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Article

Cooling Energy Benefits of Increased Green Infrastructure in Subtropical Urban Building Environments

1
Faculty of Built Environment, University of New South Wales, Sydney, NSW 2052, Australia
2
Department of Geography, Lalbaba College, University of Calcutta, Howrah 711202, India
*
Author to whom correspondence should be addressed.
Buildings 2023, 13(9), 2257; https://doi.org/10.3390/buildings13092257
Submission received: 23 July 2023 / Revised: 20 August 2023 / Accepted: 28 August 2023 / Published: 5 September 2023
(This article belongs to the Section Building Energy, Physics, Environment, and Systems)

Abstract

:
Due to urban warming, the energy demand for cooling buildings is rising. The current study used CitySim (building energy model) to estimate the cooling energy requirements for 40 buildings in downtown Dubai using high-resolution climate data from weather research and forecasting (WRF) coupled with the single layer urban canopy model (SLUCM). Simulating the four mitigation scenarios allowed for the examination of the reduction in cooling load caused by the addition of greenery at a rate ranging from 25% to 100%. The insulated building’s cooling demand reduced by a maximum of 13.89% under 100% GI (M4). Scenario M4 resulted in a reduction of 4.6 kWh/m2 and 3.1 kWh/m2 for the non-insulated and insulated low-rise residential buildings, respectively, while the high-rise buildings saw a reduction of 3.09–4.91 kWh/m2 for the non-insulated and 2.07–3.09 kWh/m2 for the insulated buildings. This study offers a potential remedy to deal with the problem of urban heating in subtropical environments.

1. Introduction

Among the most crucial issues facing governments and experts worldwide are the environmental challenges brought on by urbanisation and climate change. Cities are facing a major threat from rising temperatures, which will have a negative impact on the ecosystem and climate. The environment, the need for energy for cooling systems, the need for water for irrigation, the need for power, and people’s quality of life—especially those living in low-income households—are all negatively impacted by urban heat [1]. Urban population growth, rising temperatures, and increased energy use are all contributing factors to the large rise in greenhouse gas emissions and energy use [2,3]. Energy demand is rising as a result of industry, construction, and transportation. According to one prediction, by 2050, 34% of the entire energy demand for the world will be used to address cooling needs, and by 2100, this percentage will rise to 61% [3]. The impact of rising temperatures and energy consumption in urban areas has a significant impact on building attributes, the quantity of heating needed, the urban layout, and the local urban environment [4,5,6,7]. With regard to their effects on the environment and the substantial health problems they bring about, some of which are life threatening, urban heating and global warming have reached a point where significant concern has been expressed [2].
Various studies have focused on the consequences of urban heating on energy consumption. According to a study by Santamouris, a large amount of the cooling demand is met by urban heating when summer temperatures in hot climatic zones reach or exceed 27 °C [8]. According to predictions, during the next 30 to 40 years, the demand for cooling energy will surpass that for heating energy [3]. The use of air conditioners will increase by 84%, and Melbourne’s maximum electricity demand will rise by 10% [9], primarily as a result of global warming. As a result, it can be projected that in the future, there will be significant issues with urban heating and greenhouse gas emissions from cooling systems [10].
Different thermal mitigation solutions have been developed for urban areas to help mitigate the effects of these climate challenges [11]. The employment of albedo materials, the inclusion of green infrastructure (GI), and the installation of evaporative systems are the main components of these technologies [12]. These mitigating measures try to increase the capacity of heat sinks to absorb heat and lessen the potential of heat-generating sources [13]. Cool materials play a vital role in reducing urban heat and building energy consumption due to the reflectance of solar radiation back to the atmosphere. This contributes to the broader goal of enhancing energy efficiency and mitigating urban heat in subtropical urban environments. There are certain mitigation strategies that have been proven to be more appropriate than others. For instance, after high albedo and inland water, a study carried out in London discovered that vegetation was one of the most efficient mitigating measures [14] due to their effects on the thermal equilibrium of the urban surface, and the consequent reduction in heat storage, evapotranspiration, and urban vegetation mitigate the impact of an urban heat wave [15,16].
Numerous studies have been conducted to assess the impact of mitigation strategies on urban heat. According to a Melbourne study that used the weather research and forecasting (WRF) and Princeton urban canopy model (PUCM) in conjunction, GI, whether it includes cool roofs or not, will lessen the thermal stress on people. According to studies, the amount of urban vegetation such as grassy areas and urban vegetation diminishes as the amount of city grows [16,17]. The association between daytime and night-time ambient temperatures and the rise in the amount of urban vegetation was found to be statistically significant in a study on extreme urban heat-induced mortality and environmental quality, which included fifty-five case studies [18]. For every 1 °C decrease in temperature, an increase in urban greenery resulted in 3% less heat-related mortality [18]. According to a number of studies on reducing urban heat, existing mitigation measures can lower the outside temperature by up to 3 °C, which lowers the need for cooling resources, cuts down on electricity use, and reduces heat-related morbidity and mortality [19,20,21,22,23]. Urban cities must address a number of issues that call for the integration of social, technological, and ecological systems while putting an emphasis on natural and planted vegetation that can help create resilient and sustainable urban ecosystems [24,25,26,27].
Green infrastructure (GI) is defined in a number of ways that vary in scope and intensity. The GI, according to the European Environmental Agency, is a network of connected green features that adds to the built environment’s usability and adaptability [28]. A network of natural and semi-natural green areas such as woods, parks, and green roofs are referred to as GI and are meant to support environmentally friendly and economically sensible solutions, according to a different study [29]. Developing strategies to enhance urban climate resiliency and lower energy usage is a problem for the building sector. The addition of urban greenery to the building’s exterior or the outdoors in an urban setting was one of the mitigating techniques used in various studies [30,31,32,33].
According to studies, the amount of energy required for cooling a building depends on two things: the shading that covers its surface, which reduces the amount of solar energy that is absorbed, stored, and transmitted through conduction [34], and the evapotranspiration of plants and other physical processes that cool the air [35,36]. A study conducted in Florida found that vegetation can lower a building’s energy use because it can intercept solar radiation and evapotranspiration, which can reduce the amount of power used for air conditioning by 50% each day [37]. Another study carried out in Mexico found that compared to an unshaded building, trees lowered the annual energy demand of a residential building by 76.6% [38]. Additionally, the presence of urban vegetation is very important for lowering both urban heat and environmental pollution [39]. According to a study conducted in Dubai, particular trees help to lower pollution levels and improve the quality of the air in metropolitan areas [40]. Previous research has demonstrated that trees can help lower energy use around buildings. Assessing and comprehending the effects of tree characteristics on the energy requirements of buildings are required for future elucidation [41,42,43]. To determine the effect of vegetation on the cooling energy requirements of buildings, a study was carried out in Thessaloniki, Greece. The ENVI-met model and the Energy Plus building energy modelling application were both used in the study. The study found that the leaf density and spacing between shade trees directly affected the cooling capability of urban trees, potentially cutting energy use by 54% [44]. The height, type, and proximity of trees to buildings may have an impact on the cooling requirements of those structures [32].
It is challenging to lower the cooling load needs in the United Arab Emirates (UAE), where there is a significant amount of humidity, a general warmth, and sun radiation. The UAE consumes the most energy per person in the world as a result of its exceptionally high energy needs, with the construction industry making up 70% of the country’s overall energy requirements. By 2050 and 2080, it is predicted that the UAE will need to cool its buildings by an additional 22.2% and 40%, respectively [45,46].
The main objective and scope of the current study was to use WRF and CitySim modelling to examine the impact of increased urban greenery on the building cooling loads of residential and commercial structures. In conducting the energy modelling scenarios in downtown Dubai, different amounts of vegetation fraction were considered, and the effects of increasing the urban greenery area on a building’s cooling demand were determined. Afterwards, the findings were examined and discussed.
This study contributes to the current understanding of cooling energy benefits in subtropical urban building environments. The novelty of this study can be witnessed by its inclusion of two simulation methods (WRF and CitySim model) for the building performance evaluation of the cooling energy requirement by increasing the vegetation in urban areas.
There is a research gap in conducting detailed quantitative analyses of building energy consumption for urban areas. An encompassing technique for the modelling of building energy use on an urban scale needs to be developed, however, there is a research void in this area. Because there is currently little information accessible for small cities, the energy modelling tools that are currently available are limited to the analysis of individual buildings rather than addressing the interplay between the built environment and GI. In order to perform an energy simulation on a building scale, a multi-modelling approach and high-resolution data for GI and transpiration, building envelope, climatic data, and energy demands are needed.

