Influence of Chemical Polymer Additive on the Physical and Mechanical Properties of Expanded Polystyrene Concrete

John, Wasiu; Baba, Daoud Mohammad

doi:10.14311/ap.2020.60.0158

Cited by 1 publication

(1 citation statement)

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“…Expanded polystyrene (EPS), a white color foam primarily used for packaging and insulation, is basically produced from small spherical solid beads of polystyrene (Rydzkowski et al, 2020). It is a lighter material and exhibits excellent adaptability, greater dimensional stability, high resistance toward bending and compression, less toxicity, high moisture resistance, and remarkable thermal insulation properties (Ramli Sulong et al, 2019; Tahir & Hamed, 2022; Wasiu & Baba, 2020). Hence, these properties make it an excellent material for packaging and construction (buildings, roads, railway, etc.)…”

Section: Introductionmentioning

confidence: 99%

Evaluation of a novel composite of expanded polystyrene with rGO and SEBS‐g‐MA

Fatima,

Qamar,

Zahra

et al. 2024

Microscopy Res & Technique

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This study displays the effect of reduced graphene oxide (rGO) nanofiller and polystyrene‐b‐poly(ethylene‐ran‐butylene)‐b‐polystyrene‐grafted maleic anhydride (SEBS‐g‐MA) on the optical, thermal, and mechanical features of expanded polystyrene (EPS). First, the thin films of pristine EPS and composites were prepared using solution cast method. The prepared films were subjected to fourier‐transform infrared (FTIR), SEM, UV–visible spectrophotometer, thermogravimetric analysis/differential scanning calorimetry, and universal testing machine for structural, morphological, optical, thermal, and mechanical characterizations. Optical study revealed a significant increase in refractive index and absorption of composites than EPS. Indirect band‐gap energy of EPS (~4.08 eV) was reduced to ~1.61 eV for rGO composite and ~ 2.23 eV for composite composed of rGO and SEBS‐g‐MA. Thermal analyses presented improvement in characterization temperatures such as T10, T50, Tp, Tm, and Tg of composites, which ultimately lead to the thermal stability of prepared composites than pristine EPS. Stress–strain curves displayed higher yield strength (46.62 MPa), Young's modulus (96.29 MPa), and strain at break (0.54%) for EPS+rGO composite than pure EPS having stress at break (1.01 MPa), Young's modulus (12.44 MPa), and strain at break (0.08%). Moreover, ductility with relatively higher strain at break (0.61%) and lower Young's modulus (79.32 MPa) and yield strength (32.98 MPa) was noticed in EPS+rGO+SEBS‐g‐MA composite than EPS+rGO composite film. Morphological analysis revealed a change in globular morphology of EPS and inhomogeneous dispersion of rGO in EPS to homogeneously dispersed rGO in EPS matrix without globules owing to the addition of SEBS‐g‐MA. The increase in compatibility of EPS and rGO due to SEBS‐g‐MA was also observed in FTIR spectra.Research Highlights Here, the solution casting approach was used to create the composite film of EPS and rGO with globules of various sizes. After adding SEBS‐g‐MA, the shape altered to globular free films exhibiting homogenous dispersion of rGO in EPS matrix. An optical investigation showed that composite materials had a significantly higher refractive index and absorption than EPS. The optical, thermal, and mechanical investigations suggest that the produced composites may be a great substitute for virgin EPS, allowing for a wider range of applications.

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