2018
DOI: 10.1002/adem.201701159
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Piezoresistivity, Strain, and Damage Self‐Sensing of Polymer Composites Filled with Carbon Nanostructures

Abstract: Previous and current research on piezoresistivity of polymer composites filled with carbon nanostructures is reviewed. The review covers the use of the coupled electro‐mechanical response of these materials to self‐sense their strain and damage during mechanical loading. The mechanisms yielding changes in electrical resistance upon mechanical loading in polymer composites filled with carbon nanostructures are first discussed. Published knowledge is then summarized, starting with framework literature on carbon … Show more

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Cited by 123 publications
(119 citation statements)
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“…For this reason, a viable strategy can be the use of polymer/CNTs nanocomposites as sensing materials. Indeed, several polymer/CNTs nanocomposites have been previously investigated and tested as strain-sensors, exploring the use of different polymer matrices: epoxy resin [32][33][34], polymethyl methacrylate [35] and polypropylene [36][37][38][39][40][41][42]. Polymer/CNTs are excellent sensing materials if the electrical percolation threshold (EPT) is exceeded.…”
Section: Introductionmentioning
confidence: 99%
See 1 more Smart Citation
“…For this reason, a viable strategy can be the use of polymer/CNTs nanocomposites as sensing materials. Indeed, several polymer/CNTs nanocomposites have been previously investigated and tested as strain-sensors, exploring the use of different polymer matrices: epoxy resin [32][33][34], polymethyl methacrylate [35] and polypropylene [36][37][38][39][40][41][42]. Polymer/CNTs are excellent sensing materials if the electrical percolation threshold (EPT) is exceeded.…”
Section: Introductionmentioning
confidence: 99%
“…Even if several authors investigated sensing ability of PP/CNT alone [36][37][38][39][40][41][42], to the best of our knowledge, no studies investigated the possibility to use PP/CNT strain sensors directly embedded in cementitious materials. Several authors proposed the use of sensing skins or sensing elements to be applied on external surfaces of buildings/infrastructures [53][54][55][56][57].…”
Section: Introductionmentioning
confidence: 99%
“…Since the surface of a material is where it connects to its environment, a similar trend from “passive” to “active” interfaces is leading to functional interfaces that respond to external stimuli and enable versatile material interfaces with tunable and reversible properties such as wettability and adhesion . Potential applications are found in a wide range of areas such as electronics and energy materials, biotechnology and biomaterials, sensing, additive manufacturing, and many more …”
Section: Introductionmentioning
confidence: 99%
“…Applications of smart concretes comprise the development of integral smart structures, embedded strain sensors, as well as superficial sensors or smart skins . Also promising are self‐sensing polymer composites for the development of large surface strain sensors and stretchable electronics . It is worth noting the work by Laflamme et al, who proposed low‐cost soft elastomeric capacitor strain transducers in combination with a Kriging interpolator for damage identification in wind turbine blades.…”
Section: Introduction and Research Aimmentioning
confidence: 99%
“…25 Also promising are self-sensing polymer composites for the development of large surface strain sensors and stretchable electronics. 26 It is worth noting the work by Laflamme et al, 27 who proposed low-cost soft elastomeric capacitor strain transducers in combination with a Kriging interpolator for damage identification in wind turbine blades. Although many authors have striven to apply smart materials to concrete or aerospace structures, the number of attempts to bring this concept to masonry structures is very scarce.…”
Section: Introduction and Research Aimmentioning
confidence: 99%