2. Geography and Climatic Conditions in Dubai

The coordinates of Dubai are 25°16′ N and 55°18′ E, placing it on the Tropic of Cancer. On the eastern tip of the Arabian Peninsula, its 72 km of coastline [47] are open to the sea. In a relatively short period of time, Dubai has become the most renowned city in the entire world due to its rapid urbanisation. Dubai is the second-largest metropolis among the UAE’s seven emirates, covering an area of 4114 km2, or 5% of the country’s total territory. Due to its geographic location, Dubai has a subtropical desert climate. Mild winters and hot, muggy summers are typical in the city. The city’s average temperature varies from 10 to 30 °C in the winter and reaches 48 °C in the summer [47]. Warm air advection from desert fetch and sea wind, which has a noticeable impact primarily at night, are two synoptic meteorological conditions that have an impact on Dubai’s urban heating. Coastal towns like Dubai, in general, face more protracted and frequent excessive urban temperatures. A long-term strategy, the National Climate Change Plan 2017–2050, was designed by the UAE to address the impact of UHI and the problem of rising urban heat. In the central business centre (CBD) of downtown Dubai, a zone was taken into consideration for this study. Buildings for both residential and business use can be found within this 2 km2 region. As the input climate data, CitySim used the Meteonorm software dataset. In the form of an XML file, CitySim made use of the building data. In Dubai, it is important to look into how vegetation affects the demand for urban cooling in various types of structures. There is a paucity of information on the role of flora in subtropical desert climates in terms of lowering the cooling load of buildings. Thus, to calculate the energy needs for a building size in the Dubai metropolis, this study used high resolution climate data from WRF as the input for CitySim. The goal of the present study was to assess the corresponding cooling load demand by considering various GI fractions. The study included two main steps: running the WRF coupled with a single layer urban canopy model (SLUCM) simulation for several GI mitigation scenarios, and then importing the results into CitySim to assess the building cooling load for each mitigation option.

3. Materials and Methods

The focus of this research was on how the vegetation fraction affects the cooling load of different commercial and residential building types in downtown Dubai, where an increase in urban greenery could result in a large drop in surface temperature. The number of trees and other types of flora could be increased, which would assist in cooling the urban climate and reducing the intensity of the summer heat. Building energy models (BEMs) are frequently used to assess a structure’s thermal performance in response to the negative effects of urban heat on energy consumption [48,49]. The development of urban building energy models (UBEMs) was made possible by improvements in computing resources [50,51]. UBEMs, which are used in conjunction with other urban modelling tools to evaluate a building’s thermal behaviour in response to energy balance at the urban scale, latent and sensible heat, advective and anthropogenic heat, are primarily focused on urban sustainability and energy efficiency. The EPFL-developed CitySim Pro is one of the UBEMs used in the current work to carry out urban energy simulations [52]. CitySim utilises a physics-based modelling simulation engine and a C++-based user interface [50]. CitySim employs a number of models including hourly urban radiation models, building thermal characteristics, and heating, ventilation, and air-conditioning (HVAC) models [51]. A HVAC system is used by CitySim to carry out the simulation tasks. There are two steps in the methodology. First, urban scale WRF simulations were run for the base case and four mitigation scenarios that corresponded to the variable vegetative fraction. In order to assess the effects of expanding GI on the building cooling demands, the simulation’s results were also incorporated into the CitySim model. In our earlier research [33], we studied four mitigation strategies and one control case on the scale of the Dubai urban area. While building data from SketchUp were directly used by CitySim, weather data from WRF were transformed to a format that was compatible with CitySim using Meteonorm. The study also investigated four mitigation scenarios with vegetative proportions of GI 25% (M1), GI 50% (M2), GI 75% (M3), and GI 100% (M4) for the sake of comparison. In the subtropical desert climate of Dubai city, four modified GI scenarios with an increasing rate in the starting GI value of 0.10 (control case) to 0.15, 0.40, 0.65, and 0.90 were investigated in our earlier study [33]. This explicitly refers to the initial GI value of 0.10, with increments of 0.15 (0.10 + 0.15 = GI25), 0.40 (0.10 + 0.40 = GI50), 0.65 (0.10 + 0.65 = GI75), and 0.90 (0.10 + 0.90 = GI100). This entailed one control scenario (GI10) and four modified GI scenarios (GI25, GI50, GI75, and GI100). The base case was chosen to be a vegetation fraction of 10%, which corresponds to a GI proportion of 10%.
In our prior work [33], we tested and assessed the efficacy of increased vegetation in Dubai city. The details of the WRF model configuration and the selected physical parameterisations are available in [33]. The choice of parameterisation schemes for atmospheric processes can impact the accuracy of the model outputs. The parameterisation schemes employed in our simulations encompassed schemes related to microphysics, radiation, boundary layers, and land surface processes, among others [33].

