Impact Of Microclimate Research Articles

Effects of No-Tillage on Field Microclimate and Yield of Winter Wheat

Field studies were conducted in the North China Plain (NCP) during the 2023–2024 season to investigate the vertical microclimate, yield, and yield-related characteristics of winter wheat during the grain-filling stage under no-till direct seeding and conventional tillage. The aim was to compare the differences in microclimate between the two tillage methods in wheat fields and the impact of microclimate on yield. The results indicated that, compared to conventional tillage, no-till direct seeding reduced the air temperature and increased the relative humidity of the air at 20 cm and 100 cm above the ground during the wheat grain-filling period. The soil moisture content at 20 cm below the ground under no-till direct seeding was higher than under conventional tillage during the early grain-filling stage. Seven days before the wheat harvest, the dry weight per plant and the dry weight per spike were significantly greater under no-till direct seeding than under conventional tillage. Consequently, the thousand-grain weight of no-till direct seeding was significantly higher than that of conventional tillage, with an increase of 7.9%. The number of wheat sterile spikelets under no-till direct seeding was significantly lower than that under conventional tillage. Furthermore, the number of grains per spike was higher than that of conventional tillage. Although the number of harvested spikes under no-till direct seeding was 10.8% lower than under conventional tillage, the increase in thousand-grain weight and the number of grains per spike compensated for the reduced number of harvested spikes. As a result, the grain yield of winter wheat under no-till direct seeding was higher than that of conventional tillage, increasing by 2.7%. Therefore, adopting no-till direct seeding in the NCP is conducive to increasing winter wheat production and efficiency, as well as supporting sustainable agricultural development.

Nature-Based Solutions Planning for Urban Microclimate Improvement and Health: An Integrated Ecological and Economic Approach

Nature-based Solutions (NbSs) play a pivotal role in mitigating the impact of microclimates on human well-being. The effectiveness of NbSs is contingent upon the synergy between natural capital, defined by the ecological structure and functions of the ecosystem, and human-derived capital, encompassing the economic investments required for implementation. This study introduces a decision-making framework designed to evaluate the impact of NbSs and advocate for optimal solutions for human health at the local scale, amalgamating ecological and economic assessments. Physiological Equivalent Temperature (PET) was chosen as a key urban parameter to assess the efficacy of NbSs in mitigating urban microclimates and enhancing human health. The PET analysis was conducted using ENVI-met 5.0.3 software across diverse urban scenarios in Gallipoli city, Italy. Integrated with a cost–benefit analysis of NbSs considering various investment scenarios, the study aimed to identify the most effective solution. Results indicated positive effects of NbSs in open spaces and around building blocks where the PET levels remained below 30 °C. Conversely, scenarios without NbSs exhibited PETs exceeding 40 °C, with peaks of 50 °C, posing potential risks to human health. Considering the social and economic benefits associated with PET mitigation, the cost–benefit analysis suggests that implementing NbSs using a mix of young and mature plants in the initial phase is advantageous compared to using only young plants. Thus, in establishing NbSs, it is crucial to consider not only the quantity of vegetation but also the strategic timing of implementation. In conclusion, our work offers an innovative framework that combines ecological and economic perspectives, providing valuable insights for decision-makers in urban planning and promoting the practical application of NbSs for enhanced human well-being.

Chemical fractions of potassium in arid region calcareous soils: The impact of microclimates and physiographic variability.

Factors such as topography, mineralogy, physicochemical properties, and climate can affect the distribution of soil potassium (K) forms. However, often the special effects of physiographic units are neglected. Therefore, this study aimed to investigate the factors controlling the distribution of chemical fractions of K in different physiographic units of calcareous soils (piedmont plain, flood plain, alluvial plain, lowland, badland, and plateau) in southern Iran. The XRD analyzing patterns showed that the distribution of K forms is controlled by K-bearing minerals (i.e., illite) in finer particles of the soils. Physiographic units significantly affect the distribution of K forms due to different microclimates (such as soluble, exchangeable, and non-exchangeable). In addition, different correlations between the K forms and some physicochemical properties of the soils such as soil texture (i.e., silt (r = 0.511** to 0.527**) and sand (r = -0.357* to -0.389*)), electrical conductivity (EC) (r = 0.617** to 0.723**), sodium absorption ratio (SAR) (r = 0.478** to 0.577**), pH (r = 0.347* to 0.519**), and gypsum (r = 0.372* to 0.475**) were found in soils of the study area. It is recommended that cultivation sites are chosen with a deeper understanding of land conditions e.g., slope, elevation, microclimatic conditions, soil development, and clay mineralogy.

