Polymeric microcapsules with switchable mechanical properties for self-healing concrete: synthesis, characterisation and proof of concept

Kanellopoulos, Antonios; Palmer, D.A.; Kerr, Alex; Al‐Tabbaa, Abir

doi:10.1088/1361-665x/aa516c

Cited by 122 publications

(93 citation statements)

References 28 publications

(33 reference statements)

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“…Similarly, the investigation of more thermally stable materials like polyurea has led to the development of capsules ( Figure b) for survivability in elevated temperature environments . A different approach included the production of microcapsules with switchable mechanical properties to ensure survivability during the concrete mixing process. In this context, recent collaboration between universities and companies led to the design and production of microcapsules that exhibit ductile “rubbery” behavior when hydrated and when dried transition to stiff, brittle glass‐like behavior (Figure a) …”

Section: Encapsulated Autonomous Self‐healing (Polymers or Minerals)mentioning

confidence: 99%

“…Recent research activities in microencapsulation for self‐healing in cementitious systems: a) gum Arabic/gelatin shell microcapsules containing sodium silicate core, b) polyurea shell microcapsules produced containing semicrystalline sodium silicate, c) schematic of the microfluidics process including the photopolymerization process, d) a laboratory setup of double emulsion flow focusing microfluidics platform, e) optical microscope image of microfluidics produced monodisperse acrylate microcapsules and f) corresponding surface functionalized acrylate microcapsules . Reproduced with permission . Copyright 2017, IOP publishing.…”

Section: Encapsulated Autonomous Self‐healing (Polymers or Minerals)mentioning

confidence: 99%

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A Review of Self‐Healing Concrete for Damage Management of Structures

Belie

Gruyaert

Al‐Tabbaa

et al. 2018

Adv Materials Inter

489

278

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The increasing concern for safety and sustainability of structures is calling for the development of smart self-healing materials and preventive repair methods. The appearance of small cracks (<300 µm in width) in concrete is almost unavoidable, not necessarily causing a risk of collapse for the structure, but surely impairing its functionality, accelerating its degradation, and diminishing its service life and sustainability. This review provides the state-ofthe-art of recent developments of self-healing concrete, covering autogenous or intrinsic healing of traditional concrete followed by stimulated autogenous healing via use of mineral additives, crystalline admixtures or (superabsorbent) polymers, and subsequently autonomous self-healing mechanisms, i.e. via, application of micro-, macro-, or vascular encapsulated polymers, minerals, or bacteria. The (stimulated) autogenous mechanisms are generally limited to healing crack widths of about 100-150 µm. In contrast, most autonomous self-healing mechanisms can heal cracks of 300 µm, even sometimes up to more than 1 mm, and usually act faster. After explaining the basic concept for each self-healing technique, the most recent advances are collected, explaining the progress and current limitations, to provide insights toward the future developments. This review addresses the research needs required to remove hindrances that limit market penetration of self-healing concrete technologies.

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Section: Encapsulated Autonomous Self‐healing (Polymers or Minerals)mentioning

confidence: 99%

Section: Encapsulated Autonomous Self‐healing (Polymers or Minerals)mentioning

confidence: 99%

A Review of Self‐Healing Concrete for Damage Management of Structures

Belie

Gruyaert

Al‐Tabbaa

et al. 2018

Adv Materials Inter

489

278

View full text Add to dashboard Cite

show abstract

“…The results of thermalgravimetric analysis test showed that the mass loss of microcapsules is very small even at 180 °C and the morphology is intact, indicating the microcapsule can resist the high‐temperature condition during the mixing and compaction process after being added to the cementitious material. In 2017, Kanellopoulos et al investigated the geometry of microcapsules between wet and dry conditions. It was found that there was no effect on the structural integrity of the shell under the dehydration/rehydration cycles test.…”

Section: Applications In Shmmentioning

confidence: 99%

Microcapsule‐Based Visualization Smart Sensors for Damage Detection: Principles and Applications

Zheng

Wang

et al. 2019

Adv Materials Technologies

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The smart sensor is an effective way to detect damage and improve structural safety in structural health monitoring. Microcapsule‐based visualization sensors stand out from the smart sensors. Here, the research progress of microcapsule visualization materials in recent years is summarized and the sensing principles, influence factors, performances, applications, and future prospects are introduced. The way to achieve the visualizing function of microcapsule visualization sensors is the fabrication of microcapsules that are encapsulated with solutions of dyes or indicator. When the protective shell of microcapsules is broken, the dyes will be released and activated under optical, chemical, or mechanical conditions. These visualized microcapsules can be added to the interior of the structure or prepared as a coating to provide structural health monitoring of the interior and surface of the structure. They can accurately detect microcracks and highlight them in bright colors. Additionally, the structural health monitoring applications of microcapsule visualization sensing coatings in concrete, asphalt, and steel are presented with detailed examples. The development and application of these microcapsule visualization sensors are of great significance in improving the structural life and avoiding structural failure in engineering.

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“…Alongside this work on autogenous healing has been a major research effort on autonomic (manufactured) healing systems . The three main techniques explored for delivering and releasing healing agents are as follows: i)The embedment of brittle vessels (normally tubes) into structural elements; ii)The addition of microcapsules into cementitious mixes; iii)The creation of interconnected channels or “vascular networks” within cementitious structural members …”

Section: Overview Of Existing Self‐healing Technologies and Mechanismsmentioning

confidence: 99%

Research Progress on Numerical Models for Self‐Healing Cementitious Materials

Jefferson

Javierre

Freeman

et al. 2018

Adv Materials Inter

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In this paper, research progress on numerical models for self‐healing cementitious materials (SHCMs) is discussed. Models developed specifically for SHCMs, as well as other relevant work, are considered. A summary of current self‐healing (SH) techniques is provided along with descriptions of the processes that govern their behavior. Models for mechanical self‐healing, transport processes in materials with embedded healing systems, fully coupled models, and other modeling techniques used to simulate SH behavior are discussed. The mechanics models discussed include those based on continuum–damage–healing mechanics (CDHM), micromechanics, as well as models that use discrete elements and particle methods. A considerable section is devoted to the simulation of carbonation in concrete since the essential mechanisms that govern this process are applicable to SH systems that employ calcite as a healing material. A number of transport models for simulating early‐age self‐healing are also considered. This highlights the fact that there are currently very few papers that describe fully coupled models, although a number of approaches that couple some aspects of transport and mechanical healing behavior are discussed. This article closes with a discussion that highlights the fact that many models are presented with limited or no experimental validation.

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Polymeric microcapsules with switchable mechanical properties for self-healing concrete: synthesis, characterisation and proof of concept

Cited by 122 publications

References 28 publications

A Review of Self‐Healing Concrete for Damage Management of Structures

A Review of Self‐Healing Concrete for Damage Management of Structures

Microcapsule‐Based Visualization Smart Sensors for Damage Detection: Principles and Applications

Research Progress on Numerical Models for Self‐Healing Cementitious Materials

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