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The Analysis of Micro-Scale Deformation and Fracture of Carbonized Elastomer-Based Composites by In Situ SEM
- Source :
- Molecules, Volume 26, Issue 3, Molecules, Vol 26, Iss 587, p 587 (2021)
- Publication Year :
- 2020
-
Abstract
- Carbonized elastomer-based composites (CECs) possess a number of attractive features in terms of thermomechanical and electromechanical performance, durability in aggressive media and facile net-shape formability, but their relatively low ductility and strength limit their suitability for structural engineering applications. Prospective applications such as structural elements of micro-electro-mechanical systems MEMS can be envisaged since smaller principal dimensions reduce the susceptibility of components to residual stress accumulation during carbonization and to brittle fracture in general. We report the results of in situ in-SEM study of microdeformation and fracture behavior of CECs based on nitrile butadiene rubber (NBR) elastomeric matrices filled with carbon and silicon carbide. Nanostructured carbon composite materials were manufactured via compounding of elastomeric substance with carbon and SiC fillers using mixing rolling mill, vulcanization, and low-temperature carbonization. Double-edge notched tensile (DENT) specimens of vulcanized and carbonized elastomeric composites were subjected to in situ tensile testing in the chamber of the scanning electron microscope (SEM) Tescan Vega 3 using a Deben microtest 1 kN tensile stage. The series of acquired SEM images were analyzed by means of digital image correlation (DIC) using Ncorr open-source software to map the spatial distribution of strain. These maps were correlated with finite element modeling (FEM) simulations to refine the values of elastic moduli. Moreover, the elastic moduli were derived from unloading curve nanoindentation hardness measurements carried out using a NanoScan-4D tester and interpreted using the Oliver–Pharr method. Carbonization causes a significant increase of elastic moduli from 0.86 ± 0.07 GPa to 14.12 ± 1.20 GPa for the composite with graphite and carbon black fillers. Nanoindentation measurements yield somewhat lower values, namely, 0.25 ± 0.02 GPa and 9.83 ± 1.10 GPa before and after carbonization, respectively. The analysis of fractography images suggests that crack initiation, growth and propagation may occur both at the notch stress concentrator or relatively far from the notch. Possible causes of such response are discussed, namely, (1) residual stresses introduced by processing<br />(2) shape and size of fillers<br />and (3) the emanation and accumulation of gases in composites during carbonization.
- Subjects :
- Materials science
Carbon Compounds, Inorganic
Finite Element Analysis
composite materials
Pharmaceutical Science
Fractography
Tescan Vega 3
μ-DENT
digital image correlation (DIC)
Elastomer
Article
Analytical Chemistry
Nanocomposites
lcsh:QD241-441
lcsh:Organic chemistry
Residual stress
Hardness
Elastic Modulus
Tensile Strength
Drug Discovery
Ultimate tensile strength
Materials Testing
Computer Simulation
Deben microtest
Physical and Theoretical Chemistry
Composite material
Ductility
NanoScan-4D
Carbonization
Organic Chemistry
Silicon Compounds
Nanoindentation
in situ tensile test
Carbon
Elastomers
Chemistry (miscellaneous)
Microscopy, Electron, Scanning
Molecular Medicine
Stress, Mechanical
Deformation (engineering)
carbonized elastomeric matrices
C/SiC fillers
Subjects
Details
- ISSN :
- 14203049
- Volume :
- 26
- Issue :
- 3
- Database :
- OpenAIRE
- Journal :
- Molecules (Basel, Switzerland)
- Accession number :
- edsair.doi.dedup.....0523dfe0d4b38b16b144e8ef2eed4d12