Self‐Healing Materials

Hager, Martin D.; Greil, Peter; Leyens, Christoph; Zwaag, Sybrand van der; Schubert, Ulrich S.

doi:10.1002/adma.201003036

Cited by 1,028 publications

(709 citation statements)

References 85 publications

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“…The dispersions seem to be in the vicinity of surface near MoSi 2 -particles, which explains the different surface of the composites. Hager et al 33) report the positive effect of MoSi 2 as a filler in a SiOC-matrix. They conclude that at high temperatures the oxidation leads to self-healing of cracks within the SiOC/MoSi 2 composite.…”

Section: Ageing At Elevated Temperatures and Electrical Resistivitymentioning

confidence: 99%

Precursor derived SiOC/MoSi<sub>2</sub>-composites for diesel glow plugs: preparation and high temperature properties

Reitz

Schell

Bucharsky

et al. 2016

J. Ceram. Soc. Japan

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In this study precursor derived SiOC/MoSi 2 composites were evaluated with respect to their potential for the application as glow plug material. In a first step, fully dense composite materials with different fractions of electrical conductive MoSi 2 were fabricated by field-assisted sintering technique (FAST). The percolation threshold, where the electrical properties change from insulating to a suitable level of conduction depends on the microstructure, which can be controlled by the initial particle size of the used SiOC particles. It becomes principally possible to fabricate both, the insulating part and the heater material with the same MoSi 2 content and therefore without thermal mismatch. Room temperature properties, high temperature strength, oxidation and creep behaviour depend strongly on the MoSi 2 volume fraction. MoSi 2 contents beyond the percolation threshold lead to significantly enhanced creep rates. At high temperatures, reactions between SiOC and MoSi 2 can be observed, which differ at the air exposed surface and in the interior of the samples. From these findings, an upper limit for the application temperature can be derived.

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Section: Ageing At Elevated Temperatures and Electrical Resistivitymentioning

confidence: 99%

Precursor derived SiOC/MoSi<sub>2</sub>-composites for diesel glow plugs: preparation and high temperature properties

Reitz

Schell

Bucharsky

et al. 2016

J. Ceram. Soc. Japan

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“…The healing polymerisation process takes energy from ultra-violet light and re-creates an even surface. By treating micro-cracks in their early phases, bigger cracks are prevented from spreading [119,120]. It remains, however, unsolved at present if largerscale damage caused by mechanical influence can be healed as well.…”

Section: Surveymentioning

confidence: 99%

“…Adjustments and additions will certainly be necessary at a later stage. For now, the example of capsule-based self-healing materials [3,119,120], discussed in Section 5, serves as an illustration: -Failure causes: mechanic, thermic -Failure types: accidental damage, corrosion, fatigue -Failure characteristics: permanent -Damage: mechanical -Solution characteristics: one-off, extrinsic, autonomic, without external power, without intelligence -Solution mechanisms: material self-healing, intrinsic -Outcome: within a few seconds to minutes, permanent, consuming the self-healing capability, restoring full functionality…”

Section: Application Of the Taxonomy To An Examplementioning

confidence: 99%

Self-healing and self-repairing technologies

Frei

McWilliam

Derrick

et al. 2013

Int J Adv Manuf Technol

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This article reviews the existing work in selfhealing and self-repairing technologies, including work in software engineering, materials, mechanics, electronics, MEMS, self-reconfigurable robotics, and others. It suggests a terminology and taxonomy for self-healing and selfrepair, and discusses the various related types of other self-* properties. The mechanisms and methods leading to selfhealing are reviewed, and common elements across disciplines are identified.

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“…The construction of self‐healing materials has been driven by developments in materials science and biotechnology with a view to environmental sustainability 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11. To develop maintenance‐free self‐healing structures, the ideal materials should be liquid‐like before processing and then be converted into a free‐standing solid‐like network 12, 13, 14, 15.…”

mentioning

confidence: 99%

Supramolecular Nested Microbeads as Building Blocks for Macroscopic Self‐Healing Scaffolds

Liu

Tan

et al. 2018

Angew Chem Int Ed

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The ability to construct self‐healing scaffolds that are injectable and capable of forming a designed morphology offers the possibility to engineer sustainable materials. Herein, we introduce supramolecular nested microbeads that can be used as building blocks to construct macroscopic self‐healing scaffolds. The core–shell microbeads remain in an “inert” state owing to the isolation of a pair of complementary polymers in a form that can be stored as an aqueous suspension. An annealing process after injection effectively induces the re‐construction of the microbead units, leading to supramolecular gelation in a preconfigured shape. The resulting macroscopic scaffold is dynamically stable, displaying self‐recovery in a self‐healing electronic conductor. This strategy of using the supramolecular assembled nested microbeads as building blocks represents an alternative to injectable hydrogel systems, and shows promise in the field of structural biomaterials and flexible electronics.

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Self‐Healing Materials

Cited by 1,028 publications

References 85 publications

Precursor derived SiOC/MoSi<sub>2</sub>-composites for diesel glow plugs: preparation and high temperature properties

Precursor derived SiOC/MoSi<sub>2</sub>-composites for diesel glow plugs: preparation and high temperature properties

Self-healing and self-repairing technologies

Supramolecular Nested Microbeads as Building Blocks for Macroscopic Self‐Healing Scaffolds

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