Hostname: page-component-78c5997874-ndw9j Total loading time: 0 Render date: 2024-11-15T22:51:45.830Z Has data issue: false hasContentIssue false

Of other reefs: designing habitats in blasted seascapes

Published online by Cambridge University Press:  15 October 2024

A response to the following question: Bio-calibrated: tools and techniques of biodesign practices

Rasa Weber*
Affiliation:
Matters of Activity, Cluster of Excellence, Humboldt University of Berlin (DE), Berlin, Germany Interfacing the Ocean - Swiss National Science Research Fund, Zurich University of the Arts, Zurich, Switzerland University of Arts and Design Linz (AT), Linz, Austria Zürich University of the Arts (CH), Zurich, Switzerland
*
Corresponding author: Rasa Weber; Email: [email protected] Website: rasaweber.com
Rights & Permissions [Opens in a new window]

Abstract

Migrating reefs, unprecedented species assemblages, neophytes, toxicities, pollutants, aquatic ruins – The future of coral reefs in the Anthropocene is likely to look different from anything we have experienced so far. While the classic conservation debate on coral reef restoration still treats these ecosystems as “sick patients,” a radically different view of convivial conservation is beginning to challenge exclusive human control over these endangered habitats. Putting aside notions of natural “purity” and adopting a much more humble and highly interconnected perspective on marine habitats, we can begin to see reefs as transformative, sympoïetic and blasted seascapes for a convivial future. The discipline of biodesign has been primarily focussed on researching ecological relationships with regard to new materials and products. The emerging interest in shaping the multi-layered ecological relationships of habitats for other-than-human lives, however, is steering design practice towards terraforming or, in the case of marine environments, “aquaforming.” This paper argues for taking convivial conservation practices in marine environments as a starting point for the development of a new design methodology that focuses on the design of living systems in open environments: a proposed methodology called Sympoïetic Design.

Type
Impact Paper
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial licence (https://creativecommons.org/licenses/by/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the original article is properly cited. The written permission of Cambridge University Press must be obtained prior to any commercial use.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

»I argue against purism not because I want a devastated world, (…). I argue against purism because it is one bad but common approach to devastation in all its forms. It is a common approach for anyone who attempts to meet and control a complex situation that is fundamentally outside our control. «

Alexis Shotwell (Reference Shotwell2016), Against Purity: Living Ethically in Compromised Times: 8.

Introduction

The increasing efforts of ecological design research over the past decade have prepared the ground for bio-based practices in design and the development of new materials. Designers focusing on specific organisms such as mycelium, microalgae, bacteria et al., have begun to adopt laboratory environments, their scientific protocols and tools for developing a new interdisciplinary design research methodology commonly referred to as “biodesign” (Myers, Reference Myers2018; Crawford, Reference Crawford2023). The transition from mining natural resources to cultivating them marks a paradigm shift in a bio-based material production (Hebel & Heisel, Reference Hebel and Heisel2017).

However, given the drastic impact of humanity on planetary systems, the question arises as to whether the bio-based material solutions on offer are sufficient for contemporary ecological design practice to adequately address the multi-layered problems of the climate crisis. Progressive voices in design and architecture are currently discussing the concept of cohabitation as the basis for a new perspective on the built environment that proposes a collaborative project of shared survival.

While architecture has traditionally been regarded as a discipline that provides living space for Homo sapiens, the term “cohabitation” suggests shifting the focus of architectural production to the urban intersections between human and other-than-human species. Beyond the mere provision of living space, authors ask how these new convivial spaces can also be co-designed by a multiplicity of actors (Roudavski, Reference Roudavski, Boess, Cheung and Cain2020).

An in-depth analysis of an emerging field of design concerned with sympoïetic forms of living is necessary and beyond the scope of this publication. Nevertheless, a few examples of the recently developing design landscape should be mentioned here, which takes up the challenge of dealing with multispecies communities in order to create convivial habitat:

Architects Marcos Cruz and Richard Beckett extend the concept of conviviality from the architectural to the microbial level when they propose façades as “bioreceptive” surfaces for the settlement of other-than-human species (Cruz & Beckett, Reference Cruz and Beckett2018). Some recent design projects even go so far as to design entire ecosystems, challenging the exclusive role of architecture for human use and designing ecosystems for marine species (See e.g. Buoyant Ecologies, Architecture Ecologies Lab, California College of Arts, 2017; As Close As We Get, Superflex, 2022), for bees (Mama, Marlene Huissoud, Reference Huissoud2022), for local wetlands (Symbiotic Spaces, Symbiotic Spaces Collective, 2022), or for corals (Coral Brick, Rrreefs e.V.). The design of ecosystems, however, that takes into account the complex roles, needs and relationships of various species is not yet sufficiently methodologically anchored in the field of design.

Furthermore, Het Nieuwe Instituut introduced the “Zoöp” model (co-op = cooperation + zoë = Greek “life”), to provide a legal basis that considers other-than-human species and humans as “collaborative legal entity” (Kuitenbrouwer, Reference Kuitenbrouwer2023) that form a “multispecies community” (Ibid.). This economic framework makes it possible to assess “quality and density of ecological relationships inside and among multispecies” actors (Ibid.), as Klaas Kuitenbrouwer, initiator of the Zoöps, explains.

In their recent discussion of a (non-)modern and (de-)colonial perspective on design practices, designers Claudia Mareis and Nina Paim aptly describe the discipline [a]s a practice deeply linked to the rise of capitalism, industrial mass-culture and the exploitation of both natural resources and human labor (…) [that] contributes to the logic of Western modernity as both enlightening and oppressive, both productive and extractive” (Mareis & Paim, Reference Mareis and Paim2022: 15). Recognizing that design and architecture have been anchored in a deeply anthropocentric worldview for most of their disciplinary existence, the authors therefore conclude that design has inevitably been unable to live up to its own claim to be “universal.” Recently emerging subcategories such as Ontological Design (Winograd & Flores, Reference Winograd and Flores1986; Willis, Reference Willis2006; Escobar, Reference Escobar2018) and Cosmopolitan Design (Yaneva & Zaera-Polo, Reference Yaneva and Zaera-Polo2015), on the other hand, propose a repositioning of the discipline as a situated, non-modern and interspecies collaborative practice.

As architectural theorist Alberta Yaneva and architect Alejandro Zaera-Polo write in their introduction to “What is Cosmopolitical Design? Design, Nature and the Build Environment” (2017), [e]cology has become an alternative to modernization: a new way to handle all the objects of human and non-human collective life” (Yaneva & Zaera-Polo, Reference Yaneva and Zaera-Polo2015: 4). The question therefore arises as to how an ecological practice can be translated into a methodological design approach that addresses the fundamental environmental impacts of ongoing human encroachment on the livelihoods and habitats of countless species – a cosmopolitical approach is needed, as philosopher Isabelle Stengers reminds us, in which the “technical, cultural, social and political dimension” (Stengers, Reference Stengers2015: 102) must inevitably and intimately relate to each other.

In this paper, I argue for a design methodology that focuses on the complex interconnectedness of living systems, including a variety of species communities and the sympoïetic relationship of biotic and abiotic life when creating (artificial) habitats. Designing habitats in open environments is a risky and sometimes messy practice that requires moving beyond a human-centered design approach (Cooley, Reference Cooley1980) in favor of designing for and with other-than-human entities. Based on Donna Haraway’s concept of sympoïesis (Greek: σύν sun = together, ποίησις poïesis = creation) (Haraway, Reference Haraway2016) and its historical reference to the evolutionary principle of symbiogenesis (Mereschkowski, Reference Mereschkowski, Kowallik and Martin1910; Margulis, Reference Margulis1990), this article proposes to call such a practice Sympoïetic Design.

Sympoïetic Design seeks to fill a disciplinary gap by considering the sympoïetic relationships between species as a basis for ecosystem design, as argued in my paper “A Sympoïetic Ocean. Design Research with/in the Marine Holobiont” (Weber, Reference Weber2023).