3.1. CitySim Configuration for Energy Simulations

For accurate simulations of the urban environment for the cooling load of 40 different commercial and residential buildings in Dubai, CitySim included unique settings. As indicated in Figure 1, there are numerous procedures that must be taken in order to set up the simulation correctly. The first step was to input the local meteorological and geometric data into the CitySim program. Cli and Hor files, which include climate data, were used. Building attributes were specified after importing the climatic data. For commercial buildings, the inside and outdoor temperatures were taken to be 19 °C and 24 °C, respectively; for residential buildings, these values were 20 °C and 26 °C.
The invasion was determined as 1. The glazing g-value was set at 0.85, the cut-off irradiance was 100 W/m2, and the shading device was set at 0.2. The surface reflectance was calculated as 0.2. As stated in Table 1, the glazing U-values for the insulated buildings were taken as 1.6, 1.9, and 2.1 W/m2K, respectively, whereas the glazing U-value for non-insulated structures was 5.8 W/m2K. The value for the open able proportion was assigned as 0.5. The parameters of the roof, wall, and floor envelopes as well as composite materials were defined in the XML with consideration for the simulation needs. For both insulated and uninsulated buildings, these materials were specified. The final step was to provide CitySim with information on the occupant density and heat gains. According to Figure 2, the current case study considered a 2 km2 urban area in downtown Dubai, which is located at 25.18° N and 55.27° E. Umm Al Tarif was the previous name for this location before the 2000. Business Bay is to the south and Financial Centre Road is to the northeast of this region. This study looked at 40 buildings in the neighbourhood including 10 commercial and 30 residential structures. There are both high-rise and low-rise structures among these. Commercial structures range in height from 12 to 89 m and house offices, malls, theatres, and fitness centres. Residential structures, on the other hand, can be anywhere between 22 and 605 m tall.

3.2. Simulation Process

Two steps can be used to divide the simulation process: (a) using SketchUp and WRF to retrieve climatic and building data for use as CitySim’s input parameters, and (b) executing CitySim’s simulation of the energy performance of 40 buildings.

3.2.1. CitySim Data from SketchUp and WRF

Data from WRF were used as the CitySim input data. As a result, the reliability of the precision and correctness of this climatic data can be stated. The accuracy of the results from the CitySim simulation was closely correlated with the accuracy of the data. Surface temperature, wind speed, ambient temperature, humidity level, and wind direction were all included in the WRF data. The simulation was conducted for 40 buildings including both residential and commercial. Over 2 km2 was used for the simulation. SketchUp was used to import these structures from Google Earth, and models were produced, as seen in Figure 3.
In order to be compatible with the simulation software, models were created in metres. The common surfaces between buildings were removed, and each building had its own layers as a result of the north being pointed towards the top of the building model. The final model was then directly loaded into CitySim as dxf files. The models’ traits included building space, window–wall ratio (WWR), number of stories, and geometrical measurements, which are all in accordance with the archetypes indicated in Table 2. As shown in Table 3, the American Society of Heating, Refrigerating and Air-conditioning Engineers (ASHRAE) standards and the Dubai Building Code manual were used to select the building materials.

3.2.2. Building Energy Simulation by CitySim

To evaluate the performance of the buildings in relation to different GI fractions, energy simulations of both insulated and non-insulated buildings were run on a building scale. According to the hypothetical classification system, buildings were divided into low-rise, medium-rise, and high-rise categories depending on the number of floors they had—six stories, 7–12 stories, and more than 12 stories, respectively. The building energy simulation test (BESTEST) was used to validate the simulation results of CitySim, and the results were compared to those of a reference software suite (IEA BESTEST set) [53]. Additionally, when the results of CitySim were contrasted with the actual data on energy use, slight differences were found [54]. In order to create climatic (.cli) and horizon (.hor) files that worked with the simulation software, Meteonorm 8.0 was used to convert the output data from WRF. Then, the .cli and .hor files with the climate data for the base and mitigation scenarios were created. The climate (.cli) file included the different climatic variables as stated in Table 4 as well as the hourly climate data for an entire year (8760 h). Using these climate and horizon files for the month of July, cooling load simulations for the base and mitigation scenarios were run. Separate simulations of uninsulated and insulated buildings were run, and the efficiency of the vegetation infrastructure was examined. The simulation also needed a set of variables that included precipitation, cloud cover fraction, and surface temperature. Any of the lacking parameters could be produced using Meteonorm. These hourly climate data files were utilised by the CitySim program to simulate cooling loads for the month of July in both the control case and the mitigation scenario. For each scenario, two cooling load simulations of insulated and non-insulated buildings were run using the climate data parameters. This study focused on gathering simulation results for both non-insulated and insulated structures in order to evaluate the efficacy of mitigation techniques on the cooling load requirements in metropolitan locations. Finally, the results of this study were compared with those from the existing literature as well as with our previous study explaining the impact of cool materials on building energy consumption in order to understand the role of these mitigation techniques in an urban built environment in decreasing the energy consumption.

