Faceted-rough surface with disassembling of macrosteps in nucleation-limited crystal growth

Akutsu, Noriko

doi:10.1038/s41598-021-83227-8

Cited by 12 publications

(19 citation statements)

References 69 publications

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“…In our previous work regarding the step-faceting zone in the non-equilibrium steady state 22 , 26 , 55 , we showed that the mean height of a faceted macrostep for in the step-faceting zone is sensitive to the initial configuration. Here, represents the bulk chemical difference between the crystal and the ambient phases, represents a crossover point between the 2D single nucleation and the poly-nucleation processes at the edge of the faceted macrosteps, and L is the linear size of the system.…”

Section: Resultsmentioning

confidence: 88%

“…We found zipping phenomena 50 and pinning phenomena 51 , 56 . At a slope of , we observed disassembling/assembling of faceted macrosteps 22 , 25 , 26 and a faceted rough surface 55 between the atomically rough and thermodynamic rough surfaces. From the slope dependence of the surface width, which is the standard deviation of the surface height, in the RSOS model ( ), the roughness exponent near (001) is different from that near (111) for large 35 .…”

Section: Discussionmentioning

confidence: 95%

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Slope–temperature faceting diagram for macrosteps at equilibrium

Akutsu

2022

Sci Rep

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Faceting diagrams between surface slope and temperature are calculated numerically based on statistical mechanics for inclined surfaces between (001) and (111) surfaces at equilibrium. A lattice model is employed that includes point-contact-type step–step attractions from the quantum mechanical couplings between neighbouring steps. Comparing the obtained faceting diagrams with the phase diagram for step bunching proposed by Song and Mochrie for Si(113), the effective step–step attraction energy for Si(113) is approximately estimated to be 123 meV. The slope dependences of the mean height of the faceted macrosteps with a (111) side surface and that with a (001) side surface are calculated using the Monte Carlo method. The faceting diagrams can be used as a guide for controlling the assembling/disassembling of faceted macrosteps for designing new surface arrangements.

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Section: Resultsmentioning

confidence: 88%

Section: Discussionmentioning

confidence: 95%

Slope–temperature faceting diagram for macrosteps at equilibrium

Akutsu

2022

Sci Rep

Self Cite

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“…With all due caution, namely the difference of Péclet number and growth regime (diffusion limited growth versus slow growth), origin of growth anisotropy (capillary versus kinetic), as well as the peculiarities of smooth and rough faceting [49], the presently described mechanism for ISB might provide an alternative scenario for the sprouting of side branches in snowflake as was experimentally observed upon changing growth conditions in [30]. In his book, Libbrecht ascribes ISB to a purely morphological origin.…”

Section: Discussionmentioning

confidence: 99%

Induced side-branching in smooth and faceted dendrites: theory and phase-field simulations

Demange

Patte

Zapolsky

2022

Phil. Trans. R. Soc. A.

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The present work is devoted to the phenomenon of induced side branching stemming from the disruption of free dendrite growth. We postulate that the secondary branching instability can be triggered by the departure of the morphology of the dendrite from its steady state shape. Thence, the instability results from the thermodynamic trade-off between non monotonic variations of interface temperature, surface energy, kinetic anisotropy and interface velocity within the Gibbs–Thomson equation. For the purposes of illustration, the toy model of capillary anisotropy modulation is prospected both analytically and numerically by means of phase-field simulations. It is evidenced that side branching can befall both smooth and faceted dendrites, at a normal angle from the front tip which is specific to the nature of the capillary anisotropy shift applied. This article is part of the theme issue ‘Transport phenomena in complex systems (part 2)’.

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“…With all due caution, namely the difference of Péclet number and growth regime (diffusion limited growth vs. slow growth), origin of growth anisotropy (capillary vs. kinetic), as well as the peculiarities of smooth and rough faceting [46], the presently described mechanism for ISB might provide an alternative scenario for the sprouting of side branches in snowflake as was experimentally observed upon changing growth conditions in [31]. In his book, Libbrecht ascribes ISB to a purely morphological origin.…”

Section: Discussionmentioning

confidence: 99%

Induced side-branching in smooth and faceted dendrites: theory and Phase-Field simulations

Demange,

Patte,

Zapolsky

2021

Preprint

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The present work is devoted to the phenomenon of induced side branching stemming from the disruption of free dendrite growth. Therein, we postulate that the secondary branching instability can be triggered by the departure of the morphology of the dendrite from its steady state shape. Thence, the instability results from the thermodynamic trade-off between non monotonic variations of interface temperature, surface energy, kinetic anisotropy and interface velocity within the Gibbs Thomson equation. For purposes of illustration, the toy model of capillary anisotropy modulation is prospected both analytically and numerically by means of phase field simulations. It is evidenced that side branching can befall both smooth and faceted dendrites, at a normal angle from the front tip which is specific to the nature of the capillary anisotropy shift applied.

show abstract

Faceted-rough surface with disassembling of macrosteps in nucleation-limited crystal growth

Cited by 12 publications

References 69 publications

Slope–temperature faceting diagram for macrosteps at equilibrium

Slope–temperature faceting diagram for macrosteps at equilibrium

Induced side-branching in smooth and faceted dendrites: theory and phase-field simulations

Induced side-branching in smooth and faceted dendrites: theory and Phase-Field simulations

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