Non-Destructive Investigation of Dispersion, Bonding, and Thermal Properties of Emerging Polymer Nanocomposites Using Close-Up Lens Assisted Infrared Thermography

Ashraf, Ali; Jani, Nikhil; Farmer, Francis; Lynch-Branzoi, Jennifer

doi:10.1557/adv.2020.121

Cited by 5 publications

(4 citation statements)

References 10 publications

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“…No filler agglomeration was observed from the SEM images. This uniform distribution of GNFs within PSU is similar to our previous work investigating in situ exfoliation of graphite into GNFs within an Ecoflex 00-30 using an infrared thermography approach [30,31]. The original graphite flake diameter was ~300 µm; however, the GNF size measured in SEM images is ~10 µm, indicating a shear-induced fracture across the basal plane resulting in edge sites that are available to form covalent bonds with surrounding polymer molecules.…”

Section: Materials Characterizationsupporting

confidence: 83%

“…The hysteresis (difference in resistance change at the same temperature during heating and subsequent cooling) can be as high as ~20%, whereas in our case it was only 0.42% [23]. Thermal images (from thermal video recording during the entire test) show a uniform temperature profile across the sample area being heated, indicating uniform dispersion of the nanofillers in the polymer composite (Figures 7b and 8b) [30,31].…”

Section: Temperature Sensingmentioning

confidence: 58%

“…Under an external load, the distance between graphene in the composite and the structure of the hexagonal honeycomb will change, resulting in a change in resistance and therefore current flow through the composite sensor [34]. Electrons tunnel or hop from one graphene flake to another (if the filler content is above the percolation threshold in the composite), and that is why the change in distance between graphene flakes changes the resistance to electron flow [31].…”

Section: Electromechanical Strain Sensingmentioning

confidence: 99%

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Multifunctional Graphene–Polymer Nanocomposite Sensors Formed by One-Step In Situ Shear Exfoliation of Graphite

et al. 2023

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Graphene nanocomposites are a promising class of advanced materials for sensing applications; yet, their commercialization is hindered due to impurity incorporation during fabrication and high costs. The aim of this work is to prepare graphene–polysulfone (G−PSU) and graphene–polyvinylidene fluoride (G−PVDF) nanocomposites that perform as multifunctional sensors and are formed using a one-step, in situ exfoliation process whereby graphite is exfoliated into graphene nanoflakes (GNFs) directly within the polymer. This low-cost method creates a nanocomposite while avoiding impurity exposure since the raw materials used in the in situ shear exfoliation process are graphite and polymers. The morphology, structure, thermal properties, and flexural properties were determined for G−PSU and G−PVDF nanocomposites, as well as the electromechanical sensor capability during cyclic flexural loading, temperature sensor testing while heating and cooling, and electrochemical sensor capability to detect dopamine while sensing data wirelessly. G−PSU and G−PVDF nanocomposites show superior mechanical characteristics (gauge factor around 27 and significantly enhanced modulus), thermal characteristics (stability up to 500 °C and 170 °C for G−PSU and G−PVDF, respectively), electrical characteristics (0.1 S/m and 1 S/m conductivity for G−PSU and G−PVDF, respectively), and distinguished resonant peaks for wireless sensing (~212 MHz and ~429 MHz). These uniquely formed G−PMC nanocomposites are promising candidates as strain sensors for structural health monitoring, as temperature sensors for use in automobiles and aerospace applications, and as electrochemical sensors for health care and disease diagnostics.

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Section: Materials Characterizationsupporting

confidence: 83%

Section: Temperature Sensingmentioning

confidence: 58%

Section: Electromechanical Strain Sensingmentioning

confidence: 99%

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Multifunctional Graphene–Polymer Nanocomposite Sensors Formed by One-Step In Situ Shear Exfoliation of Graphite

et al. 2023

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“…For instance, infrared thermography was used by Pantano et al to evaluate the poor dispersion of carbon nanotubes in nanocomposites 19 . Ashraf et al studied the dispersion (quantified as dispersion index) and thermal properties of graphene polymer composites using a close-up lens infrared thermography 20 . Gresil et al studied the thermal diffusivity mapping of graphene-based polymer nanocomposites at a resolution of 200 µm per pixel 21 .…”

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confidence: 99%

Automatic dispersion, defect, curing, and thermal characteristics determination of polymer composites using micro-scale infrared thermography and machine learning algorithm

Rahman

Ashraf

2023

Sci Rep

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Infrared thermography is a non-destructive technique that can be exploited in many fields including polymer composite investigation. Based on emissivity and thermal diffusivity variation; components, defects, and curing state of the composite can be identified. However, manual processing of thermal images that may contain significant artifacts, is prone to erroneous component and property determination. In this study, thermal images of different graphite/graphene-based polymer composites fabricated by hand, planetary, and batch mixing techniques were analyzed through an automatic machine learning model. Filler size, shape, and location can be identified in polymer composites and thus, the dispersion of different samples was quantified with a resolution of ~ 20 µm despite having artifacts in the thermal image. Thermal diffusivity comparison of three mixing techniques was performed for 40% graphite in the elastomer. Batch mixing demonstrated superior dispersion than planetary and hand mixing as the dispersion index (DI) for batch mixing was 0.07 while planetary and hand mixing showed 0.0865 and 0.163 respectively. Curing was investigated for a polymer with different fillers (PDMS took 500 s while PDMS-Graphene and PDMS Graphite Powder took 800 s to cure), and a thermal characteristic curve was generated to compare the composite quality. Therefore, the above-mentioned methods with machine learning algorithms can be a great tool to analyze composite both quantitatively and qualitatively.

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Interface thermal resistance of micron-thin film

Chen

Zheng

Wei

et al. 2023

International Journal of Heat and Mass Transfer

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Non-Destructive Investigation of Dispersion, Bonding, and Thermal Properties of Emerging Polymer Nanocomposites Using Close-Up Lens Assisted Infrared Thermography

Cited by 5 publications

References 10 publications

Multifunctional Graphene–Polymer Nanocomposite Sensors Formed by One-Step In Situ Shear Exfoliation of Graphite

Multifunctional Graphene–Polymer Nanocomposite Sensors Formed by One-Step In Situ Shear Exfoliation of Graphite

Automatic dispersion, defect, curing, and thermal characteristics determination of polymer composites using micro-scale infrared thermography and machine learning algorithm

Interface thermal resistance of micron-thin film

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