4. Results and Discussion

For Dubai, where the highest ambient temperature in the winter months ranges between 10 and 30 °C and the maximum temperature in the summer months can reach 48 °C with an average temperature of 41 °C, the thermal performance of an enhanced GI fraction was tested. According to the results of the reference scenarios, synoptic weather conditions like hot, dry desert winds and chilly sea breezes have a significant impact on metropolitan heat. As a result of the reduction in sensible heat, the results showed that increasing the vegetative percentage had an impact on the thermal balance of cities and could greatly lower the cooling load requirements. At 14:00 LT in the summer, the reductions in ambient temperature were 0.60 °C, 1.10 °C, 1.40 °C, and 1.70 °C, respectively. The decrease in surface temperature was determined to be 1.40 °C, 1.90 °C, 2.10 °C, and 2.70 °C for the increase in greenery, which corresponded to the mitigation measures M1, M2, M3, and M4.

4.1. WRF Model Evaluation and Validation

By considering the four meteorological datasets provided by the national centre of meteorology (NCM) of the UAE, this study examined and validated the performance of additional GI. The local weather stations at Saih Al-Salem, Lahbab Station, Al-Maktoum International Airport, and Dubai International Airport provided the meteorological data. A statistical comparison between the local climatic measurements and the hourly base case simulation results of 2 m temperature at the seasonal scale is necessary for the validation and evaluation of the performance of the WRF model [55].
We have changed the surface vegetation. Our prior work on Dubai [33] contains the specifics of the scenarios (i.e., increased green infrastructure). To quantify the performance of various types of GI, a section of each urban grid cell was replaced with supposed plant patches, particularly GI 25% (M1), GI 50% (M2), GI 75% (M3), and GI 100% (M4), using the mosaic technique (vegetation patches). We used the same scenarios in this paper to examine the energy benefits at the building scale.
Following on from our previous study in which we tested and evaluated the performance of cool materials in Dubai city [24], we analysed the entire months of January 2019 and July 2019. The United Arab Emirates (UAE) National Centre of Meteorology (NCM) provides hourly ambient temperature data based on different in situ meteorological observations. We employed four local meteorological datasets from distinct urban LULC settings that are kept by the NCM and were used for the WRF model validation and assessment in this study. To test and analyse the WRF model performance, the hourly output of 2 m temperature at the seasonal scale (summer and winter) from the untreated simulation (control scenario) was statistically compared with separate local meteorological observations.

4.2. Effects of Increased Urban Vegetation on Building Cooling Loads

Utilising weather information from WRF, CitySim simulations for the month of July 2019 were run for the control case and four extra vegetation scenarios. Forty high-rise and low-rise commercial and residential structures were included in this simulation. The study took a wide range of commercial structures into account such as theatres, malls, dining establishments, offices, and gyms. In Figure 4, the cooling demand is shown in kWh/m2 for all buildings under various mitigation strategies. According to the study, in the case of residential buildings lacking insulation, the reference case showed a cooling load of 34.94 kWh/m2, which decreased to 33.65 kWh/m2, 32.92 kWh/m2, 32.33 kWh/m2, and 30.35 kWh/m2 for low-rise buildings according to mitigation scenarios GI 25% (M1), GI 50% (M2), GI 75% (M3), and GI 100% (M4), respectively. In contrast, high-rise structures saw cooling loads between 31.57 and 23.12 kWh/m2 in the base case, which decreased from 22.15 kWh/m2 to 30.43 kWh/m2, 21.60 kWh/m2 to 29.77 kWh/m2, 21.17 to 29.26 kWh/m2, and 19.76 to 27.50 kWh/m2 for the mitigation scenarios M1, M2, M3, and M4, respectively, as shown in Figure 5. In contrast, non-insulated commercial buildings showed cooling load ranges for low-rise structures of 24.77–52.19 kWh/m2, 24.30–51.21 kWh/m2, 23.92–50.46 kWh/m2, and 22.68–47.91 kWh/m2 for the four mitigation scenarios, respectively.
A high-rise building’s cooling load, on the other hand, ranged from 25.43 to 48.84 kWh/m2 for the control case, 24.5 to 47.01 kWh/m2 for mitigation scenario M1, 23.98 to 45.95 kWh/m2 for mitigation scenario M2, 23.58 to 45.17 kWh/m2 for scenario M3, and 22.26 to 42.61 kWh/m2 for mitigation scenario M4, as shown in Figure 6. It follows that the mitigation scenario M4 had the lowest cooling load observed across all building types. This is because more tree cover leads to increased shade, evapotranspiration, and wind modification.
As the wind is directed in a particular way by additional tree cover, it had the greatest cooling impact on the buildings [56]. Additionally, compared to the commercial structures in our study, the residential buildings displayed a higher reduction in cooling demand. This might be because the residential buildings in this study were taller than the commercial ones. In comparison to the uninsulated mitigation scenarios, the results for the insulated buildings demonstrated lower cooling loads [57] because the increase in insulation lowers the energy required for cooling loads.
Insulated low-rise residential structures showed a cooling load of 22.01 kWh/m2 in the base case, which decreased to 21.10 kWh/m2, 20.57 kWh/m2, 20.18 kWh/m2, and 18.92 kWh/m2 for the mitigation scenarios M1, M2, M3, and M4, respectively. On the other hand, the cooling loads for high-rise buildings were observed to range from 13.72 to 20.58 kWh/m2 in the base case, which decreased to 13.10 to 19.74 kWh/m2, 12.74 to 19.25 kWh/m2, 12.48 to 18.90 kWh/m2, and 17.73 to 11.62 kWh/m2 for mitigation scenarios M1, M2, M3, and M4, respectively. Urban areas could benefit from more vegetative patches by having fewer long-wave heat radiations emitted from the surface, which would further lower the ambient temperature and improve the thermal performance of buildings. For low-rise commercial buildings with insulation, the cooling load ranged from 16.06 to 38.97 kWh/m2 for the control case, and from 15.49 to 37.61 kWh/m2, 15.16 to 36.81 kWh/m2, 14.92 to 36.23 kWh/m2, and 14.14 to 34.34 kWh/m2 for the four mitigation scenarios, respectively. As depicted in Figure 6, high-rise buildings, on the other hand, had cooling loads ranging from 16.02 to 31.08 kWh/m2 for the control case, 15.41 to 29.88 kWh/m2 for mitigation scenario M1, 15.05 to 29.19 kWh/m2 for mitigation scenario M2, 14.79 to 28.69 kWh/m2 for mitigation scenario M3, and 13.96 to 27.06 kWh/m2 for mitigation scenario M4. Building shape also has a significant impact on how much cooling load is used. As a result of the inverse relationship between building height and cooling load requirements, high-rise buildings, as opposed to low -rise ones have significant reductions in cooling load [58]. Additionally, the results showed that the maximum cooling load reduction in the mitigation scenario corresponded to a 100% increase in GI since a greater amount of greenery would boost evapotranspiration, which lowers the ambient temperature [59]. For the mitigation scenarios M1, M2, M3, and M4, insulated buildings showed an average decrease of 4.11%, 6.49%, 8.23%, and 13.89%, respectively, whereas uninsulated buildings saw an average reduction of 3.89%, 6.12%, 7.84%, and 13.52%, respectively. In comparison to the control condition, Figure 7 shows a decrease in the cooling load.
The reduction in cooling load for residential structures under various vegetation mitigation scenarios is shown in Figure 8. Low-rise buildings without insulation saw a decrease of 4.6 kWh/m2, whereas high-rise buildings saw reductions ranging from 3.09 kWh/m2 to 4.91 kWh/m2 with the largest increase in GI 100%. Similarly, insulation reduced the energy use in buildings by 3.1 kWh/m2 for low-rise buildings and by 2.07 to 3.09 kWh/m2 for high-rise ones. In the case of non-insulated buildings, the cooling load reduction for commercial buildings, which corresponded to mitigation scenario M4, revealed a reduction value of between 2.94 and 7.24 kWh/m2 for low-rise structures and between 3.2 and 6.2 kWh/m2 for high-rise buildings. On the other hand, there was a decrease of 2.1–4 kWh/m2 for insulated high-rise structures and 1.92–6.39 kWh/m2 for insulated low-rise buildings. Figure 9 depicts the reduction in cooling load for commercial buildings under each scenario. It is important to consider the fact that this study focused on the energy performance of both high- and low-rise structures with and without insulation. The study region might be viewed as a sample of downtown Dubai, which is known for its hot and muggy climate.

