0000000000765081

AUTHOR

Gediminas Monastyreckis

showing 4 related works from this author

Micromechanical modeling of MXene-polymer composites

2020

Polymer composites are considered among the most promising materials for functional and structural applications. Improvement of mechanical properties of polymer composites using nanomaterials has generated much interest in recent years. This study aimed to predict the tensile strength and determine the damage mechanism of MXene-polyvinyl alcohol and MXene-epoxy composites. All parameters such as particle size, mechanical properties and interface layer strength were calibrated by finite element modeling with respect to experimental results. The influence of aspect ratio, volume fraction and MXene flake alignment on final mechanical properties of representative volume element models were inve…

Materials scienceComposite numberModulus02 engineering and technologyGeneral ChemistryEpoxy010402 general chemistry021001 nanoscience & nanotechnology01 natural sciences0104 chemical sciencesNanomaterialsvisual_artUltimate tensile strengthVolume fractionRepresentative elementary volumevisual_art.visual_art_mediumGeneral Materials ScienceParticle sizeComposite material0210 nano-technologyCarbon
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Deformation and failure of MXene nanosheets

2020

This work is aimed at the development of finite element models and prediction of the mechanical behavior of MXene nanosheets. Using LS-Dyna Explicit software, a finite element model was designed to simulate the nanoindentation process of a two-dimensional MXene Ti3C2Tz monolayer flake and to validate the material model. For the evaluation of the adhesive strength of the free-standing Ti3C2Tz-based film, the model comprised single-layered MXene nanosheets with a specific number of individual flakes, and the reverse engineering method with a curve fitting approach was used. The interlaminar shear strength, in-plane stiffness, and shear energy release rate of MXene film were predicted using th…

Materials science02 engineering and technology010402 general chemistrylcsh:Technology01 natural sciencesArticleMonolayermedicineGeneral Materials ScienceComposite materiallcsh:Microscopylcsh:QC120-168.85Strain energy release ratelcsh:QH201-278.5lcsh:TTension (physics)MXene; mechanical behavior; finite element modelingStiffnessfinite element modelingNanoindentation021001 nanoscience & nanotechnologyFinite element method0104 chemical sciencesShear (sheet metal)lcsh:TA1-2040mechanical behaviorlcsh:Descriptive and experimental mechanicslcsh:Electrical engineering. Electronics. Nuclear engineeringDeformation (engineering)medicine.symptomlcsh:Engineering (General). Civil engineering (General)0210 nano-technologyMXenelcsh:TK1-9971
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Wettability of MXene and its interfacial adhesion with epoxy resin

2021

Abstract The surface energies of MXene nanofillers critically affect the mechanical properties and durability of any polymer-based devices and composites to which these fillers are applied. In this context, this study comprehensively investigates Ti3C2Tz MXenes prepared via the hydrochloric acid/lithium fluoride etching of Ti3AlC2. The surface energy values of 10-layer MXene coatings were evaluated to be between 47.98 and 64.48 mJ/m2 as per contact-angle measurements. The wettability properties were found to depend on the number of coating layers and the liquids used. Additionally, the coating roughness was evaluated by using atomic force microscopy. The effectiveness of MXenes as a reinfor…

Materials scienceScanning electron microscopeContext (language use)02 engineering and technologyEpoxyAdhesionengineering.material010402 general chemistry021001 nanoscience & nanotechnologyCondensed Matter Physics01 natural sciencesSurface energy0104 chemical sciencesCoatingvisual_artvisual_art.visual_art_mediumengineeringGeneral Materials ScienceWettingComposite material0210 nano-technologyMXenesMaterials Chemistry and Physics
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Strain Sensing Coatings for Large Composite Structures Based on 2D MXene Nanoparticles

2021

Real-time strain monitoring of large composite structures such as wind turbine blades requires scalable, easily processable and lightweight sensors. In this study, a new type of strain-sensing coating based on 2D MXene nanoparticles was developed. A Ti3C2Tz MXene was prepared from Ti3AlC2 MAX phase using hydrochloric acid and lithium fluoride etching. Epoxy and glass fibre–reinforced composites were spray-coated using an MXene water solution. The morphology of the MXenes and the roughness of the substrate were characterised using optical microscopy and scanning electron microscopy. MXene coatings were first investigated under various ambient conditions. The coating experienced no sign…

MXenes; coatings; strain sensors; electrical properties; cyclic loadingMaterials scienceScanning electron microscopeComposite numbercoatings02 engineering and technologySurface finishengineering.materiallcsh:Chemical technology010402 general chemistry7. Clean energy01 natural sciencesBiochemistryArticleMXenesAnalytical ChemistryCoatingElectrical resistance and conductancelcsh:TP1-1185strain sensorsElectrical and Electronic EngineeringComposite materialInstrumentationcyclic loadingEpoxy021001 nanoscience & nanotechnologyAtomic and Molecular Physics and Optics0104 chemical sciencesGauge factorvisual_artelectrical propertiesengineeringvisual_art.visual_art_medium0210 nano-technologyMXenesSensors
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