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1 article(s) from Farid, Ali Asghar

Nonclassical dynamic modeling of nano/microparticles during nanomanipulation processes

Moharam Habibnejad Korayem,
Ali Asghar Farid and
Rouzbeh Nouhi Hefzabad

Beilstein J. Nanotechnol. 2020, 11, 147–166, doi:10.3762/bjnano.11.13

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Figure 1: Schematic of the manipulation process of a cylindrical nanoparticle by means of AFM.

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Figure 2: Nanoparticle manipulation forces and angles in a) 3D view and b) side view.

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Figure 3: Timoshenko beam model: kinematic parameters, loading and coordinate system [27].

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Figure 4: General algorithm for dynamic and mechanical modeling.

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Figure 5: Simulation of critical times and forces in sliding and rolling modes for a gold nanoparticle with a...

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Figure 6: Simulations of the variation of the tip force angle (α) during the manipulation process until achie...

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Figure 7: Classical and nonclassical modeling of the deflections of a cylindrical gold nanoparticle (length =...

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Figure 8: Classical and nonclassical modeling of the rotation angles of a cylindrical gold nanoparticle (leng...

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Figure 9: Natural frequencies of the classical and nonclassical models of a cylindrical gold nanoparticle wit...

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Figure 10: Sensitivity of classical and nonclassical Timoshenko beam model deflections to the change in aspect...

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Figure 11: Simulation of motion of a cylindrical gold nanoparticle during a manipulation of 200 nm. A) Aspect ...

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Figure 12: The sensitivity of manipulation dynamics to size effects (length = 25 µm and aspect ratio = 30).

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Figure 13: Manipulation of the nonclassical Timoshenko model for 0.5l and 1.5l.

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Figure 14: Classical stresses in a cylindrical gold nanoparticle with a length of 25 µm and aspect ratio of 30....

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Figure 15: Equivalent stresses (nonclassical) in a cylindrical gold nanoparticle with a length of 25 µm and as...

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Figure 16: Comparison of the classical stresses and nonclassical equivalent stresses with respect to changes i...

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Figure 17: Variation of nonclassical equivalent stresses with material length scale parameter and change in as...

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Figure 18: Comparison of the critical force and time simulation using the JKR contact model for a gold particl...

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Figure 19: Comparison of the critical force and time simulation using the Lundberg cylindrical contact model f...

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Figure 20: Comparison of the deflections of a polystyrene nanorod using classical and nonclassical models assu...

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Figure 21: Comparison of polystyrene nanorod deflections in the nonclassical Timoshenko beam model with respec...

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Figure 22: Simulation of the manipulation process of a polystyrene nanorod and comparison with the presented m...

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Figure 23: Variation of the failure aspect ratio versus l/d for a polystyrene nanorod.

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Full Research Paper

Published 13 Jan 2020

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