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Systematic Review

Biomimetic Strategies for Sustainable Resilient Cities: Review across Scales and City Systems

by
Omar Borham
1,*,
Ben Croxford
1 and
Duncan Wilson
2
1
UCL Institute for Environmental Design and Engineering (IEDE), The Bartlett, UCL Faculty of the Built Environment, 14 Upper Woburn Place, London WC1H 0NN, UK
2
UCL Centre for Advanced Spatial Analysis (CASA), University College London, London WC1E 6BT, UK
*
Author to whom correspondence should be addressed.
Biomimetics 2024, 9(9), 514; https://doi.org/10.3390/biomimetics9090514
Submission received: 2 July 2024 / Revised: 12 August 2024 / Accepted: 20 August 2024 / Published: 27 August 2024
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Abstract

Biomimicry applications in different domains, from material science to technology, have proven to be promising in inspiring innovative solutions for present-day challenges. However, biomimetic applications in the built environment face several barriers including the absence of biological knowledge of architects and planners and the lack of an adequate common means to transfer biomimetic concepts into strategies applicable in the urban context. This review aims to create a multidimensional relational database of biomimetic strategies from successful precedent case studies in the built environment across different city systems and on different application scales. To achieve this, a thorough systematic search of the literature was implemented to map relevant biomimetic case studies, which are analyzed to extract biomimetic strategies that proved to be applicable and successful in an urban context. These strategies are then classified and documented in a relational database. This will provide a guide for architects and planners on how to transfer biomimetic strategies to strategies applicable in the urban context, thus bridging the gap of their lack of biological knowledge. The resulting matrix of strategies provides potential strategies across most of the different city systems and scales with few exceptions. This gap will be covered in a future work, currently in progress, to expand the database to include all city systems and scales.

1. Introduction

While cities represent just 3% of the Earth’s surface, they house over half of the world’s population, consume about 70% of global resources including energy resources, and account for three-quarters of the total greenhouse gas (GHG) emissions. These numbers are expected to worsen further since, according to a report by the United Nations, approximately two-thirds of the world’s population will move to urbanized areas by 2050 [1]. There is a need for rapid urbanization to meet the demands of the booming population worldwide, but at the same time, continuing down this path poses a huge threat to the environment, and as cities grow faster, they become more complex and harder to govern sustainably.
Cities have long been viewed as living organisms that require food to survive and that produce waste in a linear, non-cyclic process. Similarly, the urban metabolism in cities is linear, requires extensive energy, and produces waste. In the quest to rectify this, concepts of sustainability and eco-efficiency have emerged, but their application rather focuses on parts or elements in the built environment in isolation and attempts to improve them. This current thinking pattern turns a blind eye to the complex nature of cities with their many constituent systems and elements that affect one another and would, therefore, only provide approximate simplistic and reductionist solutions [2,3] instead of comprehensive solutions to environmental sustainability that will consider these complexities.
Therefore, a shift in mindset is needed to change the model by which cities are designed to a model of similar complexity and time-tested successes—nature. This is what biomimicry tries to achieve [4]. A breakdown of how natural ecosystems manage energy, water, and materials could provide insights into how cities can sustainably manage these resources, which sometimes require trade-offs within the system for the greater good.
This paper is a systematic review that focuses on applications of biomimetic strategies in the built environment—where nature’s organisms, processes, or ecosystems are mimicked in architectural and urban design—and the potential to present a novel approach for designing built environments to be truly sustainable or regenerative. The database collected and analyzed through this study and the ontology used to create relationships between the various examples will provide a valuable tool for city stakeholders, designers, and urban planners to create sustainable and resilient city systems.

2. Aim and Objectives

This paper aims to create a database that includes a selection of biomimetic strategies, based on patterns found in nature, from case studies in the built environment, which has a high potential of being useful to wider built environment applications. This review of the literature will help designers by increasing awareness of some specific applications and examples and categorizing them across scales, city systems, and biomimicry levels.
Accordingly, this study adopts the following objectives:
-
A systematic review of previous literature identifying applications of biomimicry in the built environment is carried out.
-
The most promising selected strategies and case studies of prior applications of biomimicry are assessed and ranked.
-
A select database of biomimetic strategies is created and classified.

3. Background

The following sub-sections set out the definition of some high-level terms used in this systematic literature review. Figure 1 summarizes approaches to sustainability in the form of a line graph, where the differences in terms of impact can be seen from degenerating to regenerative, and also shows the energy required to carry out certain approaches, with less energy used being positive on the y-axis. The current conventional practices of sustainability lie on the degenerative side of the graph and are net energy users. This section discusses some more regenerative approaches to sustainability.

3.1. Regenerative Sustainability

Regenerative sustainability is about creating built environments that regenerate ecosystems and enable communities to thrive without ongoing intervention. It is a shift from a human-only oriented design that focuses on efficiency to a systems approach that acknowledges humans as an integral part of an ecosystem. Regenerative development aims to improve ecological health rather than degrade it and uses place-based, integrative, and participatory design methods to ensure significant community health and well-being benefits. A systems-based approach is crucial to regenerative development, allowing, for example, mutually beneficial interactions between the built environment, the living world, and human inhabitants over time.
The main challenges in implementing regenerative development are the current lack of an integrated approach and the scarcity of completed examples to provide quantifiable evidence of the benefits of regenerative built environments [6]. Regenerative design is described as “building capacity not things” where buildings are designed as systems that interact with each other, the living world, and their human inhabitants rather than as objects [5]. Leading thinkers on regenerative design argue that a shift from a built environment that ultimately degrades ecosystems to one that restores local environments and regenerates the capacity for ecosystems to thrive will require a fundamental rethinking of not just the architectural design [7] but also, as Hunt points out, rethinking the present competitive economic landscape of the built environment [8].
As explained in Table 1 below, despite the numerous benefits of a regenerative approach over conventional and eco-efficient approaches, it is faced with the challenge of its lack of compatibility with the current status quo and business-as-usual mindset.

3.2. Urban Resilience

The concept of resilience has a rich history across engineering, psychology, and disaster literature [9]. While various scholars have contributed to its development, ecologist C.S. Holling’s seminal paper in 1973 [10] is often regarded as the origin of modern resilience theory. Holling challenged the traditional ecological stability paradigm by recognizing ecosystems as dynamic and having multiple stable states. Resilience, according to Holling, describes an ecological system’s ability to persist and function even when altered without necessarily remaining unchanged [11,12,13].
Cities, like ecosystems, are not static and continuously evolve due to a variety of internal and external pressures (e.g., population growth, environmental changes, economic shifts, and technological advances. Urban resilience refers to the capability of an urban system, including its socio-ecological and socio-technical networks, to perform the following: 1. Maintain or rapidly return to desired functions after disturbances (e.g., natural disasters, social disruptions); 2. Adapt to ongoing changes (e.g., climate shifts); 3. Swiftly transform systems that currently limit adaptive capacity or hinder future resilience. This does not mean maintaining a status quo since cities (as in Holling’s resilience model) constantly undergo transformations [10].
Cities, being complex systems, require holistic approaches that consider interconnections among various domains. For example, a shock to the transportation system can affect economic productivity, social mobility, and even access to essential services. Therefore, planning for urban resilience must account for these interdependencies to ensure the city can withstand and adapt to disruptions while maintaining or quickly regaining desired functions even if the city’s structure or functions change. In this context, urban resilience serves as a boundary object, bridging expertise from multiple disciplines and stakeholders [14]. Therefore, implementing urban resilience involves diverse stakeholders with varying motivations, power dynamics, and trade-offs. Moreover, spatial and temporal scales play a crucial role in shaping resilience strategies [15]. This perspective means that urban planners should plan for adaptability, for the potential of transformation in ways that embrace change rather than merely resist it. This could mean rethinking urban infrastructure or governance models in the context of the interconnectedness of city systems [16].

