Torsional characteristics of carbon nanotubes: Micropolar elasticity models and molecular dynamics simulation

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dc.contributor.author Razie Razieh Izadi
dc.contributor.author Meral Tuna
dc.contributor.author Patrizia Trovalusci
dc.contributor.author Esmaeal Ghavanloo
dc.date.accessioned 2025-10-06T17:50:34Z
dc.date.issued 2021
dc.description.abstract Efficient application of carbon nanotubes (CNTs) in nano-devices and nano-materials requires comprehensive understanding of their mechanical properties. As observations suggest size dependent behaviour non-classical theories preserving the memory of body’s internal structure via additional material parameters offer great potential when a continuum modelling is to be preferred. In the present study micropolar theory of elasticity is adopted due to its peculiar character allowing for incorporation of scale effects through additional kinematic descriptors and work-conjugated stress measures. An optimisation approach is presented to provide unified material parameters for two specific class of single-walled carbon nanotubes (e.g. armchair and zigzag) by minimizing the difference between the apparent shear modulus obtained from molecular dynamics (MD) simulation and micropolar beam model considering both solid and tubular cross-sections. The results clearly reveal that micropolar theory is more suitable compared to internally constraint couple stress theory due to the essentiality of having skew-symmetric stress and strain measures as well as to the classical local theory (Cauchy of Grade 1) which cannot accounts for scale effects. To the best of authors’ knowledge this is the first time that unified material parameters of CNTs are derived through a combined MD-micropolar continuum theory. © 2021 Elsevier B.V. All rights reserved.
dc.identifier.doi 10.3390/nano11020453
dc.identifier.issn 20794991
dc.identifier.issn 2079-4991
dc.identifier.uri https://www.scopus.com/inward/record.uri?eid=2-s2.0-85100691680&doi=10.3390%2Fnano11020453&partnerID=40&md5=d5b37facb2dafebf827a008ed36fd193
dc.identifier.uri https://gcris.yasar.edu.tr/handle/123456789/9014
dc.language.iso English
dc.publisher MDPI AG
dc.relation.ispartof Nanomaterials
dc.source Nanomaterials
dc.subject Micropolar Continua, Molecular Dynamics, Optimisation, Swcnts Parameters Identification
dc.title Torsional characteristics of carbon nanotubes: Micropolar elasticity models and molecular dynamics simulation
dc.type Article
dspace.entity.type Publication
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gdc.description.startpage 453
gdc.description.volume 11
gdc.identifier.openalex W3128087140
gdc.identifier.pmid 33670119
gdc.index.type Scopus
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gdc.oaire.keywords Chemistry
gdc.oaire.keywords optimisation
gdc.oaire.keywords SWCNTs parameters identification
gdc.oaire.keywords SWCNTs parameters identification; micropolar continua; molecular dynamics; optimisation
gdc.oaire.keywords Micropolar continua; Molecular Dynamics; SWCNTs parameters identification; Optimisation
gdc.oaire.keywords Micropolar continua; Molecular dynamics; Optimisation; SWCNTs parameters identification
gdc.oaire.keywords QD1-999
gdc.oaire.keywords micropolar continua
gdc.oaire.keywords molecular dynamics
gdc.oaire.keywords Article
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gdc.oaire.sciencefields 0203 mechanical engineering
gdc.oaire.sciencefields 02 engineering and technology
gdc.oaire.sciencefields 0210 nano-technology
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gdc.opencitations.count 33
gdc.plumx.crossrefcites 33
gdc.plumx.mendeley 11
gdc.plumx.pubmedcites 11
gdc.plumx.scopuscites 34
oaire.citation.endPage 20
oaire.citation.startPage 1
person.identifier.scopus-author-id Izadi- Razie (Razieh) (6506336809), Tuna- Meral (56305598100), Trovalusci- Patrizia (6602160159), Ghavanloo- Esmaeal (26221582300)
project.funder.name Funding: This work was done when Razie Izadi had a research scholarship at DISG Sapienza University of Rome with financial support of Italian Ministry of Education University and Research PRIN 2017 project 2017HFPKZY (Grant No. B86J16002300001) “Modeling of constitutive laws for traditional and innovative building materials ” CUP: B88D19001130001 with Patrizia Trovalusci as Sapienza local PI. The support of Sapienza Research Grants “Progetti Medi” 2017 (Grant No. B83C17001440005) and “Progetti Grandi” 2018 (Protocol No. RG1181642E3B3117) are also acknowledged.
publicationissue.issueNumber 2
publicationvolume.volumeNumber 11
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