Modeling the mechanical properties of nanoparticles: a review

Amodeo, Jonathan; Pizzagalli, Laurent

doi:10.5802/crphys.70

Cited by 26 publications

(30 citation statements)

References 179 publications

(345 reference statements)

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“…Two types of core–shell systems are studied, Au 3 Pd 97 with a small core and Au 30 Pd 70 with a larger Au core. The pristine Pd nanocubes show an elastic-to-plastic transition at 4.46% strain (as determined by the abrupt drop in the stress), followed by a seesaw behavior, as expected for an FCC single crystal during indentation . The quasi-elastic stress increases up to 2.5 GPa, creating plastic nucleation events, leading to a 40–60% drop in the stress.…”

Section: Results and Discussionmentioning

confidence: 67%

“…Despise this, as SFs play a crucial role in the deformation of nanosized structures and can be of lengths comparable to the nanoparticle size, approximating partial dislocations to full dislocations can significantly affect the prediction of dislocation generation and propagation . Additional information can be found in a recent review work where different simulation techniques are described for the nanoindentation of nanoparticles . Experimentally, nanoindentation provides a means to study a material’s elastic–plastic and failure behavior by analyzing the initial and final states. , In order to obtain a complete picture of the deformation process, scanning electron microscopy (SEM) and transmission electron microscopy (TEM) are used to perform mechanical experiments in situ at the nanoscale while observing the behavior of the nanostructured sample directly upon subjecting to an external force. − For example, in situ TEM nanoindentation experiments have shown softening effects with the decrease in size for nanoscaled metals , below a critical size, that is, an inverse Hall–Petch effect …”

Section: Introductionmentioning

confidence: 99%

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Soft or Hard? Investigating the Deformation Mechanisms of Au–Pd and Pd Nanocubes under Compression: An Experimental and Molecular Dynamics Study

et al. 2021

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In the search for new mechanisms to improve and control the mechanical properties of nanostructures, the idea of tuning the strength through composition is appealing because of the extensive experimental availability of nanoparticles with segregated configurations, such as core−shell nanoparticles. However, not much is known about the deformation mechanism of these types of systems because of the lack of correlation between theoretical predictions and experimental observations. In this work, we investigate the atomistic mechanical response of Au−Pd core−shell and Pd nanocubes under indentation, using molecular dynamics simulations. These results are compared to experimental observations of in situ transmission electron microscopy (TEM) nanoindentation on similar nanoparticles. Our study resolves the nucleation of Shockley partial dislocations and their propagation in Au−Pd core−shell and single-crystalline Pd nanocubes. In the latter, Shockley partial dislocations originate at the cube corners and create stacking faults that propagate across the nanoparticle, creating the so-called V-shaped defects. In contrast, in Au−Pd core−shell nanocubes, nucleation starts at the semicoherent Au−Pd interface, where a network of misfits acts as dislocation storage, reducing the nanocube's strength. We explore the effect of the core size and its function as a dislocation barrier for nanocubes of smaller sizes. Additionally, strain hardening was observed as the core size increased and, for the case of the largest core (Au 30 Pd 70 ) at strain values above 20%, where a complex network of different types of dislocations, including sessile dislocations, is observed. Our results suggest a clear agreement between simulation and experiments, which points to a promising field in which combining two or more metals in a core−shell configuration can be used to tune and control the mechanical properties at the nanoscale.

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Section: Results and Discussionmentioning

confidence: 67%

Section: Introductionmentioning

confidence: 99%

Soft or Hard? Investigating the Deformation Mechanisms of Au–Pd and Pd Nanocubes under Compression: An Experimental and Molecular Dynamics Study

et al. 2021

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“…Compression of small metal FCC nanoparticles has also been studied with simulation methods such as density functional theory (DFT), molecular dynamics (MD), and finite element methods (FEM). 15,16 Among these methods, DFT calculations are usually limited to small numbers of atoms because of the high computational cost, and FEM simulations include continuum assump-tions that may not be valid at the nanoscale, and also cannot provide atomic resolution. 15 MD allows the modeling of nanoparticles of different sizes and geometries at the atomic level, with a reasonable computational cost.…”

mentioning

confidence: 99%

“…15,16 Among these methods, DFT calculations are usually limited to small numbers of atoms because of the high computational cost, and FEM simulations include continuum assump-tions that may not be valid at the nanoscale, and also cannot provide atomic resolution. 15 MD allows the modeling of nanoparticles of different sizes and geometries at the atomic level, with a reasonable computational cost. 17 Previous MD models of metal FCC nanoparticles found that nanoparticles exhibit elasticity at low stress [18][19][20] .…”