3.3. City Systems and Flows

Globalization connects cities with distant places through material, energy, and capital exchanges [17,18]. This is mainly through trade and the movement of goods, fuel, and capital between distant cities. Nonetheless, each city in itself is a dynamic place where human and natural processes interact, forming urban ecosystems [19,20,21]. Cities can, therefore, be thought of as complex systems composed of interconnected subsystems [22].
City systems consist of four subsystems [10,21]:
  • The physical built environment or the urban infrastructure and buildings: Built environment, transportation, energy, water grids, and green spaces.
  • Networked material and energy flows, also referred to as “metabolic flows”: These include water, energy, food, materials, waste, and consumer goods.
  • Governance Networks: Actors and institutions shaping urban decisions such as consumers, NGOs, labor, industry, and the state.
  • Socioeconomic Dynamics: Social aspects influencing urban resilience like demographics, mobility, public health, capital, education, equity, and justice.
Figure 2 provides a heuristic for understanding the intricate structures and dynamics of these urban systems [16]. The figure illustrates this concept of multilevel networks within the mentioned city systems. However, conventional design and governance often treat these subsystems as separate silos. This is due to the increasing specialization within the construction industry, which hinders holistic city-system interconnectivity. Transdisciplinary solutions require changes in city powers, cooperation, and mindset adaptation [10].
These subsystems interact at various scales (spatial and temporal), emphasizing interconnections [23,24,25]. For instance, by investing in wind turbines and biomass energy, a city can reduce its carbon footprint and improve air quality. This shift can also influence other systems, such as reducing the load on healthcare due to fewer respiratory issues from air pollution and encouraging economic growth in green technology sectors. Similarly, a well-functioning transportation system allows labor to commute easily, and it facilitates the movement of goods and services, thus increasing productivity and capital. Understanding such spatial and temporal interactions across networks is crucial for designing resilient cities. To comprehensively assess urban resilience, all these subsystems and their elements must be considered. This helps decision-makers think through the complexities involved in managing cities effectively.

3.4. What Is Biomimicry?

The term biomimicry was coined in 1997 by Janine Benyus. Biomimicry is from the Greek words “bios”, meaning “life”, and “mimesis”, meaning to “imitate”. Benyus, who is a biologist and a writer, defines it as “a new discipline that studies nature’s best ideas and then imitates these designs and processes to solve human problems” [4]. She explains that the field is grounded in the principles of ecological thinking and sustainability, where nature-inspired solutions are not only efficient but also have a low environmental impact.
Biomimicry has been adopted in a wide range of fields, from robotics and engineering to medicine and material science. Between each of these fields, the definition of biomimicry varies greatly. This is perhaps why Pederson Zari notes that there is no clear definition of biomimicry that architects could apply in designing their projects, and therefore, it is best to focus on analyzing the different approaches to biomimicry to come out with the best methods to apply biomimicry for maximum benefit [26]. Guber, on the other hand, defined biomimicry as “the study of overlapping fields of biology and architecture that show innovative potential for architectural problems” [27].

3.5. Levels of Biomimicry?

According to Benyus and Zari, there are three levels of biomimicry [28]. Firstly, if an organism’s form is mimicked, this is Organism level biomimicry. An example of this is the Lotusan paint, where the nanostructure of the lotus leaf’s surface was mimicked to create an engineered paint with similar surface properties that allow the paint to self-clean when subjected to the rain in a similar manner to the lotus leaves. The second level is behavior-level biomimicry, where an organism’s behavior or process is mimicked in design. This was the case with the Eastgate building in Zimbabwe, where the architect mimicked the way termites passively ventilated their mounds and created a similar ventilation mechanism that reduced the energy needed for artificial ventilation. Lastly, ecosystem-level biomimicry is when a design holistically mimics an entire ecosystem, including the complex links that relate to its components. HOK’s Lavasa masterplan proposal is an example of this level of biomimicry, where the hydrological cycle and the forest were analyzed and mimicked in the design of the buildings, landscape, and roads to create a city with minimum surface runoff and reducing the risk of flooding. The urban surfaces were designed to be permeable like a forest floor, while the buildings’ roof design was multilayered like a forest canopy to retain and re-evaporate rainwater back into the atmosphere. This is besides onsite rainwater collection and wastewater treatment and reuse for landscape irrigation. The latter, although seen as the ultimate goal, was, until lately, considered the most difficult form of biomimicry.
Kibert (2006) suggested that the complexity in understanding ecosystems makes it impossible for designers to engage in modeling ecosystems in their work since, according to Kibert, human designs are insufficiently complex. However, Zari argues otherwise. Zari defends that the ever-increasing knowledge about nature would enable us to mimic the complex relationships in ecosystems to increase the sustainability of the built environments [29].
There could be overlaps between the various levels of biomimicry, as are evident in the case studies handled in this review. For instance, several systems that relate to each other, such as in an ecosystem, are part of an ecosystem-level biomimicry. At the same time, the components of those systems may be modeled after organisms or their behavior in a similar way that a forest ecosystem is home to many interrelated organisms [26].

3.6. Nature’s Approach to Sustainable Design

Biomimicry involves applying nature’s design principles to human design. These principles were identified by Benyus [4] and were later refined by the Biomimicry Institute to include the use of only the energy needed, recycling of all materials, resilience to disturbances, optimization rather than maximization, reward for cooperation, use of information, use of safe chemistry and materials, use of abundant resources, being locally attuned and responsive, and using shape to determine functionality [30]. It is argued that the application of these principles in human designs would make these designs biomimetic; they would be sustainable and behave in a way similar to nature’s resilient designs. The concept of biomimicry can be applied to address challenges across various scales [31,32]. In built environment applications, this approach extends from the nanostructure of building materials to entire buildings and even urban areas that extend kilometers [33] (Figure 3).

3.7. Biomimicry in the Built Environment: Current State of Research

Although the approach of the application of biomimetic strategies is promising to reach regenerative built environments, the application of biomimicry in the built environment faces several challenges, according to various scholars. Firstly, there is a lack of a consistent and clear definition of biomimicry, which poses a challenge to understanding the implications of applying its abstract concepts [35]. Secondly, there is a gap in the availability of applicable methodologies to aid its incorporation into architectural and urban design [2,36]. Thirdly, there is a main concern that biological knowledge is not commonly accessible to architects and urban planners, which discourages them from trying to incorporate biomimicry in their designs [2]. This has led some scholars to suggest having a biologist on the design team in the early stages of the design process. Lastly, even if designers were aware of biological concepts, there are further knowledge barriers to transferring these concepts into designs and technologies that would be applicable within the built environment [33,37]. Although the awareness of the potential of biomimicry is increasing, it is still far from being common practice.

3.8. Contribution of the Study

This study is not concerned with providing a definition for biomimicry in the urban context. However, this paper is focused on addressing and bridging the rest of the gaps presented in the previous section by reviewing and selecting biomimetic strategies with high potential for their application to solve built environment problems. This study is focused on the mapping of successful precedent cases of the applications of biomimicry in the built environment on different scales. An analysis of the biomimetic strategies used and transferred to urban applications could overcome the barriers to the transferability of biomimetic concepts and bridge the gap of the lack of biological knowledge of architects and planners.
The classification and ontology presented in this study hope to offer a methodology for the comprehensive application of biomimicry in the built environment on various scales and across different city systems. For this purpose, different application scales were considered that varied from macro-scale, which this review refers to as urban scale, which includes applications of biomimicry on a scale larger than a building like a neighborhood, district, or even a city. This would be the scale that city planners or urban designers address in their designs. The second scale is the scale of a single building. This scale addresses the field of work of an architect. The final micro-scale is the scale of a building component or a building system within a building.

4. Materials and Methods

This review adopts an exploratory and analytic research methodology in an attempt to clarify the potential that lies in adopting biomimicry strategies to enable environmentally sustainable cities. The research follows a qualitative research design, which involves the collection and analysis of non-numerical data. The study starts with a systematic review approach where relevant scientific literature is reviewed, and appropriate case studies are analyzed. From this literature, biomimetic strategies are extracted to create a database of those that are most applicable in the built environment field. The review has been conducted in four phases.
First, a systematic search is conducted to identify literature that studies applications of biomimicry in the built environment. Second, a screening process filters the results of the literature search according to the inclusion and exclusion criteria. Third, relevant case studies of prior applications of biomimicry from the chosen literature are collected and analyzed. Finally, a database of biomimetic, environmental, and sustainability strategies is created and classified according to application scale and relevant city system(s). The flowchart (Figure 4) summarizes the following four phases of this paper.

