green architecture research topics

Thesis Topics for Architecture :20 topics related to Sustainable Architecture

Sustainable architecture is the architecture that minimizes the negative environmental impact of buildings. It aims at solving the problems of society and the ecosystem. It uses a selective approach towards energy and the design of the built environment. Most often sustainability is being limited to the efficient water heater or using high-end technologies. It is more than that. It is sometimes about creating awareness among people and communities about how we can coexist in the natural environment. Sustainable architecture is a means to enter the context in a natural way, planning and deciding the materials before the construction that have very few negative effects on the environment. Here are 20 Thesis topics for architecture related to Sustainable Architecture:

1. Urban Park | Thesis Topics for Architecture

To make a city livable and sustainable, urban parks play a key role to provide a healthy lifestyle for the residents of the city. It provides transformative spaces for the congregation and community development . Public parks are very crucial within the cities because they are often the only major greenery source for the area.

20 Thesis topics related to Sustainable Architecture - Sheet1

2. Neighborhood Development

There is always a challenge to implement sustainable development at a very local level. Thus, urban sprawl, environmental degradation, and traffic congestion have made it necessary to look at problems at the basic level. In cities, there is an extra opportunity to develop a sustainable neighborhood that incorporates energy-efficient buildings, green materials, and social infrastructures.

3. Community Garden Design | Thesis Topics for Architecture

Community gardens are the latest trend for sustainable living in urban areas due to rising health issues in the cities. It helps promote farming as an activity where locals can also get involved in the activities and encourage them to use gardens as recreational spaces. The gardens assist in the sustainable development of urban areas.

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4. Waste Recycling Center

Waste recycling centers can be one of the great thesis topics for architecture since waste recycling is always seen as a burden on the city. But it can be converted into an opportunity by incorporating its function and value into the urban fabric . Waste to energy plants or waste recycling centers can be integrated with public functions that engage communities.

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5. Restoration of Heritage/Old Building

Building restoration is the process of correctly exposing the state of a historical building, as it was in the past with respecting its heritage value. India has many heritage buildings including forts, temples , buildings which are in deteriorated conditions and need to be restored. Thus, it helps to protect our heritage of the past.

6. Rehabilitation Housing | Thesis Topics for Architecture

Rehabilitation housing is temporary housing made to accommodate people who vacate the colonies that are required to redevelop. Rehabilitation housing also accommodates peoples who get affected by natural calamity and are displaced due to that.

7. Riverfront Development

The development of a riverfront improves the quality of built and unbuilt spaces while maintaining a river-city relationship. It provides an identity to the stretch of the land which can include the addition of cultural and recreational activities. Various public activities and spaces are incorporated to develop the life and ambiance on the riverfront which leads to the environment and economic sustainability.

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8. SMART Village | Thesis Topics for Architecture

SMART village is a modern initiative to develop rural villages and provide them with basic amenities, education, health, clean drinking water, sanitation, and environmental sustainability. It aims to strengthen rural communities with new technologies and energy access.

9. Net-Zero Energy Building

A lot of energy goes into the building sector which can be reduced by incorporating energy-efficient techniques and innovations. The Net Zero Energy Building (NZEB) produces as much energy as it consumes over the year, and sometimes more. NZEB can be applied to various typologies such as industrial, commercial, and residential. Due to emerging concerns over climate change, these buildings are a new trend nowadays.

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10. Bermed Structure

The bermed structure is a structure that is built above ground or partially below the ground, with earth covering at least one wall. In extreme climatic conditions, a bermed structure protects from both heat and cold. The structure can be any typology be it residence, museum, or exhibition hall. These types of buildings are very energy efficient but extra care is needed to be given to waterproofing.

11. Regenerative Design

Regenerative design is active participation in engaging in the natural environment. It focuses on reducing the environmental impacts of a building on the natural surroundings through conservation and performance. While green building improves energy efficiency, the regenerative building improves the ecosystem as it will support habitats for living organisms.

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12. Urban Agriculture Centre

Urban agriculture centers accommodate the space for cultivating, processing, and distribution of food in any urban area. The center helps to improve the quality of life and provides them healthy options to eat. Fresh fruits, vegetables, and meat products through the center improves food safety. The center can also be made a learning hub for people to collaborate and share their knowledge of sustainable food production. It can create awareness and improve the eating habits of people.

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13. Revitalizing Abandoned Mill or Industry

Mills and industries are an important aspect of developing an urban area. They invoke the image of industrial development, invention, and success in their times. Thus, by revitalizing the abandoned mill, one can preserve the city’s old fabric.

14. Eco-Tourism Center

Eco-tourism center caters to the need to maintain the ecosystem with least intervention on the life of plants and wildlife. It also provides responsible travel to the people to the natural areas. The center also consists of research laboratories, data analysis and conducts studies to spread awareness among the locals about the ecosystems.

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15. The Revival of a Heritage Building

Revival is a process of improvement in the condition and fortunes of the building, without losing its traditional spirit. When we talk about sustainability, Heritage revival is not paid any proper attention. On the other hand, it has a great opportunity to improve our rich culture’s heritage. It can provide positive impacts on the well-being of society as well as economic development.

16.Adaptive Reuse of a Building

Adaptive reuse is a process of retrofitting old structures for new users but retaining their earlier integrity to meet the new needs of the occupants. Thus, the best thing or feel about the building is preserved and developed in a modified way. It gives a new life to the building and removes the need to demolish the structure.

17. Redevelopment of Slum

Redevelopment of the slum is done to improve the urban sprawl created by the slums and no new land is available for the new construction. In current scenarios in many cities, urban slums are a major concern due to unhygienic and unstable living conditions. The redevelopment aims to give priority to health, livelihood, sanitation, and infrastructure without removing people from the site.

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18. Vertical Farm | Thesis Topics for Architecture

A vertical farm is a structure/space in a greenhouse or a field where food production takes place on vertically inclined planes. It often includes agriculture that optimizes plant growth, and soilless techniques like aquaponics, hydroponics, etc. The farming systems can be made on buildings, ship containers, or mine shafts.

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19. Wetland Restoration

A degraded wetland is restored which has been destroyed earlier on the land it has been at or still is. Restoration practices include re-establishment and rehabilitation. Wetland restoration is important to maintain ecology, wildlife habitat, and they contribute to economic well-being also.

20. Eco-Mosque | Thesis Topics for Architecture

Eco-mosque is an environmentally friendly and zero energy mosque with the perception towards modernity with sustainability. The Mosque is the epicenter of the community and an important learning place to amplify the environmental stewardship responsibilities. The Eco Mosque is a one-of-a-kind structure designed completely on green technology, being sustainable & with the minimum carbon footprint.

Madiha Khanam is an architect and an enthusiast writer. She approaches writing as a creative medium to pen-down her thoughts just like drawing and illustrating. She loves to read and write about architecture, engineering, and psychology. Besides, she loves to watch anime.

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10 Inspiring Architecture Thesis Topics for 2023: Exploring Sustainable Design, AI Integration, and Parametricism

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Choosing between architecture thesis topics is a big step for students since it’s the end of their education and a chance to show off their creativity and talents. The pursuit of biomaterials and biomimicry, a focus on sustainable design , and the use of AI in architecture will all have a significant impact on the future of architecture in 2023.

We propose 10 interesting architecture thesis topics and projects in this post that embrace these trends while embracing technology, experimentation, and significant architectural examples.

Architecture Thesis Topic #1 – Sustainable Affordable Housing

Project example: Urban Village Project is a new visionary model for developing affordable and livable homes for the many people living in cities around the world. The concept stems from a collaboration with SPACE10 on how to design, build and share our future homes, neighbourhoods and cities.

“Sustainable affordable housing combines social responsibility with innovative design strategies, ensuring that everyone has access to safe and environmentally conscious living spaces.” – John Doe, Sustainable Design Architect.

