Thermal performance evaluation of bio-bricks and conventional bricks in residential buildings in Aswan city, Egypt | Scientific Reports

Thank you for visiting You are using a browser version with limited support for CSS. To obtain the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles and JavaScript.

Scientific Reports volume  13, Article number: 15993 (2023 ) Cite this article Special Refractory Brick

Thermal performance evaluation of bio-bricks and conventional bricks in residential buildings in Aswan city, Egypt | Scientific Reports

From raw material extraction to final product disposal, the construction industry is integrally involved in every stage of the greenhouse gas emissions life cycle. One of the main causes of the climate catastrophe is the increasing use of polluting energy sources to power our homes and businesses. This massive problem of global warming has now forced countries to act. To further address sustainability, they seek to reduce energy consumption and CO2 emissions by adopting more sustainable materials. The current trend in scientific research is to use waste resources to improve the properties of various materials to exacerbate the problems of climate change because of the use of traditional building materials. Therefore, one of the most environmentally friendly alternatives to the standard procedure is the use of agricultural residues to improve the quality of building materials. This improvement will modify the thermal properties of building materials such as bricks, which will lead to an improvement in energy efficiency inside buildings, especially residential buildings. As a result, the research focused solely on simulating several bio-brick alternatives that had been discovered in earlier studies in order to test their viability in terms of increasing the energy efficiency of residential buildings in one of the hot cities. The study demonstrated that using bio-building materials can lower energy usage. In addition to saving energy in residential constructions, rice straw cement bricks and sugarcane bricks have operating efficiency rates of roughly 7% and 12%, respectively. All these advancements over conventional brick reduce greenhouse gas emissions and carbon dioxide.

Jianhua Li, Xueyong Xu & Xiaoqin Liu

Nour Bassim Frahat, Abid Ustaoglu, ... John Jose of the Coz Diaz

Yi Huang, Xu Chong & Wang Liang

The concentration of atmospheric greenhouse gases (GHGs) is being amplified by human activity. With the continuous increase in the world's population, the problems related to using raw materials increased, leading to an environmental imbalance. However, in recent years, environmental issues have not been reduced to this, but awareness has increased. As a result, the extent of the built environment's impact on environmental problems is known1 . So, Nowadays, countries care about the global warming problem and the greenhouse effect, which acts actively on our plants. So now researchers study reasons for environmental pollution and greenhouse effects to face risks (climate change, urban heat islands, etc.). Globally, buildings play a crucial role in the use of energy. The construction industry considerably impacts overall natural resource usage and emissions2,3. The increase in waste creation is a consequence of population growth, which has a direct impact on both the environment and the economy. In recent times, agricultural residues have emerged as a notable contributor to environmental contamination. The indiscriminate incineration of agricultural waste, such as straw and livestock manure, within the context of an agrarian nation, has resulted in a multitude of environmental issues. The escalating volume of garbage and its improper disposal, particularly in developing nations, have consistently posed a significant threat to the safety of the environment and the health of its inhabitants. Additionally, this issue has exacerbated the contribution of these countries to the global emission of greenhouse gases4. Since the beginning of the twentieth century, Construction has become entirely dependent on concrete structures and fired clay bricks, whose manufacture leads to the emission of enormous quantities of greenhouse gases. Moreover, despite their high compressive properties, their thermal properties are poor, leading to an increase in microclimate problems. The operational energy reduction is achieved by substantially increasing the insulating materials. So, a possible strategy to counterbalance this effect is to select building materials with low embodied energy; in this respect, natural materials are perfect candidates because they usually undergo few industrial manufacturing operations, accumulating low embodied energy1 . So, many researchers began creating environmental ways to eliminate these wastes by integrating them into different sectors, whether in the paper industry, the building materials industry, animal feeding, or other fields.

One of the biggest reasons for greenhouse gas emissions is buildings, as buildings are responsible for more than 35% of total emissions because of the energy consumption used in the materials manufacturing phase and the operation phase to achieve thermal comfort for users in different types of buildings.