4.1. Phase 1: Data Collection

First, a comprehensive search of the literature was carried out using SCOPUS and Web of Science. The inclusion criterion was as follows:
-
Literature search only using Web of Science and Scopus (Google Scholar was dismissed due to an anomaly in results, which produced an excessive number of irrelevant results);
-
The combination of keywords as specified below in Table 2;
-
Language: English;
-
Published after 1997, when the term biomimicry was coined by Janine Benyus;
-
Only peer-reviewed articles, conference papers, reviews, and books were selected, not magazine articles.
Table 2. Literature search parameters.
Table 2. Literature search parameters.
Key terms
-
Biomimicry
-
Biomimetic strategies
-
Nature-inspired solutions
-
Sustainability
-
Resilience
-
Built environment
Search string usedTITLE-ABS-KEY ((“biomimetic” OR “biomimicry” OR “nature-inspired”) AND (“built environment” OR “architecture” OR “urban” OR “cities” OR “Buildings”) AND (“sustainable” OR “sustainability” OR “resilient”))
Inclusion criteria
-
Scopus and Web of Science
-
Written in English
-
Published after 1997
-
Peer reviewed
-
Strategies applicable in the built environment
-
Further papers were added following review of references of included papers.
Exclusion criteria
-
irrelevant to the built environment
-
Duplicates

4.2. Phase 2: Data Screening

The results gathered during phase 1 were filtered using the following processes applied iteratively and in the following order:
-
Titles and authors were arranged in a spreadsheet, allowing for sorting.
-
Duplicates were identified and removed.
-
Irrelevant documents according to title were removed.
-
At this stage, abstracts were reviewed, and irrelevant documents were removed according to their abstracts.
The remaining documents were read and graded on relevance. The relevance scale was between 1 and 5. With 1, being the least relevant. Only those articles that were the most relevant (graded 5) were considered.
This selection process resulted in the 53 most relevant documents from a first search of 713 to be considered in detail as the source for extraction of biomimetic strategies with high potential to be useful to help solve built environment problems.

4.3. Phase 3: Data Analysis (for Case Studies)

In this phase, the researcher extracted strategies and summarized and synthesized the findings from the selected literature to create a database. In a Microsoft Excel spreadsheet, a table was created that included author(s), title, publication year, document focus, number of citations, document type, source title, and a coded description for each biomimetic case study mentioned in the source documents, note that some documents had several case studies. These coded case study descriptions were each assigned a unique identifier code prefixed by CS.

4.4. Phase 4: Data Synthesis (for Strategies)

A database of biomimetic strategies from the previous phase, which was used in the case studies extracted previously, was generated. These strategies, as well as other parameters extracted from the case studies that could be used to classify them, were added to a separate, linked database, which was a second Microsoft Excel spreadsheet. This database has a coded description for each strategy as well as other parameters, including built environment challenge, city system/flow involved, biomimicry level, and applied scale.
It was decided that although the 2017 list of Sustainable Development Goals and their indicators by the United Nations is comprehensive [38], limited indicators are relevant to city-level development. Therefore, city systems/categories included in the Green City Index were used instead to classify the different strategies as they are tailored to the built environment [39]. These categories/city systems are namely Energy and Carbon, Water, Waste, Mobility and Transport, Infrastructure and Buildings, Food, Air Quality, Biodiversity and Green Infrastructure, and Governance and Data.
Each strategy also had the case study code (CS###) from where the strategy was extracted. Each strategy was also given a unique identifier code with a prefix (S###). Some strategies were duplicated in several case studies.
The author continued reviewing and refining this strategy database until no further strategies were found. Through this process, a fully comprehensive list of high-potential strategies was found. This set of strategies was then further classified according to the application scale and the city systems.