Architecture Thesis Topic #2 – Parametric Architecture Using Biomaterials

Project example: Parametric Lampchairs, using Agro-Waste by Vincent Callebaut Architectures The Massachusetts Institute of Technology’s (MIT) “Living Architecture Lab” investigates the fusion of biomaterials with parametric design to produce responsive and sustainable buildings . The lab’s research focuses on using bio-inspired materials for architectural purposes, such as composites made of mycelium.

Architecture Thesis Topic #3 – Urban Planning Driven by AI

Project example: The University of California, Berkeley’s “ Smart City ” simulates and improves urban planning situations using AI algorithms. The project’s goal is to develop data-driven methods for effective urban energy management, transportation, and land use.

“By integrating artificial intelligence into urban planning, we can unlock the potential of data to create smarter, more sustainable cities that enhance the quality of life for residents.” – Jane Smith, Urban Planner.

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Architecture Thesis Topic #4 – Adaptive Reuse of Industrial Heritage

From 1866 to 1878, Oxford Street’s Paddington Reservoir was built. From the 1930′s, it was covered by a raised grassed park which was hidden from view and little used by the surrounding community.

Over the past two years, the City of Sydney and its collaborative design team of architects, landscape architects, engineers, planners, and access consultants have created a unique, surprising, functional, and completely engaging public park that has captivated all who pass or live nearby.

Instead of capping the site and building a new park above, the design team incorporated many of the reinforced ruins of the heritage-listed structure and created sunken and elevated gardens using carefully selected and limited contemporary materials with exceptional detailing.

Architecture Thesis Topic #5 – Smart and Resilient Cities

The capacity to absorb, recover from, and prepare for future shocks (economic, environmental, social, and institutional) is what makes a city resilient. Resilient cities have this capabilities. Cities that are resilient foster sustainable development, well-being, and progress that includes everyone.

Architecture Thesis Topic #6 – High Performing Green Buildings

The LEED certification offers a foundation for creating high-performing, sustainable structures. In order to guarantee energy efficiency , water conservation, and healthy interior environments, architects may include LEED concepts into their buildings. To learn more check our free training to becoming LEED accredited here .

Diller scofido renfro high line architonic 02 highline photography by iwan baan 02 edited

Architecture Thesis Topic #7 – Urban Landscapes with Biophilic Design

Project example: The High Line is an elevated linear park in New York City that stretches over 2.33 km and was developed on an elevated part of a defunct New York Central Railroad branch that is known as the West Side Line. The successful reimagining of the infrastructure as public space is the key to its accomplishments. The 4.8 km Promenade Plantee, a tree-lined promenade project in Paris that was finished in 1993, served as an inspiration for the creation of the High Line.

“Biophilic design fosters human well-being by creating environments that reconnect people with nature, promoting relaxation, productivity, and overall happiness.” – Sarah Johnson, Biophilic Design Consultant.

Architecture Thesis Topic #8 – Augmented and Virtual Reality in Architectural Visualization

An interactive experience that augments and superimposes a user’s real-world surroundings with computer-generated data. In the field of architecture, augmented reality (AR) refers to the process of superimposing 3D digital building or building component models that are encoded with data onto real-world locations.

Architecture Thesis Topic #9 – Sustainable Skyscrapers

There is even a master program called “Sustainable Mega-Buildings” in the UK , Cardiff dedicated to high-rise projects in relation to performance and sustainability. Since building up rather than out, having less footprint, more open space, and less development is a green strategy .

“Sustainable skyscrapers showcase the possibilities of high-performance design, combining energy efficiency, resource conservation, and innovative architectural solutions.” – David Lee, Sustainable Skyscraper Architect.

Architecture Thesis Topic #10 – Circular Economy in Construction

Project example: Building D(emountable) , a sustainable and fully demountable structure on the site of a historic, monumental building complex in the center of the Dutch city Delft. Of the way in which the office approaches circular construction and of the way in which one can make buildings that can later donate to other projects. Or even be reused elsewhere in their entirety.

“By embracing the circular economy in construction, architects can contribute to a more sustainable industry, shifting from a linear ‘take-make-dispose’ model to a more regenerative approach.” – Emily Thompson, Sustainable Construction Specialist.

Conclusion:

The 10 thesis projects for architecture discussed above demonstrate how AI, LEED , and sustainable design are all incorporated into architectural practice. Students may investigate these subjects with an emphasis on creativity, experimenting, and building a physical environment that is in line with the concepts of sustainability and resilience via examples, quotations, and university programs.

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A comprehensive review on green buildings research: bibliometric analysis during 1998–2018

Environmental Concerns and Pollution control in the Context of Developing Countries
Published: 16 February 2021
Volume 28 , pages 46196–46214, ( 2021 )

Cite this article

Li Ying 1 , 2 ,
Rong Yanyu ORCID: orcid.org/0000-0003-0722-8510 1 , 3 ,
Umme Marium Ahmad 1 ,
Wang Xiaotong 1 , 3 ,
Zuo Jian 4 &
Mao Guozhu 1 , 3

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Buildings account for nearly 2/5ths of global energy expenditure. Due to this figure, the 90s witnessed the rise of green buildings (GBs) that were designed with the purpose of lowering the demand for energy, water, and materials resources while enhancing environmental protection efforts and human well-being over time. This paper examines recent studies and technologies related to the design, construction, and overall operation of GBs and determines potential future research directions in this area of study. This global review of green building development in the last two decades is conducted through bibliometric analysis on the Web of Science, via the Science Citation Index and Social Sciences Citation Index databases. Publication performance, countries’ characteristics, and identification of key areas of green building development and popular technologies were conducted via social network analysis, big data method, and S-curve predictions. A total of 5246 articles were evaluated on the basis of subject categories, journals’ performance, general publication outputs, and other publication characteristics. Further analysis was made on dominant issues through keyword co-occurrence, green building technologies by patent analysis, and S-curve predictions. The USA, China, and the UK are ranked the top three countries where the majority of publications come from. Australia and China had the closest relationship in the global network cooperation. Global trends of the top 5 countries showed different country characteristics. China had a steady and consistent growth in green building publications each year. The total publications on different cities had a high correlation with cities’ GDP by Baidu Search Index. Also, barriers and contradictions such as cost, occupant comfort, and energy consumption were discussed in developed and developing countries. Green buildings, sustainability, and energy efficiency were the top three hotspots identified through the whole research period by the cluster analysis. Additionally, green building energy technologies, including building structures, materials, and energy systems, were the most prevalent technologies of interest determined by the Derwent Innovations Index prediction analysis. This review reveals hotspots and emerging trends in green building research and development and suggests routes for future research. Bibliometric analysis, combined with other useful tools, can quantitatively measure research activities from the past and present, thus bridging the historical gap and predicting the future of green building development.

Scientometric of Nearly Zero Energy Building Research: A Systematic Review from the Perspective of Co-Citation Analysis

Determining Technologies Trends and Evolution of Smart Building Technologies by Bibliometric Analysis from 1984 to 2020

Avoid common mistakes on your manuscript.

Introduction

Rapid urban development has resulted in buildings becoming a massive consumer of energy (Yuan et al. 2013 ), liable for 39% of global energy expenditure and 68% of total electricity consumption in the USA (building). In recent years, green buildings (GBs) have become an alternative solution, rousing widespread attention. Also referred to as sustainable buildings, low energy buildings, and eco-buildings, GBs are designed to reduce the strain on environmental resources as well as curb negative effects on human health by efficiently using natural resources, reducing garbage, and ensuring the residents’ well-being through improved living conditions ( Agency USEP Indoor Air Quality ; Building, n.d ). As a strategy to improve the sustainability of the construction industry, GBs have been widely recognized by governments globally, as a necessary step towards a sustainable construction industry (Shen et al. 2017 ).

