Understanding the Role of Controlled Environments for Producing Mycelium-bound Composites: Advancing Circular Practices for Integrating Biotechnology into the Construction Industry

IF 4.4 4区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Global Challenges Pub Date : 2024-05-30 DOI:10.1002/gch2.202300197

Tiziano Derme, Francis W. M. R. Schwarze, Benjamin Dillenburger

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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´s production process and the transfer from the laboratory to the industrial scale. In this regard, the design and engineering of novel controlled environments are fundamental in maintaining optimal growth conditions during material production. This, in turn, influences the overall material performance and potential use in construction.

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了解受控环境在生产菌丝复合材料中的作用：推进将生物技术融入建筑业的循环实践

建筑、工程和施工行业正在发生重大转变，引导建筑物从资源密集型工艺转向气候减缓工具。在这一转变过程中，通过生物技术和酶法工艺整合循环型生物基替代品并减少排放具有巨大潜力。具体来说，菌丝复合材料已成为新材料和增值木制品的可再生替代品。尽管这些材料具有诸多优势，但将其融入当前的工程实践中仍面临着挑战，因为材料的生产过程和从实验室到工业化生产的转移过程十分复杂。在这方面，新型受控环境的设计和工程是在材料生产过程中保持最佳生长条件的基础。这反过来又会影响材料的整体性能和在建筑中的潜在用途。

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来源期刊

Global Challenges MULTIDISCIPLINARY SCIENCES-

CiteScore

8.70

自引率

0.00%

发文量

审稿时长

16 weeks