Urban Microclimate Impact on Vertical Building-Integrated Photovoltaic Panels

The ongoing climate crisis and turbulence on the world stage has highlighted the need for sustainability and resilience in the development and maintenance of urban areas regarding climate comfort and energy access. Local production of green energy increases both the sustainability and resilience of an area. Traditionally, photovoltaic (PV) panels are deployed wherever the amount of sunlight is highest but lowering costs for PV panels makes them cost-effective even in colder climates. Within the broader umbrella of positive energy districts, façade mounted building-integrated PV panels in urban areas additionally present unique opportunities and challenges, as factors such as wind, solar irradiance, or nearby obstructions can have either a positive or negative effect on the performance of the PV panels. In this article, we aimed to answer the question: What factors inform the optimization of vertical PV panels? To answer this, we developed a method for the optimization of placement of PV panels. By building upon readily available weather data, local panel conditions were examined, and field-driven aggregation algorithm used to guide panel placement. Performance of the resulting panel configurations were then compared to a baseline case. Results indicate that our developed method helped mitigate negative impacts of the aforementioned factors, and often improved performance over baseline.

Effects of Design Factors and Multi-Stage Environmental Factors on Hydrological Performance of Subtropical Green Roofs

Environmental and design factors determine the stormwater management capacity of green roofs; however, the design and environmental factors that impact their hydrological performance in subtropical humid regions are poorly understood. In particular, meteorological factors have received little attention. Meteorological factors vary greatly at different stages of a rainfall event (e.g., during the rainfall and outflow). Therefore, the impact of meteorological factors at different stages on hydrological performance should be considered separately to obtain a more accurate picture of their effects on hydrological performance. In this study, experimental green roofs were established based on four substrate types and two depths. For the first time, this study systematically explored the effects of design factors for the substrate (type and depth) and multi-stage environmental factors on the hydrological performance of green roofs. Environmental factors, including meteorological factors, from three critical stages (before and during a rainfall event and during the outflow), and rainfall characteristics (e.g., rainfall depth and rainfall duration) were incorporated to determine the variation in hydrological performance. The effects of multi-stage environmental factors on retention and peak reduction were analyzed, with a ranking of each factor’s relative importance. Environmental factors played a leading role in determining hydrological performance. However, the impact of multi-stage environmental factors was not as important as that of rainfall depth and antecedent volumetric water content. Differences in hydrological performance were compared across combinations of design factors. No significant differences were observed across substrate types and depths. However, potential interactive effects might exist, though these were not significant compared to environmental factors (e.g., rainfall depth and rainfall duration). These results confirmed that the meteorological factors in the different event-related stages significantly impacted the hydrological performance. Quantifying the effects of design and environmental factors is critical for hydrological performance evaluation. The results provided a broader perspective on understanding influence mechanisms of hydrological performance and highlighted the impact of microclimates on hydrological performance.

Rethinking Pliny’s “Sicilian Crocus”: Ecophysiology, Environment, and Classical Texts

Classical scholars have long held that the saffron in widespread use throughout the ancient Mediterranean was Crocus sativus (Iridaceae), a sterile triploid descendant of the wild Crocus cartwrightianus, and indeed use of Crocus sativus in antiquity has been extensively borne out both by iconographic and phylogenetic studies. Two principal scholars of the Roman world, Dioscorides the physician and Pliny the natural historian, disagreed radically over the virtues and commercial value of saffron crocus from Sicily, with one praising its quality, and the other excoriating it. This study draws on ecophysiology, classical texts, environmental archeology, and phytochemistry to explain this disagreement and its implications. It explores the potential impact of microclimate on crocus cultivation in the ancient Mediterranean and proposes a new species identification for Sicilian crocus: Crocus longiflorus. The identification of Crocus longiflorus as “Sicilian saffron” offers an important corrective to the assumption that Crocus sativus was the sole crocus species of commercial value in the ancient Mediterranean and renews attention to the economic potential and utility of an indigenous southern Italian species overlooked in classical and later scholarship.

Behaviour and distribution of Aedes aegypti mosquitoes and their relation to dengue incidence in two transmission hotspots in coastal Ecuador.