5. Comparison of Cooling Benefits: Green Infrastructure and Cool Materials

The findings of the current study were contrasted with those found in the literature, and comparisons were made. It was found that comparable studies carried out by Tsoka et al. evaluated the impact of increasing urban greenery on the cooling load reduction in the urban city of Thessaloniki, Greece, and found a reduction of 9% and 13%, corresponding to the increase in the vegetative fraction by 30% and 60%, respectively [44]. In Rome and Milan, two Italian cities, Barbera et al. reported an 8% and 11% reduction in cooling load in response to a 10% increase in vegetative area, respectively [60]. This is a lot higher than our results for the mitigation plan, which corresponded to increases in vegetation of 25% and 50%, respectively, of 3.89% and 6.12%. It was found that an increase in tree cover in a subtropical region of Nanjing, China might lead to a reduction in cooling demand of up to 15.2% [32]. Five million trees might be planted in Western Sydney, Australia, by 2050, which would reduce the cooling load requirements for homes, offices, and schools by 19.3%, 13.4%, and 19.0%, respectively [61].
In Tel Aviv, Israel, Erell et al. looked at how different building types would be affected by increasing the greenery fraction, where they found that the cooling load for the various types of buildings may be decreased by between 5.04% and 6.06% with a 50% increase in plant cover [62]. This reduction is nearly identical to the 6.12% decrease that was seen in our analysis for the mitigating scenario that corresponded to the 50% greenery fraction. Santamouris et al. assessed the effects of mitigation strategies using enhanced albedo and vegetative fraction in Sydney, Australia, and proposed that increasing the urban greenery would result in a reduction of cooling load of 0.48%, 1.23%, and 2.31% for the enhanced vegetative fractions of 20%, 40%, and 60%, respectively [63]. Comparing this decrease in cooling load demand to the decreases of 3.89% and 6.13% for mitigation scenarios M1 and M2, respectively, there was a clear improvement. The difference in vegetation type, leaf area index (LAI), building morphology, indoor temperatures, and the local meteorological conditions may be the cause of the mismatch between the current literature and our results. In Figure 10, the contrast between the findings of the prior literature and our findings is represented visually. Slope, which measures the amount of cooling load demand that decreases for each 1% increase in greenery fraction, was approximately 0.1224% for the current study and 0.1202% for the body of previous literature. The slopes of the two regression lines were nearly comparable, demonstrating a remarkable correlation between our findings and the available data.
To investigate the most effective method of reducing building energy consumption in urban buildings, it is essential to not only compare one mitigation technique with multiple fractions but also to compare the effectiveness of more than one mitigation strategy. This can be achieved by comparing the cooling load demand reduction potential of the current study implementing GI with those from our previous study, in which cool materials with an albedo fraction of 0.4 (M1), 0.65 (M2), and 0.8 (M3) were used as a mitigation strategy for the cooling energy demand in Dubai. Thus, it becomes significant to understand the relative impacts and advantages of both strategies in the context of cooling energy reduction and urban thermal comfort.
When comparing the results of both mitigation techniques (GI and albedo), it is evident that for the non-insulated low-rise residential buildings, a cooling load similar to 34.9 kWh/m2 was seen in the base case. This cooling demand was lowered to a maximum of 21.7 kWh/m2 for mitigation scenario M3 in the case of the modified albedo and to 30.4 kWh/m2 for mitigation scenario M4 in the event of enhanced vegetation infrastructure. Similar results were found for non-insulated high-rise structures, which had cooling loads between 23 and 31.5 kWh/m2 in the base case, but between 15.1 and 21.6 kWh/m2 in albedo mitigation scenario M3 and between 19.8 and 27.5 kWh/m2 in the greenery mitigation scenario M4. The results of the simulations for the commercial buildings pointed to a similar pattern, with non-insulated low-rise structures in both cases having a cooling load of about 25 to 53 kWh/m2, which decreased to a maximum of 17.3 to 38.8 kWh/m2 corresponding to mitigation scenario M3 for cool materials and 22.7 to 47.9 kWh/m2 for additional greenery scenario M4. High-rise buildings, on the other hand, had cooling loads that ranged from 25 to 48 kWh/m2 in the base case but dropped to 18.4 to 37 kWh/m2 and 22.3 to 42.6 kWh/m2 in albedo mitigation scenario M3 and GI mitigation scenario M4, respectively. Figure 11 shows the comparison of the findings for the non-insulated residential and commercial structures. When the results were examined, it became clear that insulated buildings had a lower overall cooling burden than the non-insulated ones. Low-rise residential structures had cooling loads of about 22 kWh/m2 under the unmitigated scenario, which decreased to 16 kWh/m2 under the modified albedo scenario M3 and to 18.92 kWh/m2 in the enhanced GI scenario M4. Similar high-rise residential structures displayed cooling loads of 13 to 20 kWh/m2 in the base case, which decreased to 10.1 to 15.6 kWh/m2 for the M3 mitigation scenario of improved albedo and to 11.6 to 17.7 15.6 kWh/m2 for the M4 mitigation scenario corresponding to increased GI. Insulated commercial buildings, on the other hand, saw a similar pattern, with low-rise buildings having a base case cooling load ranging from 16 to 38.9 kWh/m2, a mitigated cooling load of 30.7 kWh/m2 to 12.3 kWh/m2, and a range of 14.9 to 36.2 kWh/m2 for a mitigation scenario involving a 100% increase in vegetation. Commercial high-rise structures displayed a control case cooling load of approximately 16–31 kWh/m2, which was measured as 12.4–24.6 kWh/m2 for an albedo percentage of 0.65 and 14–27 kWh/m2 for GI 100%. In comparison to the analogous scenario for more vegetation, other mitigating strategies for cool materials also had a reduced cooling burden.
In Figure 12, the comparison of the findings for insulated residential and commercial structures is shown. Overall, the average cooling load reduction for non-insulated buildings was found to be 11.7%, 17.6%, and 32.2% for the increased albedo fractions of 0.4, 0.65, and 0.8, respectively. As shown in Figure 13, a reduction of 3.9%, 6.1%, 7.8%, and 13.5% was noted for the enhanced vegetation corresponding to M1, M2, M3, and M4, respectively. The three changed albedo scenarios, however, showed a cooling load reduction of 9.3%, 12.5%, and 24.3% for the insulated structures, respectively. Similar results were obtained by increasing the vegetative fraction to 25%, 50%, 75%, and 100%, which, as shown in Figure 14, decreased the average cooling load by 4.1%, 6.5%, 8.2%, and 13.9%, respectively.
A comparison of the energy performance simulation results revealed that both improved albedo and higher GI had an important role in efficiently reducing the cooling load needs. However, a much higher cooling load demand reduction was seen in the case of using cool materials compared to the increased GI. This may be because of the higher albedo values of cool materials (CMs) compared to the plantation cover as higher albedo is responsible for an increased reflectance of solar radiation, which leads to a reduction in the cooling load demand. In contrast, increased vegetation mainly produces a cooling effect through the evaporation of vapours that drops the ambient temperature and elevates the latent heat flux. Furthermore, the shadowing effect produced by the plants also prevents heat storage in the urban built environment. Building factors such as the window-to-wall ratio, height, orientation, and building shapes also affect the cooling energy demand. For instance, high-rise buildings in both mitigation scenarios had a substantially lower cooling burden than the similar low-rise buildings in downtown Dubai.