I use the complex ecological challenges of a rapidly changing ocean as the backdrop to outline the concept of Sympoïetic Design by comparing different strategies of designing artificial reefs – a historical form of aquaforming. By looking at three different examples of artificial reefs through the lens of philosopher Alexis Shotwell, I will take up her argument “against purity” (Shotwell, Reference Shotwell2016) to conceptualize habitat design as a vital strategy of multispecies survival that – impure, compromised and compromising – could play a relevant role in abandoning the ideal of the human as ‘doctor’ of (living) systems. Based on this analysis, I will conclude with a call to action through my own impure and compromised design experiment in the sea.

Designing habitats

In order to approach an unfamiliar habitat, such as the sea, with the means of design research, it is necessary to experience the environment in an immersive and embodied way. Elsewhere I argue in favor of the method of direct immersion in marine ecology through scuba diving as a form of ecological attunement (Despret, Reference Despret2008; Lipari, Reference Lipari2014; Franinović & Kirschner, Reference Franinović, Kirschner, Franke and Matter2021). A comparison of design research and marine biological methods in underwater environments can be found in our forthcoming publication “Attunement to the Ocean. Underwater Methods between Design Research and Marine Biology.” (Weber & Wegner, Reference Weber and Wegner2022).

With the coral holobiont melting in “hot and acid oceans that become more acidic and hotter by the decade” (Haraway, Reference Haraway2016: 72), humans are beginning to create cultivated habitats to provide a fertile substrate for corals, fish, sponges, algae, etc. in an attempt to tackle declining biodiversity. Even if these attempts are undertaken with the best of intentions, they are not free from imposing an inherent “biopolitical regime” (Foucault, Reference Foucault1978; Braverman, Reference Braverman2018; Helmreich, Reference Helmreich2016) on the lives of reef dwellers. To preserve coral life, conservation management is beginning to make irreversible selective choices. Most of these biopolitical measures taken in the context of coral conservation and management are still based on the binary logic of distinguishing between “healthy” and “diseased” habitats, between “native” and “invasive” species, between “pristine” and “anthropogenic” landscapes. Coral propagation has thus become a highly speculative biopolitical practice (Figure 1).

Figure 1. PhD Thesis SYMBIOCEAN, the installed prototype »Kiki« underwater, minus 10 meters. Diver: Noémie Chabrier. Photographer : »Aquanaute« Stéphane Jamme. Location: STARESO – Station de Recherche Sous-Marines et Océanographiques de Calvi, Corsica (FR). Design: Rasa Weber. Date: August 2023.

Our own species’ extensive involvement in coral lives and livelihoods reveals interesting analogies to human reproductive medicine: The establishment of coral nurseries (note the term), as breeding grounds for broken coral branches – assisted spawning of corals in the lab – and the use of Coral-IVF (in vitro fertilization), which raises “corals from their embryonic stage to the level of constant supervision” (Levy, Reference Levy2020: 34), do not only confront us with our productive capacities for care-taking, but also remind us of our hubris toward human responsibility for and stewardship of marine ecosystems. “Coral (…) fates”, as some marine scientists admit, “are not easy to define with certitude (…)” (Stévenne et al., Reference Stévenne, Micha, Plumier and Roberty2021). Following Michel Foucault’s concept of biopower (Foucault, Reference Foucault1978), the question therefore arises as to how much control humans can exercise over life in the sea through highly selective categories that ultimately, to use Foucault’s words, “make live” and “let die.”

The promising claim behind these efforts may be the idea of returning nature to its “original state.” However, this promise also directly raises the question of how to determine such a “pristine” or “natural” state? What parameters, norms and time periods do we clandestinely apply to define the “original” function and species composition of a reef?

Under the term convivial conservation, the conviction that we can preserve an “untouched state of nature” far removed from human influences has recently been problematized by a group of conservationists who are trying to integrate the Anthropocene into their environmental efforts (Reichholf, Reference Reichholf2006; Pearce, Reference Pearce2016; Kegel, Reference Kegel2022, Büscher & Fletcher, Reference Büscher and Fletcher2019, Reference Büscher and Fletcher2020). Convivial conservation, as proposed by political scientist Bram Büscher and Robert Fletcher, breaks with the traditional nature conservation debate, which still promises a return to an “original” or “pristine” landscape, and instead starts from the premise that the claim of a return to a pre-human state is no longer tenable.

Applying the conceptual framework of convivial conservation to the design of marine habitats harbors enormous potential by renegotiating the power relations between humans (as designers) and other living beings and embedding artificial habitats as cultural landscapes in the concept of “nature.” The design of artificial reefs thus provokes an important question: are we preserving and restoring ‘original’ ecosystems, or are we creating new human-environmental co-dependencies that turn coral reefs into cultured habitats?

A brief history of artificial reefs

A look at the history of human-induced cultivation of marine life confirms the assumption that “ecological” measures for nature conservation have always been driven by human, and thus, by resource-related interests: Surprisingly, from a historical perspective, the typology and use of artificial reefs and fish traps, for example, are often blurred to a certain extent and exhibit overlapping functions. By providing rocks and coral rubble as a substrate for the growth of marine life, the earliest (re)construction efforts of reef habitats were primarily aimed to create a fertile ground to increase fish populations (Farrell, Reference Farrell2021) and thus positively influence human fishing practices. Other examples of the dual function of artificial reefs that serve as fish traps are the Brewarrina fish traps of the Australian Aborigines (Martin et. al., Reference Martin, Chanson, Bates, Keenan-Jones and Westaway2023), which, according to estimates, could be up to 40,000 years old; the bamboo traps in the Philippines (Tsuji, Reference Tsuji2009); or the 100-year-old Penghu stone fish weirs, with the “The Double Heart of Stacked Stones” in Taiwan as the best-known example (Chen & Lee, Reference Chen and Lee2023).

Given these historical traces, it seems questionable whether the protection and restoration of coral reefs can be viewed solely as an ecological act of conservation or if these earliest forms of habitat creation were always a sophisticated and long-term project of aquaforming by humans. How pure are our human intentions when shaping habitats?

Impurity by design

Philosopher Alexis Shotwell develops a radical proposition in response to the politics and ethics of complex systemic challenges by suggesting to abandon philosophy’s generalized pursuit of purity and instead embrace “open normativities” (Shotwell, Reference Shotwell2016: 154) and “constitutive impurity” (Ibid.: 1–20) as the starting point of all our human actions. In her disruptive book “Against Purity – living ethically in compromised times” (2016), she further proposes to “understand (…) ourselves as relationally constituted” (Ibid.: 139) within the web of life and its sociopolitical constraints. The concept of impurity that Shotwell introduces to interrogate issues of race, gender, ecology and colonialism also allows for a fundamental shift of perspective when addressing the ongoing human-induced destruction and pollution of habitats. The philosopher makes clear that we are still subject to the fallacy “that we can access or recover a time and state before or without pollution, without impurity, before the fall of innocence, when the world as a whole was truly beautiful.” (Ibid.: 3) In this sense, contrary to popular belief, the Anthropocene does not mark the loss of “a natural state of purity” (Ibid.: 3), but a time of indissoluble co-dependencies.

Shotwell’s plea for impurity, implication and compromise might to some designers and conservationist, that grapple everyday with the challenge of restauration and conservation, seem like a walk on thin ice. It may seem dangerous or even heretic to propose that we adopt our “blasted landscapes of disturbance regimes” (Ibid.: 9), as Shotwell quotes Anna Tsing, as the blueprint for the design of marine habitats. Does the concept of working with blasted seascapes risk abandoning the protection of “nature” to continue our destructive path?