5. Results

The data collection and screening phases of the methodology resulted in a list of 53 articles to be considered in the study, as summarized in Table 3 below. These are the source documents that will be used in the following tables to extract biomimetic case studies and strategies. The articles were ordered from the most cited articles to the least cited ones. The leftmost column contains the document ID number that will be used to identify each of the source document records. This identifying ID number will be used in Table 4 to link both tables together.
Each of these 53 articles was read and analyzed to extract the biomimetic case studies relevant to the built environment. Along with each case study, other parameters were also collected, including location, natural inspiration model, biomimicry level, and the corresponding source documents. These are summarized in Table 4 below. The leftmost column contains the case study ID (CS###) that will be used to identify each of the case studies. This identifying code will be used in Table 5 to link both tables (4 and 5) together. Moreover, to link each case study to the source documents in which they were mentioned, the source document ID(s) are provided in the rightmost column. This column acts as the link between both tables (3 and 4) to illustrate how they are related.
Table 4. List of biomimetic case studies extracted from the source documents in the previous table. Abbreviations Legend Biomimicry Level: Organism Level (OL), Behavior Level (BL), Ecosystem Level (EL).
Table 4. List of biomimetic case studies extracted from the source documents in the previous table. Abbreviations Legend Biomimicry Level: Organism Level (OL), Behavior Level (BL), Ecosystem Level (EL).
Case Study IDCase StudiesLocationNatural ModelBiomimicry LevelSource
Document ID(s)
CS001Eastgate BuildingZimbabweTermite moundBL4, 8, 10, 17, 22, 23, 27, 32, 33, 37, 43, 46, 48, 50, 52
CS002City Council House 2 (CH2)AustraliaTermite mound, trees barkBL4, 10, 22, 23, 32, 33, 37, 43, 46, 50
CS003LavasaIndiaIndian Harvester Ant, Fig leaf, Natural water cycle, Ecosystem Performance StandardsBL, EL9, 10, 19, 22, 26, 34, 40, 51, 52
CS004Flectofins by ITKEStuttgart, GermanyValvular pollination mechanism in the Strelitzia reginae flower (aka Bird-Of-Paradise flower)OL1, 3, 5, 17, 20, 27, 40
CS005One Ocean Thematic Pavilion by SOMA ArchitectureYeosu, South KoreaValvular pollination mechanism in the Strelitzia reginae flower (aka Bird-Of-Paradise flower)OL1, 3, 23, 27, 33
CS006HygroSkin PavilionOrleans, Francespruce (pine?) cones passive response to humidity changesOL1, 3, 5, 17, 27
CS007Lotusan PaintNot ApplicableLotus LeavesOL4, 8, 29, 39, 52
CS008MMAAQatarCactusOL, BL22, 32, 43, 46, 48
CS009Intitute de monde ArabeFranceEye IrisBL4, 22, 27, 33
CS010Water Cube National Swimming Center BeijingChinaBubblesOL4, 10, 22, 27
CS011Eiffel TowerFranceThigh BoneOL10, 22, 23, 43
CS012Pechino National Stadium (Birds Nest Stadium)Beijing, ChinaBird’s nestOL4, 10, 22, 27
CS013Espalande theaterSingaporeDurian Fruit, sea urchin shellsOL10, 22, 27, 33
CS014Lloyd CrossingUSALocal ecosystem patternsEL19, 40, 51, 52
CS015Self-repairing concrete (Bio-concrete/Bionic self-healing concrete)Not ApplicableTrees/fauna and human skinBL4, 37, 39
CS016Calera Portland cement, Eco-CementNot ApplicableSalp fish, seashells, and the Saguaro cactusBL9, 37, 39
CS017Urban Green Print ProjectSeattle, USAWater cycle, ForestEL9, 51, 52
CS018Cooke’s koki’o photosensitiveNot ApplicablePhotosynthesis, Cooke’s Koki`o (Kokia cookei)BL9, 37, 39
CS019Living Machine/Eco-machineNot ApplicableNatural water purification, WetlandsEL18, 37, 39
CS020Lotus TempleNew Delhi, IndiaLotus FlowerOL22, 27, 33
CS021Hydrological Center Namib UniversityNamibiaStenocara BeetleOL35, 44, 52
CS022IRLens Spot Heating SystemNot Applicablecrayfish and lobster eyesBL37, 39, 50
CS023Rafflesia Zero Energy HouseNot ApplicableRafflesia flowerBL22, 33, 43
CS024The Las Palmas Water TheaterSpainStenocara Namib BeetleOL4, 44
CS025HeliotropeGermanySunflowerOL4, 17
CS026MobiusLondon, UKecosystem’s recycling of resources, WetlandsEL9, 20
CS027Eco-Smart City of LangfangLangfang, ChinaNatural water cycle, wetlandsEL9, 26
CS028Tensegrity (Kurilpa) BridgesAustraliaSpider web, human body’s adaptation to damageOL, BL9, 22
CS029Biocement, Engineered cement compositeNot Applicableflexible self-healing skinBL17, 48
CS030i2 Modular CarpetsNot ApplicableForest floor, organized chaos of nature’s ground coveringsOL18,39
CS031Explore Biomimetic office BuildingZurich, SwitzerlandSpookefish eye, brittle starfish, Stone Plant, Bird’s skull, mimosa leaves, Beetle’s wings, mollusc’s iridescent shell, double-duty spinal column, mimosa pudica plantOL, BL23, 46
CS032Sagrada FamiliaBarcelona, SpainTreeOL22, 27
CS033Milwaukee Art MuseumMilwaukee, USABird Wings, Animal boneOL4, 27
CS034Eden ProjectCornwall, UKSoap Bubbles FormationBL27, 33
CS035Sahara Forest ProjectQatar, Tunisia, and JordanNamibian Desert Beetle, EcosystemBL, EL24, 33
CS036The carbon-neutral Utopian Village (coral reef project)HaitiCoral ReefsEL35, 43
CS037BioWaveNot ApplicableBull Kelp, Cochayuyo seaweed withstand strong wave forces by being flexible and stretchyOL37, 39
CS038Biolytix SystemNot ApplicableEarth EcosystemEL37, 39
CS039COMOLEVI Forest CanopyNot ApplicableShadow TreesOL37,39
CS040Sage GlassQuantum GlassNot ApplicableBobtail squid, hummingbirdOL37, 39
CS041Aquaporin MembraneNot Applicablelipid bilayer of living cells, cell membraneBL37,39
CS042Chaac-haNot ApplicableSpiders and BromeliadsOL37, 39
CS043Purebond (Bioplywood)Not ApplicableBlue mussel mollusk adhesionOL37, 39
CS044Gherkin Tower, SwissRe HeadquartersLondon, UKVenus flower basket spongeOL22, 43
CS045Encycle BMS Swarm LogicNot ApplicableHoneybees BL23, 50
CS046Waterloo International TerminalWaterloo, UKpangolinOL22, 53
CS047brewery near TsumebNamibiaEcosystemEL2
CS048Sunflower fiber optic lighting systemJapanSunflowerOL4
CS049Urban CactusNetherlandsphyllotaxy, which refers to the way in which the leaves of different plants grow on the stem and which varies between alternate phyllotaxyOL4
CS050Haikou TowerChinafinsOL4
CS051Duisburg Business Support CenteGermanybiological circulatory systemOL4
CS052The Sky house by kiyonori KikutakeJapanGrowth and MetabolismBL4
CS053Tokyo Dome StadiumJapanBubblesOL4
CS054School of Youth Education designed by Thomas HerzogGermanyPolar Bear SkinOL4
CS055Self-cleaning traffic light glassGermanyLotus LeavesOL4
CS056Willis TowerChicago, USABamboo OL4
CS057BMW Office BuildingMunich, GermanyEars of wheatOL4
CS058Rome Gatt Wool FactoryItalyLotus leaf veinOL4
CS059Worker’s StadiumBeijing, ChinaCobwebOL4
CS060Fuji Pavilion World Expo, 1970Osaka, JapanSoap bubble OL4
CS061National Industries & Techniques CenterFranceEggshellOL4
CS062The Montreal BiosphereMontreal, CanadaHoneycombOL4
CS063Palazzeto DellosporiRome, ItalyAmazon Water LillyOL4
CS064Albufeira River RestorationPortugalNature Based Solutions, Soil, EvapotranspirationEL6
CS065Van Gogh Roosegaarde cycle routeEindhoven, NetherlandsBioluminescenceBL6
CS066Tokyo railway mapping experimentTokyo, JapanPhysarum polycephalum Slime MouldBL9
CS067WellingtonNew ZealandEcosystem services (provision of water and energy)EL17
CS068Green surge projectEuropeNatureEL17
CS069Kalundborg Industrial ComplexKalundborg, Denmarkecosystem’s recycling of resourcesEL18
CS070Organic Waste BiodigesterNot ApplicableNatural Decomposition ProcessBL, EL18
CS071Bullet trainJapanKingfisher Bird’s beakOL20
CS072Silk PavilionMassachusetts, USASilkwormOL20
CS073Biohaven’s Floating IslandsNot ApplicableWetland ecosystemsEL20
CS074Sinosteel International PlazaTianjin, ChinaBeehive OL22
CS075Habitat 2020Not Applicablestomata of leavesBL22
CS076Tree scraper, tower of tomorrowNot ApplicableTree growthBL22
CS077Taichung Opera houseTaichung, TaiwanSchwarz P typeOL22
CS078Earth shipsNot ApplicableShip?EL22
CS079TreepodsBoston, USADragon treeBL22
CS080All seasons tent towerArmeniaMt. AraratOL22
CS081Lily pad floating cityNot ApplicableLily padEL22
CS082Loblolly HouseMaryland, USAtree houseBL22
CS083Shi ling bridgeChinashell lace structureOL22
CS084Guggenheim MuseumNew York, USAShipOL22
CS085ParkroyalSingaporeVertical GardenBL22
CS086SUTD library pavilionSingaporetimber shellBL22
CS087Sydney opera houseSydney, Australiashell structureOL22
CS088Redwood Tree houseNew Zealandseed podOL22
CS089TWA terminalNew York, USAbird flightOL22
CS090Institute for Computer-Based DesignStuttgart, Germany BL23
CS091Himalayan rhubarb towersChinaMetabolism heatBL23
CS092Cabo Llanos TowersSanta Cruz de Tenerife, Spain BL23
CS093Simon Center for Geometry and Physics at the State UniversityNew York, USATree CanopyOL23
CS094Hobermann’s Dynamic WindowsNot ApplicableTree CanopyOL23
CS095phyllotactic towersIranPlants with phyllo-tactic geometryOL23
CS096PantheonRome, ItalySeashellOL23
CS097Vertical Wind turbinesNot ApplicableSchools of fishBL23
CS098humpback fin wind turbineNot Applicablehumpback whale finOL23
CS099Green Power IslandNot ApplicableEnergy storageBL23
CS100Max Fordham’s HouseLondon, UKMetabolism heatBL24
CS101IKEA’s Space 10 lab miniature wooden villageCopenhagen, DenmarkMycelliumBL24
CS102Here EastLonon, UKNature recycles everythingEL24
CS103Waterloo City FarmWaterloo, UKNature recycles everythingEL24
CS104Rieselfeld & VaubanFreiburg, GermanyEcosystemEL25
CS105Hammarby Sjostad DistrictSwedenecosystem’s recycling of resourcesEL25
CS106Crystal PalaceLondon, UKVictoria amazonicaOL27
CS107Teatro del AguaCanary IslandsStenocara Beetle, Hydrological cycleBL28
CS108Self-cleaning Solar PanelsNot ApplicableLotus LeavesOL29
CS109Homeostatic FaçadeNew York, USAMusclesBL33
CS110Cairo Gate ResidenceCairo, EgyptTermite MoundBL33
CS111Durban resilient development planSouth AfricaKwazulu Natal-Cape coastal forests, Southern Africa mangrovesEL34
CS112Interface Inc.: factory as a forest Lagrange, USAOak–hickory–pine forestEL34
CS113Adaptive fitting glassNot ApplicableNamaqua chameleonBL35
CS114Dockside Green developmentB.C, CanadaHydrological cycleEL36
CS115Vancouver Olympic Village at Southeast False CreekVancouver, CanadaHydrological cycleEL36
CS116Radiant Cooling TechnologyNot ApplicableGround water channelsEL37
CS117Turtle glassNot ApplicableChelonia mydasOL37
CS118sharkletNot ApplicableShark skinOL39
CS119Lotus clay roofing tilesNot ApplicableLotus LeavesOL39
CS120Ornilux insulated glass, Not ApplicableOrb weaver spidersOL, BL39
CS121BioUrban 2.0Panama City, PanamaTreesBL40
CS122Photocatalytic cementMilan, Italynature uses nonharmful chemicalsEL40
CS123IONITYEuropeNature uses clean energyEL40
CS124Sierpinski roofNot ApplicableSierpinski forestOL40
CS125La Paz and El AltoBoliviaant colony algorithmBL40
CS126Plus-energy Rooftop UnitNot ApplicableLianaBL41
CS127CSET buildingNingbo, Chinanatural flowsEL42
CS128Pearl River TowerChinaSea spongeOL43
CS129Warka TowersEthiopiaSpider WebOL44
CS130RainbellowsSeattle, USAIce FlowerOL44
CS131The Media TIC buildingBarcelona, SpainStomataBL46
CS132Doha TowerDoha, QatarCactus PoresBL46
CS133Tricon Corporate CenterLahore, PakistanOxalis Oreganada leafBL46
CS134Al Bahar TowerAbu Dhabi, UAEWhite ButterflyBL46
CS135Model Community at Salton SeaCalifornia, USAEcosystem, AlgaeEL47
CS136MemBrain blocksNot Applicablestomata transpirationBL48
CS137Zira IslandAzerbaijan Forest EcosystemEL48
CS138Davis Alpine House in Kew GardensLondon, UKtermite moundBL52
CS139HemisfericValencia, SpainEyelidOL27
An analysis of each case study produced one or more entries in the database, as shown in Table 5; these are the biomimetic strategies that were used in each preceding case. Strategies were categorized according to a number of parameters, including city systems (Energy and Carbon, Water, Waste, Mobility and Transport, Infrastructure and Buildings, Food, Air Quality, Biodiversity and Green Infrastructure, and Governance and Data) and application scale (Urban Scale, Building Scale, and Building Component Scale). These parameters were added in the two rightmost columns. These parameters will play a role in the classification process of the strategies to form a framework for applying them in the built environment across different scales and city systems. Moreover, to link each biomimetic strategy to the corresponding precedent case study or case studies, the case study ID(s) are provided in the middle column. This column acts as the link between both tables to illustrate how they are related.
Each strategy was given an identification code (S###) to facilitate referencing it in the rest of the study. The strategies above represent a set of biomimetic strategies that were applied in the built environment in precedent case studies and can, therefore, represent a guide to architects and planners on how to apply biomimicry in the built environment. However, these applications are on different scales in the built environment. A fraction of these strategies can be applied on a scale as large as a district, neighborhood, or even a city, while others can be applied to a building or a building component. Moreover, the strategies target different aspects of city systems such as energy efficiency, water conservation, material efficiency, data flow, and biodiversity.