6. Conclusions

Climate-induced global warming has significantly increased the amount of energy needed to cool buildings. GI such as trees, shrubs, and green roofs provide natural shading, reducing direct exposure to sunlight and lowering ambient temperatures. This shade can significantly reduce the cooling load on buildings and decrease the need for air conditioning, resulting in energy savings. Vegetation in GI releases moisture through a process called evapotranspiration. This evaporation cools the surrounding air, creating a microclimate with lower temperatures. As a result, buildings near GI experience decreased heat absorption and improved thermal comfort. GI helps mitigate this effect by absorbing and dissipating heat. Trees and vegetation act as natural air conditioners, reducing the overall urban temperatures and relieving the strain on cooling systems. The effectiveness of expanding urban greenery on lowering the cooling load demand for high- and low-rise commercial and residential structures in downtown Dubai was investigated using simulations of the behaviour of a range of buildings. The simulations were run using the weather information provided by WRF to CitySim. The energy demand for the 40 buildings was significantly reduced in July 2019 according to the results of an energy simulation that increased the vegetation portion from 25% to 100%. In fact, for the insulated structures, the maximum average reduction of 13.89% was found to correlate to a 100% increase in the greenery fraction. The simulation results for mitigation scenario M4 (100% vegetation fractions) showed a reduction of 4.6 and 3.1 kWh/m2 for non-insulated and insulated low-rise residential buildings, respectively, and a reduction of 3.09 to 4.91 kWh/m2 for non-insulated and 2.07 to 3.09 kWh/m2 for insulated high-rise structures. Overall, it is clear from the results that regardless of the kind, material, and form of the building, an increase in plant cover might greatly reduce the urban heat. The degree of cooling load decrease can be affected by factors including synoptic meteorological conditions, type of vegetation, building characteristics, and other urban aspects. When combined with insulation, improved urban greenery is more efficient. The data also revealed a strong correspondence between this study’s conclusions and those of other similar investigations.
The paper presents a detailed quantitative analysis of how the implementation of different types of green infrastructure affects the cooling energy consumption of buildings in subtropical urban areas. It provides specific data on the amount of energy savings that can be achieved through various green infrastructure strategies. The paper also introduced innovative modelling techniques or simulation tools from the city scale to building scale to accurately predict the cooling energy benefits of green infrastructure. This could involve combining building energy simulations with microclimate models to provide a comprehensive analysis of the interactions between urban form, vegetation, and energy consumption.
Better urban planning and architecture could also help to cut down on the amount of energy needed for cooling. A mitigation plan has now been added to the list of potential remedies that policymakers can use to combat climate change and urban heating as a result of this study.