To classify this assumption, it is essential to critically reassess the modernist notion of a “passive nature” as something “out there” (Yaneva & Zaera-Polo, Reference Yaneva and Zaera-Polo2015: 3), as anthropologist Albena Yaneva and architect Alejandro Zaera-Polo’s proposal for “Cosmopolitical Design” boldly argues. The criticism formulated by the authors, which builds on Isabelle Stenger’s “Cosmopolitics I & II” (Reference Stengers2010, Reference Stengers2011), concludes that nature cannot be “mastered by engineers and scientists from outside” (Ibid.: 3).

The design of habitats is a deeply situated act that involves a multitude of actors such as different species, materials, technologies, human disciplines, energy flows, but also their toxicities, pollutants and ruins. Habitat design should therefore no longer be the subject of a clear-cut debate “about ‘nature,’ about conflicting human interests, but about people and wildlife and, more generally, about people and landscapes” (Ibid.: 3); with the inevitable remark that these categories can never be considered as neatly separable.

“Blasted landscapes”, to borrow Eben Kirksey and Anna Tsing’s term (Kirksey, eds., 2014), or in the case of marine habitats – blasted seascapes (Figures 2 and 3) – represent patches of hope in the context of which we must position our current efforts to design and culture habitats. A detailed analysis of the concept of blasted seascapes can be found in my paper “Queer Reefs. A queer ecological journey into blown seascapes” (Weber, Reference Weber2024).

Figure 2. Diving at the remains of a former coral reef. Location: Mega Cruise Pier, Willemstad, Curaçao (ANT). Diver: Mike Duss. Research Project: Symbiocean (2022 – ongoing). Photographer: Rasa Weber. February 2022.

Figure 3. Diving at the remains of a former coral reef. Location: Mega Cruise Pier, Willemstad, Curaçao (ANT). Diver: Mike Duss. Research Project: Symbiocean (2022 – ongoing). Photographer: Rasa Weber. February 2022.

When I speak of Other Reefs, I suggest that we sharpen our understanding of artificial habitat design as a sympoïetic act and, to some degree, relinquish system control. Of Other Reefs is a proposal to conceptualize future reef ecologies as feral, uncurated, chaotic and sympoïetic life forms that reside in the blasted landscapes we ourselves have created. Habitat design is by default an act of impurity, as it always starts from a conflicted, presupposed and compromised environment that has never been pure.

Artificial Reefs – Three case-studies of blasted seascapes

The sometimes deliberate, but often unconscious, choices made in the design of artificial reef habitats provide an interesting window to observe the relationship between us humans and other-than-human species in the way we have historically shaped and culturally constructed these seascapes as projections of “hope.” The following three examples illustrate the contradictory history of reef design as a messy process with/in aquatic “ruins” (Tsing, Reference Tsing and Kirksey2014; Shotwell, Reference Shotwell2016), where success often remains difficult to predict.

Chuuk lagoon

The re-appropriation of the ruins of military disaster by a seemingly pristine ecosystem does not necessarily speak to the unbridled resilience of nature, but could just as well be seen as the emergence of a new ecological alliance between human-made infrastructures and marine ecosystems:

A small atoll in the middle of the Pacific, once the scene of one of the pivotal events of World War II, is today known as one of the “world’s biggest ship graveyard” (Trumbull, Reference Trumbull1972). Chuuk lagoon (formerly Truk Atoll) was a stronghold of Japanese naval power in 1944, claiming nearly 5,000 human lives and the destruction of 265 aircraft (Ibid.) after an attack by the U.S. military, not to mention the casualties among marine organisms. Most of the remains of war stayed under the sea surface and were slowly adopted by marine organisms as a habitat.

Today, almost a century later, Chuuk Lagoon is known for having the highest concentration of “artificial reefs” in the world and attracting a burgeoning dive tourism scene. The genre of dark dive tourism, in which divers are drawn to the morbid charm of a former war site, was partly inspired by Jacques-Yves Cousteau’s famous television documentary “Lagoon of Lost Ships” (1972), which focuses on the romantic notion of life thriving amidst ruins. Cousteau puts it aptly in his unmistakable voiceover:

»I am struck by a contrast. In the dry world above, fragmented structures loom in rusted ugliness. But here, beneath the surface of the lagoon, the skeletal remains are fleshed out with new life; They blossom with myriads of creatures.«

Jacques-Yves Cousteau (1972). Lagoon of Lost Ships, minute 16:36.

The case of Chuuk Lagoon seems to confirm the conventional belief that marine life thrives everywhere anyway. The lagoon and its medial portrayal feed the normative divide between a “pure” coral reef and its “encroachment” by human presence; In this case the ruins of ships and airplanes, which must be “reclaimed” by an all-enduring “wilderness.” The case provides ideal justification to the claim that we simply need to “let nature do its thing” (Lewis, Reference Lewis2019: 264) – a slogan that all too easily drifts into Neo-Darwinian notions of evolution as having a steadily progressive character.

Recognizing that reefs have never been pure and that we need to deepen our awareness of the destructive forces that we humans unleash when we encroach on land- and seascapes anywhere on this planet does not mean that we applaud governments and industries for the irreparable damage they inflict on people and ecosystems. As Shotwell points out, “being against purity does not mean being for pollution” (Shotwell, Reference Shotwell2016: 9)! As we observe the transformation and reclaiming of catastrophic environments into new habitats, we must recognize that we ourselves become part of this mutating nature, establishing ourselves in irreversibly altered conditions. A toxic relationship.

The subway reef program

The romantic belief that the environment can easily recover under any unfortunate circumstances due to its “resilience” risks rendering any conservation efforts moot. Ultimately, however, the design of artificial reefs is not as simple as is commonly assumed:

As part of the U.S. Subway Reef Program, 2,500 decommissioned subway cars were sunk in the Atlantic as a substrate for reef building organism. The video work “Ocean II Ocean” (2019) by artist Cyprien Gaillard poetically documents the almost ceremonial sinking of the stainless steel “brightliners” after 58 years of their service. The subway cars were carefully cleaned and shipped to the coasts of Delaware, Georgia, New Jersey, Maryland, South Carolina and Virginia as part of the federal program to promote marine growth, which ran from 2001 to 2010 initiated by the City of New York. In addition to the motivation of supporting the recreational fishing and diving industries, the project presumably saved the New York City Subway an estimated $30 million that would have been required to scrap the railcars in a land-based program.

Ironically, the Subway Reef Program did not go as planned. To this day, the Subway Reef Program is controversially debated as either a successful or failed ecological restoration measure. While some of the discarded steel skeletons became a substrate for new forms of marine life, a larger proportion of the wagons, which were to remain in the sea for at least 25 years, quickly decomposed due to their unsuitable material composition and have been lying around on the seabed ever since. Much of the steel skeletons probably never served their purpose of supporting marine growth and are now another scattered and fragmented legacy of human presence in the ocean. After all, designing an artificial reef habitat may not be quite so simple.

The Osborne Reef

The practice of dumping industrial waste into the sea as a “living substrate” is likely to be taken to extremes by the Osborne Reef, which has sadly gained notoriety as one of the biggest environmental disasters in the history of the ocean:

In the 1970s, Broward Artificial Reef Inc. launched an artificial reef development program on the Florida coast with an ambitious plan to build the world’s longest artificial reef project by dumping 2 million discarded car tires into the ocean initiated by the Goodyear Tire and Rubber Company with the support of the U.S. Navy. Alarmingly, the tire bundles soon broke loose and turned into dangerous projectiles, destroying all marine life in their way. The Osborne Reef project began with a disastrous alliance of conservation policy and the industry – a coupling we should always view with great suspicion. Today, more than 50 years later, private companies are still busy capitalizing on attempts to clean up the disaster site.

A plea against healthism

Aside from the fact that marine restoration practices are much more delicate and complex than we humans are willing to admit, the ecological, infrastructural, material and technological layers of what architects Brugidou & Clouette refer to as “anthropOcean” (Reference Brugidou and Clouette2018) need to be negotiated in the design of marine habitats. The messy, complex and unpredictable reefs ecosystems do not demand that we continue our destructive path in a “whatever works” logic, assuming that life will thrive anyways. Rather, they suggest that our usual conservation methods need to act as a counter to the capitalist logics of conservation policies and adapt to the changing dynamics of crisis-ridden oceans.