6. Discussion

The outcome of the methodology applied is a relational database consisting of three tables (Table 3, Table 4 and Table 5) which are linked together. Table 5 provides the biomimetic strategies that are applicable in the built environment for the design of regenerative, resilient cities, and these strategies are applicable on different scales and through different city systems. Table 4 provides a mapping of best-practice biomimetic case studies in the built environment. The precedent application of any of the strategies from Table 5 can be found in one or more precedent case studies, which can provide a guide to architects and planners on how to successfully apply a certain strategy to the built environment. Therefore, Table 5 and Table 4 were linked together via the case study identification code (CS###) to cross-reference the strategies with their corresponding precedent case studies. Where more information is needed by the architect or planner about a particular case study or a strategy, the source document(s) in Table 3 can be consulted. Accordingly, Table 3 and Table 4 were linked together via the source document ID number to cross-reference the case studies with their corresponding source documents in which they were mentioned and analyzed. How best to organize and use this relational database is the subject of current research by the authors, as will be discussed in the Future Work section.
The diverse parameters included in the database allowed for a multidimensional set of strategies that could be filtered and reordered to provide insights on how to tackle a particular dimension. For instance, all strategies related to energy could be filtered to provide a set of strategies that focus on minimizing energy consumption. Another dimension could be filtering all strategies relating to the applied scale to give guidelines on how to design sustainable buildings, for example. This ontology allows this database to be used in different ways that correspond to the different goals of the architect or planner using the database. This filtering across the application scales and city systems can act as a valuable tool for architects and planners and facilitate the application of biomimetic strategies in the built environment.
An indication of how this will work can be summarized in the following matrix (Table 6), where all biomimetic strategies applicable on a particular scale can be found in the same column, while all strategies addressing a particular urban system can be found in the same row. This classification can make it more accessible to architects and planners to decide on which scale they are tackling and what challenges they are trying to address in their designs, who can, therefore, refer to the relevant biomimetic strategies after getting the strategy codes (S###) from the matrix of Table 6 and cross-referencing them to Table 5 to find the corresponding strategy. For further information on how to apply these strategies, the next step would be to cross-reference the strategies with the corresponding precedent case studies (in Table 4), as explained earlier using the case study ID(s) (CS###). For further details on a case study, a further step would be to cross-reference the case study to the relevant source document in Table 3 using the corresponding source document ID(s).
For example, to consider water use at the building scale, one might review one of the five strategies relevant strategies in Table 6 below. If the architect referring to the matrix decides to consider applying strategy S149; fog-catching (highlighted in bold in the matric below), the architect can refer to the relational database for ideas on how to apply this in the building design. Strategy S149 is linked to case studies CS020, CS021, CS024, CS035, CS042, CS107, and CS129 and the source documents 4, 22, 24, 27, 28, 33, 35, 37, 39, 44, and 52. These documents along with the case studies will provide a detailed guide on how to apply fog-catching technologies on the building scale and present previous successes.
It is observed in Table 6 that some cells were empty, presenting no strategies for a particular city system on a particular application scale. This can be due to two reasons. Firstly, certain challenges may only be tackled on a particular scale. For instance, all strategies collected for Mobility and Transport were on the urban scale and none on the other two scales. This can be understood since transport is usually between distant places normally on a scale larger than one building. Secondly, it could be that the collected source documents lacked case studies or strategies for that particular city system and scale, as will be explained in the Limitations section. An example of this is the lack of strategies for Food on the building scale or the building component scale. One might argue that a productive green roof can be a potential strategy to fill this gap, but such a strategy was missing from the collected source documents. The Future Work section will outline how this will be overcome in further research after this study.

7. Conclusions

Architects and planners require great awareness to achieve efficiency and sustainability in buildings, especially in this era when meeting sustainability targets is more critical than in the past. Architects and planners need to rethink the way they build in order to achieve a truly sustainable future. Novel ideas need to be explored and tested; a new design model is needed. The natural world provides an extensive design database that can inspire solutions as sustainable, resilient, and self-perpetuating as those seen in nature. The case studies and strategies presented here are successful precedents biomimetic applications in the built environment. Accumulating and presenting them in this relational database can help to develop wider awareness and understanding of the potential of biomimicry, which can help develop cities that are regenerative and resilient.
The design and management of future cities could also incorporate biomimicry but may have significant barriers due to the wider transdisciplinary nature of the field. While it is true that there is a gap in the biological knowledge of architects and planners, this gap can be bridged by providing a database of biomimetic strategies that have already been successfully applied in the built environment, along with the precedent case studies and source documents to support the understanding of how biomimicry applications can be transferred to the built environment.
Biomimicry, the science of imitating natural models, has good potential when integrated into the design of the built environment. While Benyus suggests that “a full emulation of nature engages at least three levels of mimicry: form, process, and ecosystem” [4], the authors propose a comprehensive vision of applying biomimicry in the built environment on different scales and across all city systems to achieve a regenerative, resilient city.
Ecosystem-level biomimicry gives a more holistic approach to the design of built environments. If applied on an urban scale, it would allow designing better cities that behave like natural ecosystems, and within those ecosystems, architects could also design buildings and building systems that thrive in themselves to achieve higher levels of efficiency in terms of energy, water, and resource use. Moreover, how natural ecosystems respond to place and the local environment is very important in setting design goals in terms of energy, air, water, and carbon budgets for a given design to ensure that cities can behave as a natural ecosystem would behave.

8. Limitations and Future Work

The authors acknowledge that this database is of limited scale, but it is expandable as more strategies or case studies are found. It is also noted that the resultant number and variety of strategies and case studies depended on the criteria put forward to limit the number of source documents that were reviewed. Widening the search scope in the future to include more articles will result in a richer database of case studies and strategies that better cover areas lacking in the biomimetic strategies matrix presented in Table 6.
Since this database is a work in progress that is set to be expanded and developed further in the future, it will be materialized into a digital application to facilitate access to the database. This would also allow for the accumulation of more biomimetic best practice cases in the built environment from architects and planners using this platform.

Author Contributions

Conceptualization, O.B. and B.C.; methodology, O.B. and B.C.; formal analysis, O.B.; investigation, O.B.; resources, O.B.; data curation, O.B.; writing—original draft preparation, O.B.; writing—review and editing, O.B., B.C. and D.W.; visualization, O.B.; supervision, B.C. and D.W. All authors have read and agreed to the published version of the manuscript.

Funding

This paper is part of a PhD funded by the MINISTRY OF HIGHER EDUCATION OF THE ARAB REPUBLIC OF EGYPT, grant number NMM13/21.

Institutional Review Board Statement

Not applicable.

Data Availability Statement

The data presented in this study are available on request from the corresponding author.

Conflicts of Interest

The authors declare no conflicts of interest. The funders had no role in the design of the study, in the collection, analyses, or interpretation of data, in the writing of the manuscript, or in the decision to publish the results.

