| Title | Understanding the Role of Controlled Environments for Producing Mycelium-bound Composites: Advancing Circular Practices for Integrating Biotechnology into the Construction Industry |
|---|---|
| ID_Doc | 24029 |
| Authors | Derme, T; Schwarze, FWMR; Dillenburger, B |
| Title | Understanding the Role of Controlled Environments for Producing Mycelium-bound Composites: Advancing Circular Practices for Integrating Biotechnology into the Construction Industry |
| Year | 2024 |
| Published | Global Challenges, 8, 7 |
| Abstract | The architecture, engineering, and construction industry is undergoing a significant shift, steering buildings away from resource-intensive processes toward becoming instruments for climate mitigation. In this transformative landscape, integrating circular bio-based alternatives and reducing emissions through biotechnological and enzymatic processes have significant potential. Specifically, mycelium-bound composites have emerged as renewable alternatives for new materials and added-value wood products. Despite their numerous advantages, integrating these materials into current engineering practices presents challenges deriving from the complex nature of the material |
| https://onlinelibrary.wiley.com/doi/pdfdirect/10.1002/gch2.202300197 |
Similar Articles
| ID | Score | Article |
|---|---|---|
3473
|
Globa, A; Lee, R; Bram-Billa, A WASTE NOT: BUILDING MATERIALS FOR A SUSTAINABLE FUTURE Implementation of circular economy and living mycelium materials for architecture(2024) | |
| 16925
|
Muiruri, JK; Yeo, JCC; Zhu, Q; Ye, EY; Loh, XJ; Li, ZB Sustainable Mycelium-Bound Biocomposites: Design Strategies, Materials Properties, and Emerging Applications(2023)Acs Sustainable Chemistry & Engineering, 11, 18 | |
| 14129
|
Elsacker, E; Vandelook, S; Van Wylick, A; Ruytinx, J; De Laet, L; Peeters, E A comprehensive framework for the production of mycelium-based lignocellulosic composites(2020) | |
| 10600
|
Mohseni, A; Vieira, FR; Pecchia, JA; Guersoy, B Three-Dimensional Printing of Living Mycelium-Based Composites: Material Compositions, Workflows, and Ways to Mitigate Contamination(2023)Biomimetics, 8, 2 | |
| 24227
|
Livne, A; Pearlmutter, D; Gal, E; Wösten, HAB Increased CO2 fixation and reduced embodied energy of mycelium bio-composite materials grown on a mixed substrate over diurnal temperature cycles(2024) | |
| 12748
|
Alaux, N; Vasatko, H; Maierhofer, D; Saade, MRM; Stavric, M; Passer, A Environmental potential of fungal insulation: a prospective life cycle assessment of mycelium-based composites(2024)International Journal Of Life Cycle Assessment, 29.0, 2 | |
| 22574
|
Livne, A; Wösten, HAB; Pearlmutter, D; Gal, E Fungal Mycelium Bio-Composite Acts as a CO2-Sink Building Material with Low Embodied Energy(2022)Acs Sustainable Chemistry & Engineering, 10.0, 37 | |
| 8935
|
Girometta, C; Picco, AM; Baiguera, RM; Dondi, D; Babbini, S; Cartabia, M; Pellegrini, M; Savino, E Physico-Mechanical and Thermodynamic Properties of Mycelium-Based Biocomposites: A Review(2019)Sustainability, 11.0, 1 |