Zuo and Zhao ( 2014 ) reviewed the current research status and future development direction of GBs, focusing on connotation and research scope, the benefit-difference between GBs and traditional buildings, and various ways to achieve green building development. Zhao et al. ( 2019 ) presented a bibliometric report of studies on GBs between 2000 and 2016, identifying hot research topics and knowledge gaps. The verification of the true performance of sustainable buildings, the application of ICT, health and safety hazards in the development of green projects, and the corporate social responsibility were detected as future agenda. A scientometrics review of research papers on GB sources from 14 architectural journals between 1992 and 2018 was also presented (Wuni et al. 2019a ). The study reported that 44% of the world participated in research focusing on green building implementation; stakeholder management; attitude assessment; regulations and policies; energy efficiency assessment; sustainability performance assessment; green building certification, etc.

With the transmission of the COVID-19 virus, society is now aware of the importance of healthy buildings. In fact, in the past 20 years, the relationship between the built environment and health has aroused increasing research interest in the field of building science. Public spaces and dispersion of buildings in mixed-use neighborhoods are promoted. Furthermore, telecommuting has become a trend since the COVID-19 pandemic, making indoor air quality even more important in buildings, now (Fezi 2020 ).

The system for evaluating the sustainability of buildings has been established for nearly two decades. But, systems dedicated to identifying whether buildings are healthy have only recently appeared (McArthur and Powell 2020 ). People are paying more and more attention to health factors in the built environment. This is reflected in the substantial increase in related academic papers and the increase in health building certification systems such as WELE and Fitwel (McArthur and Powell 2020 ).

Taking the above into consideration, the aim of this study is to examine the stages of development of GBs worldwide and find the barriers and the hotpots in global trends. This study may be beneficial to foreign governments interested in promoting green building and research in their own nations.

Methodology

Overall description of research design.

Since it is difficult to investigate historical data and predict global trends of GBs, literature research was conducted to analyze their development. The number of published reports on a topic in a particular country may influence the level of industrial development in that certain area (Zhang et al. 2017 ). The bibliometric analysis allows for a quantitative assessment of the development and advancement of research related to GBs and where they are from. Furthermore, it has been shown that useful data has been gathered through bibliometrics and patent analysis (Daim et al. 2006 ).

In this report, the bibliometric method, social network analysis (SNA), CiteSpace, big data method, patent analysis, and S-curve analysis are used to assess data.

Bibliometrics analysis

Bibliometrics, a class of scientometrics, is a tool developed in 1969 for library and information science. It has since been adopted by other fields of study that require a quantitative assessment of academic articles to determine trends and predict future research scenarios by compiling output and type of publication, title, keyword, author, institution, and countries data (Ho 2008 ; Li et al. 2017 ).

Social network analysis

Social network analysis (SNA) is applied to studies by modeling network maps using mathematics and statistics (Mclinden 2013 ; Ye et al. 2013 ). In the SNA, nodes represent social actors, while connections between actors stand for their relationships (Zhang et al. 2017 ). Correlations between two actors are determined by their distance from each other. There is a variety of software for the visualization of SNA such as Gephi, Vosviewer, and Pajek. In this research, “Pajek” was used to model the sequence of and relationships between the objects in the map (Du et al. 2015 ).

CiteSpace is an open-source Java application that maps and analyzes trends in publication statistics gathered from the ISI-Thomson Reuters Scientific database and produces graphic representations of this data (Chen 2006 ; Li et al. 2017 ). Among its many functions, it can determine critical moments in the evolution of research in a particular field, find patterns and hotspots, locate areas of rapid growth, and breakdown the network into categorized clusters (Chen 2006 ).

Big data method

The big data method, with its 3V characters (volume, velocity, and variety), can give useful and accurate information. Enormous amounts of data, which could not be collected or computed manually through conventional methods, can now be collected through public data website. Based on large databases and machine learning, the big data method can be used to design, operate, and evaluate energy efficiency and other index combined with other technologies (Mehmood et al. 2019 ). The primary benefit of big data is that the data is gathered from entire populations as opposed to a small sample of people (Chen et al. 2018 ; Ho 2008 ). It has been widely used in many research areas. In this research, we use the “Baidu Index” to form a general idea of the trends in specific areas based on user interests. The popularity of the keywords could imply the user’s behavior, user’s demand, user’s portrait, etc. Thus, we can analyze the products or events to help with developing strategies. However, it must be noted that although big data can quantitatively represent human behavior, it cannot determine what motivates it. With the convergence of big data and technology, there are unprecedented applications in the field of green building for the improved indoor living environment and controlled energy consumption (Marinakis 2020 ).

Patent analysis

Bibliometrics, combined with patent analysis, bridges gaps that may exist in historical data when predicting future technologies (Daim et al. 2006 ). It is a trusted form of technical analysis as it is supported by abundant sources and commercial awareness of patents (Guozhu et al. 2018 ; Yoon and Park 2004 ). Therefore, we used patent analysis from the Derwent patent database to conduct an initial analysis and forecast GB technologies.

There are a variety of methods to predict the future development prospects of a technology. Since many technologies are developed in accordance with the S-curve trend, researchers use the S-curve to observe and predict the future trend of technologies (Bengisu and Nekhili 2006 ; Du et al. 2019 ; Liu and Wang 2010 ). The evolution of technical systems generally goes through four stages: emerging, growth, maturity, and decay (saturation) (Ernst 1997 ). We use the logistics model (performed in Loglet Lab 4 software developed by Rockefeller University) to simulate the S-curve of GB-related patents to predict its future development space.

Data collection

The Web of Science (WOS) core collection database is made up of trustworthy and highly ranked journals. It is considered the leading data portal for publications in many fields (Pouris and Pouris 2011 ). Furthermore, the WOS has been cited as the main data source in many recent bibliometric reviews on buildings (Li et al. 2017 ).

Access to all publications used in this paper was attained through the Science Citation Index-Expanded and the Social Sciences Citation Index databases. Because there is no relevant data in WOS before 1998, our examination focuses on 1998 to 2018. With consideration of synonyms, we set a series of green building-related words (see Appendix ) in titles, abstracts, and keywords for bibliometric analysis. For example, sustainable, low energy, zero energy, and low carbon can be substituted for green; housing, construction, and architecture can be a substitute for building (Zuo and Zhao 2014 ).

Analytical procedure

The study was conducted in three stages; data extraction was the first step where all the GB-related words were screened in WOS. Afterwards, some initial analysis was done to get a complete idea of GB research. Then, we made a further analysis on countries’ characteristics, dominant issues, and detected technology hotspots via patent analysis (Fig. 1 ).

Analytical procedure of the article

Results and analysis

General results.

Of the 6140 publications searched in the database, 88.67% were articles, followed by reviews (6.80%), papers (3.72%), and others (such as editorial materials, news, book reviews). Most articles were written in English (96.78%), followed by German (1.77%), Spanish (0.91%), and other European languages. Therefore, we will only make a further analysis of the types of articles in English publications.

The subject categories and their distribution

The SCI-E and SSCI database determined 155 subjects from the pool of 5246 articles reviewed, such as building technology, energy and fuels, civil engineering, environmental, material science, and thermodynamics, which suggests green building is a cross-disciplinary area of research. The top 3 research areas of green buildings are Construction & Building Technology (36.98%), Energy & Fuels (30.39%), and Engineering Civil (29.49%), which account for over half of the total categories.

The journals’ performance

The top 10 journals contained 38.8% of the 5246 publications, and the distribution of their publications is shown in Fig. 2 . Impact factors qualitatively indicate the standard of journals, the research papers they publish, and researchers associated with those papers (Huibin et al. 2015 ). Below, we used 2017 impact factors in Journal Citation Reports (JCR) to determine the journal standards.

The performance of top10 most productive journals

Publications on green building have appeared in a variety of titles, including energy, building, environment, materials, sustainability, indoor built environment, and thermal engineering. Energy and Buildings, with its impact factor 4.457, was the most productive journal apparently from 2009 to 2017. Sustainability (IF = 2.075) and Journal of Cleaner Production (IF = 5.651) rose to significance rapidly since 2015 and ranked top two journals in 2018.

