Research Data Leeds Repository

Low Magnetic Field Induced Extrinsic Strains in Multifunctional Particulate Composites

Mucolli, Andiol and Midmer, Alden and Manolesos, Marinos and Aldosari, Salem and Lira, Cristian and Yazdani Nezhad, Hamed (2024) Low Magnetic Field Induced Extrinsic Strains in Multifunctional Particulate Composites. University of Leeds. [Dataset] https://doi.org/10.5518/1544

Dataset description

The current paper reports on the quantification of the effect of magnetic field on the mechanical performance of ferromagnetic nanocomposites in situ during a basic standard tensile testing. The research investigates altering the basic mechanical properties (Modulus and Strength) via application of contact-less magnetic field, as primary attempt for a future composites strengthening mechanism. The nanocomposite specimens were fabricated using filament-based 3D printing and were comprised of ferromagnetic nanoparticle embedded thermoplastic polymers. The nanoparticles were iron particles dispersed at 21wt.% (10.2 Vol.%) inside polylactic acid (PLA) polymer, as characterized utilising optical microscopy and 3D X-ray computed tomography. The magnetic field was stationary and produced using permanent Neodymium round-shaped magnets available at two field strengths below 1 Tela. The 3D printing was a MakerBot Replicator machine operating based upon fused deposition method which utilised 1.75mm-diameter filaments made of the iron particles-based PLA composites. The magnetic field equipped tensile tests were accompanied with real-time digital image correlation technique for localized strain measurements across the specimens at 10-micron pixel resolution. It was observed that the lateral magnetic field induces slight Poisson’s effect on development of extrinsic strain across the length of the tensile specimens. However, the effect reasonably interferes with the evolution of strain fields via introduction of localised compressive strains attributed to accumulated magnetic polarisation at the magnetic particles at extrinsic scale. The theory overestimated the moduli by a factor of approximately 3.1. To enhance the accuracy of its solutions for 3D printed specimens, it is necessary to incorporate pore considerations into the theoretical derivations. Additionally, a modest 10% increase in ultimate tensile strength was observed during tensile loading. This finding suggests that field-assisted strengthening can be effective for as-received 3D printed magnetic composites in their solidified state, provided that the material and field are optimally designed and implemented. This approach could propose a viable method for remote field tailoring to strengthen the material by mitigating defects induced during the 3D printing process.

Subjects:	H000 - Engineering > H300 - Mechanical engineering
Divisions:	Faculty of Engineering and Physical Sciences > School of Mechanical Engineering
Related resources:	Location Type https://doi.org/10.3390/jcs8060231 Publication
License:	Creative Commons Attribution 4.0 International (CC BY 4.0)
Date deposited:	19 Jun 2024 16:45
URI:	https://archive.researchdata.leeds.ac.uk/id/eprint/1299
Additional details Additional details Creators: Creators ORCID Other ID Email Primary affiliation Primary affiliation ID Primary affiliation ID type Secondary affiliation Secondary affiliation ID Secondary affiliation ID type Mucolli, Andiol City, University of London https://ror.org/04489at23 ror Midmer, Alden https://orcid.org/0000-0002-3288-0597 City, University of London https://ror.org/04489at23 ror Manolesos, Marinos https://orcid.org/0000-0002-5506-6061 National Technical University of Athens https://ror.org/03cx6bg69 ror Aldosari, Salem King Abdulaziz City for Science and Technology https://ror.org/05tdz6m39 ror Lira, Cristian https://orcid.org/0000-0002-2223-4604 National Composites Centre https://ror.org/00bpwbx65 ror Yazdani Nezhad, Hamed https://orcid.org/0000-0003-0832-3579 University of Leeds https://ror.org/024mrxd33 ror Type of data: Dataset Research funders: EPSRC Grant numbers: EP/R016828/1 Publication date: 2024 Resource language: English Metadata language: English Publisher: University of Leeds Contact Email Address: h.yazdaninezhad@leeds.ac.uk Last Modified: 20 Jun 2024 08:31

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Documentation

README_Yazdani-Nezhad_2024.txt [2kB] README_Yazdani-Nezhad_2024.txt [2kB] README_Yazdani-Nezhad_2024.txt [2kB] Visible to: Anyone File name: README_Yazdani-Nezhad_2024.txt Content type: Documentation Mime-Type: text/plain License: Creative Commons Attribution 4.0 International (CC BY 4.0) File size: 2kB

3Dprinting.mp4 [5MB] 3Dprinting.mp4 [5MB] 3Dprinting.mp4 [5MB] Visible to: Anyone File name: 3Dprinting.mp4 Content type: Documentation Description: short video demonstrating printing out magnetic composite dogbone sample Mime-Type: video/mp4 License: Creative Commons Attribution 4.0 International (CC BY 4.0) File size: 5MB

3Dprinting_model.mp4 [18MB] 3Dprinting_model.mp4 [18MB] 3Dprinting_model.mp4 [18MB] Visible to: Anyone File name: 3Dprinting_model.mp4 Content type: Documentation Description: short video showing modelling dogbone CAD model for 3D printing Mime-Type: video/mp4 License: Creative Commons Attribution 4.0 International (CC BY 4.0) File size: 18MB

DIC_test.mp4 [7MB] DIC_test.mp4 [7MB] DIC_test.mp4 [7MB] Visible to: Anyone File name: DIC_test.mp4 Content type: Documentation Description: short video showing DIC test setup and conduct Mime-Type: video/mp4 License: Creative Commons Attribution 4.0 International (CC BY 4.0) File size: 7MB

DIC_with_magnet.mp4 [8MB] DIC_with_magnet.mp4 [8MB] DIC_with_magnet.mp4 [8MB] Visible to: Anyone File name: DIC_with_magnet.mp4 Content type: Documentation Description: short video showin typical DIC strain evolution measurement in the presence of magnetic field Mime-Type: video/mp4 License: Creative Commons Attribution 4.0 International (CC BY 4.0) File size: 8MB

DIC_without_magnet.mp4 [114MB] DIC_without_magnet.mp4 [114MB] DIC_without_magnet.mp4 [114MB] Visible to: Anyone File name: DIC_without_magnet.avi Content type: Documentation Description: short video showin typical DIC strain evolution measurement without magnetic field Mime-Type: video/x-msvideo License: Creative Commons Attribution 4.0 International (CC BY 4.0) File size: 114MB

Data

Further_data.xlsx [3MB] Further_data.xlsx [3MB] Further_data.xlsx [3MB] Visible to: Anyone File name: Further_data.xlsx Content type: Data Description: Excel file containing raw data Mime-Type: application/vnd.openxmlformats-officedocument.spreadsheetml.sheet License: Creative Commons Attribution 4.0 International (CC BY 4.0) File size: 3MB

Tensiletest_data.xlsx [18MB] Tensiletest_data.xlsx [18MB] Tensiletest_data.xlsx [18MB] Visible to: Anyone File name: Tensiletest_data.xlsx Content type: Data Description: Excel file containing tensile data Mime-Type: application/vnd.openxmlformats-officedocument.spreadsheetml.sheet License: Creative Commons Attribution 4.0 International (CC BY 4.0) File size: 18MB

Program

Theoretical_model_code.m [4kB] Theoretical_model_code.m [4kB] Theoretical_model_code.m [4kB] Visible to: Anyone File name: Theoretical_model_code.m Content type: Program Description: MATLAB code for the proposed constitutive expression developed and used in the paper Mime-Type: application/vnd.wolfram.mathematica.package License: Creative Commons Attribution 4.0 International (CC BY 4.0) File size: 4kB