Roadmap for animate matter

Volpe, Giorgio; Araújo, Nuno A.M.; Guix, Maria; Miodownik, Mark; Martin, Nicolas; Alvarez, Laura; Simmchen, Juliane; Leonardo, Roberto Di; Pellicciotta, Nicola; Martinet, Quentin; Palacci, Jérémie A; Ng, Wai Kit; Saxena, Dhruv; Sapienza, Riccardo; Nadine, Sara; Mano, João F.; Mahdavi, Reza; Beck Adiels, Caroline; Forth, Joe; Santangelo, Christian; Palagi, Stefano; Seok, Ji Min; Webster-Wood, Victoria A.; Wang, Shuhong; Yao, Lining; Aghakhani, Amirreza; Barois, Thomas; Kellay, Hamid; Coulais, Corentin; Van Hecke, Martin; Pierce, Christopher J.; Wang, Tianyu; Chong, Baxi; Goldman, Daniel I.; Reina, Andreagiovanni; Trianni, Vito; Volpe, Giovanni; Beckett, Richard; Nair, Sean P.; Armstrong, Rachel

Roadmap for animate matter

Volpe G, Araújo NAM, Guix M, Miodownik M, Martin N, Alvarez L, Simmchen J, Leonardo RD, Pellicciotta N, Martinet Q, Palacci JA, Ng WK, Saxena D, Sapienza R, Nadine S, Mano JF, Mahdavi R, Beck Adiels C, Forth J, Santangelo C, Palagi S, Seok JM, Webster-Wood VA, Wang S, Yao L, Aghakhani A, Barois T, Kellay H, Coulais C, Van Hecke M, Pierce CJ, Wang T, Chong B, Goldman DI, Reina A, Trianni V, Volpe G, Beckett R, Nair SP, Armstrong R. 2025. Roadmap for animate matter. Journal of Physics Condensed Matter. 37(33), 333501.

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2025_CondensedMatter_Volpe.pdf 9.00 MB [Published Version]

DOI

10.1088/1361-648X/adebd3

Journal Article | Published | English

Scopus indexed

Author

Volpe, Giorgio; Araújo, Nuno A.M.; Guix, Maria; Miodownik, Mark; Martin, Nicolas; Alvarez, Laura; Simmchen, Juliane; Leonardo, Roberto Di; Pellicciotta, Nicola; Martinet, Quentin^ISTA ; Palacci, Jérémie A^ISTA ; Ng, Wai Kit
All

Department

Palacci Group

Abstract

Humanity has long sought inspiration from nature to innovate materials and devices. As science advances, nature-inspired materials are becoming part of our lives. Animate materials, characterized by their activity, adaptability, and autonomy, emulate properties of living systems. While only biological materials fully embody these principles, artificial versions are advancing rapidly, promising transformative impacts in the circular economy, health and climate resilience within a generation. This roadmap presents authoritative perspectives on animate materials across different disciplines and scales, highlighting their interdisciplinary nature and potential applications in diverse fields including nanotechnology, robotics and the built environment. It underscores the need for concerted efforts to address shared challenges such as complexity management, scalability, evolvability, interdisciplinary collaboration, and ethical and environmental considerations. The framework defined by classifying materials based on their level of animacy can guide this emerging field to encourage cooperation and responsible development. By unravelling the mysteries of living matter and leveraging its principles, we can design materials and systems that will transform our world in a more sustainable manner.

Publishing Year

2025

Date Published

2025-08-18

Journal Title

Journal of Physics Condensed Matter

Publisher

IOP Publishing

Acknowledgement

Living Architecture is Funded by the EU Horizon 2020 Future Emerging Technologies Open programme (2016–2019) Grant Agreement 686585 a consortium of 6 collaborating institutions—Newcastle University, University of Trento, University of the West of England, Spanish National Research Council, Explora Biotech and Liquifer Systems Group. The Active Living Infrastructure: Controlled Environment (ALICE) project is funded by an EU Innovation Award for the development of a bio-digital ‘brick’ prototype, a collaboration between Newcastle University, Translating Nature, and the University of the West of England (2019–2021) under EU Grant Agreement No. 851246. Microbial Hydroponics: Circular Sustainable Electrobiosynthesis (Mi-Hy) is Funded by the European Union under Grant Agreement Number 101114746, which is a collaboration between Beneficiaries, KU Leuven (Belgium), the University of Southampton (UK), SONY Computer Science Laboratory (France), BioFaction KG (Austria), Spanish National Research Council (Spain), and Associated Partners, the University of the West of England (UK) and University of Southampton (UK). Mi-Hy is also supported through the interdisciplinary KU Leuven Institute for Cultural Heritage (HERKUL).

Volume

Issue

Article Number

333501

ISSN

0953-8984

eISSN

1361-648X

IST-REx-ID

20218

Cite this

Volpe G, Araújo NAM, Guix M, et al. Roadmap for animate matter. Journal of Physics Condensed Matter. 2025;37(33). doi:10.1088/1361-648X/adebd3

Volpe, G., Araújo, N. A. M., Guix, M., Miodownik, M., Martin, N., Alvarez, L., … Armstrong, R. (2025). Roadmap for animate matter. Journal of Physics Condensed Matter. IOP Publishing. https://doi.org/10.1088/1361-648X/adebd3

Volpe, Giorgio, Nuno A.M. Araújo, Maria Guix, Mark Miodownik, Nicolas Martin, Laura Alvarez, Juliane Simmchen, et al. “Roadmap for Animate Matter.” Journal of Physics Condensed Matter. IOP Publishing, 2025. https://doi.org/10.1088/1361-648X/adebd3.

G. Volpe et al., “Roadmap for animate matter,” Journal of Physics Condensed Matter, vol. 37, no. 33. IOP Publishing, 2025.

Volpe, Giorgio, et al. “Roadmap for Animate Matter.” Journal of Physics Condensed Matter, vol. 37, no. 33, 333501, IOP Publishing, 2025, doi:10.1088/1361-648X/adebd3.

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