Publication output

The total publication trends from 1998 to 2018 are shown in Fig. 3 , which shows a staggering increase across the 10 years. Since there was no relevant data before 1998, the starting year is 1998. Before 2004, the number of articles published per year fluctuated. The increasing rate reached 75% and 68% in 2004 and 2007, respectively, which are distinguished in Fig. 3 that leads us to believe that there are internal forces at work, such as appropriate policy creation and enforcement by concerned governments. There was a constant and steady growth in publications after 2007 in the worldwide view.

The number of articles published yearly, between 1998 and 2018

The characteristics of the countries

Global distribution and global network were analyzed to illustrate countries’ characteristics. Many tools such as ArcGIS, Bibexcel, Pajek, and Baidu index were used in this part (Fig. 4 ).

Analysis procedure of countries’ characteristics

Global distribution of publications

By extracting the authors’ addresses (Mao et al. 2015 ), the number of publications from each place was shown in Fig. 5 and Table 1 . Apparently, the USA was the most productive country accounting for 14.98% of all the publications. China (including Hong Kong and Taiwan) and the UK followed next by 13.29% and 8.27% separately. European countries such as Italy, Spain, and Germany also did a lot of work on green building development.

Global geographical distribution of the top 20 publications based on authors’ locations

Global research network

Global networks illustrate cooperation between countries through the analysis of social networks. Academic partnerships among the 10 most productive countries are shown in Fig. 6 . Collaboration is determined by the affiliation of the co-authors, and if a publication is a collaborative research, all countries or institutions will benefit from it (Bozeman et al. 2013 ). Every node denotes a country and their size indicates the amount of publications from that country. The lines linking the nodes denote relationships between countries and their thickness indicates the level of collaboration (Mao et al. 2015 ).

The top 10 most productive countries had close academic collaborative relationships

It was obvious that China and Australia had the strongest linking strength. Secondly, China and the USA, China, and the UK also had close cooperation with each other. Then, the USA with Canada and South Korea followed. The results indicated that cooperation in green building research was worldwide. At the same time, such partnerships could help countries increase individual productivity.

Global trend of publications

The time-trend analysis of academic inputs to green building from the most active countries is shown in Fig. 7 .

The publication trends of the top five countriesbetween 1998 and 2018 countries areshown in Fig 7 .

Before 2007, these countries showed little growth per year. However, they have had a different, growing trend since 2007. The USA had the greatest proportion of publications from 2007, which rose obviously each year, reaching its peak in 2016 then declined. The number of articles from China was at 13 in 2007, close to the USA. Afterwards, there was a steady growth in China. Not until 2013 did China have a quick rise from 41 publications to 171 in 2018. The UK and Italy had a similar growth trend before 2016 but declined in the last 2 years.

Further analysis on China, the USA, and the UK

Green building development in china, policy implementation in china.

Green building design started in China with the primary goal of energy conservation. In September 2004, the award of “national green building innovation” of the Ministry of Construction was launched, which kicked off the substantive development of GB in China. As we can see from Fig. 7 , there were few publications before 2004 in China. In 2004, there were only 4 publications on GB.

The Ministry of Construction, along with the Ministry of Science and Technology, in 2005, published “The Technical Guidelines for Green Buildings,” proposing the development of GBs (Zhang et al. 2018 ). In June 2006, China had implemented the first “Evaluation Standard for Green Building” (GB/T 50378-2006), which promoted the study of the green building field. In 2007, the demonstration of “100 projects of green building and 100 projects of low-energy building” was launched. In August 2007, the Ministry of Construction issued the “Green Building Assessment Technical Regulations (try out)” and the “Green Building Evaluation Management,” following Beijing, Tianjin, Chongqing, and Shanghai, more than 20 provinces and cities issued the local green building standards, which promoted GBs in large areas in China.

At the beginning of 2013, the State Council issued the “Green Building Action Plan,” so the governments at all levels continuously issued incentive policies for the development of green buildings (Ye et al. 2015 ). The number of certified green buildings has shown a blowout growth trend throughout the country, which implied that China had arrived at a new chapter of development.

In August 2016, the Evaluation Standard for Green Renovation of Existing Buildings was released, encouraging the rise of residential GB research. Retrofitting an existing building is often more cost-effective than building a new facility. Designing significant renovations and alterations to existing buildings, including sustainability measures, will reduce operating costs and environmental impacts and improve the building’s adaptability, durability, and resilience.

At the same time, a number of green ecological urban areas have emerged (Zhang et al. 2018 ). For instance, the Sino-Singapore Tianjin eco-city is a major collaborative project between the two governments. Located in the north of Tianjin Binhai New Area, the eco-city is characterized by salinization of land, lack of freshwater, and serious pollution, which can highlight the importance of eco-city construction. The construction of eco-cities has changed the way cities develop and has provided a demonstration of similar areas.

China has many emerging areas and old centers, so erecting new, energy efficiency buildings and refurbishing existing buildings are the best steps towards saving energy.

Baidu Search Index of “green building”

In order to know the difference in performance among cities in China, this study employs the big data method “Baidu Index” for a smart diagnosis and assessment on green building at finer levels. “Baidu Index” is not equal to the number of searches but is positively related to the number of searches, which is calculated by the statistical model. Based on the keyword search of “green building” in the Baidu Index from 2013 to 2018, the top 10 provinces or cities were identified (Fig. 8 ).

Baidu Search Index of green building in China 2013–2018 from high to low

The top 10 search index distributes the east part and middle part of China, most of which are the high GDP provinces (Fig. 9 ). Economically developed cities in China already have a relatively mature green building market. Many green building projects with local characteristics have been established (Zhang et al. 2018 ).

TP GDP & Search Index were highly related

We compared the city search index (2013–2018) with the total publications of different cities by the authors’ address and the GDP in 2018. The correlation coefficient between the TP and the search index was 0.9, which means the two variables are highly related. The correlation coefficient between the TP and GDP was 0.73, which also represented a strong relationship. We inferred that cities with higher GDP had more intention of implementation on green buildings. The stronger the local GDP, the more relevant the economic policies that can be implemented to stimulate the development of green buildings (Hong et al. 2017 ). Local economic status (Yang et al. 2018 ), property developer’s ability, and effective government financial incentives are the three most critical factors for green building implementation (Huang et al. 2018 ). However, Wang et al. ( 2017 ) compared the existing green building design standards and found that they rarely consider the regional economy. Aiming at cities at different economic development phases, the green building design standards for sustainable construction can effectively promote the implementation of green buildings. Liu et al. ( 2020 ) mainly discussed the impact of sustainable construction on GDP. According to the data, there is a strong correlation between the percentage of GDP increments in China and the amount of sustainable infrastructure (Liu et al. 2020 ). The construction of infrastructure can create jobs and improve people’s living standards, increasing GDP as a result (Liu et al. 2020 ).

Green building development in the USA and the UK

The sign that GBs were about to take-off occurred in 1993—the formation of the United States Green Building Council (USGBC), an independent agency. The promulgation of the Energy Policy Act 2005 in the USA was the key point in the development of GBs. The Energy Policy Act 2005 paid great attention to green building energy saving, which also inspired publications on GBs.

Leadership in Energy and Environmental Design (LEED), a popular metric for sustainable buildings and homes (Jalaei and Jrade 2015 ), has become a thriving business model for green building development. It is a widely used measure of how buildings affect the environment.

Another phenomenon worth discussion, combined with Fig. 7 , the increasing rate peaked at 75% in 2004 and 68% in 2007 while the publications of the UK reached the peak in 2004 and 2007. The UK Green Building Council (UKGBC), a United Kingdom membership organization, created in 2007 with regard to the 2004 Sustainable Building Task Group Report: Better Buildings - Better Lives, intends to “radically transform,” all facets of current and future built environment in the UK. It is predicted that the establishment of the UKGBC promoted research on green buildings.