If corals begin to migrate to cooler hemispheres f. ex. (Sakar, Reference Sakar and JN2017; Chaudhary et al., Reference Chaudhary, Alfaro-Lucas, Simões, Brandt and Saeedi2023), which species should we consider as aliens or neophytes of the future? Some marine biologists thus state that, “Coral reef ecosystems of the future, and the associated management/governance approaches used to protect them, are probably going to be unlike anything previously seen. (…)” (Bellwood et al., Reference Bellwood, Pratchett, Morrison, Gurney, Hughes, Álvarez-Romero, Day, Grantham, Grech, Hoey, Jones, Pandolfi, Tebbett, Techera, Weeks and Cumming2019: 608). So, the question is: “What needs to be managed, why and how?” (Ibid.: 608)

However, some voices in the discourse on coral reef conservation and restoration techniques still advocate treating these ecosystems as if they were a “sick patient” (Earle, Reference Earle1996; Goreau et al., Reference Goreau, Larson and Campe2015):

The Biorock technology, for example, developed by architect Wolf Hilbertz and biochemist Tom Goreau in the 1970s, is a technique for creating a bioreceptive substrate for the growth of endangered coral species (Hilbertz, 1979 & Reference Hilbertz1987; Weber, Reference Weber2022). It works by electrolysis in seawater to deposit limestone onto conductive steel structures, which then serve as a substrate for the restoration of marine life. Significantly, Tom Goreau eventually named his technology “electrotherapy” (Goreau, Reference Goreau2022) – a name that suggests it is a “cure” for deteriorating marine ecosystems. In this context, Goreau also brings up the concept of “geotherapy.” With unwavering optimism, he explains: “There’s a one-word term for Healing Earth: Geotherapy, regenerating the planet’s natural life support systems, like a doctor prescribes a cure to restore a sick patient to health” (Goreau, Reference Goreau2019).

Surprisingly, even diver and biologist Sylvia Earle states in a similar tone “that effective restoration efforts are comparable to the actions of doctors treating a sick patient” (Earle, Reference Earle1996: 303, emphasis added). Yet, Earle also admits that restauration processes can frighteningly easy lead to disruption and destruction and that “true healing” (Ibid.: 303, emphasis added) cannot necessarily be achieved through acceleration and “quick-fix solutions” (Ibid.), but rather through “time and active, natural processes that are beyond human understanding” (Ibid.). Meanwhile, Goreau even goes so far as to claim that technology may be able to “restor[e] ecosystems to reverse global warming” (Goreau [online], 2014, emphasis added). During an interview, however, Goreau qualified this statement, as follows: “I am not in favor of geoengineering. I am in favor of the natural mechanisms. But we are now at that point where that may not be enough” (Goreau & Weber, Reference Goreau and Weber2023, minute 28:30).

But what is enough?

Given the recent U.N. report that climate change is on the brink of “catastrophic warming” (U.N. IPCC, 2023), which might lead to unprecedented mass bleaching in 2024 (Einhorn, Reference Einhorn2024) and the resulting impacts on ocean temperatures, that are turning the distribution of corals into a patchy landscape under constant threat (Ocean warming map: earth.nullschool.net), it seems hard to question any effort to “try[…] to protect what we have while we can” (Goreau & Weber, Reference Goreau and Weber2023, minute 28:20).

If we move away from what Shotwell calls “healthism” (Shotwell, Reference Shotwell2016: 29) – which sees individual health (of humans, other species, ecosystems) as a given moral imperative – we may be able to develop a much more modest and highly interconnected view of marine habitats. “Health”, as Shotwell points out, “is a contingent, multivalent and complexly intertwined” issue that is linked to “social and material environments” (Ibid.: 30). And here at least Goreau might agree with Shotwell’s call for “collective response to collective harm” (Ibid. p. 30) when he claims: “I am more worried about the extinction of the ecosystem itself than the species” (Goreau & Weber, Reference Goreau and Weber2023, minute 27:50).

How can we collectively respond to the collective harm inflicted on marine ecosystems? How does an artificial reef look like that does not aim to reconstruct a pre-human coral reef? How do you design an ecosystem without claiming to “heal” nature?

The first attempts to consider unconventional norms for ecological conservation are making their appearance in the debate: When the Danish art studio Superflex places its pink underwater sculptures as “fish architecture” in the harbor of Copenhagen, it deliberately choses for a habitat-driven design approach in an ecosystem that cannot be perceived as “pure” (Superflex, 2022). Furthermore, the “Rigs-to-Reefs” practice (Pereira et al., Reference Pereira, Omotuyi, Koenck, Obani, Gopaulsingh and Mohammed2023) proposes to repurpose decommissioned offshore oil and petroleum platforms as artificial habitats for marine life, assuming that the overlap of human infrastructure and marine life should be considered in the conservation debate (although it should be noted that this practice could be an all-too-easy exit for oil companies). Finally, the growing interest of marine biologists in commercial harbors as unexpected places to promote marine biodiversity (Madon et al., Reference Madon, David, Torralba, Jung, Marengo and Thomas2023) is leading to promising ideas beyond the distinction of “pristine” nature and “artificial” habitat, with the port of Marseille being one of the most popular experimental sites.

Working with coral reefs as “feral ecologies” that represent “ecological worlds created when non-human entities become tangled up with human infrastructure projects” (Tsing et al., [online] 2021) requires a twofold and thus delicate positioning: On the one hand, it must be acknowledged that there may be no cure, as any of our well-intentioned actions will always fall victim to the larger changes at stake in our current “catastrophic times” (Stengers, Reference Stengers2015). Recognizing that we are the cause of the crisis does not necessarily empower us to solve it. On the other hand, this realization must also be understood as a clear call to action! Again, Shotwell might be of help here when she says: “Listening well, taking responsibility and acting even though we recognize that we can’t be pure is going to be much harder than disengaging would be. (Shotwell [online], Reference Shotwell2017) So, how can we act when those actions are always compromised?

The seascape has always been subject to intense human impact and is in a constant state of change. For us, designers and humans, looking at the marine environment is an opportunity to understand that working on coral reefs is not just about treating the “health” of an affected ecosystem, but is fundamental to securing our own human existence – the doctor is therefore the patient.

An/Other reef – Kiki as a marine case-study

»The point, however, is to change it.« (Shotwell, Reference Shotwell2016: 195)

Moved by Shotwell’s words, I conducted a field study on the design of a marine habitat in the Mediterranean. As part of my dissertation project “SymbiOcean”, in which I am investigating the design of artificial reefs in marine environments, I developed a submerged prototype that probes open normativities in marine conservation. The structure was placed underwater in June 2023 at the STARESO scientific research station in Corsica (FR). Based on the Biorock principle (Hilbertz, US patent, 1995–2015: US5543034A), which enables the accretion of minerals in seawater through electrolysis, I designed a woven structure that slowly solidifies into a limestone-like material (Weber, Reference Weber2022) and serves as a substrate for the growth of marine life. The 2.5-m-wide sphere is designed as a lightweight scaffold made of a steel frame and filigree conductive steel yarns (Figure 4), connected to a solar panel on land, which supplies the structure with low voltage current to trigger electrolysis.

Figure 4. PhD Thesis SYMBIOCEAN, placing the prototype »Kiki« underwater, minus 3 meters. Divers: Noémie Chabrier, Mathieu Kelhetter, Rasa Weber, Anja Wegner. Location: STARESO – Station de Recherche Sous-Marines et Océanographiques de Calvi, Corsica (FR). Photo: Mathieu Kelhetter. Design: Rasa Weber. Date: June 2023.

