Atomic-Scale Study of Plastic-Yield Criterion in Nanocrystalline Cu at High Strain Rates

Dongare, Avinash M.; Rajendran, A. M.; LaMattina, Bruce; Brenner, Donald W.; Zikry, M. A.

doi:10.1007/s11661-009-0113-x

Cited by 21 publications

(15 citation statements)

References 31 publications

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“…The plots suggest higher values for elastic modulus, macroscopic yield stress and flow stress values with an increase in the volume fraction of the reinforcing nanocrystalline Si particles as observed experimentally [5]. The flow stress (oy) is defined as the peak value of the stress in the stress-strain curve [6,7]. The values for the flow stress for the nanocrystalline Al/Si composite for various volume fractions are tabulated in Table 1 for conditions of tensile and compressive loading, respectively.…”

Section: Strengthening Behavior Of the Metal-ceramic Nanocompositementioning

confidence: 99%

“…The grain size of 6 nm considered here belongs to the inverse Hall-Petch regime (d< 15 nm), where GB sliding/rotation dominates the deformation behavior as compared to dislocations [31]. Recent MD simulations of deformation behavior of nanocrystalline metals at this grain size suggest that higher strain rates result in higher strengths of the nanocrystalline metal as well as a larger asymmetry in the strength values in tension and compression with the nanocrystalline metal being stronger in compression than in tension [6,7]. The higher strain rates further reduce the limited GB sliding/rotation behavior during plastic deformation and thereby render higher flow stress values.…”

Section: Strengthening Behavior Of the Metal-ceramic Nanocompositementioning

confidence: 99%

“…The reduction in the GB sliding/rotation behavior is greater for loading in compression as compared to tension and thus results in an increased asymmetry at higher strain rates. This strength asymmetry needs to the accounted for in order to use the von Mises type of criterion for the prediction of macro scale behavior at high strain rates [7]. Nanocrystalline Si, on the other hand, has contributions only from the diffusion of disordered atoms at the grain boundaries to plasticity (GB sliding is not observed).…”

Section: Strengthening Behavior Of the Metal-ceramic Nanocompositementioning

confidence: 99%

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Strengthening Behavior and Tension–Compression Strength–Asymmetry in Nanocrystalline Metal–Ceramic Composites

Dongare

LaMattina

Rajendran

2012

Journal of Engineering Materials and Technology

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Metal-ceramic composites are an emerging class of materials for use in the nextgeneration high technology applications due to their ability to sustain plastic deformation and resist failure in extreme mechanical environments. Large scale molecular dynamics simulations are used to investigate the performance of nanociystalline metal-matrix composites (MMCs) formed by the reinforcement of the nanociystalline Al matrix with a random distribution of nanoscale ceramic particles. The interatomic interactions are defined by the newly developed angular-dependent embedded atom method (A-EAM) by combining the embedded atom method (EAM) potential for Al with the Stillinger-Weber (SW) potential for Si in one functional form. The molecular dynamics (MD) simulations are aimed to investigate the strengthening behavior and the tension-compression strength asymmetiy of these composites as a function of volume fraction of the reinforcing Si phase. MD simulations suggest that the strength of the nanocomposite increases linearly with an increase in the volume fraction of Si in the Al-rich region, whereas the increase is very sharp in the Si-rich region. The higher strength of the nanocomposite is attributed to the reduced sliding/rotation between the AllSi and the Si/Si grains as compared to the pure nanociystalline metal.