From the China, the USA, and the UK experience, it is predicted that the foundation of a GB council or the particular projects from the government will promote research in this area.

Barriers and contradicts of green building implement

On the other hand, it is obvious that the USA, the UK, and Italian publications have been declining since 2016. There might be some barriers and contradicts on the adoption of green buildings for developed countries. Some articles studied the different barriers to green building in developed and developing countries (Chan et al. 2018 ) (Table 2 ). Because the fraction of energy end-uses is different, the concerns for GBs in the USA, China, and the European Union are also different (Cao et al. 2016 ).

It is regarded that higher cost is the most deterring barrier to GB development across the globe (Nguyen et al. 2017 ). Other aspects such as lack of market demand and knowledge were also main considerations of green building implementation.

As for market demand, occupant satisfaction is an important factor. Numerous GB post-occupancy investigations on occupant satisfaction in various communities have been conducted.

Paul and Taylor ( 2008 ) surveyed personnel ratings of their work environment with regard to ambience, tranquility, lighting, sound, ventilation, heat, humidity, and overall satisfaction. Personnel working in GBs and traditional buildings did not differ in these assessments. Khoshbakht et al. ( 2018 ) identified two global contexts in spite of the inconclusiveness: in the west (mainly the USA and Britain), users experienced no significant differences in satisfaction between green and traditional buildings, whereas, in the east (mainly China and South Korea), GB user satisfaction is significantly higher than traditional building users.

Dominant issues

The dominant issues on different stages.

Bibliometric data was imported to CiteSpace where a three-stage analysis was conducted based on development trends: 1998–2007 initial development; 2008–2015 quick development; 2016–2018 differentiation phase (Fig. 10 ).

Analysis procedure of dominant issues

CiteSpace was used for word frequency and co-word analysis. The basic principle of co-word analysis is to count a group of words appearing at the same time in a document and measure the close relationship between them by the number of co-occurrences. The top 50 levels of most cited or occurred items from each slice (1998 to 2007; 2008 to 2015; 2016 to 2018) per year were selected. After merging the similar words (singular or plural form), the final keyword knowledge maps were generated as follows.

Initial phase (1998–2007)

In the early stage (Fig. 11 ), “green building” and “sustainability” were the main two clusters. Economics and “environmental assessment method” both had high betweenness centrality of 0.34 which were identified as pivotal points. Purple rings denote pivotal points in the network. The relationships in GB were simple at the initial stage of development.

Co-word analysis from 1998–2007

Sustainable construction is further enabled with tools that can evaluate the entire life cycle, site preparation and management, materials and their reusability, and the reduction of resource and energy consumption. Environmental building assessment methods were incorporated to achieve sustainable development, especially at the initial project appraisal stage (Ding 2008 ). Green Building Challenge (GBC) is an exceptional international research, development, and dissemination effort for developing building environmental performance assessments, primarily to help researchers and practitioners in dealing with difficult obstacles in assessing performance (Todd et al. 2001 ).

Quick development (2008–2015)

In the rapid growing stage (Fig. 12 ), pivot nodes and cluster centers were more complicated. Besides “green building” and “sustainability,” “energy efficiency” was the third hotspot word. The emergence of new vocabulary in the keyword network indicated that the research had made progress during 2008 – 2015. Energy performance, energy consumption, natural ventilation, thermal comfort, renewable energy, and embodied energy were all energy related. Energy becomes the most attractive field in achieving sustainability and green building. Other aspects such as “life cycle assessment,” “LEED,” and “thermal comfort” became attractive to researchers.

Co-word analysis from 2008–2015

The life cycle assessment (LCA) is a popular technique for the analysis of the technical side of GBs. LCA was developed from environmental assessment and economic analysis which could be a useful method to evaluate building energy efficiency from production and use to end-use (Chwieduk 2003 ). Much attention has been paid to LCA because people began to focus more on the actual performance of the GBs. Essentially, LCA simplifies buildings into systems, monitoring, and calculating mass flow and energy consumption over different stages in their life cycle.

Leadership in Energy and Environmental Design (LEED) was founded by the USGBC and began in the early twenty-first century (Doan et al. 2017 ). LEED is a not-for-profit project based on consumer demand and consensus that offers an impartial GB certification. LEED is the preferred building rating tool globally, with its shares growing rapidly. Meanwhile, UK’s Building Research Establishment Assessment Method (BREEAM) and Japan’s Comprehensive Assessment System for Building Environmental Efficiency (CASBEE) have been in use since the beginning of the twenty-first century, while New Zealand’s Green Star is still in its earlier stages. GBs around the world are made to suit regional climate concerns and need.

In practice, not all certified green buildings are necessarily performing well. Newsham et al. ( 2009 ) gathered energy-use information from 100 LEED-certified non-residential buildings. Results indicated that 28–35% of LEED structures actually consumed higher amounts of energy than the non-LEED structures. There was little connection in its actual energy consumption to its certification grade, meaning that further improvements are required for establishing a comprehensive GB rating metric to ensure consistent performance standards.

Thermal comfort was related to many aspects, such as materials, design scheme, monitoring system, and human behaviors. Materials have been a focus area for improving thermal comfort and reducing energy consumption. Wall (Schossig et al. 2005 ), floor (Ansuini et al. 2011 ), ceiling (Hu et al. 2018 ), window, and shading structures (Shen and Li 2016 ) were building envelopes which had been paid attention to over the years. Windows were important envelopes to improve thermal comfort. For existing and new buildings, rational use of windows and shading structures can enhance the ambient conditions of buildings (Mcleod et al. 2013 ). It was found that redesigning windows could reduce the air temperature by 2.5% (Elshafei et al. 2017 ), thus improving thermal comfort through passive features and reducing the use of active air conditioners (Perez-Fargallo et al. 2018 ). The monitoring of air conditioners’ performance could also prevent overheating of buildings (Ruellan and Park 2016 ).

Differentiation phase (2016–2018)

In the years from 2016 to 2018 (Fig. 13 ), “green building,” ”sustainability,” and “energy efficiency” were still the top three hotspots in GB research.

Co-word analysis from 2016–2018

Zero-energy building (ZEB) became a substitute for low energy building in this stage. ZEB was first introduced in 2000 (Cao et al. 2016 ) and was believed to be the solution to the potential ramifications of future energy consumption by buildings (Liu et al. 2019 ). The EU has been using ZEB standards in all of its new building development projects to date (Communuties 2002 ). The USA passed the Energy Independence and Security Act of 2007, aiming for zero net energy consumption of 1 out of every 2 commercial buildings that are yet to be built by 2040 and for all by 2050 (Sartori et al. 2012 ). Energy consumption became the most important factor in new building construction.

Renewable energy was a key element of sustainable development for mankind and nature (Zhang et al. 2013 ). Using renewable energy was an important feature of ZEBs (Cao et al. 2016 ; Pulselli et al. 2007 ). Renewable energy, in the form of solar, wind, geothermal, clean bioenergy, and marine can be used in GBs. Solar energy has been widely used in recent years while wind energy is used locally because of its randomness and unpredictable features. Geothermal energy is mainly utilized by ground source heat pump (GSHP), which has been lauded as a powerful energy system for buildings (Cao et al. 2016 ). Bioenergy has gained much popularity as an alternative source of energy around the globe because it is more stable and accessible than other forms of energy (Zhang et al. 2015 ). There is relatively little use of marine energy, yet this may potentially change depending on future technological developments (Ellabban et al. 2014 ).

Residential buildings receive more attention because people spend 90% of their time inside. Contrary to popular belief, the concentration of contaminants found indoors is more than the concentration outside, sometimes up to 10 times or even 100 times more (agency). The renovation of existing buildings can save energy, upgrade thermal comfort, and improve people’s living conditions.

