. | 2017 | When exposed to a standard thermal source at 323.15 K and a wind speed of 3 m·s−1, it can produce a net cooling power of 363.68 W/m2, demonstrating an 18.26% increase compared to non-radiative heat exchange (natural cooling) under identical circumstances. | [119] |
34 | SiC doped PDMS + Al. | 2017 | Utilizing available commercial polymers for selective emitters offers the promise of reducing the expenses associated with radiative cooling solutions. This configuration has the capability to deliver natural cooling of as much as 12 °C below the surrounding temperature during nighttime conditions. | [120] |
35 | SiO2 + PMMA + SiO2 + Ag + Glass. | 2017 | Effective radiative cooling results in a temperature drop of 3.0 °C compared to the surrounding environment, which equates to a cooling of 6.6 °C below the temperature of the bare silver (Ag) mirror. | [121] |
36 | SiO2 + Al2O3 + Ag. | 2018 | Exceptional absorption efficiency exceeding 99% across the spectrum from 435 to 1520 nm while maintaining low emissivity below 20% in the mid-infrared range. | [122] |
37 | Meta surface + SiO2 + Al. | 2018 | The meta-reflector design achieves an emittance tunability of 0.48, signifying a 30% enhancement when contrasted with the unstructured film. | [123] |
38 | White Glass + Ag. | 2019 | Emitters successfully achieved sub-ambient daytime radiative cooling effects. | [124] |
39 | PDMS + Al. | 2019 | In the laboratory and an outdoor setting, temperature decreases of 9.5 °C and 11.0 °C were observed, respectively, using the thin film thermal emitter, which exhibited an average cooling power of approximately 120 W/m2. | [125] |
40 | PVF + Ag. | 2020 | Simple structure with dual layers of PVF and Ag coating. Low-cost, scalable-manufactured, durable, and anti-staining. Experimental performance of 2 °C lower than ambient under direct sunlight. | [126] |
41 | LiF + Ag. | 2020 | A module is integrated into an RC system, serving as a thermoelectric refrigerator during the day and functioning as a thermoelectric generator during the night. The later system achieves a maximum power density of 4.78 W/m2, enabling both daytime building cooling and nighttime power generation. | [127] |
42 | SiO2 + PP + Ag + Cu + Silica aerogel pad. | 2020 | A temperature-regulated phase change structure (TCPCS) enhances the performance of radiative cooling systems by allowing them to adapt their cooling capacity based on the surrounding temperature. During outdoor testing, the TCPCS enables the cooler to automatically deactivate at low temperatures and activate at high temperatures. As a result, the coolers equipped with TCPCS and those without it exhibit maximum temperature differences of 9.7 °C and 19.6 °C, respectively, over the course of a full day. Additionally, a V-shaped TCPCS has been designed to serve the dual purposes of cooling during summer and heating during winter simultaneously. | [128] |
43 | Al2O3+Sapphire substrate + Ag. | 2020 | Al2O3 and SiO2 microparticles were selected to be filter materials for RC paint. RC paint exhibits extremely low absorptivity (3.2%) and high emissivity (93.5%). RC paint had a temperature difference of 10 °C with CW paint in hot summer weather. RC paint was applied to various measurement setups compared to CW paint. | [129] |
44 | SiCNO + Ag + Al. | 2021 | The structure, featuring a 5 µm thin coating, can reduce the temperature to 6.8 °C lower than the surrounding environment due to a cooling power of 93.7 W/m2. The evaluation of the Passive Daytime Radiative Cooling (PDRC) structure included assessments of its optical properties and reliability through extended outdoor performance tests and degradation tests conducted in various environmental conditions. | [130] |
45 | Cellulose acetate-based films, which are recyclable, sustainable, and bioclimatic. | 2022 | Daytime radiative cooling material based on TiO2 and SiO2 mixture coating in terms of cooling performances was compared. Results have shown a drastic sub-ambient cooling of more than 3 °C and a great reduction in the indoor temperature of the building, and a reduction in the total electricity consumption of up to 60.38%. | [131] |
46 | Roof + Wall + Window. | 2023 | A radiative cooling coating with high solar reflectivity and thermal emissivity (β = 0.98, ε = 0.97) can result in electricity savings for cooling ranging from 8.2% to 29.7% across various climate regions. | [114] |
47 | Radiative cooling glass (RCG). | 2023 | RCG (Reflective Coated Glass) reduces indoor temperatures by 26.43◦C compared to regular glass. It significantly improves the indoor thermal environment for rooms facing different directions, with a decrease of 45.06◦C in the east and west directions and 15.05◦C in the north and south directions compared to ordinary glass. The study also highlights a correlation between indoor and outdoor temperatures, where indoor temperatures rise with increasing outdoor temperatures. However, RCG’s effectiveness is reduced in areas with high relative humidity. | [132] |