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Biomimetics 09 00514 g001
Figure 1. Trajectory of Ecological Design. Adapted with permission from reference [5].
Figure 1. Trajectory of Ecological Design. Adapted with permission from reference [5].
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Figure 2. A simplified conceptual schematic of the multilevel networks within the city system. Reprinted with permission from reference [16].
Figure 2. A simplified conceptual schematic of the multilevel networks within the city system. Reprinted with permission from reference [16].
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Figure 3. Historical trend of biomimicry across scales. Source [34].
Figure 3. Historical trend of biomimicry across scales. Source [34].
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Figure 4. Process of systematic literature review. Source: designed by the author using Miro.
Figure 4. Process of systematic literature review. Source: designed by the author using Miro.
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Table 1. Benefits of eco-efficient and regenerative design. Source: [7].
Table 1. Benefits of eco-efficient and regenerative design. Source: [7].
ConventionalEco-EfficiencyRegeneration
Works within the existing mindset
Minimizes environmental impact
Enhances people’s physical well-being
Boosts psychological health
Reduces overall lifecycle costs
Enhances economic value in projects
Fosters innovation in projects
Yields positive environmental outcomes
Transforms development into a potential income source
Manages global issues strategically via place-based approaches
Improves integrated knowledge of place
Promotes mutually beneficial relationships between people and place
Enhances resilience, flexibility, and adaptability in built environments
Strengthens equitable communities
√: benefits.
Table 3. List of scientific articles relevant to biomimetic applications in the built environment. Full list of the source documents is available upon request from the author. For readability reasons, the table has been formatted with shortened references.
Table 3. List of scientific articles relevant to biomimetic applications in the built environment. Full list of the source documents is available upon request from the author. For readability reasons, the table has been formatted with shortened references.
SourceDoc IDAuthor, YearTitleSource Document FocusCitation Ref-No
1(López et al., 2017)How plants inspire facades. From plants to architecture: Biomimetic principles for the development of adaptive architectural envelopesAdaptive building envelopes[40]
2(Mathews, 2011)Towards a Deeper Philosophy of BiomimicryPhilosophical principles[41]
3(Al-Obaidi et al., 2017)Biomimetic building skins: An adaptive approachAdaptive building envelopes[42]
4(Yuan et al., 2017)Bionic building energy efficiency and bionic green architecture: A reviewEnergy efficiency, structure, and materials[43]
5(Anzaniyan et al., 2022)Design, fabrication and computational simulation of a bio-kinetic façade inspired by the mechanism of the Lupinus Succulents plant for daylight and energy efficiencyBiomimetic kinetic envelope design[44]
6(Blau et al., 2018)Urban River Recovery Inspired by Nature-Based Solutions and Biophilic Design in Albufeira, PortugalNature-based solutions[45]
7(Hayes et al., 2019)Leveraging socio-ecological resilience theory to build climate resilience in transport infrastructureTransport infrastructure[46]
8(Ahamed et al., 2022)From biology to biomimicry: Using nature to build better structures-A reviewEnvelopes, structure, and materials[47]
9(Buck, 2017)The art of imitating life: The potential contribution of biomimicry in shaping the future of our citiesCity systems[48]
10(Radwan & Osama, 2016)Biomimicry, An Approach For Energy Efficient Building Skin DesignBuildings envelopes[49]
11(Hayes et al., 2020)Learning from nature—Biomimicry innovation to support infrastructure sustainability and resilienceStructure and infrastructure[50]
12(Zari & Hecht, 2020)Biomimicry for Regenerative Built Environments: Mapping Design Strategies for Producing Ecosystem ServicesEcosystem services[51]
13(Gruber & Imhof, 2017)Patterns of Growth-Biomimetics and Architectural DesignGrowth patterns[52]
14(Badarnah, 2015)A Biophysical Framework of Heat Regulation Strategies for the Design of Biomimetic Building EnvelopesEnvelopes (heat regulation)[53]
15(Chou et al., 2016)Big data analytics and cloud computing for sustainable building energy efficiencyEnergy efficiency management[54]
16(Pedersen Zari & Koner, n.d.)An ecosystem based biomimetic theory for a regenerative built environmentEcosystem principles[55]
17(Uchiyama et al., 2020)Application of biomimetics to architectural and urban design: A review across scalesBiomimicry across scales[33]
18(Carlos Montana-Hoyos & Carlos Fiorentino, 2016)Bio-utilization, bio-inspiration, and bio-affiliation in design for sustainability: Biotechnology, biomimicry, and biophilic designEducation[56]
19(Blanco et al., 2021)Urban Ecosystem-Level Biomimicry and Regenerative Design: Linking Ecosystem Functioning and Urban Built EnvironmentsEcosystem biomimicry[57]
20(Ilieva et al., 2022)Biomimicry as a Sustainable Design Methodology-Introducing the ‘Biomimicry for Sustainability’ FrameworkClassification framework[58]
21(Badarnah, 2016)Light management lessons from nature for building applicationsLight management[59]
22(Dash, 2018)Application of biomimicry in building designCase studies classification[60]
23(Jamei & Vrcelj, 2021)Biomimicry and the Built Environment, Learning from Nature’s SolutionsEnvelopes, structure, materials, and energy retrofits[61]
24(Timea Kadar & Manuella Kadar, 2020)Sustainability Is Not Enough: Towards AI Supported Regenerative DesignAI for regenerative design[62]
25(Spiegelhalter & Arch, 2010)Biomimicry and circular metabolism for the cities of the futureEcosystem biomimicry[63]
26(Lazarus & Crawford, n.d.)Returning genius to the placeEcosystem biomimicry[64]
27(Sommese et al., 2022)A critical review of biomimetic building envelopes: towards a bio-adaptive model from nature to architectureAdaptive building envelopes[65]
28(Pedersen Zari, 2009)An architectural love of the living: Bio-inspired design in the pursuit of ecological regeneration and psychological well-beingEcosystem biomimicry[66]
29(Dicks et al., 2021)Applying Biomimicry to Cities: The Forest as Model for Urban Planning and DesignForest ecosystem biomimicry[67]
30(Faragalla & Asadi, 2022)Biomimetic Design for Adaptive Building Facades: A Paradigm Shift towards Environmentally Conscious ArchitectureAdaptive building envelopes[68]
31(Imani & Vale, 2022)Developing a Method to Connect Thermal Physiology in Animals and Plants to the Design of Energy Efficient BuildingsThermal energy efficiency[69]
32(Faragllah, 2021)Biomimetic approaches for adaptive building envelopes: Applications and design considerationsAdaptive building envelopes[70]
33(Verbrugghe et al., 2023)Biomimicry in Architecture: A Review of Definitions, Case Studies, and Design MethodsBiomimetic design methods[37]
34(Benyus et al., 2022)Ecological performance standards for regenerative urban designEcological performance standards (EPS)[71]
35(Elshapasy et al., 2022)Bio-Tech Retrofitting To Create A Smart-Green UniversityBiomimicry and smart buildings[72]
36(Hao et al., n.d.-b)Closed-Loop Water and Energy Systems: Implementing Nature’s Design in Cities of the FutureClosed-loop urban water systems[73]
37(Movva & Velpula, 2020)An analytical approach to sustainable building adaption using biomimicryBuilding scale biomimetic design[74]
38(Hao et al., 2010a)Network Infrastructure—Cities of the FutureUrban water management[73]
39(Oguntona & Aigbavboa, 2019)Assessing the awareness level of biomimetic materials and technologies in the construction industryBiomimetic construction materials and technologies[75]