Dengue (DENV) transmission is endemic throughout coastal Ecuador, showing heterogeneous incidence patterns in association with fine-scale variation in Aedes aegypti vector populations and other factors. Here, we investigated the impact of micro-climate and neighbourhood-level variation in urbanization on Aedes abundance, resting behaviour and associations with dengue incidence in two endemic areas. Aedes aegypti were collected in Quinindé and Portoviejo, two urban cantons with hyperendemic dengue transmission in coastal Ecuador. Aedes vectors were sampled in and around houses within urban and peri-urban neighbourhoods at four time periods. We tested for variation in vector abundance and resting behaviour in relation to neighbourhood urbanization level and microclimatic factors. Aedes abundance increased towards the end of the rainy season, was significantly higher in Portoviejo than in Quinindé, and in urban than in peri-urban neighbourhoods. Aedes vectors were more likely to rest inside houses in Portoviejo but had similar abundance in indoor and outdoor resting collections in Quinindé. Over the study period, DENV incidence was lower in Quinindé than in Portoviejo. Relationships between weekly Ae. aegypti abundance and DENV incidence were highly variable between trapping methods; with positive associations being detected only between BG-sentinel and outdoor Prokopack collections. Aedes aegypti abundance was significantly higher in urban than peri-urban neighbourhoods, and their resting behaviour varied between study sites. This fine-scale spatial heterogeneity in Ae. aegypti abundance and behaviour could generate site-specific variation in human exposure and the effectiveness of indoor-based interventions. The trap-dependent nature of associations between Aedes abundance and local DENV incidence indicates further work is needed to identify robust entomological indicators of infection risk.

Impact of Microclimate on Perception and Physical Activities in Public Spaces of New Urban Areas in Beijing, China

The development of new urban areas in Beijing has alleviated overcrowding in old urban centers and has ample public spaces for recreational activities. However, these public spaces are not ideally designed and have not been as successful as expected. Few studies have investigated the ineffective use of these public spaces in terms of microclimatic and thermal comfort factors. Our study investigated microclimatic factors, the subjective assessment of thermal comfort, the intensity of human activities, and the spatial features of public spaces in conjunction with surrounding buildings in a mixed commercial and residential complex in the Fangshan District, Beijing. We used a mixed-methods approach comprising microclimate measurements, questionnaires (n = 150), spatiotemporal behavior mapping, and field measurements. Our results showed that the human perception of the microclimate is related to the exposure duration and other microclimatic factors. The perception of people who spend longer periods outdoors is often inconsistent with objectively measured thermal comfort values. Activity intensity (low, medium, and high) was also related to the duration of time spent outdoors. Microclimatic factors affect the number of people at different activity intensities and the trajectory of the activities. Different spatial features cause different microclimate formations and can directly influence the human subjective assessment of thermal comfort. This study uniquely links the microclimate to human perceptions, physical activities, and spatial features in service of redesigning public spaces. We developed a comprehensive methodology that expands the post-occupancy evaluation and proposes new urban public space designs that consider microclimates. This study also provides a new perspective for promoting physical activity by enhancing the thermal comfort of the environment to achieve physical and mental health goals.

Improving urban resilience and habitability by an effective regeneration of the streets: A comprehensive approach step-by-step validated in a real case

The world's average temperature has increased by 1 °C, leading to more frequent and intense extreme weather events. Attention has turned to the Urban Heat Island (UHI), a warming phenomenon in cities resulting from human activities and the urban design. In this way, urban adaptation of streets and the development of new urban spaces focus on achieving thermal comfort. While the research community proposed surface energy balances (SEB), a limitation arises from SEB's ability to identify UHI due to its exclusion of anthropogenic heat. This study highlights the need to address anthropogenic variables and the importance of continuous monitoring in urban areas undergoing adaptation. A calculation method called co-simulation is suggested to incorporate anthropogenic heat using ENVI-met software as the basis. Adaptation justification involves monitoring and assessing the COMFA comfort index in an avenue. The calculation process proposes improvements for a comfortable environment, evaluating the microclimate impact on urban adaptation. Implementation, ongoing monitoring, and a comprehensive sensitivity analysis of the COMFA comfort index ensure a 60% improvement in the thermal sensation from June to September. This approach promotes the adoption of innovative solutions for climate change, emphasizing energy efficiency and well-being in urban spaces.