Conventional building materials used traditionally in the construction phase allow heat to transfer through them, which raises the value of the inside temperature more than the default5.

This research aims to compare conventional materials and biomaterials (bricks) to achieve energy savings in residential buildings by enhancing building materials (bricks) characteristics, mainly thermal properties, to achieve thermal comfort for and improve human health for residents and decrease active solutions like using air conditioning.

In this paper, the research depends on the following steps to achieve a comparison between the different types of building materials (traditional and biomaterials), especially for the brick material, and it appeared in:

Evaluate the functionality of biomaterials in different examples.

Evaluation of the climatic region of Aswan City as a case study area.

Evaluate the energy consumption of Aswan city residential buildings, which use conventional materials in construction projects.

Evaluate the performance if biomaterial (Brick) is used in residential buildings by recycling two different types of agricultural waste available in Upper Egypt.

Determine the amount of energy savings achieved by replacing conventional brick with bio-brick in residential buildings.

Studying the different economical alternatives and calculating the life cycle assessment to see the impact of using bio-bricks in saving the cost of the electricity used.

Due to their durability and adaptability, bio-based materials are considered valuable construction resources in the twenty-first century. They can be manufactured locally and sustainably, with little shipping expenditure. Moreover, it has been found that this biomaterial is an excellent replacement for traditional materials because it reduces carbon and energy emissions and offers thermal comfort with reduced energy consumption for the operation of buildings6,7.

Several researchers have combined waste materials such as organic waste, waste treatment sludge, fly ash, cigarette butts, rice husk, and processed waste tea into a fired clay brick. This application suggests a way to use waste materials with little environmental impact8,9,10,11. Researchers in Sri Lanka discovered brick with new properties by adding cow dung ash to the mixture to decrease manufacturing costs and make it a more durable and eco-friendly clay brick. The best ratio for adding waste was 10%, which improved the properties of conventional brick as shown (density from 1450 to 1447 kg/m3, water absorption from 12 to 14.5%, and thermal conductivity from 0.85 to 0.2 W/m.k)12.

The increase in greenhouse emissions in the world and Egypt resulted in climate change and a marked rise in temperatures, and as a result, the climate affected human health in three ways: a direct effect through weather variables such as heat and storms; and indirectly through natural systems such as disease vectors and pathways caused by human systems such as undernutrition13,14. One of the effects of high temperatures is the deaths, injuries, and psychological trauma to which humans are exposed because of extreme natural phenomena, as well as increased respiratory infections, diarrhea, and vascular and heart diseases14. Also, due to the environmental deterioration that has been reached, the road has paved the way for viral epidemics transmitted from animal sources15.

The construction sector is one of the critical sectors in the economy of any country, whether it is developed or developing. Therefore, this sector is considered to have an important and prominent position in developing countries' national economies. It undertakes the implementation and establishment of all industrial, agricultural, tourism, infrastructure, and public utility projects and other projects necessary for the comprehensive development of these countries. It is known that the construction industry in Egypt is ancient16.

According to the latest report of the Electricity Holding Company for 2020/2021, Electricity consumed in distribution is 40.5% inside residential buildings, 13% in commercial buildings, 4.8% in government buildings, 27.3% in industry, 5.2% in agriculture, and 9.2% in other buildings as shown in Fig. 1. This percentage is a warning sign, as half of the energy consumption is used in residential buildings, which does not result in any applicable product, as in the industrial sector17.

Sold energy according to purposes (2020/2021).

The construction sector in Egypt is one of the largest and most dynamic sectors in the national economy. It is essential to economic growth through sector relationships, development plans, and various economic activities. Since 2016, the Egyptian government has paid attention to the construction sector since the launch of the economic reform program until the construction sector contributes to the growth of real GDP from 6.3% for the year 2018–2019 to 6.8% for 2020–2021. It is expected that the amount of its contribution to economic growth will increase by 8.5% for the years 2021–2022 as shown in Fig. 218.

Distribution of public investments for different sectors of the economy in Egypt in 2021/2020.