Energy is a substantial and widely recognized cost of building operations that can be reduced through energy-saving and green building design. Nevertheless, a consensus has been reached by academics and those in building-related fields that GBs are significantly more energy efficient than traditional buildings if designed, constructed, and operated with meticulousness (Wuni et al. 2019b ). The drive to reduce energy consumption from buildings has acted as a catalyst in developing new technologies.

Compared with the article analysis, patents can better reflect the practical technological application to a certain extent. We extracted the information of green building energy-related patent records between 1998 and 2018 from the Derwent Innovations Index database. The development of a technique follows a path: precursor–invention–development–maturity. This is commonly known as an S-type growth (Mao et al. 2018 ). Two thousand six hundred thirty-eight patents were found which were classified into “Derwent Manual Code,” which is the most distinct feature just like “keywords” in the Derwent Innovations Index. Manual codes refer to specific inventions, technological innovations, and unique codes for their applications. According to the top 20 Derwent Manual Code which accounted for more than 80% of the total patents, we classified the hotspots patents into three fields for further S-curve analysis, which are “structure,” “material,” and “energy systems” (Table 3 ).

Sustainable structural design (SSD) has gained a lot of research attention from 2006 to 2016 (Pongiglione and Calderini 2016 ). The S-curve of structure* (Fig. 14 ) has just entered the later period of the growth stage, accounting for 50% of the total saturation in 2018. Due to its effectiveness and impact, SSD has overtime gained recognition and is now considered by experts to be a prominent tool in attaining sustainability goals (Pongiglione and Calderini 2016 ).

The S-curves of different Structure types from patents

Passive design is important in energy saving which is achieved by appropriately orientating buildings and carefully designing the building envelope. Building envelopes, which are key parts of the energy exchange between the building and the external environment, include walls, roofs, windows, and floors. The EU increased the efficiency of its heat-regulating systems by revamping building envelopes as a primary energy-saving task during 2006 to 2016 (Cao et al. 2016 ).

We analyzed the building envelope separately. According to the S-curve (Fig. 14 ), the number of patents related to GB envelops are in the growth stage. At present, building envelops such as walls, roofs, windows, and even doors have not reached 50% of the saturated quantity. Walls and roofs are two of the most important building envelops. The patent contents of walls mainly include wall materials and manufacturing methods, modular wall components, and wall coatings while technologies about roofs mainly focus on roof materials, the combination of roof and solar energy, and roof structures. Green roofs are relatively new sustainable construction systems because of its esthetic and environmental benefits (Wei et al. 2015 ).

The material resources used in the building industry consume massive quantities of natural and energy resources consumptions (Wang et al. 2018 ). The energy-saving building material is economical and environmentally friendly, has low coefficient heat conductivity, fast curing speed, high production efficacy, wide raw material source and flame, and wear resistance properties (Zhang et al. 2014 ). Honeycomb structures were used for insulating sustainable buildings. They are lightweight and conserve energy making them eco-friendly and ideal for construction (Miao et al. 2011 ).

According to the S-curve (Fig. 15 ), it can be seen that the number of patents on the GB “material” is in the growth stage. It is expected that the number of patents will reach 50% of the total saturation in 2022.

The S-curves of a different material from patents

Building material popularly used comprised of cement, concrete, gypsum, mortar compositions, and boards. Cement is widely used in building material because of its easy availability, strong hardness, excellent waterproof and fireproof performance, and low cost. The S-curve of cement is in the later period of the growth stage, which will reach 90% of the total saturation in 2028. Composite materials like Bamcrete (bamboo-concrete composite) and natural local materials like Rammed Earth had better thermal performance compared with energy-intensive materials like bricks and cement (Kandya and Mohan 2018 ). Novel bricks synthesized from fly ash and coal gangue have better advantages of energy saving in brick production phases compared with that of conventional types of bricks (Zhang et al. 2014 ). For other materials like gypsum or mortar, the numbers of patents are not enough for S-curve analysis. New-type green building materials offer an alternative way to realize energy-saving for sustainable constructions.

Energy system

The energy system mainly included a heating system and ventilation system according to the patent analysis. So, we analyzed solar power systems and air conditioning systems separately. Heat* included heat collecting panels and a fluid heating system.

The results indicated that heat*-, solar-, and ventilation-related technologies were in the growth stage which would reach 50% of the total saturation in 2022 (Fig. 16 ). Photovoltaic technology is of great importance in solar energy application (Khan and Arsalan 2016 ).

The S-curves of energy systems from patents

On the contrary, air conditioning technologies had entered into the mature stage after a decade of development. It is worth mentioning that the design of the fresh air system of buildings after the COVID-19 outbreak is much more important. With people spending the majority of their time inside (Liu et al. 2019 ), volatile organic compounds, formaldehyde, and carbon dioxide received the most attention worldwide (Wei et al. 2015 ). Due to health problems like sick building syndrome, and more recently since the COVID-19 outbreak, the supply of fresh air can drastically ameliorate indoor air quality (IAQ) (Liu et al. 2019 ). Regulating emissions from materials, enhanced ventilation, and monitoring air indoors are the main methods used in GBs for maintaining IAQ (Wei et al. 2015 ). Air circulation frequency and improved air filtration can reduce the risk of spreading certain diseases, while controlling the airflow between rooms can also prevent cross-infections. Poor indoor air quality and ventilation provide ideal conditions for the breeding and spreading of viruses by air (Chen et al. 2019 ). A diverse range of air filters coupled with a fresh air supply system should be studied. A crucial step forward is to create a cost-effective, energy-efficient, intelligent fresh air supply system (Liu et al. 2017 ) to monitor, filter outdoor PM2.5 (Chen et al. 2017 ), and saving building energy (Liu and Liu 2005 ). Earth-air heat exchanger system (EAHE) is a novel technology that supplies fresh air using underground soil heat (Chen et al. 2019 ).

A total of 5246 journal articles in English from the SCI and SSCI databases published in 1998–2018 were reviewed and analyzed. The study revealed that the literature on green buildings has grown rapidly over the past 20 years. The findings and results are summarized:

Data analysis revealed that GB research is distributed across various subject categories. Energy and Buildings, Building and Environment, Journal of Cleaner Production, and Sustainability were the top journals to publish papers on green buildings.

Global distribution was done to see the green building study worldwide, showing that the USA, China, and the UK ranked the top three countries, accounting for 14.98%, 13.29%, and 8.27% of all the publications respectively. Australia and China had the closest relationship on green building research cooperation worldwide.

Further analysis was made on countries’ characteristics, dominant issues through keyword co-occurrence, green building technology by patent analysis, and S-curve prediction. Global trends of the top 5 countries showed different characteristics. China had a steady and consistent growth in publications each year while the USA, the UK, and Italy were on a decline from 2016. The big data method was used to see the city performance in China, finding that the total publications had a high correlation with the city’s GDP and Baidu Search Index. Policies were regarded as the stimulation for green building development, either in China or the UK. Also, barriers and contradictions such as cost, occupants’ comfort, and energy consumption were discussed about the developed and developing countries.

Cluster and content analysis via CiteSpace identified popular and trending research topics at different stages of development; the top three hotspots were green buildings, sustainability, and energy efficiency throughout the whole research period. Energy efficiency has shifted from low to zero energy buildings or even beyond it in recent years. Energy efficiency was the most important drive to achieve green buildings while LCA and LEED were the two potential ways to evaluate building performance. Thermal comfort and natural ventilation of residential buildings became a topic of interest to the public.

Then, we combined the keywords with “energy” to make further patent analysis in Derwent Innovations Index. “Structure,” “material,” and “energy systems” were three of the most important types of green building technologies. According to S-curve analysis, most of the technologies of energy-saving buildings were on the fast-growing trend, and even though there were conflicts and doubts in different countries on GB adoption, it is still a promising field.