Climate Modelling and Analytics for Urban Heat Risks Mitigation and Adaptation

This study highlights the need for climate-sensitive urban planning and design in the face of climate change, with a specific focus on Singapore. Rapid urbanization has led to significant warming trends, increased heat stress, and heightened electricity demand for cooling. The Urban Climate Design Lab (UCDL) at the National University of Singapore employs a multidisciplinary approach, merging urban planning, architecture, and urban climate science. The research introduces GIS-based tools to evaluate the microclimate impact of new developments, replacing time-consuming simulations and wind tunnel experiments. These tools encompass: 1) The Urban Wind Environment Model, assessing urban permeability for natural ventilation; 2) The Fine-Scale Wind Environment Model, providing high-resolution pedestrian-level wind speed data. 3) The Urban Tree-Airflow Model, aiding tree placement and species selection for optimal cooling. 4) The Anthropogenic Heat Dispersion Model, estimating the impact of human-generated heat emissions. These GIS tools are integrated into the open-access UCDL Microclimate Digital Platform, facilitating knowledge transfer and empowering stakeholders in climate-sensitive urban planning. The platform offers various climate models and visualization capabilities to enhance evidence-based decision-making for urban climate sustainability and resilience. In the future, the platform will expand its offerings, becoming a valuable resource for urban planners, engineers, health practitioners, environmental experts, and residents adapting to a changing climate.

The microclimate impact of treetop walk based on plant community simulation.

The treetop walk is an innovative urban greenway that harmoniously integrates with the natural topography, meandering through the tree canopy. It serves as a vital element in elevating the urban mountain landscape while also significantly impacting the recreational experiences of the public through its microclimate effects. Moreover, the distinctive plant community characteristics of the treetop walk significantly enhance the microclimate. Examining the plant community attributes that potentially influence the microclimate conditions of the treetop walk is of utmost importance. We chose the Fu Forest Trail in Fuzhou as the sample site for this research. By implementing an orthogonal experimental design and using ENVI-met software, we simulated data to explore the impacts of various plant community characteristics on the microclimate of the treetop walk in autumn. The findings revealed the following results: (1) The presence of tree height, leaf area index, crown type, and planting density significantly influenced the microclimate of the treetop walk green spaces, with some factors having primary effects while others having secondary effects. (2) No significant variations were observed in the microclimate effects of diverse plant community characteristics in the treetop walk during morning, noon, and evening hours. (3) Scheme 13 emerged as the optimal choice for cooling and humidifying ventilating, characterized by a tree height of 20m, leaf area index of 4.4, spherical crown shape, and planting spacing of 2m. The tree species available in the Fuzhou area include Ligustrum quihoui Carr., Buxus sinica, Laurus nobilis, Myrica rubra, and Osmanthus fragrans. (4) Compared to traditional understory trails, tree height and planting spacing notably influence the microclimate environment of the treetop walk.

Quality Characteristics of Twelve Advanced Lines of Avena magna ssp. domestica Grown in Three Contrasting Locations in Morocco.

The popularity of oats (Avena sativa) continues to increase in the cereal market due to their health benefits. The recent domestication of Avena magna, a Moroccan oat, presents an opportunity to enhance these benefits due to their higher nutritional composition. As the impact of microclimates on A. magna grain composition has not been explored, this study evaluates twelve A. magna ssp. domestica lines across three Moroccan locations, providing new data into microclimate effects on key grain characteristics. Significant variability is observed among lines and sites for nutrients, with mean protein, fat, and dietary fiber contents at 23.1%, 8.38%, and 7.23%, respectively. High protein levels, reaching 27.1% in Alnif and 26.5% in El Kbab, surpass the 'Avery' control (21.7% and 24.2%) in these environments. Groats from Bouchane exhibited elevated fat and fiber contents (10.2% and 9.94%) compared to the control (8.83% and 7.36%). While β-glucan levels remain consistent at 2.53%, a negative correlation between protein content, fat, and starch was observed. A. magna lines exhibited higher levels of iron (7.50 × 10-3 g/100 g DM) and zinc (3.40 × 10-3 g/100 g DM) compared to other cereals. Environmental conditions significantly influence grain quality, with El Kbab yielding higher protein and ash contents, as well as Bouchane having increased fat, fiber, and starch. Stability analysis indicates that fat content was more influenced by the environment, while 25% of protein variability is influenced by genetics. Lines AT3, AT5, AT6, AT13, and AT15 consistently exceeds both the mean for protein and fiber across all sites, emphasizing their potential nutritional value. This study highlights the potential of A. magna ssp. domestica to address nutritional insecurity, particularly for protein, iron, and zinc in domestic settings.