According to the annual report of the Mobilization and Statistics Authority for the year 2018/2019, the number of projects that have been completed in the construction sector equals 38,830 million pounds, and building projects represent about 83% of the total completed projects as shown in Fig. 319.

Distributed for construction section of economic activity for 2018/2019.

According to the interest of the Egyptian government in the construction sector through increasing national projects, the construction sector has become one of the most influential industrial sectors in recent years20.

Egypt enjoys many mineral resources, which are the raw materials for building materials, contributing significantly to the Egyptian economy. They are found in large quantities on the upper surface of the Earth's layers, making their extraction and exploitation easy20.

According to the report of the Mobilization and Statistics Authority for the year 2018/2019, the total production of field crops reached 118,486,134 tons, and it included many types of crops, including wheat, barley, corn, rice, legumes, sugar cane, fodder, cotton, and others. According to Omyma Swan, each ton of crop yield generates from 5 to 6 tons of waste, considered an untapped revolution21 . Agriculture in Egypt produces annually 33.477 million tons. However, more than 50% are not used. which can be exploited in several industries21,22.

The case study was selected in Aswan (a hot, arid region) to test the effect of modified bricks on thermal comfort in a residential building by reducing the heat gain from walls. The per capita share of green lands is about 0.7 m2/person and 5.3 m2/person, including the agricultural area north of Aswan city23. The case study shows the district covers (0.12 km2) area, with built up about 40% of the total area as shown in Fig. 4, and the average building height is 18 m. All structures were constructed using traditional materials as shown in Fig. 5.

Case-study area google earth map (Google Earth Pro).

One of block design in existing case (Taken by Authors).

On the warmest day in Aswan, which occurred on June 5, the climate of the region under investigation was determined. The yearly maximum and lowest temperatures are 47 °C and 29.5 °C, respectively. To evaluate the impact of bio-bricks in thermal insulation in a hot, arid climate that helped in achieving thermal comfort inside residential buildings without using mechanical facilities, the Onset-HOBO-MX1104 (Analogue/e/Temp/R.H./Light Data Logger) was used daily for 3 months (July, August, and September) to record the actual temperature and humidity in urban areas.

Using Design-Builder energy simulation 5.5 software, compare the amount of heat gained or lost within a structure constructed with conventional bricks (default Scenario used as a reference brick) vs. rice straw–cement bricks and sugarcane bagasse bricks. These types of bio-bricks were chosen because of the availability of these crops in Upper Egypt, in particular. Therefore, the use of its residues will be considered self-sufficiency in the brick industry. to determine the thermal conductivity of bricks with fixed other variables. Note that utilizing the EPW file for the city of Aswan in different scenarios and installing all parameters such as the HVAC system (Fan Coil Unit(4-pipe), Air-cooled Chiller), opening size, and floor and roof layers are required as defined in Table 124.

In the initial stage of this research, conventional brick (red-fired clay brick) is tested by preparing a model for one of the blocks in the case-study area with the existing material and original orientation to determine the amount of heat gain inside the residential unit through the construction material as shown in Fig. 6. According to the climate consultant software program, thermal comfort for users in Aswan City ranges from 19.5 to 26 °C. So, need to cool them to equal the amount of heat that has been gained through construction materials to achieve thermal comfort and health quality inside residential units. The amount of CO2 emitted because of using electricity to cool the building will rise due to this increased need for cooling as shown in Figs. 7 and 8. Bricks play a crucial role in air conditioning. The wall substantially impacts heat transmission and embodied carbon (kgCO2), as shown in Table 225.

Heat transfer through construction elements.

Distribution of electricity in residential building.

CO2 emissions from residential buildings.

In this stage, the outer skin of the structure (Bricks) is improved by using rice plant agriculture waste to generate rice straw–cement bricks with conductivity 0.41 (W/m–k) and density 884 (Kg/m3) 26. Figure 9 demonstrates that using rice straw–cement bricks reduce the heat transfer through walls, and the heat balance graph of walls becomes smoother than in the Default Scenario, minimizing the disparity between values, reducing the need to use air-conditioning to cool units, as shown in Fig. 10, and reducing embodied carbon (kgCO2) as shown in Fig. 11. On the other side, it will help to enhance the environment by reducing the burning of rice straw, which causes black clouds in Egypt, according to Omayma’s study about agricultural waste, more than 70% of rice straw is not used, and it generates about 3.6 million tons annually3.