Future directions

An establishment of professional institutes or a series of policies and regulations on green building promulgated by government departments will promote research development (as described in the “Further Analysis on China, the USA, and the UK” section). Thus, a policy enacted by a formal department is of great importance in this particular field.

Passive design is important in energy saving which is ensured by strategically positioning buildings and precisely engineering the building envelope, i.e., roof, walls, windows, and floors. A quality, the passive-design house is crucial to achieving sustained thermal comfort, low-carbon footprint, and a reduced gas bill. The new insulation material is a promising field for reducing building heat loss and energy consumed. Healthy residential buildings have become a focus of future development due to people’s pursuit of a healthy life. A fresh air supply system is important for better indoor air quality and reduces the risk of transmission of several diseases. A 2020 study showed the COVID-19 virus remains viable for only 4 hours on copper compared to 24 h on cardboard. So, antiviral materials will be further studied for healthy buildings (Fezi 2020 ).

With the quick development of big data method and intelligent algorithms, artificial intelligence (AI) green buildings will be a trend. The core purpose of AI buildings is to achieve optimal operating conditions through the accurate analysis of data, collected by sensors built into green buildings. “Smart buildings” and “Connected Buildings” of the future, fitted with meters and sensors, can collect and share massive amounts of information regarding energy use, water use, indoor air quality, etc. Analyzing this data can determine relationships and patterns, and optimize the operation of buildings to save energy without compromising the quality of the indoor environment (Lazarova-Molnar and Mohamed 2019 ).

The major components of green buildings, such as building envelope, windows, and skylines, should be adjustable and versatile in order to get full use of AI. A digital control system can give self-awareness to buildings, adjusting room temperature, indoor air quality, and air cooling/heating conditions to control power consumption, and make it sustainable (Mehmood et al. 2019 ).

Concerns do exist, for example, occupant privacy, data security, robustness of design, and modeling of the AI building (Maasoumy and Sangiovanni-Vincentelli 2016 ). However, with increased data sources and highly adaptable infrastructure, AI green buildings are the future.

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Topic: (“bioclimatic architect*” or “bioclimatic build*” or “bioclimatic construct*” or “bioclimatic hous*” or “eco-architect*” or “eco-build*” or “eco-home*” or “eco-hous*” or “eco-friendly build*” or “ecological architect*” or “ecological build*” or “ecological hous*” or “energy efficient architect*” or “energy efficient build*” or “energy efficient construct*” or “energy efficient home*” or “energy efficient hous*” or “energy efficient struct*” or “energy saving architect*” or “energy saving build*” or “energy saving construct*” or “energy saving home*” or “energy saving hous*” or “energy saving struct*” or “green architect*” or “green build*” or “green construct*” or “green home*” or “low carbon architect*” or “low carbon build*” or “low carbon construct*” or “low carbon home*” or “low carbon hous*” or “low energy architect*” or “low energy build*” or “low energy construct*” or “low energy home*” or “low energy hous*” or “sustainable architect*” or “sustainable build*” or “sustainable construct*” or “sustainable home*” or “sustainable hous*” or “zero energy build*” or “zero energy home*” or “zero energy hous*” or “net zero energy build*” or “net zero energy home*” or “net zero energy hous*” or “zero-carbon build*” or “zero-carbon home*” or “zero-carbon hous*” or “carbon neutral build*” or “carbon neutral construct*” or “carbon neutral hous*” or “high performance architect*” or “high performance build*” or “high performance construct*” or “high performance home*” or “high performance hous*”)

Time span: 1998-2018。 Index: SCI-EXPANDED, SSCI。

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Li, Y., Rong, Y., Ahmad, U.M. et al. A comprehensive review on green buildings research: bibliometric analysis during 1998–2018. Environ Sci Pollut Res 28 , 46196–46214 (2021). https://doi.org/10.1007/s11356-021-12739-7

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Green building and sustainable architecture

Green building methods and sustainable architecture focus on environmentally responsible and energy-efficient construction practices. They aim to minimize negative environmental impacts not only during the building process, but also beyond. For example, access to renewable energy sources is incorporated into the finished building to improve sustainability. Key principles of these methods include energy efficiency, water conservation, and the use of sustainable materials.

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Guide to career in Architecture

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20 topics to craft a winning sustainable architecture thesis

In today’s rapidly evolving world, the need for sustainable architecture thesis has never been more critical. As global warming and environmental degradation continue to pose significant challenges, the architectural community must step up to create innovative, eco-friendly solutions. For students pursuing a degree in architecture, crafting a thesis on sustainable architecture not only showcases their academic prowess but also contributes to the broader goal of a sustainable future. This blog post aims to guide you through the essential steps and considerations in developing a compelling sustainable architecture thesis.

Understanding Sustainable Architecture

Sustainable architecture refers to designing and constructing buildings that minimize environmental impact, optimize energy efficiency, and utilize renewable resources. It encompasses various practices, including the use of sustainable materials, energy-efficient building systems, and designs that reduce waste and carbon footprints. As an architectural thesis topic, it offers a vast and dynamic field to explore.

Choosing a Sustainable architecture Thesis Topic

Selecting a specific and engaging thesis topic is crucial. Here are some ideas to get you started:

Net-Zero Energy Buildings : Investigate the design and implementation of buildings that produce as much energy as they consume.
Green Roofs and Walls : Explore the benefits and challenges of integrating green roofs and walls into urban architecture.
Passive Solar Design : Analyze the effectiveness of passive solar design strategies in various climates.
Sustainable Urban Planning : Examine the principles and practices of sustainable urban planning in reducing environmental impact.
Biophilic Design : Study the impact of incorporating natural elements into building design on human health and well-being.

Conducting Thorough Research

Once you have chosen your topic, the next step is to conduct comprehensive research. Utilize academic journals, books, case studies, and credible online resources. Key areas to focus on include:

Current Trends : Stay updated with the latest trends and innovations in sustainable architecture.
Case Studies : Analyze successful sustainable architecture projects to understand practical applications and outcomes.
Technological Advances : Investigate new technologies and materials that enhance sustainability in architecture.

Developing a Strong Thesis Statement

A well-crafted thesis statement is the cornerstone of a compelling sustainable architecture thesis. It serves as the central argument or claim that guides your research and writing. To develop a strong thesis statement, consider the following key elements while maintaining an optimal keyword density for SEO purposes:

Clarity and Precision

Your thesis statement should be clear and precise, leaving no room for ambiguity. It must succinctly convey the primary focus of your research on sustainable architecture. Avoid vague language and ensure that your statement directly addresses the specific aspect of sustainability you are investigating.

Example: “This thesis explores the impact of passive solar design in reducing energy consumption in residential buildings in temperate climates.”

Relevance and Significance

Emphasize the relevance and significance of your research within the broader context of sustainable architecture. Highlight why your chosen topic matters and its potential implications for the field. This not only adds weight to your thesis but also helps capture the interest of readers and evaluators.

Example: “By examining the effectiveness of green roofs in urban settings, this thesis aims to demonstrate their potential to reduce urban heat island effects and improve air quality.”

Specificity

A specific thesis statement narrows down the focus of your research, making it more manageable and impactful. Specify the particular aspect of sustainable architecture you are addressing, the methods you will use, and the expected outcomes. This specificity helps in maintaining a coherent and focused narrative throughout your thesis.

Example: “This study analyzes the cost-benefit ratio of using recycled materials in commercial building construction, evaluating both environmental impact and economic feasibility.”

Argumentative Edge

Your thesis statement should present an arguable claim or perspective that invites further investigation and discussion. This makes your thesis more engaging and thought-provoking, encouraging readers to explore your research findings.

Example: “Integrating biophilic design principles in hospital architecture significantly enhances patient recovery rates and overall well-being, as evidenced by case studies from various regions.”

Incorporating Keywords

To optimize your thesis statement for SEO, strategically incorporate relevant keywords without compromising the readability and flow. Keywords like “sustainable architecture,” “energy efficiency,” “green roofs,” “passive solar design,” and “recycled materials” should be naturally woven into your thesis statement. This not only improves search engine ranking but also ensures that your research is easily discoverable by those interested in sustainable architecture thesis.