We named the structure “Kiki” (French for “cute”) in ironic recognition of its enormous size and the incredible challenge of placing the structure in deep water (Figure 4). It took us two dives, a total of six divers and a boat to bring “Kiki” to her new home at minus 10 m (Figure 7). I have literally never used my fins to walk on the seabed while dragging a beast!

Figure 5. PhD Thesis SYMBIOCEAN, assembly of the prototype »Kiki«. In the photo: Rasa Weber. Location: STARESO – Station de Recherche Sous-Marines et Océanographiques de Calvi, Corsica (FR). Photo: Mathieu Kelhetter. Design: Rasa Weber. Date: June 2023.

The prototype functions as a contact zone between different species and challenges the role of design as a human-centered practice by attempting to relinquish selective control over the composition of species. By abandoning these selective choices normally applied in the creation of artificial reefs (through fragmentation and transplantation) it argues in favor of a feral proliferation of so-called “pioneer organisms” that slowly begin to inhabit the structure.

Design anthropologists Åsa Ståhl and Kristina Lindström state that “a crucial (…) practice in design anthropology is the crafting of invitations” (Ståhl & Lindström, Reference Ståhl, Lindström, Smith and Vangkilde2016: 183, emphasis added). While their idea was primarily formulated in terms of human interactions, the design of habitats similarly represents an open invitation to different life forms to settle on, or interact with it. In this sense, “Kiki” could be described as an invitation for marine dwellers – an invitation that can be accepted or declined (Figure 5).

Figure 6. Participants help to weave the conductive looms of »Kiki«. Left and below: Teal. Right: Julian. Place: STARESO – Station de Recherche Sous-Marines et Océanographiques de Calvi, Corsica (FR). Photo: Rasa Weber. Design: Rasa Weber. Date: June 2023.

When making the prototypes, I also realized that weaving the looms proves to be a fantastic communication tool for collaboration with my human participants (biologists, sound artists, children) (Figure 6): A way of weaving together – or, as designer Svenja Keune put it, a way of “weaving entangled worlds” (Keune, Reference Keune2021). On the one hand, the prototype is literally an object of dialogue that invites people to weave together; on the other hand, it interweaves the design field with conservation biology and the socio-political sphere.

Figure 7. PhD Thesis SYMBIOCEAN, the prototype »Kiki« with first layer of pioneering organisms (left) and after its destruction by a storm (right). Location: STARESO – Station de Recherche Sous-Marines et Océanographiques de Calvi, Corsica (FR). Photo: Noémie Chabrier. Design: Rasa Weber. Date: November 2023.

“Kiki” illustrates the attempt to collaborate with sea organisms and co-create a habitat, as well as it grapples with ocean forces, the currents, the tides, the changing seasons in the Mediterranean and much longer periods of time.

STARESO staff monitored the project with 360° cameras and underwater action cams to demonstrate its slow transformation through the interaction with the local ecosystem. Ultimately, the design of Kiki as an artificial reef was influenced not only by the collaboration of various humans involved in its production process, but also by sea dwellers such as algae, fish and sponges that temporarily inhabited the structure, by currents that shaped and eventually even distorted its appearance and by material flows that influenced its species composition.

The prototype bore the wounds of collisions with underwater rocks (Figure 4), was deformed by currents, began to accumulate some algae colonies (Cladophora glomerata) and attracted schools of fish (Chromis chromis) since its first deployment in the sea.

“Kiki” remained submerged on the coast of Punta de la Revellata for six months until a Corsican storm decided otherwise and took her apart. “The queer art of failure” – to paraphrase Jack Halberstam (Reference Halberstam2011) – demands to be continued. The prototype questions the category of “brokenness” as a norm applied from a human perspective. When Shotwell reminds us how important it is to change things beyond pure or flawless solutions, she also calls for a change of perspective: a broken design object – broken for whom? (Figure 8).

Figure 8. PhD Thesis SYMBIOCEAN, the installed prototype »Kiki« underwater, minus 10 meters. Diver & photographer: Noémie Chabrier. Location: STARESO – Station de Recherche Sous-Marines et Océanographiques de Calvi, Corsica (FR). Design: Rasa Weber. Date: July 2023.

Conclusion

Working on Other Reefs always carries the risk of getting it wrong in the end. Rather than restoring “pristine nature”, these co-created habitats encourage architects and designers to relinquish control of the system and incorporate feral life forms and environmental forces into their design process. These habitats are created to establish “open normativities” in the conservation debate through a design practice that prioritizes conviviality and co-authorship over a human-centered design approach. An unpredictable process of Sympoïetic Design.

I will therefore conclude with Shotwell’s words: “We need practices of open normativities to pursue visions and practices that are hospitable to future worlds to determine what deserves a future” (Shotwell, Reference Shotwell2016: 163). It will be the subject of our convivial negotiations to formulate these open normativites. Who will be involved in designing a marine habitat for and with corals, sponges, humans, limestone, electrical circuits, technologies, climatic conditions, fish, storms, material flows, bacteria and algae in those blasted seascapes we currently inhabit?

Data availability statement

All data which is generated within the PhD Thesis “SYMBIOCEAN” as part of the Swiss National Science Fund research project “Interfacing the Ocean” will be saved and made accessible via the Medienarchiv of Zurich University of the Arts.

Acknowledgements

I would like to thank Station de Recherches Sous-Marine et Océanographiques de Calvi (STARESO) for their ongoing support and collaboration in monitoring my structures. My PhD-supervisors Karmen Franinović and Karin Harrasser for their fruitful critique. The entire team of collaborators including: Arnaud Boulenger, Sandra Bracun, Noemi Chabrier, Mélodie Chapat, Sylvain Coudray, Stéphane Jamme, Leonie John, Alex Jordan, Teal Jordan, Michael Karle, Mathieu Kelhetter (design intern), Michaela Roger, Bram van der Schoot, Kelly Stiver, Anja Wegner, Lena Wesenberg, Aubin Woehrel and all the other divers that helped me to install and monitor Kiki.

Financial support

This PhD project is funded by the Swiss National Science Fund project ‘Interfacing the Ocean’ led by Prof. Dr. Karmen Franinović and Dr. Roman Kirschner at Zurich University of the Arts, conducted together with PhD researchers Antoine Bertin and Anthea Oestreicher. The doctorate takes place within the practice-based PhD program cooperation between Zurich University of the Arts and University of Arts and Design Linz, supervised by Prof. Dr. Karmen Franinović (Design) and Dr. Karin Harrasser (Cultural Theory, University of Arts and Design Linz). As associated member, Rasa Weber has further joined the Cluster of Excellence “Matters of Activity” at Humboldt University of Berlin in 2022 and is part of its PhD research cohort. This research was supported by the Interaction Design Department of Zurich University of the Arts, PROCOPE Mobility Grants by EFG & the French Embassy of Berlin, the “Material Form Function” research group of “Matters of Activity. Cluster of Excellence.” and the mobility grant of Linz University of Arts and Design.

Competing interests

Author Rasa Weber is employed at Zurich University of the Arts and part of the Swiss National Science Research Fund project ‘Interfacing the Ocean’ at ZHdK with PIs Karmen Franinović and Roman Kirschner. The author’s thesis ‘SymbiOcean’ is supervised by Karmen Franinović (ZHdK) & Karin Harrasser (Linz University of Arts and Design). Rasa Weber is a research associate at Humboldt University of Berlin, ‘Matters of Activity’ Cluster of Excellence. The author has retrieved grants from PROCOPE Mobility Fund of French Embassy Berlin and DAAD, from the Transdiciplinary Artistic PhD program at Zurich University of the Arts and from travel grant of Linz University of Art and Design.

