Bioreceptivity

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Bioreceptive Lightweight Concrete, Bartlett School of ArchitectureConcrete materials that are designed to encourage the growth of moss, lichens, and algae that reduce air pollution. Bioreceptive lightweight concrete.jpg
Bioreceptive Lightweight Concrete, Bartlett School of ArchitectureConcrete materials that are designed to encourage the growth of moss, lichens, and algae that reduce air pollution.

Bioreceptivity is defined as "the ability of a material to be colonized by living organisms." [1] First defined by Guillitte in 1995 as a new term in ecology to discuss the beneficial applications of building materials for ecological uses. Previous understandings termed the colonization of organisms as "degradation," implying a negative connotation, leading to the creation of "bioreceptivity" for positive benefits of colonization on materials. [1] It is an interdisciplinary field of study between materials science and ecology.

Contents

Bioreceptive design is commonly mistaken for biomimicry, or nature inspired design. Marco Cruz and Richard Beckett provide an alternative explanation known as architectural bark, in which it is both nature-inspired and nature-integrated where colonization by the microbiome and organisms plays a role in the architectural design. [2] Bioreceptivity is different from green infrastructure, such as green roofs, green walls, and storm water management, but has been observed to be related to these research areas in architecture. Bioreceptive design has led to further research studies in concrete materials for use in urban environments through walls and non-green spaces. [3] However, bioreceptive designs have implications outside creating new green spaces, and can be used for conservation biology and ecological restoration.

Urban ecologies

Living Wall Living wall Blackwelder.jpg
Living Wall

A more recent trend in architectural design has been an effort to include green spaces in public areas to improve the connection between people and nature. However the creation of green spaces includes pressures such as space, natural resource demand, and development limitations that reduce the amount of green spaces available in urban environments.[ citation needed ] Land space is limited due to increased urbanization and human dominated landscapes reduce regional biodiversity. To adapt to these challenges, designers are utilizing the vertical spaces provided by urban architecture to promote biodiversity.[ citation needed ] To address the issue of space availability, wall space has been shown to be a promising area to improve vegetation and native flora, creating an effective method for natural conservation. A "Nature takes its course," method can also allow for vegetation to naturally colonize new urban spaces without economic constraints on landscape design and vegetation selection. [4]

In conservation

Bioreceptive designs help promote biodiversity, and have been used outside of the architectural context for implications in conservation biology.

Examples of Bioreceptive Design

  1. Urban Reef is a company founded by Pierre Oskam and Max Latour to create habitats and promote biodiversity in urban environments. The company utilizes 3D printing with natural materials to create "reef" structures that provide microclimates and nutrients for organisms in city environments.
  2. EcoShape is building Artificial Reefs using ceramics, geo-textiles, bio-rocks, and 3D printing to promote coral reef growth. Utilizing recycled materials they are able to design reef balls that can promote niche habitats for plants and coral, while providing hollow structures for fish and mammals.
  3. Jason deCaires Taylor is an artist who utilizes bioreceptive and pH neutral concrete that promotes coral reef growth and provides ecological restoration in marine environments. Additionally their work has led to the creation of the world's first underwater sculpture park that provides a non-invasive artistic experience without disrupting the marine environment. Taylor's pieces integrate messages on the complexity of human and the environment, while also integrating reflection on conservation.

See also

Related Research Articles

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<span class="mw-page-title-main">Habitat conservation</span> Management practice for protecting types of environments

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<span class="mw-page-title-main">Ecosystem diversity</span> Diversity and variations in ecosystems

Ecosystem diversity deals with the variations in ecosystems within a geographical location and its overall impact on human existence and the environment.

<span class="mw-page-title-main">Ecosystem engineer</span> Ecological niche

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<span class="mw-page-title-main">Ecological engineering</span> Environmental engineering

Ecological engineering uses ecology and engineering to predict, design, construct or restore, and manage ecosystems that integrate "human society with its natural environment for the benefit of both".

<span class="mw-page-title-main">Habitat destruction</span> Process by which a natural habitat becomes incapable of supporting its native species

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<span class="mw-page-title-main">Restoration ecology</span> Scientific study of renewing and restoring ecosystems

Restoration ecology is the scientific study supporting the practice of ecological restoration, which is the practice of renewing and restoring degraded, damaged, or destroyed ecosystems and habitats in the environment by active human interruption and action. Ecological restoration can reverse biodiversity loss, combat climate change and support local and global economies.

<span class="mw-page-title-main">Reconciliation ecology</span> Study of maintaining biodiversity in human-dominated ecosystems

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<span class="mw-page-title-main">Sustainable habitat</span>

A Sustainable habitat is an ecosystem that produces food and shelter for people and other organisms, without resource depletion and in such a way that no external waste is produced. Thus the habitat can continue into the future tie without external infusions of resources. Such a sustainable habitat may evolve naturally or be produced under the influence of man. A sustainable habitat that is created and designed by human intelligence will mimic nature, if it is to be successful. Everything within it is connected to a complex array of organisms, physical resources, and functions. Organisms from many different biomes can be brought together to fulfill various ecological niches.

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This page is an index of sustainability articles.

<span class="mw-page-title-main">Index of environmental articles</span>

The natural environment, commonly referred to simply as the environment, includes all living and non-living things occurring naturally on Earth.

Island ecology is the study of island organisms and their interactions with each other and the environment. Islands account for nearly 1/6 of earth’s total land area, yet the ecology of island ecosystems is vastly different from that of mainland communities. Their isolation and high availability of empty niches lead to increased speciation. As a result, island ecosystems comprise 30% of the world’s biodiversity hotspots, 50% of marine tropical diversity, and some of the most unusual and rare species. Many species still remain unknown.

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<span class="mw-page-title-main">Aquaculture of coral</span> Cultivation of coral for commercial purposes

Coral aquaculture, also known as coral farming or coral gardening, is the cultivation of corals for commercial purposes or coral reef restoration. Aquaculture is showing promise as a tool for restoring coral reefs, which are dying off around the world. The process protects young corals while they are most at risk of dying. Small corals are propagated in nurseries and then replanted on the reef.

Organizations which currently undertake coral reef and atoll restoration projects using simple methods of plant propagation:

References

  1. 1 2 Guillitte, O. (1995-05-01). "Bioreceptivity: a new concept for building ecology studies". Science of the Total Environment. The Deterioration of Monuments. 167 (1): 215–220. Bibcode:1995ScTEn.167..215G. doi:10.1016/0048-9697(95)04582-L. ISSN   0048-9697.
  2. Cruz, Marcos; Beckett, Richard (March 2016). "Bioreceptive design: a novel approach to biodigital materiality". Architectural Research Quarterly. 20 (1): 51–64. doi:10.1017/S1359135516000130. ISSN   1359-1355.
  3. Veeger, M.; Ottelé, M.; Prieto, A. (2021-12-01). "Making bioreceptive concrete: Formulation and testing of bioreceptive concrete mixtures". Journal of Building Engineering. 44: 102545. doi: 10.1016/j.jobe.2021.102545 . ISSN   2352-7102. S2CID   235553835.
  4. Chen, Chundi; Mao, Longfei; Qiu, Yonggui; Cui, Jian; Wang, Yuncai (2020-06-18). "Walls offer potential to improve urban biodiversity". Scientific Reports. 10 (1): 9905. Bibcode:2020NatSR..10.9905C. doi:10.1038/s41598-020-66527-3. ISSN   2045-2322. PMC   7303168 . PMID   32555243.