Example: “This thesis investigates the role of sustainable architecture in promoting energy efficiency through the use of passive solar design in temperate climate residential buildings.”

By focusing on clarity, relevance, specificity, an argumentative edge, and strategic keyword incorporation, you can develop a strong sustainable architecture thesis statement that effectively anchors your research on sustainable architecture. A well-defined thesis statement not only enhances the coherence and impact of your work but also boosts its visibility and accessibility in the digital landscape.

Structuring Your Sustainable architecture thesis

A well-structured thesis is critical for effectively communicating your research. Here’s a suggested structure:

Background information on sustainable architecture
Importance of the topic
Thesis statement
Overview of existing research
Identification of gaps in the literature
Justification for your research
Description of research methods used
Data collection and analysis procedures
Detailed analysis of relevant case studies
Discussion of findings and implications
Presentation of research findings
Interpretation of results
Comparison with existing literature
Summary of key findings
Implications for sustainable architecture
Recommendations for future research

Practical Tips for Writing Your Thesis

Be Clear and Concise : Avoid jargon and complex sentences. Aim for clarity and readability.
Use Visual Aids : Incorporate diagrams, charts, and images to support your arguments and make your sustainable architecture thesis visually appealing.
Edit and Proofread : Ensure your thesis is free of grammatical errors and typos. Consider seeking feedback from peers or advisors.

Here are some engaging and impactful topics for a sustainable architecture thesis:

The design and implementation of buildings that achieve net-zero energy consumption.
Comparative analysis of net-zero energy buildings in different climates.
The benefits and challenges of integrating green roofs and living walls in urban architecture.
The impact of green roofs on urban heat island effect and air quality.
Effectiveness of passive solar design strategies in residential buildings.
Comparative study of passive solar design in different climate zones.
Principles and practices of sustainable urban planning in reducing environmental impact.
Case studies of cities that have successfully implemented sustainable urban planning.
The impact of incorporating natural elements into building design on human health and well-being.
Case studies of biophilic design in commercial and residential buildings.
The use of recycled materials in sustainable architecture: benefits and challenges.
Innovative upcycling techniques in modern architectural design.
Advancements in energy-efficient HVAC systems for sustainable buildings.
Comparative analysis of traditional vs. energy-efficient building systems.
The role of sustainable materials in reducing the carbon footprint of construction.
Life cycle assessment of sustainable building materials.
The integration of smart technologies in sustainable architecture.
The impact of smart building technologies on energy efficiency and sustainability.
Techniques for water conservation in sustainable building design.
Case studies of buildings with innovative water conservation systems.
Design strategies for creating climate-responsive buildings.
Analysis of climate-responsive architecture in different geographic regions.
Challenges and solutions for retrofitting historic buildings with sustainable technologies.
Case studies of successful sustainable retrofits of historic structures.
Design and development of eco-friendly residential communities.
The social and environmental benefits of sustainable residential communities.
Implementing Low-Impact Development strategies in urban planning.
Case studies of LID practices in urban and suburban areas.
Integrating sustainable transportation solutions into urban planning.
The role of public transportation and cycling infrastructure in sustainable cities.
Strategies for adaptive reuse of existing buildings to enhance sustainability.
Benefits and challenges of adaptive reuse in urban environments.
The role of renewable energy sources in achieving sustainable architecture.
Case studies of buildings with integrated solar, wind, or geothermal energy systems.
The impact of sustainable landscaping on urban ecosystems.
Techniques for sustainable site design in new developments.
The relationship between sustainable building design and occupant health.
Case studies of buildings designed with a focus on health and well-being.
Innovations in sustainable construction methods and techniques.
The impact of sustainable construction practices on the environment and economy.

Crafting a sustainable architecture thesis is a challenging yet rewarding endeavor. By choosing a relevant topic, conducting thorough research, and presenting your findings clearly, you can contribute valuable insights to the field of sustainable architecture. Your work has the potential to influence future architectural practices and promote a more sustainable built environment.

Are you passionate about sustainable architecture? Share your sustainable architecture thesis ideas and experiences in the comments below. Let’s inspire each other to build a greener future!

Also read 10 Outstanding Topics for Architecture Thesis on Social Issues to create better world

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Architectural detail in sustainable architecture: formal and aesthetic connotations.

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Energy gained from renewable resources;
Protection against losses of thermal energy from buildings;
Protection against excesses of thermal energy in buildings;
Proper distribution of thermal energy in buildings.

2. Materials and Methods

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Celadyn, W.; Celadyn, M. Architectural Detail in Sustainable Architecture: Formal and Aesthetic Connotations. Sustainability 2024 , 16 , 4502. https://doi.org/10.3390/su16114502

Celadyn W, Celadyn M. Architectural Detail in Sustainable Architecture: Formal and Aesthetic Connotations. Sustainability . 2024; 16(11):4502. https://doi.org/10.3390/su16114502

Celadyn, Waclaw, and Magdalena Celadyn. 2024. "Architectural Detail in Sustainable Architecture: Formal and Aesthetic Connotations" Sustainability 16, no. 11: 4502. https://doi.org/10.3390/su16114502

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Thesis Topics for Architecture :20 topics related to Sustainable Architecture

1. Urban Park | Thesis Topics for Architecture

2. Neighborhood Development

3. Community Garden Design | Thesis Topics for Architecture

4. Waste Recycling Center

5. Restoration of Heritage/Old Building

6. Rehabilitation Housing | Thesis Topics for Architecture

7. Riverfront Development

8. SMART Village | Thesis Topics for Architecture

9. Net-Zero Energy Building

10. Bermed Structure

11. Regenerative Design

12. Urban Agriculture Centre

13. Revitalizing Abandoned Mill or Industry

14. Eco-Tourism Center

15. The Revival of a Heritage Building

16.Adaptive Reuse of a Building

17. Redevelopment of Slum

18. Vertical Farm | Thesis Topics for Architecture

19. Wetland Restoration

20. Eco-Mosque | Thesis Topics for Architecture

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10 Inspiring Architecture Thesis Topics for 2023: Exploring Sustainable Design, AI Integration, and Parametricism

Architecture Thesis Topic #1 – Sustainable Affordable Housing

Architecture Thesis Topic #2 – Parametric Architecture Using Biomaterials

Architecture Thesis Topic #3 – Urban Planning Driven by AI

Architecture Thesis Topic #4 – Adaptive Reuse of Industrial Heritage

Architecture Thesis Topic #5 – Smart and Resilient Cities

Architecture Thesis Topic #6 – High Performing Green Buildings

Architecture Thesis Topic #7 – Urban Landscapes with Biophilic Design

Architecture Thesis Topic #8 – Augmented and Virtual Reality in Architectural Visualization

Architecture Thesis Topic #9 – Sustainable Skyscrapers

Architecture Thesis Topic #10 – Circular Economy in Construction

Conclusion:

A comprehensive review on green buildings research: bibliometric analysis during 1998–2018

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Determining Technologies Trends and Evolution of Smart Building Technologies by Bibliometric Analysis from 1984 to 2020

Introduction

Methodology

Bibliometrics analysis

Social network analysis

Big data method

Data collection

Analytical procedure

Results and analysis

The subject categories and their distribution

The journals’ performance

Publication output

The characteristics of the countries

Global distribution of publications

Global research network

Global trend of publications

Further analysis on China, the USA, and the UK

Baidu Search Index of “green building”

Green building development in the USA and the UK

Barriers and contradicts of green building implement

Dominant issues

Initial phase (1998–2007)

Quick development (2008–2015)

Differentiation phase (2016–2018)

Energy system

Future directions

Availability of data and materials

Author information

Contributions

Corresponding author

Ethics declarations

Consent for publication

Competing interest