Ghent University Academic Bibliography |

Ghent University Academic Bibliography

Matches in Ghent University Academic Bibliography for { <https://biblio.ugent.be/publication/01GMVB03HSGH5G3DQCBE6RFMTB> ?p ?o. }

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01GMVB03HSGH5G3DQCBE6RFMTB classification C3.
01GMVB03HSGH5G3DQCBE6RFMTB date "2022".
01GMVB03HSGH5G3DQCBE6RFMTB language "eng".
01GMVB03HSGH5G3DQCBE6RFMTB type conference.
01GMVB03HSGH5G3DQCBE6RFMTB hasPart 01GMXWRNXQE5WSWFG77BFKQW55.pdf.
01GMVB03HSGH5G3DQCBE6RFMTB subject "Technology and Engineering".
01GMVB03HSGH5G3DQCBE6RFMTB doi "10.5281/zenodo.7405422".
01GMVB03HSGH5G3DQCBE6RFMTB presentedAt urn:uuid:02724c4f-b12f-467d-bb12-ccccf716756b.
01GMVB03HSGH5G3DQCBE6RFMTB abstract "Increasing awareness for sustainability has led to the development of smart self-healing materials, which can extend the service life and improve safety without human intervention. Vascular networks are observed in biological systems, such as leaf venation and blood vascular systems, and provide inspiration for self-healing mechanisms in engineered systems. Embedding a vascular network in a host material has the advantage of addressing varying magnitudes of damage and allowing for an indefinite replenishment of the healing agent, which are current limitations of intrinsic and capsule-based self-healing systems. These networks are demonstrated in polymer and composite materials, with fabrication methods including removal of sacrificial elements, electrospinning, and an array of additive manufacturing (AM) techniques. Advances in AM allow more complex network configurations to be realized that optimize fluid distribution and healing potential. This review intends to provide a comprehensive overview of the current progress and limitations of the design approaches, fabrication methods, healing mechanisms, and relevant applications of embedded vascular networks. Additionally, significant research gaps and future research directions for vascular self-healing materials are described.".
01GMVB03HSGH5G3DQCBE6RFMTB author 4c0e2263-5a7e-11ea-aa4a-c6f6039b91b8.
01GMVB03HSGH5G3DQCBE6RFMTB author F4BFDAEA-F0ED-11E1-A9DE-61C894A0A6B4.
01GMVB03HSGH5G3DQCBE6RFMTB author FA3817BC-F0ED-11E1-A9DE-61C894A0A6B4.
01GMVB03HSGH5G3DQCBE6RFMTB author urn:uuid:0b3cf513-ba4b-46c7-b697-774e7fafe7b9.
01GMVB03HSGH5G3DQCBE6RFMTB dateCreated "2022-12-21T21:56:25Z".
01GMVB03HSGH5G3DQCBE6RFMTB dateModified "2024-07-09T07:42:13Z".
01GMVB03HSGH5G3DQCBE6RFMTB name "A review of vascular networks for self-healing applications".
01GMVB03HSGH5G3DQCBE6RFMTB pagination urn:uuid:73dfbbeb-4007-46b9-8fbb-3a7c7b094666.
01GMVB03HSGH5G3DQCBE6RFMTB sameAs LU-01GMVB03HSGH5G3DQCBE6RFMTB.
01GMVB03HSGH5G3DQCBE6RFMTB sourceOrganization urn:uuid:19da8d5c-5e05-47e6-8fe3-c439b38e2b21.
01GMVB03HSGH5G3DQCBE6RFMTB type C3.