References

Connections references

Diniz, N (2023) Bio-calibrated: tools and techniques of biodesign practices. Research Directions: Biotechnology Design 1, e10. https://doi.org/10.1017/btd.2023.4.CrossRefGoogle Scholar

References

Architecture Ecologies Lab (2017) Buoyant Ecologies. California College of Arts. Available at https://www.architecturalecologies.cca.edu/research/buoyant-ecologies-float-lab. Retrieved August 8, 2023.Google Scholar
Barua, M (2021) Feral ecologies: The making of postcolonial nature in London. Journal of the Royal Anthropological Institute 23(3), 896919. https://doi.org/10.1111/1467-9655.13653.Google Scholar
Bellwood, DR, Pratchett, MS, Morrison, TH, Gurney, GG, Hughes, TP, Álvarez-Romero, JG, Day, JC, Grantham, R, Grech, A, Hoey, AS, Jones, GP, Pandolfi, JM, Tebbett, SB, Techera, W, Weeks, R, and Cumming, GS (2019) Coral reef conservation in the Anthropocene: Confronting spatial mismatches and prioritizing functions. Biological Conservation 236, 604615.CrossRefGoogle Scholar
Braverman, I (2018) Coral Whisperers: Scientists on the Brink. Oakland, CA: University of California Press. https://doi.org/10.2307/j.ctvq4c11g.Google Scholar
Brugidou, J and Clouette, F (2018) ‘AnthropOcean’: Oceanic perspectives and cephalopodic imaginaries moving beyond land-centric ecologies. Social Science Information 5(3), 359385. https://doi.org/10.1177/0539018418795603.CrossRefGoogle Scholar
Büscher, B and Fletcher, R (2020) The Conservation Revolution: Radical Ideas for Saving Nature Beyond the Anthropocene. London and New York: Verso London.Google Scholar
Büscher, B and Fletcher, R (2019) Towards convivial conservation. Conservation & Society 17(3), 283296.CrossRefGoogle Scholar
Chaudhary, C, Alfaro-Lucas, JM, Simões, MVP, Brandt, A, and Saeedi, H (2023) Potential geographic shifts in the coral reef ecosystem under climate change. Progress in Oceanography 213, 10300. https://doi.org/10.1016/j.pocean.2023.103001.CrossRefGoogle Scholar
Chen, C-Y and Lee, M-J (2023) Evolution of stone fish weirs in Jibei area, Penghu Archipelago (eighteenth to twenty-first century). Journal of Maps 19, 1. https://doi.org/10.1080/17445647.2023.2277904.CrossRefGoogle Scholar
Cooley, M (1980) Architect or Bee?: The Human Price of Technology. Nottingham: Spokesman Books (2016).Google Scholar
Crawford, A (2023) A Designers Guide to Lab Practice. London: Routledge. https://doi.org/10.4324/9781003363774.CrossRefGoogle Scholar
Cruz, M and Beckett, R (2018) Bioreceptive design: A novel approach to biodigital materiality. Architectural Research Quarterly 20(1), 5164.CrossRefGoogle Scholar
David, JS (2005) Representing place: “Deserted Isles” and the reproduction of Bikini Atoll. Annals of the Association of American Geographers 95(3), 607625.Google Scholar
Despret, V (2008) The becomings of subjectivity in animal worlds. Subjectivity 23, 123139.CrossRefGoogle Scholar
Earle, S (1996) Sea Change: A Message of the Oceans. New York: Ballantine Books.Google Scholar
Einhorn, C (2024) The widest-ever global coral crisis will hit within weeks, scientists say. New York Times. Available at https://www.nytimes.com/2024/04/15/climate/coral-reefs-bleaching.html. Retrieved April 19, 2024.Google Scholar
Escobar, A (2018) Design for the Pluriverse. Radical Interdependence, Autonomy, and the Making of Worlds. Durham and London: Duke University Press.CrossRefGoogle Scholar
Farrell, MD (2021) Artificial reefs: A history, a science, a technology. Honors Theses. Paper 1318. Available at https://digitalcommons.colby.edu/honorstheses/1318.Google Scholar
Franinović, K and Kirschner, R (2021) Interacting in entangled environments. In Franke, B and Matter, H (eds.), Not at your Service, Manifestos for Design. Zürich: Zürcher Hochschule der Künste: 249260.Google Scholar
Foucault, M (1978) History of Sexuality I: The Will to Knowledge. New York: Random House.Google Scholar
Frohn, M, Weisser, WW and Hauck, TE (2022) Manifest für eine Architektur der Cohabitation. Exhibition & Website at Floating Berlin. Available at https://animal-aided-design.de/wp-content/uploads/2022/05/Mainfest_Cohabitation.pdf. Retrieved April 19, 2024.Google Scholar
Gaillard, C (2019) Ocean II Ocean. (Artwork. Film.) [Online]. USA: IFFR 2020; Sales: Sprüth Magers.Google Scholar
Goreau, TJF and Weber, R (2023) Zoom Interview: A Conversation on Restauration, Conservation and Reconstruction of Marine Habitats. Massachusetts and Berlin: Medienarchiv Zurich University of the Arts.Google Scholar
Goreau, TJF (2022) Coral reef electrotherapy: Field observations. Frontiers in Marine Science 9, 805113. https://doi.org/10.3389/fmars.2022.805113.CrossRefGoogle Scholar
Goreau, TJF (2019) A review of John Todd, 2019, HEALING EARTH: An ecologist’s journey of innovation and environmental stewardship. Available at https://www.globalcoral.org/a-review-of-john-todd-2019-healing-earth-an-ecologists-journey-of-innovation-and-environmental-stewardship/. Retrieved August 4, 2023.Google Scholar
Goreau, TJF, Larson, RW, and Campe, J (2015) Geotherapy. Innovative Methods of Soil Fertility Restoration, Carbon Sequestration, and Reversing CO2 Increase. Boca Raton: CRC Press.Google Scholar
Goreau, TJF (2014) Restoring ecosystems to reverse global warming. In Biodiversity for a Livable Climate Conference. Available at https://bio4climate.org/video/thomas-goreau-the-down-to-earth-solution-to-global-warming-how-soil-carbon-sequestration-works/. Retrieved August 7, 2023.Google Scholar
Halberstam, J (2011) The Queer Art of Failure. Durham and London: Duke University Press. https://doi.org/10.2307/j.ctv11sn283.Google Scholar
Haraway, DJ (2016) Staying with the Trouble. Making Kin in the Chthulucene. Durham and London: Duke University Press.Google Scholar
Hebel, D and Heisel, F (2017) Cultivated Building Materials. Industrialized Natural Resources for Architecture and Construction. Basel: Birkhäuser Verlag GmbH.CrossRefGoogle Scholar
Helmreich, S (2016) Sounding the Limits of Life: Essays in the Anthropology of Biology and Beyond. Princeton and Oxford: Princeton University Press.CrossRefGoogle Scholar
Hilbertz, WH (1987) Electro accretion: Grow shelters from sea materials. Newton, MA.Google Scholar
Hilbertz, WH (1979) Electrodeposition of minerals in sea water: experiments and applications. IEEE Journal on Oceanic Engineering OE-4(3).Google Scholar
Hughes, TP, Barnes, ML, Bellwood, DR, Cinner, JE, Cumming, GS, Jackson, JBC, Kleypas, J, van de Leemput, IA, Lough, JM, Morrison, TH, Palumbi, SR, van Nes, EH and Scheffer, M (2017) Coral reefs in the Anthropocene. Nature 546(7656), 8290.CrossRefGoogle Scholar
Huissoud, M (2022) Mama. (Designwork). Tulum, Mexico: SFER IK MUSEUM. Available at https://www.marlene-huissoud.com/mama. Retrieved August 7, 2023.Google Scholar
Jeffrey, B (2004) World War II underwater cultural heritage sites in Truk Lagoon: Considering a case for world heritage listing. The International Journal of Nautical Archaeology 33(1), 106121. https://doi.org/10.1111/j.1095-9270.2004.009.x.CrossRefGoogle Scholar
Kegel, B (2022) Die Natur der Zukunft. Tier- und Pflanzenwelt in Zeiten des Klimawandels. Köln: Dumont.Google Scholar
Keune, S (2021) Designing and living with organisms weaving entangled worlds as doing multispecies philosophy. Journal of Textile Design Research and Practice, 9(1), 930. https://doi.org/10.1080/20511787.2021.1912897.CrossRefGoogle Scholar
Kuitenbrouwer, K (2023) Introducing Zoöps. Rotterdam: Het Nieuwe Insituut. Available at https://nieuweinstituut.nl/en/projects/who-is-we/zoop. Retrieved: August 7, 2023.Google Scholar
Levy, S (2020) For the love of corals: life in the ruins of the museum [Online]. In Latour B and Weibel P. (eds.), Critical Zones. The Science and Politics of Landing on Earth. Cambridge, MA: MIT Press with ZKM | Center for Art and Media Karlsruhe and TBA21: 32–35.Google Scholar
Lewis, P (2019) The impact of ecological thought on architectural theory. PhD thesis, Robert Gordon University. https://openair.rgu.ac.uk. Retrieved April 20, 2024.Google Scholar