Heat transfer through construction elements after using rice straw–cement brick.

Distribution of electricity in the residential building after using rice straw–cement brick.

CO2 emissions from residential building after using rice straw–cement brick.

At this stage, the outer shell of the structure (bricks) is improved using sugarcane plant residues as a result of several previous studies that studied the physical properties of sugarcane27 residues to generate sugarcane bricks with a conductivity of 0.27 (W/m–k) and a density of 424 (Kg/m3). Figure 12 demonstrates that using sugarcane bagasse bricks reduces the heat transfer through walls, and the heat balance graph of walls becomes smoother than in the Default Scenario and rice-straw cement brick. and minimizing the disparity between values, reducing the need to use air-conditioning to cool units, as shown in Fig. 13, and reducing embodied carbon (kgCO2) as shown in Fig. 14. Egypt generates annually about 5 tons of sugar bagasse cone. But it is an unexploited amount, but the amount of agricultural waste increases annually and is disposed of in non-environmental ways, such as burning it3.

Heat transfer through construction elements after using sugarcane bagasse brick.

Distribution of electricity in the residential building after using sugarcane bagasse brick.

CO2 emissions from residential building after using sugarcane bagasse brick.

Based on the Results of the scenarios, which showed how little heat was gained through the walls designed with bio-bricks compared to those designed with traditional bricks. As seen in Fig. 15, increasing the thermal transmittance (U value) of a material will reduce CO2 emissions and greenhouse gas (GHG) emissions, and will eliminate the need to cool interior structures. Figure 16 demonstrates that this form of bio-bricks (rice straw–cement bricks & sugarcane bagasse bricks) would reduce the energy consumption of interior buildings, as shown in Table 3. It is also considered an environmental solution for recycling agricultural waste, which Egypt enjoys, and a more economical solution than traditional bricks, because it is less expensive to manufacture than its counterpart and less expensive in the long run (operating).

Comparison between different scenarios in CO2 Production.

Comparison between different scenarios in electricity consumption.

According to Fig. 16 and Table 4, to calculate the life-cycle assessment of electricity consumption to determine the present value of electricity cost during 20 years for one block. So, assume the cost was calculated according to the inflation rate factor, then return the cost value in year number 20 to the present value to compare the electricity cost for various scenarios and calculate the saving in electricity bills in $ through 20 years as shown in Table 528,29.

The financial value equivalent to the cost of electricity consumption for the building was evaluated for a period of 20 years, considering the inflation rate of Egypt in $, which reached 40.26%, based on the Central Bank of Egypt, in order to study the viability of using bio-brick instead of conventional bricks, which resulted in a reduction in electricity consumption in residential buildings according to the following equation \(Future Value=Cost Value*(1+inflation rate\mathrm{ \%})\) .

To calculate the amount of savings in electricity bills, return the future cost value in the previous table to the present value using the following equation \(Present Value=\frac{Future Value}{{(1+r)}^{n}}\) . As shown in Table 6.

Structures cause about one-third of greenhouse gas emissions. This is because it symbolizes construction materials (bricks, concrete, tiles, etc.). After all, they need massive amounts of energy in different phases (manufacturing, mobility, construction, and operation), which increases the burden on the environment. These environmental problems increase the effects of climate change, which has become a reality of living. Therefore, all research efforts are focused on finding more environmentally bio-building materials with less harmful effects. So, this study aims to evaluate the findings of earlier laboratory studies to discover new kinds of modified and improved bio-bricks in terms of their thermal qualities. As a result, the results were put to the test by simulating the amount of electrical energy needed to cool the building. Considering that modelling software uses conventional materials to determine overall cooling loads, the use of biomaterials will cut CO2 emissions.

Manufacturing has less impact on the surrounding environment than conventional methods.