40(Quintero et al., 2021)Sustainability Assessment of the Anthropogenic System in Panama City: Application of Biomimetic Strategies towards Regenerative CitiesBiomimetic regenerative cities and EPS[76]
41(Speck et al., 2022)Biological Concepts as a Source of Inspiration for Efficiency, Consistency, and SufficiencyBiological concepts of lianas[77]
42(Widera, 2016)Biomimetic And Bioclimatic Approach To Contemporary Architectural Design On The Example Of CSET BuildingBiomimicry for net zero buildings[78]
43(AlAli et al., 2023)Applications of Biomimicry in Architecture, Construction and Civil EngineeringBiomimicry in building design[79]
44(Aslan et al., 2022)A Biomimetic Approach to Water Harvesting Strategies: An Architectural Point of ViewWater harvesting on the building level[80]
45(Ortega Del Rosario et al., 2023)Environmentally Responsive Materials for Building Envelopes: A Review on Manufacturing and Biomimicry-Based ApproachesResponsive building envelopes [81]
46(Elsakksa et al., 2022)Biomimetic Approach for Thermal Performance Optimization in Sustainable Architecture. Case study: Office Buildings in Hot Climate CountriesEnvelope Thermal Performance[82]
47(Mazzoleni et al., 2008b)Eco-systematic restoration: a model community at Salton SeaBiomimetic urban Restoration[83]
48(Sharma & Singh, 2021)Protecting humanity by providing sustainable solution for mimicking the nature in construction fieldBiomimicry levels in built environment[84]
49(Van Den Dobbelsteen et al., 2010)Cities As Organisms: Using Biomimetic Principles To Become Energetically Self-Supporting And Climate ProofBiomimetic city planning principles[85]
50(Pedersen Zari M, 2018)Can built environment biomimicry address climate change?Biomimetic strategies[7]
51(Pedersen Zari M, 2018)Emulating ecosystem services in architectural and urban design Ecosystem services analysisEcosystem services
[7]
52(Pedersen Zari M, 2018)Incorporating biomimicry into regenerative designBiomimetic strategy regenerative design[7]
53(Pedersen Zari M, 2018)Translating ecosystem processes into built environment designEcosystem services[7]
Table 5. List of biomimetic strategies extracted from the precedent biomimetic case studies. Abbreviations Legend Application Scale: Urban Scale (U), Whole Building (B), Building Component (C). City Systems: Energy and Carbon (EC), Water (WR), Waste (WS), Mobility and Transport (MT), Infrastructure and Buildings (IB), Food (FD), Air Quality (AQ), Biodiversity and Green Infrastructure (BG), Governance and Data (GD).
Table 5. List of biomimetic strategies extracted from the precedent biomimetic case studies. Abbreviations Legend Application Scale: Urban Scale (U), Whole Building (B), Building Component (C). City Systems: Energy and Carbon (EC), Water (WR), Waste (WS), Mobility and Transport (MT), Infrastructure and Buildings (IB), Food (FD), Air Quality (AQ), Biodiversity and Green Infrastructure (BG), Governance and Data (GD).
Strategy IDBiomimetic StrategyCorresponding
Case Study ID		Application ScaleCity
Systems
S001Sequester atmospheric carbon into building materials, Neutral and strength-enhancing carbon sequestering cementCS003, CS016, CS111, CS112CEC, IB
S002Low Carbon Economy (LCE)CS105UEC
S003(Efficient) wind turbinesCS097, CS098, CS064, CS104, CS110, CS127, CS128, CS135U, CEC
S004Hydro turbinesCS036, CS037UEC
S005Geothermal energyCS104UEC
S006CHP—Combined Heating and Power PlantsCS104UEC
S007Solar Photovoltaic Panels (on building’s roof and façade)CS023, CS036, CS064, CS076, CS080, CS104, CS110, CS126, CS127, CS135BEC, IB
S008Dye-Sensitive Solar cellsCS018CEC
S009Solar BenchesCS064UEC
S010Solar light postsCS064UEC
S011Biofuel producing algae farmsCS135UEC, BG
S012BiomassCS104UEC
S013Blue battery, energy storage for different RE outputsCS099UEC
S014Batteries to store renewable energyCS078, CS135BEC
S015Bioluminescence MaterialsCS065UEC
S016P2P energy sharing via blockchain technologyCS101B, CEC, GD
S017Reduce Peak DemandCS045CEC, GD
S018Zero (fossil) energyCS023, CS104, CS135BEC
S019low energy passive houseCS104UEC, IB
S020Passive design strategiesCS135, CS104UEC, IB
S021Active Solar design strategiesCS104UEC, IB
S022Wall/slab thermal massCS135UEC, IB
S023Energy excess fed into gridCS135UEC
S024Double glazingCS135UEC, IB
S025Openings sizing to control solar radiationCS135UEC, IB
S026District Heating/CoolingCS104UEC
S027Spot heating systemCS022CEC
S028Underground radiant heating/coolingCS002, CS051, CS116, CS135CEC
S029Geothermal heat pumpCS110, CS127, CS135B, UEC
S030Cooling by avoiding direct sunlightCS092BEC
S031Radiative heat gainCS092BEC
S032Heat by Occupants’ MetabolismCS091, CS100BEC
S033Improved Trombe wallCS054CEC
S034Solar water heating/Solar CollectorCS025, CS127, CS135BEC
S035Sewage heat recoveryCS115UEC
S036Heat sinksCS135UEC
S037Solar pondsCS135UEC
S038Water cooled façadeCS135UEC, IB
S039Passive Cooling (Stack effect Ventilation)CS001, CS002, CS138BEC
S040Natural Cross VentilationCS050, CS135BEC, AQ
S041Demand-driven ventilation systemCS085BEC, AQ
S042Wind CatchersCS023, CS110BEC, IB
S043Minimal Structural members for maximum daylightCS034BIB, EC
S044Fiber optic lighting systemCS048CEC, IB
S045Phyllotaxy/Fibonacci order to avoid self-shadingCS049, CS095BIB, EC
S046Narrow Floor Plan DepthCS031, CS135BIB, EC
S047Reflect/Focus light into Dim AreasCS031B, CEC, BI
S048Inflatable membrane structuresCS010, CS053, CS060BIB, EC
S049Responsive Adaptive skin color change to retain or absorb heatCS113BEC, IB, GD
S050Solar Envelope MasterplanningCS104UEC, IB
S051Elastically Deformable LouversCS004, CS005CEC, IB
S052Solar Self-ShadingCS008, CS013, CS039, CS074, CS080, CS093, CS124BEC, IB
S053Responsive Adaptive Shading SystemCS009, CS031, CS134CEC, GD
S054Kinetic screenCS132BEC, GD
S055Foldable Shading DevicesCS031B, CEC
S056Adjustable Shading DeviceCS133, CS033, CS139BEC
S057inflatable shading deviceCS131CEC
S058Dynamic WindowsCS094CEC
S059Electrochromic smart windows for energy savingsCS040CEC, GD
S060Dyed glass to decrease light projectionCS117CEC
S061Self-thermoregulation hybrid systemsCS127BEC, GD
S062Responsive Adaptive envelopesCS090, CS109B, CIB, EC
S063humidity-sensitive envelopeCS006CIB
S064Envelope controls daylight and air qualityCS075BEC, IB
S065Walkable city/compact city designCS003, CS104UMT, EC, AQ
S066Building on columns for less footprintCS023BIB
S067Allow for Growth (degrowth)CS052BIB
S068Design for disassemblyCS062, CS082, CS103BIB
S069Standardized modular prefabricated partsCS030, CS036, CS062, CS082CIB
S070Refurbish rather than dismantleCS102BIB
S071Design for LongevityCS102, CS103BIB
S072Design for adaptabilityCS103UIB
S073Adaptive Building ZoningCS025B, CIB, EC
S074Reduce surface area to volume ratioCS076BIB, EC
S075Parasitic Architecture (addition of net zero units on top of existing buildings, surplus PV power provided to the building in exchange for use of staircase, etc.)CS126BIB
S076Building orientationCS135UIB, EC
S077DecentralizationCS104UGD
S078Decentralized services and marketsCS104UIB
S079Hexagonal structural elementsCS074, CS053, CS060, CS010BIB
S080Remove excess structural materialCS011, CS031, CS074, CS083BIB
S081Hollow Structural elements with integrated systemsCS031B, CIB
S082Cobiax technologyCS085BIB, WS
S083Thin-shell structure CS020, CS061, CS087, CS089BIB
S084Lightweight StructureCS034, CS072BIB
S085Shell lace structureCS083BIB
S086Branching columnsCS032BIB
S087Irregular steel trusses structureCS012BIB
S088Curved diagrid steel envelope structureCS044BIB
S089Radial bifurcating ribsCS058, CS063, CS106BIB
S090Multidimensional curvature structureCS096BIB
S091Skin as StructureCS074BIB
S092Barrel structureCS056BIB
S093Responsive adjusting to loads. Infrastructure senses structural compromises and alters structure to compensateCS028UIB, GD
