Biomimetic and Biophilic Design of Multifunctional Symbiotic Lichen–Schwarz Metamaterial

Saatchi, Daniel; Oh, Saewoong; Oh, Il‐Kwon

doi:10.1002/adfm.202214580

Cited by 7 publications

(3 citation statements)

References 79 publications

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“…The species chosen can have a significant impact on the characteristics of the final product. Commonly employed fungi for mycelium-based composites are white rot fungi, such as Pleurotus ostreatus and Ganoderma lucidum [17,20].…”

Section: Methodsmentioning

confidence: 99%

“…This study also focuses on the impact of lichen existence on sound absorption coefficients. Lichen is a natural material that has been found to have sound absorption properties which can be exploited for various applications, such as soundproofing and acoustic enhancement [20]. Through examining the relationship between the two variables, it is hoped that a better understanding of the role of lichen in the acoustic environment can be gained.…”

Section: Sound Absorption Of the Mycelium-based Compositesmentioning

confidence: 99%

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Mycelium-Based Composites as a Sustainable Solution for Waste Management and Circular Economy

Barta,

Simion,

Tiuc

et al. 2024

Materials

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The global population is expected to increase by nearly 2 billion individuals over the next three decades, leading to a significant surge in waste generation and environmental challenges. To mitigate these challenges, there is a need to develop sustainable solutions that can effectively manage waste generation and promote a circular economy. Mycelium-based composites (MBCs) are being developed for various applications, including packaging, architectural designs, sound absorption, and insulation. MBCs are made by combining fungal mycelium with organic substrates, using the mycelium as a natural adhesive. Mycelium, the vegetative part of fungi, can be grown on various organic feedstocks and functionalized into a range of diverse material types that are biobased and thus more sustainable in their production, use, and recycling. This work aims to obtain mycelium-based composites with acoustic absorption properties, using coffee grounds and agricultural waste as raw materials. The topic approached presents a new method of recovering spent coffee grounds that does not involve high production costs and reduces two current environmental problems: noise pollution and abundant waste. Measurements of the normal-incidence sound absorption coefficient were presented and analyzed. Mycelium-based composites offer an innovative, sustainable approach to developing bio-composite sound-absorbing surfaces for interior fittings. The material by Ganoderma lucidum exhibits exceptional sound-absorbing properties at frequencies below 700 Hz, which is a crucial aspect of creating sound-absorbing materials that effectively absorb low-frequency sound waves. The modular construction system allows for a high degree of flexibility to adapt to short-term changes in the workplace.

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Section: Methodsmentioning

confidence: 99%

Section: Sound Absorption Of the Mycelium-based Compositesmentioning

confidence: 99%

Mycelium-Based Composites as a Sustainable Solution for Waste Management and Circular Economy

Barta,

Simion,

Tiuc

et al. 2024

Materials

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“…Another practical application of cellular materials can be as carriers for soft organic material, acting as a skeleton. For example, Daniel Saatchi et al recently shared the sound and moisture absorption results of a multifunctional symbiotic lichen-Schwarz metamaterial, which uses Schwarz Primitive geometry as a framework, providing mechanical stability for organic lichen, which in turn has noise reduction and air humidification functions [64].…”

Section: Schwarzitesmentioning

confidence: 99%

Crystal-Inspired Cellular Metamaterials and Triply Periodic Minimal Surfaces

Arsentev,

Topalov,

Balabanov

et al. 2024

Biomimetics

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Triply periodic minimal surfaces (TPMSs) are found in many natural objects including butterfly wings, sea urchins, and biological membranes. They simultaneously have zero mean curvature at every point and a crystallographic group symmetry. A metamaterial can be created from such periodic surfaces or used as a reinforcement of a composite material. While a TPMS as a mathematical object has been known since 1865, only novel additive manufacturing (AM) technology made it possible to fabricate cellular materials with complex TPMS shapes. Cellular TPMS-based metamaterials have remarkable properties related to wetting/liquid penetration, shock absorption, and the absence of stress concentrators. Recent studies showed that TPMSs are also found in natural crystals when electron surfaces are considered. Artificial crystal-inspired metamaterials mimic such crystals including zeolites and schwarzites. These metamaterials are used for shock, acoustic waves, and vibration absorption, and as structural materials, heat exchangers, and for other applications. The choice of the crystalline cell of a material, as well as its microstructure, plays a decisive role in its properties. The new area of crystal-inspired materials has many common features with traditional biomimetics with models being borrowed from nature and adjusted for engineering applications.

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Artificial Intelligence in Metamaterial Informatics for Sonic Frequency Mechanical Identification Tags

Saatchi,

Lee,

Pandit

et al. 2024

Adv Funct Materials

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Designing mechanical metamaterials to control wave propagation often requires extensive finite element analysis and discrete Fourier transform simulations before fabricating 3D printed structures and conducting experiments. Here, an alternative approach is presented to developing a metamaterial informatics framework by integrating dataset collection with artificial intelligence (AI), which can significantly accelerate the advancement of phononic wave chip technologies based on the triply periodic minimal surface (TPMS). Visualized data analysis is performed to evaluate the sensitivity of phononic band frequency numbers (BNF). Subsequently, various machine learning algorithms are compared for the prediction of sonic BNFs to create a unique identificable encoded mechanical identification tag (EMIT) interacting with sound waves. Then, for the mechanical decoding part with the help of acoustic analogy, a novel concept technology is developed that integrates 3D‐printed EMITs with a deep‐learning audio classifier for the ownership identification of instruments. Underwater application is discussed further for civil accident investigations, such as echolocating missing aircraft, divers, sunken ships, and containers with valuable cargo. These TPMS‐based EMITs represent the first‐generation passive sonic frequency identification (SFID) transponder‐tags, marking the advent of SFID transponder systems.

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Biomimetic and Biophilic Design of Multifunctional Symbiotic Lichen–Schwarz Metamaterial

Cited by 7 publications

References 79 publications

Mycelium-Based Composites as a Sustainable Solution for Waste Management and Circular Economy

Mycelium-Based Composites as a Sustainable Solution for Waste Management and Circular Economy

Crystal-Inspired Cellular Metamaterials and Triply Periodic Minimal Surfaces

Artificial Intelligence in Metamaterial Informatics for Sonic Frequency Mechanical Identification Tags

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