48 | Photonic radiative cooler that emits highly in the atmospheric window, randomized glass polymer metamaterial, several low-cost radiative coolers based on Aluminum. | 2023 | Different radiative cooling materials in diverse global climates under identical weather conditions were investigated. An active application of these materials on a highly conductive surface was simulated, calculating hourly heat gains or losses to evaluate their cooling capabilities. To implement the system practically, a threshold for the total heat needs to be determined to assess its feasibility. | [133] |
49 | Polar dielectric embedded polymer-based radiative cooling. | 2023 | The dielectric properties of dielectric particles were determined using the FPSQ model. The optical characteristics of these particles were assessed using FDTD simulation and Mie theory. The depth of electromagnetic wave attenuation in the hybrid material was calculated by considering the effective complex refractive index. Experimental validation of the proposed approach demonstrated a strong agreement between calculated emissivity and measured values. Among the various dielectric particles tested (α-SiO2, α-Al2O3, TiO2, and SiC), α-SiO2 was identified as the most suitable material for radiative cooling. | [134] |
50 | Poly methyl pentene + acrylic resin mixed with SiO2 microparticles. | 2023 | Radiative Cooling Paint (RCP) is prepared by adding TPX to acrylic resin mixed with SiO2. RCP is optimized based on Mie theory combined with Monte Carlo simulation. Emissivity in 8–13 μm and reflectivity in 0.2–2.5 μm of RCP are 0.91 and 92%. | [135] |
51 | Recycled plastics as the foam-paper composite (FPC). | 2023 | The combination of highly diffusely reflective polystyrene foam particles and fiber-based printer paper results in a reflectivity of 96% in the solar spectrum, a sub-ambient cooling performance of 8.4 °C, and a maximum radiative cooling power of 90 W/m2 during a 24 h cycle. | [136] |
52 | Super-hydrophobic radiative cooling emitter (SRCE) and phase change material (PCM). | 2023 | The SRCE (Solar Reflective Coating and Emissivity) possesses a strong ability to reflect solar radiation (0.93) and exceptional selective emission properties, with an emissivity of 0.83 within the atmospheric window and 0.49 outside it. Furthermore, the SRCE demonstrates outstanding super-hydrophobic characteristics (162.2° contact angle), along with robust mechanical properties and resistance to UV radiation. Combining phase change materials (PCM) with the SRCE shows great potential for use in a wide range of climate conditions. | [137] |
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City | Increasing Solar Reflectivity (ISR) | Temperature Reduction | Reference | |
---|---|---|---|---|
1 | Toronto, Canada | ISR on roofs, walls, and ground to 0.65, 0.60, and 0.45, respectively, from 0.2. | 2 °C | [24] |
2 | Guangzhou, China | Cool coating, from 0.16–0.19 to 0.26–0.34 | 1–2.1 °C | [26] |
3 | United Arab Emirates | 50% increase in surface reflectivity | 22% decrease in surface temperature | [27] |
4 | Los Angeles, USA | ISR on roof to 0.35 | 3 °C | [28] |
5 | 10 urbans, USA | ISR values increased by 0.30 on residential roofs and by 0.45 on office roofs. | 1–2 °C | [29] |
6 | 27 cities; Mediterranean, humid continental, subtropical arid, and desert conditions | ISR on roofs by 0.65 | 1.2–3.78 °C | [30] |
7 | Worldwide simulation | ISR on roofs to 0.9 | 0.3–0.6 °C | [31] |
8 | Mediterranean coastal area, Italy | ISR on urban surfaces from 0.3 to 0.55 | 2 °C | [32] |
9 | Melbourne, Australia | ISR on roofs from 0.50 to 0.85 | 2.2–5.2 °C | [33] |
10 | Midland, UK | ISR on roofs from 20% to 70% | 0.3 °C | [34] |
11 | Jerusalem, Israel | ISR from 0.2 to 0.8 | 0.4 °C | [35] |
12 | Melbourne, Australia | ISR on urban surfaces to 0.27 | 0.9–1.6 °C | [36] |
Roofing Materials | Solar Reflectance % | Temperature (°C) | Infrared Emittance % |
---|---|---|---|
Bitumen–smooth surface | 6 | 46.1 | 86 |
Asphalt shingles—black granules | 5 | 45.6 | 91 |
Built-up roof—dark gravel | 12 | 42.2 | 90 |
Asphalt shingles—white granules | 25 | 35.6 | 91 |
Bitumen–white granules | 26 | 35 | 92 |
Built-up roof—light gravel | 34 | 31.7 | 90 |
Shingles—white elastomeric coating | 71 | 12.2 | 91.2 |
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Ziaeemehr, B.; Jandaghian, Z.; Ge, H.; Lacasse, M.; Moore, T. Increasing Solar Reflectivity of Building Envelope Materials to Mitigate Urban Heat Islands: State-of-the-Art Review. Buildings 2023, 13, 2868. https://doi.org/10.3390/buildings13112868
Ziaeemehr B, Jandaghian Z, Ge H, Lacasse M, Moore T. Increasing Solar Reflectivity of Building Envelope Materials to Mitigate Urban Heat Islands: State-of-the-Art Review. Buildings. 2023; 13(11):2868. https://doi.org/10.3390/buildings13112868
Chicago/Turabian StyleZiaeemehr, Bahador, Zahra Jandaghian, Hua Ge, Michael Lacasse, and Travis Moore. 2023. "Increasing Solar Reflectivity of Building Envelope Materials to Mitigate Urban Heat Islands: State-of-the-Art Review" Buildings 13, no. 11: 2868. https://doi.org/10.3390/buildings13112868
APA StyleZiaeemehr, B., Jandaghian, Z., Ge, H., Lacasse, M., & Moore, T. (2023). Increasing Solar Reflectivity of Building Envelope Materials to Mitigate Urban Heat Islands: State-of-the-Art Review. Buildings, 13(11), 2868. https://doi.org/10.3390/buildings13112868