S094Flexible structures for high wind loadsCS046, CS011BIB
S095Folding StructureCS033, CS139CIB
S096Suspension structure CS057BIB
S097Suspended-cable structureCS059BIB
S098load bearing curvilinear wallsCS084BIB
S099Locally available materialsCS086, CS088BIB
S100Recycled construction materialsCS078BIB, WS
S101Design for less maintenanceCS007, CS015, CS029, CS030, CS055, CS108, CS118, CS119, CS122CIB
S102Photocatalytic cement, neutralize organic and inorganic pollutants. It makes surfaces self-cleaning. Savings in maintenance costsCS122B, UIB
S103Smart Vapor Retarder blocksCS136CIB
S104surfaces that inhibit bacterial growth on high-touch surfacesCS118CIB
S105Non emissive materialsCS135UIB, AQ
S106Self-cleaning paintsCS007CIB
S107Self-cleaning solar panelsCS108CIB, EC
S108Self-cleaning clay roofsCS119CIB
S109Self-cleaning urban elementsCS055CIB
S110Self-healing cement/concrete CS015, CS029CIB
S111Industrial EcologyCS069, CS105UWS, EC
S112Closed-loop models/Cradle-to-cradleCS026, CS035, CS047, CS069B, UGD, WS
S113Organic Waste to Biogas and fertilizersCS026, CS070, CS075UWS, EC, FD
S114Biogas to energy (from landfills and waste treatment plants)CS104UWS, EC
S115Thermal waste treatment plant for (non-recyclables)CS104UWS
S116Fermentation of Bioorganic waste to energyCS104UWS, EC
S117Zero waste to landfillCS047, CS135UWS
S118Design out wasteCS103, CS104UWS
S119Onsite waste recyclingCS036UWS
S120Upcycle/recycle wasteCS078, CS103, CS104BWS, GD
S121Zero WasteCS135UWS, GD
S122(Net) zero emissionsCS036, CS047, CS064, CS077, CS104, CS135UAQ, EC
S123Non-toxic VOC-free wood glueCS043CAQ, IB
S124Biofilters for air purificationCS079, CS121UAQ
S125Nature-based solution (NBS) and BiophiliaCS064, CS068UBG
S126Green walls/vertical gardenCS064, CS085BBG, IB, EC, AQ
S127Gravity driven irrigationCS085BBG, WR
S128Smart irrigation (soil sensors)CS115UWR, GD
S129Green RoofsCS064, CS114, CS115UBG, IB, EC, AQ
S130Organic suspended roof gardensCS036, CS115UFD, BG, EC
S131(Pervious) green corridor/green beltCS003, CS027, CS64, CS104UBG, AQ
S132Green InfrastructureCS064UBG
S133Trees and ShrubsCS064UBG, AQ
S134Permeable (Pervious) Paving/Urban SurfacesCS064, CS003UIB, WR
S135Recycle/Purify all Urban WaterCS064UWR
S136BioswalesCS114UWR
S137Protect native landscapes/forestsCS104UBG
S138interconnect protected landscape areas with biotopesCS104UBG
S139Urban landscapesCS104UBG, IB, AQ
S140Nature sensitive farmingCS135UFD, BG
S141UV-reflective coating that mitigates bird collisionsCS120CIB, BG
S142Design for increased biodiversityCS035, CS073UBG
S143Ecosystem ServicesCS014, CS067UGD
S144Ecological Performance Standards (EPS)CS003, CS014, CS067, CS111, CS112UGD
S145Food forestCS135UFD
S146Fish pondCS135UFD
S147Edible plantsCS135UFD
S148Water NeutralityCS135UWR
S149Fog water collectionCS020, CS021, CS024, CS035, CS042, CS107, CS129BWR
S150Rainwater CollectionCS042, CS077, CS114, CS115, CS129, CS 135, CWR
S151Rainwater filtrationCS114UWR
S152Rainwater StorageCS008, CS114, CS115BWR
S153Water banking (inter-seasonal water storage)CS115, CS003UWR
S154Cistern Rainwater StorageCS114, CS115BWR
S155Rainwater storage pockets on façadeCS130CWR
S156Rainwater onsite useCS114, CS135UWR
S157Greywater onsite use for irrigation and toilet flushCS076, CS077, CS114, CS135BWR
S158Recharge AquifersCS027UWR
S159Connect water infrastructure to the surrounding watershedCS115UWR
S160water conservationCS104UWR
S161Adapt rain screens on buildings to enhance evapotranspiration and reduce runoffCS017UWR, IB
S162multipath low-grade channel designs of underground stormwater infrastructures and street layouts take a similar formCS003UWR
S163Redirect water to increased flow pathsCS003UWR
S164Eliminate chemical runoff to waterbodiesCS135UWR
S165Membrane filtration technology for safe drinking waterCS041CWR
S166Onsite wastewater treatment (Bioreactor membrane)CS114UWR
S167Chemical-free wastewater treatment and filtering systemCS019, CS026, CS027, CS038, CS073UWR
S168WetlandCS135UWR, BG
S169Electric TransportCS123UMT, EC, AQ
S170Routing AlgorithmCS125UMT, EC
S171Reduced-traffic zonesCS104UMT, AQ
S172Direct Access to public transportCS104UMT
S173Pedestrian trafficCS104UMT
S174Connecting public transport to bike lane networkCS104UMT
S175Reduce distance to nearest bus/tram stopCS104UMT
S176High-density public transportCS104UMT
S177bicycle networksCS104UMT
S178Design infrastructure to mimic capacity hierarchies, bifurcation angles, and minimal disruption of flowCS066UMT
S179Bullet trainCS071UMT, EC
S180Sensors and ActuatorsCS028UGD
S181Real-time building energy use auditingCS104UGD, EC
S182Real-time building CO2 emissions auditingCS104UGD, EC
S183Integrated systemsCS135UGD
S184self-sustaining off-grid system (energy, water)CS036, CS081, CS127, CS137UGD
Table 6. Biomimetic Strategies Matrix Across Scales and City Systems.
Table 6. Biomimetic Strategies Matrix Across Scales and City Systems.
Urban Scale (U)Whole Building
Scale (B)		Building Component Scale (C)
Energy and Carbon
(EC)		S002, S003, S004, S005, S006, S009, S010, S011, S012, S013, S015, S019, S020, S021, S022, S023, S024, S025, S026, S029, S035, S036, S037, S038, S050, S065, S076, S111, S113, S114, S116, S122, S129, S130, S169, S170, S179, S181, S182S007, S014, S016, S018, S029, S030, S031, S032, S034, S039, S040, S041, S042, S043, S045, S046, S047, S048, S049, S052, S054, S055, S056, S061, S062, S064, S073, S074, S126 S001, S003, S008, S016, S017, S027, S028, S033, S044, S047, S051, S053, S055, S057, S058, S059, S060, S062, S073, S107
Water
(WR)		S128, S134, S135, S136, S148, S151, S153, S156, S158, S159, S160, S161, S162, S163, S164, S166, S167, S168S127, S149, S152, S154, S157S150, S155, S165
Waste
(WS)		S111, S112, S113, S114, S115, S116, S117, S118, S119, S121S082, S100, S112, S120
Mobility and Transport
(MT)		S065, S169, S170, S171, S172, 173, S174, S175, S176, S177, S178, S179
Infrastructure and Buildings
(IB)		S019, S020, S021, S022, S024, S025, S038, S050, S072, S076, S078, S093, S102, S105, S129, S134, S139, S161S007, S042, S043, S045, S046, S047, S048, S049, S052, S062, S064, S066, S067, S068, S070, S071, S073, S074, S075, S079, S080, S081, S082, S083, S084, S085, S086, S087, S088, S089, S090, S091, S092, S094, S096, S097, S098, S099, S100, S102, S126S001, S044, S047, S051, S062, S063, S069, S073, S081, S095, S101, S103, S104, S106, S107, S108, S109, S110, S123, S141
Food
(FD)		S113, S130, S140, S145, S146, S147
Air Quality
(AQ)		S065, S105, S122, S124, S129, S131, S133, S139, S169, S171S040, S041, S126, S123
Governance and Data (GD)S077, S093, S112, S121, S128, S143, S144, S180, S181, S182, S183, S184S016, S049, S054, S061, S112, S120S016, S017, S053, S059
Biodiversity and Green Infrastructure (BG)S011, S125, S129, S130, S131, S132, S133, S137, S138, S139, S140, S142, S168S126, S127S141
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Borham, O.; Croxford, B.; Wilson, D. Biomimetic Strategies for Sustainable Resilient Cities: Review across Scales and City Systems. Biomimetics 2024, 9, 514. https://doi.org/10.3390/biomimetics9090514

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Borham O, Croxford B, Wilson D. Biomimetic Strategies for Sustainable Resilient Cities: Review across Scales and City Systems. Biomimetics. 2024; 9(9):514. https://doi.org/10.3390/biomimetics9090514

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Borham, Omar, Ben Croxford, and Duncan Wilson. 2024. "Biomimetic Strategies for Sustainable Resilient Cities: Review across Scales and City Systems" Biomimetics 9, no. 9: 514. https://doi.org/10.3390/biomimetics9090514

APA Style

Borham, O., Croxford, B., & Wilson, D. (2024). Biomimetic Strategies for Sustainable Resilient Cities: Review across Scales and City Systems. Biomimetics, 9(9), 514. https://doi.org/10.3390/biomimetics9090514

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