Developing a plan to dispose of agricultural waste without harming the environment.

To improve the interior environment and human health, provide suggestions for using alternative building materials for more sustainable construction.

Increasing the thermal transmittance of materials will reduce residential buildings' power use.

To achieve self-sufficiency for the city in the construction sector and to develop new types of essential building materials with thermally improved properties to improve energy efficiency in various types, future studies will point researchers to the possibility of using the various types of waste that are generated in the city of Aswan and the possibility of recycling them in the manufacture of various building materials. structures in places with unique climate features (hot, arid areas) like Aswan.

The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.

Melia, P., Ruggieri, G., Sabbadini, S. & Dotelli, G. Environmental impacts of natural and conventional building materials: A case study on earth plasters. J. Clean. Prod. 80, 179–186 (2014).

Cabeza, L. F., Rincón, L., Vilariño, V., Pérez, G. & Castell, A. Life cycle assessment (LCA) and life cycle energy analysis (LCEA) of buildings and the building sector: A review. Renew. Sustain. Energy Rev. 29, 394–416 (2014).

Fouad, Y. in Egupt's First Biennial Update Report. (Ministry of Environment, Egyptian Environmental Affairs Agency, Cairo, 2018).

Elbasiouny, H., Elbanna, B.A., Al-Najoli, E., Alsherief, A., Negm, S., Abou El-Nour, E., Nofal, A. & Sharabash, S. Agricultural waste management for climate change mitigation: Some implications to Egypt. In Waste Management in MENA Regions, 149–169 (Springer, 2020).

Pezeshki, Z., Soleimani, A., Darabi, A. & Mazinani, S. M. Thermal transport. Build. Mater. Constr. Build. Mater. 181, 238–252 (2018).

Sandak, A., Sandak, J., Brzezicki, M., Kutnar, A., Sandak, A., Sandak, J., Brzezicki, M. & Kutnar, A. Biomaterials for building skins. In Bio-based Building Skin, Hong Kong, 27–64 (Springer Open, 2019).

Yadav, M. & Agarwal, M. Biobased building materials for sustainable future: An overview. Mater. Today Proc. 43, 2895–2902 (2021).

Kadir, A. A., Sarani, N. A., & Leman, A. M. Testing on building material using waste material in fired clay brick. In Materials Science Forum, 330–336 (2015).

Farnea, R., Manea, D. L., Tamas-Gavrea, D. R. & Rosca, I. C. Hemp-clay buildingmaterials—An investigation on acoustic, thermal and mechanical properties. In The 12th International Conference Interdisciplinarity in Engineering, (Brasov, 2019).

Walker, R. & Pavía, S. Moisture transfer and thermal properties of hemp–lime concretes. Constr. Build. Mater. 64, 270–276 (2014).

Sakhare, V. V. & Ralegaonkar, R. V. Use of bio-briquette ash for the development of bricks. J. Clean. Prod. 112, 684–689 (2016).

Fernando, P. R., Krishanth, S., Rathnayake, N. B. & Welarahne, S. A. Manufacturing, physical and chemical characterization of fire clay brick value added with cow dung ash. Am. J. Mater. Synthesis Process. 4, 32–36 (2019).

E. M. a. S. Agency, "Population," Egyptian Mobilization and Statistics Agency (report), 2021.

U. S. E. P. United States Environmental Protection Agency, "Climate Change and Human Health," 7 June 2022. [Online]. Available: Accessed jul 2022.

United Nations High Commissioner for Human Rights, U. N. H. C. f. H. Frequently asked questions about human rights and climate change. (Newyork, 2022).

Rajeh, A. Z. Egyptian urbanism: Monitoring developments in the urbanization of Egypt in the late twentieth century and exploring its future paths until 2020. Vol. 2, In The Historical Development of the Construction Sector in Egypt, 327-350 (Academic Library, Egypt, 2008).

T. E. &. R. E. Ministry, The Electricity & Renewable Energy Ministry (report) "Annual report of the Electricity Holding Company," Egypt, 2020–2021.