Author Contributions

All authors contributed to this study. Methods and materials, data collection, and analysis were conducted by A.M. and A.K.; M.S. administered and supervised the project. H.S.K. prepared the data file. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

The data that support the findings of this study are available from the corresponding author upon reasonable request.

Acknowledgments

All authors are grateful to the UAE National Centre of Meteorology (NCM) for providing the data used in this study.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Flowchart of the steps involved in the study.
Figure 1. Flowchart of the steps involved in the study.
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Figure 2. Downtown Dubai location (case study area)—Google Earth Pro Maps.
Figure 2. Downtown Dubai location (case study area)—Google Earth Pro Maps.
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Figure 3. Schematic description of the workflow.
Figure 3. Schematic description of the workflow.
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Figure 4. (a) Cooling demand (kWh/m2) in all non-insulated buildings (commercial and residential) for the base case (0.2) and four heat mitigation technologies scenarios (M1, M2, M3, and M4) in the summer month. (b) Cooling demand (kWh/m2) in all insulated buildings (commercial and residential) for the base case (0.2) and four heat mitigation technologies scenarios (M1, M2, M3, and M4) in the summer month.
Figure 4. (a) Cooling demand (kWh/m2) in all non-insulated buildings (commercial and residential) for the base case (0.2) and four heat mitigation technologies scenarios (M1, M2, M3, and M4) in the summer month. (b) Cooling demand (kWh/m2) in all insulated buildings (commercial and residential) for the base case (0.2) and four heat mitigation technologies scenarios (M1, M2, M3, and M4) in the summer month.
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Figure 5. (a) Cooling needs (kWh/m2) in high-rise (H) and low-rise (L) residential buildings without insulation for the base case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month. (b) Cooling needs (kWh/m2) in high-rise (H) and low-rise (L) residential buildings with insulation for the base case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month.
Figure 5. (a) Cooling needs (kWh/m2) in high-rise (H) and low-rise (L) residential buildings without insulation for the base case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month. (b) Cooling needs (kWh/m2) in high-rise (H) and low-rise (L) residential buildings with insulation for the base case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month.
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Figure 6. (a) Cooling needs (kWh/m2) in high-rise (H) and low-rise (L) commercial buildings without insulation for the base case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month. (b) Cooling needs (kWh/m2) in high-rise (H) and low-rise (L) commercial buildings with insulation for the base case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month.
Figure 6. (a) Cooling needs (kWh/m2) in high-rise (H) and low-rise (L) commercial buildings without insulation for the base case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month. (b) Cooling needs (kWh/m2) in high-rise (H) and low-rise (L) commercial buildings with insulation for the base case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month.
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Figure 7. (a) Reduction in cooling load against the reference case (kWh/m2) in all uninsulated buildings (commercial and residential) for the base case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month. (b) Reduction in cooling load against the reference case (kWh/m2) in all insulated buildings (commercial and residential) for the base case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month.
Figure 7. (a) Reduction in cooling load against the reference case (kWh/m2) in all uninsulated buildings (commercial and residential) for the base case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month. (b) Reduction in cooling load against the reference case (kWh/m2) in all insulated buildings (commercial and residential) for the base case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month.
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Figure 8. (a) Cooling load reduction against the reference case (kWh/m2) in high-rise (H) and low-rise (L) residential buildings without insulation for the control case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month. (b) Cooling load reduction against the reference case (kWh/m2) in high-rise (H) and low-rise (L) residential buildings with insulation for the control case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month.
Figure 8. (a) Cooling load reduction against the reference case (kWh/m2) in high-rise (H) and low-rise (L) residential buildings without insulation for the control case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month. (b) Cooling load reduction against the reference case (kWh/m2) in high-rise (H) and low-rise (L) residential buildings with insulation for the control case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month.
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Figure 9. (a) Cooling load reduction against the reference case (kWh/m2) in high-rise (H) and low-rise (L) commercial buildings without insulation for the control case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month. (b) Cooling load reduction against the reference case (kWh/m2) in high-rise (H) and low-rise (L) commercial buildings with insulation for the control case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month.
Figure 9. (a) Cooling load reduction against the reference case (kWh/m2) in high-rise (H) and low-rise (L) commercial buildings without insulation for the control case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month. (b) Cooling load reduction against the reference case (kWh/m2) in high-rise (H) and low-rise (L) commercial buildings with insulation for the control case and four heat mitigation scenarios (M1, M2, M3, and M4) in the summer month.
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Figure 10. Comparison between the energy savings for enhanced vegetation with the literature results.
Figure 10. Comparison between the energy savings for enhanced vegetation with the literature results.
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Figure 11. (a) Comparison between the energy performance of modified cool materials and green infrastructure for non-insulated residential buildings. (b) Comparison between the energy performance of modified cool materials and green infrastructure for non-insulated commercial buildings.