Lipari, L (2014) Listening, Thinking, Being: Towards an Ethics of Attunement. Pennsylvania: The Pennsylvania State University Press.Google Scholar
Madon, B, David, R, Torralba, A, Jung, A, Marengo, M, and Thomas, H (2023) Rreview of biodiversity research in ports: Let’s not overlook everyday nature! Ocean & Coastal Management 241(1): 106623. https://doi.org/10.1016/j.ocecoaman.2023.106623.Google Scholar
MacDougall, W (1974) Twenty-eight years after atom blast, The Bikinians return home. U.S. News and World Report 77(16 December), 5254.Google Scholar
Mareis, C and Paim, N (eds.) (2022) Design Struggles. An Attempt to Imagine. Design Otherwise. Plural: Valiz, Amsterdam.Google Scholar
Margulis, L (1990) Words as battle cries: Symbiogenesis and the new field of endocytobiology. BioScience 40(9), 673677.CrossRefGoogle ScholarPubMed
Martin, S, Chanson, H, Bates, B, Keenan-Jones, D, and Westaway, MC (2023) Indigenous fish traps and fish weirs on the Darling (Baaka) River, south-eastern Australia, and their influence on the ecology and morphology of the river and floodplains. Archaeology in Oceania 58, 91114. https://doi.org/10.1002/arco.5279.CrossRefGoogle Scholar
Mereschkowski, K (1910) The origin of symbiogenesis: An annotated English translation of Mereschkowsky’s 1910 paper on the theory of two plasma lineages. In Kowallik, KV and Martin, WF (eds.), Biosystems (2021), vol. 199, 104281.Google Scholar
Myers, W (2018) Bio Design: Nature • Science • Creativity. London: Thames & Hudson Ltd.Google Scholar
Pearce, F (2016) The New Wild: Why Invasive Species Will Be Nature’s Salvation. Boston: Beacon Press.Google Scholar
Pereira, EG, Omotuyi, O, Koenck, A, Obani, P, Gopaulsingh, M, Mohammed, S (2023) Decommissioning offshore oil and gas platforms: Is the rigs-to-reefs program a more sustainable alternative? Journal of Sustainable Development Law and Policy (The) 14(1), 126. doi: 10.4314/jsdlp.v14i1.2s.CrossRefGoogle Scholar
Rrreefs, V (2022) Coral Brick. (Designwork). Available at https://www.rrreefs.com. Retrieved 7 August 2023.Google Scholar
Reichholf, JH (2006) Die Zukunft der Arten: Neue Ökologische Überraschungen. Beck.Google Scholar
Reverter, M, Helber, SB, Rohde, S, de Goeij, JM, and Schupp, PJ (2021) Coral reef benthic community changes in the Anthropocene: Biogeographic heterogeneity, overlooked configurations, and methodology. Global Change Biology 28(6), 19561971. https://doi.org/10.1111/gcb.16034.CrossRefGoogle Scholar
Rosen, KM (1971) Lagoon of lost ships. In Cousteau, J-Y, Cousteau, P, Sterling, R (eds.), TV Documentary. Chuuk Lagoon: Micronesia.Google Scholar
Roudavski, S (2020) Multispecies cohabitation and future design. In Boess, S, Cheung, M and Cain, R (eds.), Synergy - DRS International Conference 2020, 11-14 August. London: Design Research Society, DRS Digital Library. https://doi.org/10.21606/drs.2020.402.Google Scholar
Sakar, C (2017) Coral bleaching and migration: Steps for integrated management. In JN, Govil (ed.), Environmental Science and Engineering, Vol. 2. Biodiversity and Conservation. Texas: Studium Press LLC.Google Scholar
Scott, S (2017) What Bikini Atoll looks like today. Sixty years after the nuclear tests, the groundwater is contaminated and the coconuts are radioactive. But are the coral reefs thriving? Stanford Magazine. Available at https://stanfordmag.org/contents/what-bikini-atoll-looks-like-today. Retrieved August 4, 2023.Google Scholar
Shotwell, A (2017) A politics of imperfection, a politics of responsibility. Available at https://alexisshotwell.com/2017/04/25/a-politics-of-imperfection-a-politics-of-responsibility/. Retrieved 8 August 2023.Google Scholar
Shotwell, A (2016) Against Purity. Living Ethically in Compromised Times. Minneapolis: Minnesota Press.Google Scholar
Ståhl, A and Lindström, K (2016) Politics of inviting: Co-articulations of issues in designerly public. In Smith, RC and Vangkilde, KT, et al. (eds.), Design Anthropological Futures. London: Bloomsbury Academic.Google Scholar
Stengers, I (2010) Cosmopolitics I. Minneapolis: Minnesota Press.Google Scholar
Stengers, I (2011) Cosmopolitics II. Minneapolis: Minnesota Press.Google Scholar
Stengers, I (2015) In Catastrophic Times: Resisting the Coming Barbarism. London: Open Humanities Press.Google Scholar
Stévenne, C, Micha, M, Plumier, J-C and Roberty, S (2021) Corals and sponges under the light of the Holobiont concept: How microbiomes underpin our understanding of marine ecosystems. Frontiers in Marine Science 8, 698853. https://doi.org/10.3389/fmars.2021.698853.CrossRefGoogle Scholar
Superflex (2022) As close as we get. (Artwork). Available at https://superflex.net/works/as_close_as_we_get. Retrieved August 7, 2023.Google Scholar
Symbiotic Spaces Collective (2022) Symbiotic Spaces. (Designwork). Available at https://www.google.com/search?client=safari&rls=en&q=symbiotic+spaces&ie=UTF-8&oe=UTF-8. Retrieved August 7, 2023.Google Scholar
Trumbull, R (1972) The ‘Graveyard’ Lure of Truk Lagoon. New York Times. Available at https://select.nytimes.com/gst/abstract.html?res=F10813FC3F5F117B93C2AA178FD85F468785F9&scp=1&sq=The%20%27Graveyard%27%20Lure%20of%20Truk%20Lagoon&st=cse. Retrieved August 8, 2023.Google Scholar
Tsing, AL (2014) Blasted landscapes (and the gentle art of mushroom picking). In Kirksey, E (ed.), The Multispecies Salon. London & Durham: Duke University Press.Google Scholar
Tsing, AL, Deger, J, Saxena, AK, and Zhou, F (2021) FERAL ATLAS. The More-Than-Human Anthropocene. Stanford: Stanford University Press. https://doi.org/10.21627/2020fa.Google Scholar
Tsing, AL, Mathews, A, and Bubandt, N (2019) Patchy Anthropocene: Landscape structure, multispecies history, and the retooling of anthropology. Current Anthropology 60(20), 186–197.CrossRefGoogle Scholar
Tsing, AL (2015) The Mushroom at the End of the World: On the Possibility of Life in Capitalist Ruins. Princeton: Princeton University Press.Google Scholar
Tsuji, T (2009) Ecology and technology of bamboo fish traps in the Visayas, Philippines; with special reference to the Moray Trap. In Conference: 19th Congress of Indo-Pacific Prehistory Association.Google Scholar
U.N. IPCC (2023) AR6 Synthesis Report: Climate Change 2023. Available at https://www.ipcc.ch/report/ar6/syr. Retrieved August 8, 2023.Google Scholar
Weber, R (2024) Queer reefs. A queer ecological journey into blasted seascapes. Kritische berichte 04/2024, 52(3), 13–25.Google Scholar
Weber, R (2023) A sympoietic ocean. Design research with/in the marine holobiont. In ISEA 2023. 23rd Symposium for Digital Arts: Symbiosis, Paris (Forthcoming).CrossRefGoogle Scholar
Weber, R and Wegner, A (2022) Attunement to the Ocean. Underwater methods between marine biology and design research. In Counterparts: Exploring Design beyond the Human, Swiss Design Network Conference 2022 (Forthcoming).Google Scholar
Weber, R (2022) Symbio-design. Towards materials research in the ocean. In Conference: Design X Sustainability. Materiality/Systems/Shared Prosperity. Annual meeting DGTF - Deutsche Gesellschaft für Designforschung. Book of Abstracts. https://doi.org/10.25368/2022.136.CrossRefGoogle Scholar
Williams, GJ, Graham, NAJ, Jouffray, J-B, Nordström, AV, Nyström, TJM, Heenan, A, and Wedding, LM (2019) Coral reef ecology in the Anthropocene. Functional Ecology 33(6), 9391183 (Special Feature: Coral Reef Functional Ecology in the Anthropocene).CrossRefGoogle Scholar
Winograd, T and Flores, F (1986) Understanding computers and cognition: A New Foundation for Design. Norwood, NJ: Ablex Publishing Corporation.Google Scholar
Willis, A-N (2006) Ontological designing. Design Philosophy Papers 4(2): 6992.CrossRefGoogle Scholar
Yaneva, A and Zaera-Polo, A (2015) What Is Cosmopolitical Design? Design, Nature and the Built Environment. London and New York: Routledge.Google Scholar
Zweifler (Zvifler), A, O’Leary, M, Morgan, K, and Browne, NK (2021) Turbid coral reefs: Past, present and future—A review. Diversity 13(251). https://doi.org/10.3390/d13060251.CrossRefGoogle Scholar
Figure 0