Trends and challenges of the interactions between microclimate and electric power systems

<p>The increasing penetration of renewables has made electric power systems meteorology-sensitive. Meteorology has become one of the decisive factors and the key source of uncertainty in the power balance. Macro-scale meteorology might not fully represent the actual ambient conditions of the loads, renewables, and power equipment, thus hindering an accurate description of load and renewables output fluctuation, and the causes of power equipment ageing and failure. Understanding the interactions between microclimate and electric power systems, and making decisions grounded on such knowledge, is a key to realising the sustainability of the future electric power systems. This review explores key interactions between microclimate and electric power systems across loads, renewables, and connecting transmission lines. The microclimate-based applications in electric power systems and related technologies are described. We also provide a framework for future research on the impact of microclimate on electric power systems mainly powered by renewables.</p>

Factors of the aging process and longevity—selected data

Abstract The article presents endogenous and exogenous factors affecting the aging process and longevity, indicating their influence on the epigenome and genome. While discussing endogenous factors, we described genes and protein complexes, metabolic and signaling pathways [IIS (insulin and insulin-like growth factor 1/IGF-1 signaling), ARE/Nrf2 (antioxidant response elements/nuclear factor erythroid-related factor 2), kynurenine/NAD+ (nicotinamide adenine dinucleotide and kynurenine signaling)], and the sirtuin enzyme group and antioxidant enzymes (e.g., SOD1). While characterizing exogenous factors, we indicated the role of nutrition, including the effect of a diet balanced in terms of the number of calories and the effect of consuming polyphenols, including resveratrol, curcumin, or epigallocatechin-3-gallate, and vitamins C and E, as well as the impact of microclimate, stress, the role of physical exercise, and the use of pharmacological agents. Analysis of these data showed that the factors related to the aging process have an influence on longevity and age-related diseases.

Comparison of building energy performance in three urban sites using field measurements and modelling in Kayseri, Turkiye

Despite the fact that the interrelationships between urban microclimates and energy demand have been recognised, there are not many processes that combine microclimatic boundary conditions to estimate energy consumption in parametric morphological investigations. Therefore, this paper will demonstrate a simple step-by-step methodology to incorporate the effect of urban microclimate on building cooling energy demand in semi-arid climatic areas. In this study, the combination of ENVI-met, Urban Weather Generator (UWG) and Rhino grasshopper are used to investigate the connection between microclimate and energy in the climatic environment of Kayseri. This coupling’s potential is investigated across compact high-rise, midrise and low-rise buildings, focusing on the cooling requirement on the hottest days. The comparative study shows how and to what extent urban geometry, building height in this case, contributes to modifying the magnitude of microclimate impact on building cooling performance.

A case study of the effect of building surface cool and super cool materials on residential neighbourhood energy consumption in Nanjing

Cool materials for building surfaces have been invented to reduce building energy consumption. This study aimed to investigate the impact of cool and super cool materials on the energy consumption of residential neighbourhoods in Nanjing. First, the impact of microclimate on building energy consumption simulation is investigated. An energy correction model is obtained to consider the impact of microclimate factors when energy consumption is calculated using meteorological data. Compared to meteorological data, the wind speed in the microclimate data for the urban centre is significantly lower, and the temperature is significantly higher. In addition, the seasonal and annual energy saving rates of cool and super cool materials in six typical residential neighbourhoods are analyzed. The results show that cool and super cool materials are very effective for reducing building energy consumption in summer, with energy saving rates of up to 13.85 % for cool materials and 17.74 % for super cool materials. However, building energy consumption increases in winter when using cool and super materials, so it is necessary to evaluate the energy saving effect of cool materials based on annual energy consumption. Overall, for residential neighbourhoods in Nanjing with a sky view factor less than 0.45, the annual energy saving rate is 1.95 % for cool materials and 2.35 % for super cool materials. The conclusions of this study can provide a guide for energy conservation policy in residential neighbourhoods in Nanjing.

