Strengthening and toughening epoxy polymer at cryogenic temperature using cupric oxide nanorods

Strengthening and toughening epoxy polymer at cryogenic temperature using cupric oxide nanorods

At cryogenic temperatures thermoset polymers suffer from low fracture toughness. Herein, we present a strengthening and toughening technique for cryogenic applications using cupric oxide (CuO) nanorods. These nanorods are synthesized via a hydrothermal reaction to give an average length of 1.64 μm a...

Full description

Saved in:
Bibliographic Details
Published in:Composites science and technology Vol. 208; p. 108762
Main Authors: Chang, Wenkai, Rose, L.R. Francis, Islam, Mohammad S., Wu, Shuying, Peng, Shuhua, Huang, Feng, Kinloch, Anthony J., Wang, Chun H.
Format: Journal Article
Language:English
Published: Barking Elsevier Ltd 26-05-2021
Elsevier BV
Subjects:
Copper oxides
Cryogenic engineering
Cryogenic temperature
Diameters
Epoxy resins
Fiber composites
Fracture toughness
Fuel tanks
Hydrothermal reactions
Low temperature physics
Magnetostriction
Material modelling
Nano composites
Nanocomposites
Nanorods
Polymers
Residual stress
Room temperature
Strengthening
Temperature effects
Tensile strength
Thermal expansion
Thermosetting resins
Cryogenic engineering
Nano composites
Material modelling
Fracture toughness
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:At cryogenic temperatures thermoset polymers suffer from low fracture toughness. Herein, we present a strengthening and toughening technique for cryogenic applications using cupric oxide (CuO) nanorods. These nanorods are synthesized via a hydrothermal reaction to give an average length of 1.64 μm and a diameter of 270 nm. They exhibit a low coefficient of thermal expansion (CTE) at cryogenic temperatures, due to the magnetostriction effect. Epoxy nanocomposites containing up to 8 wt% of CuO nanorods were investigated. Both the tensile strength and the fracture energy were found to increase with CuO nanorods content up to 4 wt%, showing improvements of 18% and 133% respectively at room temperature, and of 21% and 261% at −196 °C. Current theoretical models were shown to account for the experimentally measured values of both strength and toughness at room temperature, but to significantly underestimate the observed values at −196 °C. However, modifications of these models to include thermal residual stresses generated by the CTE mismatch are proposed that lead to good agreement with the measured values. The technique to strengthen and toughen epoxy using CuO nanorods and the modified theories provide potential for designing and optimising multi-scale fibre composites for cryogenic applications such as cryogenic fuel tanks. [Display omitted] •An epoxy polymer is strengthened and toughened at cryogenic temperatures using CuO nanorods.•Thermal residual stress promotes the strengthening and toughening effects on epoxy nanocomposites at cryogenic temperatures.•Existing analytical models are modified to include the thermal residual stress developed at cryogenic temperatures.
ISSN:0266-3538
1879-1050
DOI:10.1016/j.compscitech.2021.108762