Figure 1. PhD Thesis SYMBIOCEAN, the installed prototype »Kiki« underwater, minus 10 meters. Diver: Noémie Chabrier. Photographer : »Aquanaute« Stéphane Jamme. Location: STARESO – Station de Recherche Sous-Marines et Océanographiques de Calvi, Corsica (FR). Design: Rasa Weber. Date: August 2023.

Figure 1

Figure 2. Diving at the remains of a former coral reef. Location: Mega Cruise Pier, Willemstad, Curaçao (ANT). Diver: Mike Duss. Research Project: Symbiocean (2022 – ongoing). Photographer: Rasa Weber. February 2022.

Figure 2

Figure 3. Diving at the remains of a former coral reef. Location: Mega Cruise Pier, Willemstad, Curaçao (ANT). Diver: Mike Duss. Research Project: Symbiocean (2022 – ongoing). Photographer: Rasa Weber. February 2022.

Figure 3

Figure 4. PhD Thesis SYMBIOCEAN, placing the prototype »Kiki« underwater, minus 3 meters. Divers: Noémie Chabrier, Mathieu Kelhetter, Rasa Weber, Anja Wegner. Location: STARESO – Station de Recherche Sous-Marines et Océanographiques de Calvi, Corsica (FR). Photo: Mathieu Kelhetter. Design: Rasa Weber. Date: June 2023.

Figure 4

Figure 5. PhD Thesis SYMBIOCEAN, assembly of the prototype »Kiki«. In the photo: Rasa Weber. Location: STARESO – Station de Recherche Sous-Marines et Océanographiques de Calvi, Corsica (FR). Photo: Mathieu Kelhetter. Design: Rasa Weber. Date: June 2023.

Figure 5

Figure 6. Participants help to weave the conductive looms of »Kiki«. Left and below: Teal. Right: Julian. Place: STARESO – Station de Recherche Sous-Marines et Océanographiques de Calvi, Corsica (FR). Photo: Rasa Weber. Design: Rasa Weber. Date: June 2023.

Figure 6

Figure 7. PhD Thesis SYMBIOCEAN, the prototype »Kiki« with first layer of pioneering organisms (left) and after its destruction by a storm (right). Location: STARESO – Station de Recherche Sous-Marines et Océanographiques de Calvi, Corsica (FR). Photo: Noémie Chabrier. Design: Rasa Weber. Date: November 2023.

Figure 7

Figure 8. PhD Thesis SYMBIOCEAN, the installed prototype »Kiki« underwater, minus 10 meters. Diver & photographer: Noémie Chabrier. Location: STARESO – Station de Recherche Sous-Marines et Océanographiques de Calvi, Corsica (FR). Design: Rasa Weber. Date: July 2023.

Author comment: Of Other Reefs – Designing Habitats in Basted Seascapes — R0/PR1

Comments

No accompanying comment.

Review: Of Other Reefs – Designing Habitats in Basted Seascapes — R0/PR2

Comments

The paper Of Other Reefs – Designing Habitats in Basted Seascapes, presents a compelling argument regarding the future trajectory of coral reefs in the Anthropocene era. It contends that traditional approaches to biodesign, focusing on material innovation, are evolving towards aquaforming practices aimed at reshaping habitats for non-human life. The authors advocate for convivial conservation practices as a basis for a novel design methodology termed Sympoïetic Design, which challenges the prevailing notion of coral reef restoration as treating reefs as "sick patients." Instead, it proposes viewing reefs as transformative landscapes. The paper skillfully integrates ecological, political, and social considerations, emphasizing the complexity of real-world systems and the need for co-creation approaches.

Feedback:

Better clarity is needed regarding the concept of cohabitation as defined in the introduction: “…cohabitation as the basis for a new perspective on the built environment as a collaborative project of shared survival”, particularly in terms of shared survival involving humans and over time.

Regarding structure, the framing of chapters as methods and results could be misleading. Further elaboration on the methods in relation to the case study is necessary to provide clearer insights if this structure is kept.

Furthermore, the paper would benefit from outlining additional contemporary artificial reef interventions beyond the three main examples, possibly ones that align more closely with the proposed Sympoïetic Design principles. The current examples draw strong criticism, such as The Subway Reef Program and The Osbourne Reef, and suggest inconclusiveness toward environmental recovery, as seen in Chuuk Lagoon, thus highlighting the notion of Impurity by Design. Providing additional examples would offer valuable context and establish a basis for articulating the differences and progress in the approach and implementation suggested by the KIKI case study.

While the paper critiques the 'sick patient' approach to coral reef conservation, it would benefit from further clarification on how the proposed case study, KIKI, diverges from this concept. Specifically, an exploration of the systemic design conceptualization of KIKI, including decisions regarding the intervention form, scale, assembly, and management, is necessary. How do these decisions facilitate potential transformative, less controlled landscapes? Additionally, how do they relate to differentiated marine contexts or blasted seascapes?

In summary, "Sympoïetic Design" presents a thought-provoking perspective on coral reef conservation, but further development of key concepts and clarification of the case study in relation to the outlined concepts would strengthen its impact and relevance.

Decision: Of Other Reefs – Designing Habitats in Basted Seascapes — R0/PR3

Comments

Clear and consistent reviews of this one

Author comment: Of Other Reefs – Designing Habitats in Blasted Seascapes. — R1/PR4

Comments

No accompanying comment.

Decision: Of Other Reefs – Designing Habitats in Blasted Seascapes. — R1/PR5

Comments

Reviews Completed and revisions made.