Effect of the Alumina Shell on the Melting Temperature Depression for Aluminum Nanoparticles

Levitas, Valery I.; Pantoya, Michelle L.; Chauhan, Garima; Rivero, Iris V.

doi:10.1021/jp902317m

Cited by 86 publications

(61 citation statements)

References 31 publications

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“…They include surface premelting and melting below the thermodynamic melting temperature θ e , caused by reduction in surface energy and leading to appearance of a molten, nanometer-thick layer 1,2 ; reduction in melting temperature θ m with reduction of the particle radius R down to nanoscale 3,4 ; melting of particles with radii comparable to and smaller than the equilibrium solid-liquid interface width δ e , which is a few nm 3,5 ; and overheating above θ e during very fast heating 6,7 . All of these phenomena allow one to determine the properties of solid and liquid deeply in the region of their metastability and even complete instability (that is, above the solid instability temperature θ i or below the melt instability temperature θ c , see Supplementary Fig.…”

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confidence: 99%

Size and mechanics effects in surface-induced melting of nanoparticles

2011

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Various melting-related phenomena (like surface melting, size dependence of melting temperature, melting of few nm-size particles and overheating at a very fast heating rate) are of great fundamental and applied interest, although the corresponding theory is still lacking. Here we develop an advanced phase-field theory of melting coupled to mechanics, which resolves numerous existing contradictions and allowed us to reveal exciting features of melting problems. The necessity of introducing an unexpected concept, namely, coherent solid-melt interface with uniaxial transformation strain, is demonstrated. A crossover in temperature dependence of interface energy for radii below 20 nm is found. surface-induced premelting and barrierless melt nucleation for nanoparticles down to 1 nm radius is studied, and the importance of advanced mechanics is demonstrated. our model describes well experimental data on the width of the molten layer versus temperature for the Al plane surface and on melting temperature versus particle radius.

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confidence: 99%

Size and mechanics effects in surface-induced melting of nanoparticles

2011

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“…This criterion was substantiated in [27] when considering the ignition of aluminum particles in a shock wave, taking into account surface oxidation reactions and polymorphic transformations of the oxide. According to numerous experimental ignition data [15], the ignition threshold remains at about 900 K. The theoretical explanation of the rapid ignition of nanoscale particles due to the sharp disintegration of the particle core during melting is given in Refs [28,16]. Thus, for particles of size 50 ÷ 250 nm, we consider the ignition temperature equal to the melting point…”

Section: Nanosized Particle Ignition and Combustionmentioning

confidence: 99%

Physical and mathematical model of detonation in aluminum gas suspensions with regard for transition processes of nanosized particle flow, heat transfer and combustion

Khmel

Федоров

2017

AIP Conference Proceedings

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“…The obtained experimental and theoretical results represent important progress in our main objective of designing optimal Al micron-scale particles for energy-related applications. Also, this new model for stress relaxation in an alumina shell can be used for improving the model for melting of Al particles covered by an alumina shell [21] and interpreting of experimental data.…”

Section: 85×10mentioning

confidence: 99%

Stress relaxation in pre-stressed aluminum core–shell particles: X-ray diffraction study, modeling, and improved reactivity

Levitas

McCollum

Pantoya

et al. 2016

Combustion and Flame

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Stress relaxation in pre-stressed aluminum core-shell particles: X-ray diffraction study, modeling, and improved reactivity AbstractStress relaxation in aluminum micron-scale particles covered by alumina shell after pre-stressing by thermal treatment and storage was measured using x-ray diffraction with synchrotron radiation. Pre-stressing was produced by annealing Al particles at 573 K followed by fast cooling. While averaged dilatational strain in Al core was negligible for untreated particles, it was measured at 4.40×10 -5 and 2.85×10 -5 after 2 and 48 days of storage. Consistently, such a treatment lead to increase in flame propagation speed for Al+CuO mixture by 37% and 25%, respectively. Analytical model for creep in alumna shell and stress relaxation in Al core-alumina shell structure is developed and activation energy and pre-exponential multiplier are estimated.The effect of storage temperature and annealing temperature on the kinetics of stress relaxation

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Effect of the Alumina Shell on the Melting Temperature Depression for Aluminum Nanoparticles

Cited by 86 publications

References 31 publications

Size and mechanics effects in surface-induced melting of nanoparticles

Size and mechanics effects in surface-induced melting of nanoparticles

Physical and mathematical model of detonation in aluminum gas suspensions with regard for transition processes of nanosized particle flow, heat transfer and combustion

Stress relaxation in pre-stressed aluminum core–shell particles: X-ray diffraction study, modeling, and improved reactivity

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