Ministry of Planning & Economic Development M. O. P. &. E. Development, Puplic Investments. May 2022. [Online]. Available:

C. A. F. P. M. &. Statistic, "Annual Bulletin of Construction & Bulding Statistics for Public / Pulic Bussines Sector Companies 2019/2018," Egypt, March 2021.

Fatima Ajrama, Hamdi Abdel-Fattah, Maher Al-Nimr. Analysis and evaluation of the risks facing the construction sector in Egypt since the beginning of the nineties. Eng. Res. J., 409–416 (2011).

Omyma Swan, Mahmoud Mostafa, Mohammed Bakry, Shaban Abu hessin, Meshel Farag, Hamdy Mahmoud. Omyma Swan Agricultural Waste Recycling Manual. (Ministry of State for Environmental Affairs, Egypt, 2010).

Geologist, "Row materials for building and construction materials in Egypt," 4 Novamber 2020. [Online]. Available:

Mohamed, A. F. A. & Abdelhady, R. E. Renovation of nile cornish and ancient touristic market in Aswan City; attempt to solve the public transportation problem. In Cities’ Identities Through its History of Architecture and Arts, (2020).

Rania Emad Abd El-Hady Ismail. An effect of bio-brick for energy consumption in residential building case study: An existing residential building in Aswan, Egypt M.Sc Thesis, (Arab Academy for Science, Technology & Maritime Transport, South Valley, 2022).

Zayan, A. A., Mohamed, A. F. & Abd El-Hady, R. E. Effect of bio-material in thermal insulation case-study: Energy saving in residential building in Aswan City. In IOP Conference Series: Earth and Environmental Science, (2022).

Akmal, T., Fahmy, M., & El-Kadi, A. W. Rice-straw based cement brick microclimatic thermal impact assessment in Cairo, Egypt. In World Renewable Energy Congress 2011, (Sweden, 2011).

Adefris Legesse, A., Desalegn, D., Selvaraj, S. K., Paramasivam, V. & Chadha, U. Experimental investigation of sorghum stalk and sugarcane bagasse hybrid composite for particleboard. In Advances in Materials Science and Engineering, 1–17 (2022).

Rautray, P., Roy, A., Mathew, D. J., & Eisenbart, B. Bio-brick—Development of sustainable and cost effective building material. In International Conference on Engineering Design, India, (2019).

Mohamed, A. F. Comparative study of traditional and modern building techniques in Siwa Oasis, Egypt: Case study: Affordable residential building using appropriate building technique. Case Stud. Constr. Mater. 12, e00311 (2020).

Open access funding provided by The Science, Technology & Innovation Funding Authority (STDF) in cooperation with The Egyptian Knowledge Bank (EKB).

Architectural Engineering and Environmental Design Department, Arab Academy for Science, Technology & Maritime Transport (South Valley Branch), El Sadadt Street, Aswan City, Egypt

Architectural Engineering and Environmental Design Department, Arab Academy for Science, Technology & Maritime Transport, Heliopolis, Egypt

You can also search for this author in PubMed  Google Scholar

You can also search for this author in PubMed  Google Scholar

R.E. and A.F. wrote the main manuscript text and prepared all figures. All authors reviewed the manuscript. The datasets used and analysed during the current study available from the corresponding author on reasonable request.

Correspondence to Rania Emad Abd El-Hady or Abdelaziz Farouk A. Mohamed.

The authors declare no competing interests.

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit

Abd El-Hady, R.E., Mohamed, A.F.A. Thermal performance evaluation of bio-bricks and conventional bricks in residential buildings in Aswan city, Egypt. Sci Rep 13, 15993 (2023).


Anyone you share the following link with will be able to read this content:

Sorry, a shareable link is not currently available for this article.

Provided by the Springer Nature SharedIt content-sharing initiative

By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.

Scientific Reports (Sci Rep) ISSN 2045-2322 (online)

Thermal performance evaluation of bio-bricks and conventional bricks in residential buildings in Aswan city, Egypt | Scientific Reports

High Heat Bricks Sign up for the Nature Briefing newsletter — what matters in science, free to your inbox daily.