Numerical model study on influences of photovoltaic plants on local microclimate

The construction of large-scale photovoltaic plants will inevitably change the local environment. We consider that the influences of such increasing large-scale photovoltaic installations on radiation, temperature, wind profile and other factors within the region can be described in a layer of photovoltaic canopy. This paper improves the UCRC-Solar model for photovoltaic plants, with reference to the calculation of sensible heat flux of the underlying forest surface. Model verification was done with measured data from the Red Rock photovoltaic plant, Arizona, USA. In this study, it indicates that photovoltaic plant has locally generated heat island effects in daytime. The calculation of local microclimate changes before and after the construction of the photovoltaic plants and, the impact of photovoltaic coverage finds an increase in the temperature daily range and a reduction in the ground temperature by about 5 °C. Furthermore, a 15 % increase in photovoltaic coverage increased the daily 3 m air temperature difference by 0.55 °C and reduced the ground temperature by 3.6 °C in the day and 1.1 °C at night, respectively. In the future, rain and snow processes would be considered to further explore the microclimate impact of photovoltaic plants.

Urban Cool Island as a sustainable passive cooling strategy of urban spaces under summer conditions in Mediterranean climate

Rapid urbanization of cities is changing the local climate, resulting in high temperatures and rough, dense urban environments lacking in water and vegetation. Currently, public space is the object of particular attention due to the concern of improving the quality of life on which the feeling of well-being strongly depends. This study focuses on the problem of urban warming. It is interested in evaluating the effect of natural cooling by the plant cover and water in urban spaces and their microclimatic impact on the built environment during the hot period at the level of the city of Jijel with humid climate. More precisely, it aims at comparing in a simplified and synthetic way different strategies proposed in the form of scenarios by the numerical simulation software ENVI-met. Compared to the initial case, the results have confirmed that the blue and green scenarios have produced a coolness island effect and have allowed the mitigation of urban heat islands during the day.

A comparative study of the effects of photovoltaic power plants in desert and lake on the microclimate

The utility-scale deployment of photovoltaic (PV) power plants is critical for achieving carbon peaking and carbon neutrality goals and mitigating climate change. However, the impact of a PV power plant project on the microclimate is unclear for different underlying surfaces. Therefore, PV power plants in deserts and lakes were selected to assess and compare the impact of PV array deployment on the environment by the observation. The results indicate that the PV array affected the wind pattern, the wind direction makes simple (from 10 m to 2 m), and wind speed in the PV site under two types of underlying surfaces was less than the reference site. For the PV power plant in desert, the delta (PV - REF) is increased from 0.12 m s−1 at 10 m to 0.27 m s−1 at 2 m. The counterpart in the lake is increased from 0.14 m s−1 at 10 m to 0.55 m s−1 at 2 m. However, the PV arrays had no effect on the air temperature at the center of the PV array gap. The difference in air temperature for two observation sites under two type of underlying surfaces was less than the resolution of instrument MaxiMet (0.1 °C). Instead, the heat from the PV panels is transmitted down to the land surface, causing a temperature effect in the desert and lakes. For the PV power plant in land, the arrays have heating effect on air temperature (The air temperature was 33.43 °C in the PV_land site, and 28.03 °C in the REF_land site in July, respectively). But the arrays have cooling effect on air temperature for the PV power plant in lake in the same month (PV_lake site, 28.58 °C; REF_lake site, 29.97 °C). Furthermore, evaporation is lower in the PV power plant owing to the physical shielding of PV arrays (For the land, the peak of hour evaporation (PV_land – REF_land) was 0.12 mm; for the lake, the peak of hour evaporation (PV_lake – REF_lake) was 0.32 mm). This study provides new evidence of the microclimate impact of photovoltaic array deployment on different underlying surfaces.

The impact of microclimate on energy performance of office buildings within urban contexts located in a composite climate, the city of Indore

The energy consumption and thermal performance of a building depend not only on the internal factors, geometry and orientation but also on the external microclimatic factors such as vegetation, solar radiation, air temperature, wind speed and wind direction. Further, it is also influenced by the surrounding built environment characteristics such as street geometry, buildings and surface characteristics. The main objective of the current research paper is to record the energy performance of office buildings within urban contexts, located in a composite climate, for instance, the city of Indore and to determine the influence of the external parameters on energy consumption of the built space so as to optimize the built environment factors and achieve low energy consumption. The current study involves the identification of two office buildings in Indore with different built environmental characteristics. Field measurements were carried out on street canyons along the south and west façades of the buildings and the impact of external microclimatic parameters and the surrounding built environment characteristics on energy consumption of the building was quantified in this study. It was found that the street geometry, H/W ratio, street orientation, building material, urban density and vegetation has significant effects on microclimate and energy consumption of the buildings.