High-pressure mechanochemistry: Conceptual multiscale theory and interpretation of experiments

Levitas, Valery I.

doi:10.1103/physrevb.70.184118

Cited by 166 publications

(298 citation statements)

References 56 publications

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“…99 Second, it does not relate, on a fundamental basis, the chemical reactivity to the severity of the mechanical deformation. 100 Third, it does not connect the overall kinetics with the characteristic features of the mechanical processing method. 101 Regarding the first issue, it must be noted that any novel achievement in such a direction would be significant progress in fundamental knowledge in the field.…”

Section: Kineticsmentioning

confidence: 99%

Hallmarks of mechanochemistry: from nanoparticles to technology

et al. 2013

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The aim of this review article on recent developments of mechanochemistry (nowadays established as a part of chemistry) is to provide a comprehensive overview of advances achieved in the field of atomistic processes, phase transformations, simple and multicomponent nanosystems and peculiarities of mechanochemical reactions. Industrial aspects with successful penetration into fields like materials engineering, heterogeneous catalysis and extractive metallurgy are also reviewed. The hallmarks of mechanochemistry include influencing reactivity of solids by the presence of solid-state defects, interphases and relaxation phenomena, enabling processes to take place under non-equilibrium conditions, creating a well-crystallized core of nanoparticles with disordered near-surface shell regions and performing simple dry time-convenient one-step syntheses. Underlying these hallmarks are technological consequences like preparing new nanomaterials with the desired properties or producing these materials in a reproducible way with high yield and under simple and easy operating conditions. The last but not least hallmark is enabling work under environmentally friendly and essentially waste-free conditions (822 references).

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Section: Kineticsmentioning

confidence: 99%

Hallmarks of mechanochemistry: from nanoparticles to technology

et al. 2013

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“…While most of our results below may be equally applicable to both PTs and chemical reactions, 7,8 we will focus on PTs here. It was recently recognized that strain-induced PTs differ fundamentally from the similar pressure-induced PTs.…”

Section: Introductionmentioning

confidence: 99%

“…It was recently recognized that strain-induced PTs differ fundamentally from the similar pressure-induced PTs. 7,8,24 Pressure-and stress-induced PTs start predominantly at pre-existing defects ͑various dislocation configurations and internal boundaries͒ at stress levels below the yield strength. It is necessary to increase pressure to drive the PTs further.…”

Section: Introductionmentioning

confidence: 99%

“…[15][16][17][18][19][20][21][22][23] It was found that the superposition of plastic shear under constant compressive load, due to the rotation of an anvil, leads to findings that have both fundamental and applied importance. 7,8,[15][16][17][18][19][20] They are enumerated below and reviewed in detail in Refs. 7 and 8.…”

Section: Introductionmentioning

confidence: 99%

“…All of these processes can be considered under the umbrella of high-pressure mechanochemistry. [6][7][8] One can also mention mechanochemically enhanced PTs under nanoindentation, 9 plastic-strain-enhanced reactions in rocks, 10 and mechanically induced change in reaction pathways in polymers. 11 Pioneering studies on the unique mechanochemical behavior of materials under high pressure and large plastic strains have been initiated using rotational Bridgman anvils.…”

Section: Introductionmentioning

confidence: 99%

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Modeling and simulation of strain-induced phase transformations under compression in a diamond anvil cell

2010

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Strain-induced phase transformations (PTs) under high-pressure differ fundamentally from the pressureinduced PTs under quasihydrostatic conditions. A model and finite-element approach to strain-induced PTs under compression and torsion of a sample in rotational diamond anvil cell are developed. The current paper is devoted to the numerical study of strain-induced PTs under compression in traditional diamond anvils while the accompanying paper [ V. I. Levitas and O. M. Zarechnyy Phys. Rev. B 82 174124 (2010)] is concerned with compression and torsion in rotational anvils. Very heterogeneous fields of stress tensor, accumulated plastic strain, and concentration of the high-pressure phase are determined for three ratios of yield strengths of low-pressure and high-pressure phases. PT kinetics depends drastically on the yield strengths ratios. For a stronger high-pressure phase, an increase in strength during PT increases pressure and promotes PT, serving as a positive mechanochemical feedback; however, maximum pressure in a sample is much larger than required for PT. For a weaker high-pressure phase, strong strain and high-pressure phase localization and irregular stress fields are obtained. Various experimentally observed effects are reproduced and interpreted. Obtained results revealed difficulties in experimental characterization of strain-induced PTs and suggested some ways to overcome them. Strain-induced phase transformations ͑PTs͒ under high-pressure differ fundamentally from the pressureinduced PTs under quasihydrostatic conditions. A model and finite-element approach to strain-induced PTs under compression and torsion of a sample in rotational diamond anvil cell are developed. The current paper is devoted to the numerical study of strain-induced PTs under compression in traditional diamond anvils while the accompanying paper ͓V. I. Levitas and O. M. Zarechnyy, Phys. Rev. B 82, 174124 ͑2010͔͒ is concerned with compression and torsion in rotational anvils. Very heterogeneous fields of stress tensor, accumulated plastic strain, and concentration of the high-pressure phase are determined for three ratios of yield strengths of low-pressure and high-pressure phases. PT kinetics depends drastically on the yield strengths ratios. For a stronger high-pressure phase, an increase in strength during PT increases pressure and promotes PT, serving as a positive mechanochemical feedback; however, maximum pressure in a sample is much larger than required for PT. For a weaker high-pressure phase, strong strain and high-pressure phase localization and irregular stress fields are obtained. Various experimentally observed effects are reproduced and interpreted. Obtained results revealed difficulties in experimental characterization of strain-induced PTs and suggested some ways to overcome them.

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The Mechanochemical Route to Nanoscale

Delogu

Ricci

2015

Handbook of Mechanical Nanostructuring

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High-pressure mechanochemistry: Conceptual multiscale theory and interpretation of experiments

Cited by 166 publications

References 56 publications

Hallmarks of mechanochemistry: from nanoparticles to technology

Hallmarks of mechanochemistry: from nanoparticles to technology

Modeling and simulation of strain-induced phase transformations under compression in a diamond anvil cell

The Mechanochemical Route to Nanoscale

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