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Section: Strengthening Behavior Of the Metal-ceramic Nanocompositementioning

confidence: 99%

Section: Strengthening Behavior Of the Metal-ceramic Nanocompositementioning

confidence: 99%

Section: Strengthening Behavior Of the Metal-ceramic Nanocompositementioning

confidence: 99%

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Strengthening Behavior and Tension–Compression Strength–Asymmetry in Nanocrystalline Metal–Ceramic Composites

Dongare

LaMattina

Rajendran

2012

Journal of Engineering Materials and Technology

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“…Atomic-scale study of plastic-yield criterion in nanocrystalline CU is given by Dongare et al (2010). Initial configuration of nanocrystalline Cu with an average grain size of 6nm.…”

Section: Atomic-scale Study Of Yield Criterion In Nanocrystalline Cumentioning

confidence: 99%

“…System consists of approximately 1.2 million atoms arranged in 122 grains, as shown in Fig. In the work of Dongare et al (2010), the biaxial yield surface is calculated by plotting the yield/limit stresses during loading of the nanocrystalline metal by equal/unequal amounts in the X and Y directions and keeping the stress in the Z direction constant (ı x =ı 1 , ı y =ı 2 , and ı 3 =ı z =0). Molecular dynamics (MD) simulations for yield surface are presented.…”

Section: Atomic-scale Study Of Yield Criterion In Nanocrystalline Cumentioning

confidence: 99%

Computational Plasticity

2012

Advanced Topics in Science and Technology in China

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PrefaceComputational plasticity is a new and important branch of computational mechanics. Computational Plasticity: With Emphasis on the Application of the Unified Strength Theory and Associated Flow Rule is the third title in the series on plasticity published by Springer and by Springer or by the collabration of Springer and ZJU Press. The other two files are: Generalized Plasticity (Springer, Berlin, 2006) and Structural Plasticity: Limit, Shakedown and Dynamic Plastic Analyses of Structures (Springer and ZJU Press, Hangzhou, 2009). The founding work in this series on plasticity is Unified Strength Theory and its Applications that was published by Springer in Berlin in 2004, in which the unified strength theory (UST) and its 30 years developments history are described in detail.Generalized Plasticity, the first monograph in this series on plasticity, is a combination of traditional plasticity for metallic materials (non-SD materials) and plasticity for geomaterials (SD materials, i.e. strength difference in tension and in compression, sometimes referred to as tension-compression asymmetry). It was published by Springer in 2006, in which the unified slip line theory for plane strain problems and unified characteristics theory for plane stress and spatial axisymmetric problems, as well as the unified fracture criterion for mixed mode cracks and plastic zones at the tip of a crack using the unified strength theory are described. Generalized Plasticity can be used for both non-SD materials and SD materials. The time effect, however, is not taken into account in Generalized Plasticity. The time independent UST can be extended to time dependent UST.The second title in this series on plasticity is Structural Plasticity: Limit, Shakedown and Dynamic Plastic Analyses of Structures, which was published by ZJU Press and Springer in 2009. Structural Plasticity deals with limit analysis, shakedown analysis and dynamic plastic analyses of structures using the analytical method. The straight line segments on the series yield surfaces of the unified strength theory make these surfaces convenient for analytical treatment of plasticity problems. A series of results of the unified solutions for elastic and plastic limit analysis, shakedown analysis and dynamic plastic analysis for structures are given by using the unified strength theory. These unified solutions can provide a very useful tool for the design of engineering structures. Most solutions in textbooks regarding the plastic analysis of structures are special cases of the unified solution, using the unified strength theory. The third title in this series on plasticity is Computational Plasticity: With Emphasis on the Application of the Unified Strength Theory and Associated FlowRule, in which numerical methods are applied. The unified strength theory and associated flow rule are implemented in several computational plasticity codes and applied to many engineering problems.A series of results can be obtained in Generalized Plasticity (slip line theory), Structural Plast...

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Mesomechanics and Multiscale Modelling for Yield Surface

2012

Advanced Topics in Science and Technology in China

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Atomic-Scale Study of Plastic-Yield Criterion in Nanocrystalline Cu at High Strain Rates

Cited by 21 publications

References 31 publications

Strengthening Behavior and Tension–Compression Strength–Asymmetry in Nanocrystalline Metal–Ceramic Composites

Strengthening Behavior and Tension–Compression Strength–Asymmetry in Nanocrystalline Metal–Ceramic Composites

Computational Plasticity

Mesomechanics and Multiscale Modelling for Yield Surface

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