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confidence: 99%

Platinum nanoparticle compression: Combining in situ TEM and atomistic modeling

Espinosa

Azadehranjbar

Ding

et al. 2022

Applied Physics Letters

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Platinum Nanoparticle Compression: Combining in situ TEM and Atomistic ModelingThe mechanical behavior of nanoparticles governs their performance and stability in many applications. However, the small sizes of technologically relevant nanoparticles, with diameters in the range of 10 nm or less, significantly complicate experimental examination.These small nanoparticles are difficult to manipulate onto commercial test platforms, and deform at loads that are below the typical noise floor of the testing instruments. Here we synthesized small platinum nanoparticles directly onto a mechanical tester, and used a modified nanomanipulator to enhance load resolution to the nanonewton scale. We demonstrated the in situ compression of an 11.5-nm platinum nanoparticle with simultaneous high-resolution measurements of load and particle morphology. Molecular dynamics simulations were performed on similarly sized particles to achieve complementary measurements of load and morphology, along with atomic resolution of dislocations. The experimental and simulation results revealed comparable values for the critical resolved shear stress for failure, 1.28 GPa and 1.15 GPa, respectively. Overall, this investigation demonstrated the promise of, and some initial results from, the combination of atomistic simulations and in situ experiments with an unprecedented combination of high spatial resolution and high load resolution to understand the behavior of metal nanoparticles under compression.Platinum Nanoparticle Compression: Combining in situ TEM and Atomistic Modeling Metal face-centered-cubic (FCC) nanoparticles possess unique physical, optical, electrical, and magnetic properties with applications in fields including medicine, 1 electronics, 2 water treatment, 3 and energy technologies. 4,5 Because properties depend on nanoparticle shape and size, the performance in these applications depends on the stability of the particle, and its resistance to any mechanical loading or shearing during use. Therefore, understanding the mechanical properties of metal nanoparticles is vital for controlling their performance.Great strides have been made in the experimental measurement of the mechanical properties of metal nanoparticles, including with diamond anvil cells, 6,7 and with in situ compression inside a scanning electron microscope (SEM) 8,9 or a transmission electron microscope (TEM). [10][11][12] These techniques have been extensively applied to larger nanoparticles, with diameters in the range of tens to hundreds of nanometers, but are more challenging to apply to smaller nanoparticles with diameters in the range of 10 nm and below, so the understanding of nanoparticle deformation in this size regime remains incomplete.

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“…Despite being a less studied field, the mechanical behavior of nanoparticles has been a worthy subject of study in the last years due to their unexpected mechanical properties [5][6][7][8][9][10]. Mechanical properties in nanoparticles can be advantageously tailored through several factors such as nanoparticle size [11,12], lattice orientation [13], and surface engineering [14][15][16][17]. All those factors directly impact the elastic and plastic behavior of the nanostructures.…”

Section: Introductionmentioning

confidence: 99%

Probing the Mechanical Properties of Porous Nanoshells by Nanoindentation

et al. 2022

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In this contribution, we present a study of the mechanical properties of porous nanoshells measured with a nanoindentation technique. Porous nanoshells with hollow designs can present attractive mechanical properties, as observed in hollow nanoshells, but coupled with the unique mechanical behavior of porous materials. Porous nanoshells display mechanical properties that are dependent on shell porosity. Our results show that, under smaller porosity values, deformation is closely related to the one observed for polycrystalline and single-crystalline nanoshells involving dislocation activity. When porosity in the nanoparticle is increased, plastic deformation was mediated by grain boundary sliding instead of dislocation activity. Additionally, porosity suppresses dislocation activity and decreases nanoparticle strength, but allows for significant strain hardening under strains as high as 0.4. On the other hand, Young’s modulus decreases with the increase in nanoshell porosity, in agreement with the established theories of porous materials. However, we found no quantitative agreement between conventional models applied to obtain the Young’s modulus of porous materials.

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Modeling the mechanical properties of nanoparticles: a review

Cited by 26 publications

References 179 publications

Soft or Hard? Investigating the Deformation Mechanisms of Au–Pd and Pd Nanocubes under Compression: An Experimental and Molecular Dynamics Study

Soft or Hard? Investigating the Deformation Mechanisms of Au–Pd and Pd Nanocubes under Compression: An Experimental and Molecular Dynamics Study

Platinum nanoparticle compression: Combining in situ TEM and atomistic modeling

Probing the Mechanical Properties of Porous Nanoshells by Nanoindentation

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