Figure 11. (a) Comparison between the energy performance of modified cool materials and green infrastructure for non-insulated residential buildings. (b) Comparison between the energy performance of modified cool materials and green infrastructure for non-insulated commercial buildings.
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Figure 12. (a) Comparison between the energy performance of modified cool materials and green infrastructure for insulated residential buildings. (b) Comparison between the energy performance of modified cool materials and green infrastructure for insulated commercial buildings.
Figure 12. (a) Comparison between the energy performance of modified cool materials and green infrastructure for insulated residential buildings. (b) Comparison between the energy performance of modified cool materials and green infrastructure for insulated commercial buildings.
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Figure 13. (a) Average percentage reduction in cooling load by employing green infrastructure as a mitigation technique in non-insulated buildings. (b) Average percentage reduction in cooling load by employing cool materials as a mitigation technique in non-insulated buildings.
Figure 13. (a) Average percentage reduction in cooling load by employing green infrastructure as a mitigation technique in non-insulated buildings. (b) Average percentage reduction in cooling load by employing cool materials as a mitigation technique in non-insulated buildings.
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Figure 14. (a) Average percentage reduction in cooling load by employing green infrastructure as a mitigation technique in insulated buildings. (b) Average percentage reduction in cooling load by employing cool materials as a mitigation technique in insulated buildings.
Figure 14. (a) Average percentage reduction in cooling load by employing green infrastructure as a mitigation technique in insulated buildings. (b) Average percentage reduction in cooling load by employing cool materials as a mitigation technique in insulated buildings.
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Table 1. Building scale parameters for CitySim modelling.
Table 1. Building scale parameters for CitySim modelling.
Input ParametersData
TemperaturesCommercial buildings: 19.0–24.0 °C
Residential buildings: 20.0–26.0 °C
Infiltration1.0
Shading device [λ]0.2
Glazing U-valueInsulation: 1.6, 1.9, and 2.1 W/m2K
Without insulation: 5.8 W/m2K
Cut-off irradiance100 (W/m2)
Glazing g-value0.85
Surface reflectance0.2
Openable fraction0.5
CommercialResidential
GymOfficeAuditoriumShopping MallRestaurant
Occupant density (m2/P)109.3151.418.6
Internal gains (W/P)Sensible loads3882468426810390
Latent loads3155535558045
Table 2. Building features for modelling.
Table 2. Building features for modelling.
Building TypeHeight [m]Area [m2]WWR [%]No. of StoreyCategory
B01—Residential56.046,665.050.016.0H
B02—Residential192.061,008.075.048.0H
B03—Residential151.044,650.060.037.0H
B04—Residential190.0352,800.065.046.0H
B05—Shopping Mall25.01,013,379.035.04.0L
B06—Residential266.0200,087.070.062.0H
B07—Residential158.053,760.060.042.0H
B08—Residential171.035,244.050.041.0H
B09—Shopping Mall25.0126,367.050.04.0L
B10—Offices50.036,150.065.013.0H
B11—Gym16.05683.060.04.0L
B12—Residential67.024,842.050.018.0H
B13—Residential605.0259,748.095.0162.0H
B14—Restaurant12.01248.025.03.0L
B15—Shopping Mall25.0178,594.040.05.0L
B16—Residential22.0236,924.040.06.0L
B17—Residential184.051,905.065.051.0H
B18—Residential76.036,549.040.020.0H
B19—Residential80.011,856.060.020.0H
B20—Office18.01738.040.05.0L
B21—Residential115.018,301.060.033.0H
B22—Residential70.042,580.040.017.0H
B23—Office17.05787.040.05.0L
B24—Residential119.021,280.070.034.0H
B25—Residential115.022,095.070.033.0H
B26—Residential112.022,107.065.034.0H
B27—Residential96.021,588.070.029.0H
B28—Residential115.018,445.070.033.0H
B29—Residential69.015,673.070.019.0H
B30—Residential88.015,237.070.025.0H
B31—Residential142.089,334.060.039.0H
B32—Residential73.043,498.060.019.0H
B33—Residential124.049,011.040.034.0H
B34—Offices89.099,106.090.021.0H
B35—Offices28.042,182.080.06.0M
B36—Auditorium44.037,688.095.07.0M
B37—Residential119.097,767.060.034.0H
B38—Residential98.038,039.055.028.0H
B39—Residential56.026,771.030.016.0H
B40—Residential76.021,066.030.019.0H
B41—Residential68.026,820.030.017.0H
Note: Building Category H = high-rise building, M = medium-rise building, L = low-rise building.
Table 3. Building composite properties.
Table 3. Building composite properties.
LayersFeatures
Insulated StructureNon-Insulated Structure
WallExternal mortar-cement and sand; cement block; rockwool board/slab; cement board; internal mortar; plaster (U-value: 0.32 W/m2K) External mortar-cement and sand; cement block; internal mortar; plaster (U-value: 2.53 W/m2K)
Glass (U-value 1.6, 1.9, 2.1 W/m2K)Glass (U-value 5.8 W/m2K)
RoofConcrete tiles; polyurethane (PUR); light weight concrete; bitumen layer; concrete (for residential 0.2 m and for commercial 0.3 m); plaster.
U-value—residential: 0.34 W/m2K;
U-value—commercial: 0.33 W/m2K.
Concrete tiles; light weight concrete; bitumen layer; concrete (for residential 0.2 m and for commercial 0.3 m); plaster.
U-value—residential: 2.34 W/m2K;
U-value—commercial: 1.91 W/m2K.
Roof metal (steel sheet; expanded polystyrene)
U-value: 2.11 W/m2K
Roof metal (steel sheet; expanded polystyrene
U-value: 2.11 W/m2K
FloorCeramic tiles; light weight mortar; concrete;
U-value: 3.27 W/m2K.
Ceramic tiles; light weight mortar; concrete
U-value: 3.27 W/m2K.
Table 4. Climate data parameters.
Table 4. Climate data parameters.
Climatic ElementsUnits
Day-
Month-
Hour-
Beam normal irradianceW/m2
Air temperature°C
Ground surface temperature°C
Precipitationmm
NebulosityOctas
Ambient temperature°C
Relative humidity%
Wind speedm/s
Wind directiondegree
Global horizontal radiationW/m2
Diffuse horizontal irradianceW/m2
Solar normal irradianceW/m2
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Mohammed, A.; Khan, A.; Khan, H.S.; Santamouris, M. Cooling Energy Benefits of Increased Green Infrastructure in Subtropical Urban Building Environments. Buildings 2023, 13, 2257. https://doi.org/10.3390/buildings13092257

AMA Style

Mohammed A, Khan A, Khan HS, Santamouris M. Cooling Energy Benefits of Increased Green Infrastructure in Subtropical Urban Building Environments. Buildings. 2023; 13(9):2257. https://doi.org/10.3390/buildings13092257

Chicago/Turabian Style

Mohammed, Afifa, Ansar Khan, Hassan Saeed Khan, and Mattheos Santamouris. 2023. "Cooling Energy Benefits of Increased Green Infrastructure in Subtropical Urban Building Environments" Buildings 13, no. 9: 2257. https://doi.org/10.3390/buildings13092257

APA Style

Mohammed, A., Khan, A., Khan, H. S., & Santamouris, M. (2023). Cooling Energy Benefits of Increased Green Infrastructure in Subtropical Urban Building Environments. Buildings, 13(9), 2257. https://doi.org/10.3390/buildings13092257

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