Living architecture: metabolic applications for next-generation, selectively programmable bioreactors
Living architecture: metabolic applications for next-generation, selectively programmable bioreactors
Vital natural resources are depleting and being wasted in today's industrialized and agricultural processes. Critical planetary boundaries have been transgressed with major effects on biodiversity loss and climate change. Necessary elements for our daily life such as nitrogen and phosphorus are being lost through household wastewater. The EU-funded project Living Architecture which is currently under development addresses these issues through a selectively programmable bioreactor that recovers phosphates, cleans water, and produces electricity. The Living Architecture system, to be realized in 2019 as a partition wall to be incorporated into existing buildings, is further speculated in design scenarios, including a remote research facility for extreme environments and for application into the urban context as infrastructure.
Bioreactor, Energy production, Living architecture, Metabolic applications, Programmable, wastewater treatment
595-614
Hogle, Molly
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Imhof, Barbara
8ad5b171-06be-4167-850f-8fe948226df2
Hoheneder, Waltraut
0d437a3f-4f65-4522-a588-c5df1fb3302c
Armstrong, Rachel
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Ieropoulos, Ioannis
6c580270-3e08-430a-9f49-7fbe869daf13
Wallis, Lauren
a7bbb8e7-18a0-43e7-a4a0-5e6d94b532b4
You, Jiseon
1442df08-0ea4-4134-b6be-6b773b05f58d
Nogales, Juan
4324003a-7ad0-4365-9835-3b0dfea521fc
19 January 2023
Hogle, Molly
7ce5358e-c4ec-49a4-83b7-e17f78b8468f
Imhof, Barbara
8ad5b171-06be-4167-850f-8fe948226df2
Hoheneder, Waltraut
0d437a3f-4f65-4522-a588-c5df1fb3302c
Armstrong, Rachel
3a175396-23b7-410e-9115-500a112405a0
Ieropoulos, Ioannis
6c580270-3e08-430a-9f49-7fbe869daf13
Wallis, Lauren
a7bbb8e7-18a0-43e7-a4a0-5e6d94b532b4
You, Jiseon
1442df08-0ea4-4134-b6be-6b773b05f58d
Nogales, Juan
4324003a-7ad0-4365-9835-3b0dfea521fc
Hogle, Molly, Imhof, Barbara, Hoheneder, Waltraut, Armstrong, Rachel, Ieropoulos, Ioannis, Wallis, Lauren, You, Jiseon and Nogales, Juan
(2023)
Living architecture: metabolic applications for next-generation, selectively programmable bioreactors.
In,
Droege, Peter
(ed.)
Urban and Regional Agriculture: Building Resilient Food Systems.
Academic Press, .
(doi:10.1016/B978-0-12-820286-9.00004-2).
Record type:
Book Section
Abstract
Vital natural resources are depleting and being wasted in today's industrialized and agricultural processes. Critical planetary boundaries have been transgressed with major effects on biodiversity loss and climate change. Necessary elements for our daily life such as nitrogen and phosphorus are being lost through household wastewater. The EU-funded project Living Architecture which is currently under development addresses these issues through a selectively programmable bioreactor that recovers phosphates, cleans water, and produces electricity. The Living Architecture system, to be realized in 2019 as a partition wall to be incorporated into existing buildings, is further speculated in design scenarios, including a remote research facility for extreme environments and for application into the urban context as infrastructure.
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Published date: 19 January 2023
Keywords:
Bioreactor, Energy production, Living architecture, Metabolic applications, Programmable, wastewater treatment
Identifiers
Local EPrints ID: 504491
URI: http://eprints.soton.ac.uk/id/eprint/504491
PURE UUID: ce70ef0f-e42d-419b-ba54-1d2a32028ec9
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Date deposited: 10 Sep 2025 15:27
Last modified: 11 Sep 2025 03:26
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Contributors
Author:
Molly Hogle
Author:
Barbara Imhof
Author:
Waltraut Hoheneder
Author:
Rachel Armstrong
Author:
Lauren Wallis
Author:
Jiseon You
Author:
Juan Nogales
Editor:
Peter Droege
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