Scaling of inter-pore spacing of lotus-type pores

Wei, P. S.; Luo, C. W.; Hsieh, In Cha

doi:10.1088/1402-4896/ace707

Cited by 4 publications

(2 citation statements)

References 27 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The key assumptions underlying this phenomenon are that lotus pores with a spherical cap emerge from distributed spherical bubbles within a static liquid and grow symmetrically along their axis. The interpore spacing w is a consequence of morphological instability [18]. Furthermore, the pores exclusively contain solute gas, with any vaporized gas from the solvent being negligible.…”

Section: Governing Equationsmentioning

confidence: 99%

Interfacial physico-chemical equilibrium control of lotus-type pore formation in solid

Ou,

Wei

2024

Phys. Scr.

View full text Add to dashboard Cite

This study presents a challenging analysis of interfacial equilibrium conditions that control the evolution of lotus-type pores in both metals and nonmetals during solidification. It incorporates Henry’s or Sieverts’ law, affecting solute transfer at the cap and top free surface, and pore evolution. The significance of the directional and lightweight characteristics of lotus-type porous materials makes them vitally important in functional heat sinks, energy absorption, biomedical devices, and other applications. The study extends previous solute transfer models based on solute concentration deviations in the liquid from the top surface and convection-affected segregation at the advancing liquid-solid interface by further considering the effects of interfacial equilibrium conditions on pore development. Typical data selected for the dimensionless Henry’s law constant at the cap and top free surface is 0.175, while the Sieverts’ law constant at the cap and top free surface is 0.03. MATLAB Simulink and Simscape (version R2020b) with the solver ode113 are utilized to solve the resulting simultaneous system of unsteady first-order differential equations. The results show that the size of lotus-type pores increases as the Henry’s law constant at the cap decreases while the Henry's law constant at the top free surface increases. Similar results are observed for Sieverts’ law. Lotus-type pores readily form as the Henry’s law constant at the cap increases while that at the top free surface decreases. The lotus pore length can also be determined and interpreted algebraically using solute content conservation. The model's predictions closely match analytical findings previously validated by experimental data.

show abstract

Section: Governing Equationsmentioning

confidence: 99%

Interfacial physico-chemical equilibrium control of lotus-type pore formation in solid

Ou,

Wei

2024

Phys. Scr.

View full text Add to dashboard Cite

show abstract

“…Based on the analytical solute concentration in liquids and the minimum undercooling criterion provided by the Jackson–Hunt model during eutectic solidification, Liu et al [ 10 ] predicted and experimentally confirmed decreases in porosity, pore radius, and inter-pore spacing as solidification speed, total gas pressure, and partial pressure of hydrogen and argon increased during the gasarite solidification of copper. The Jackson–Hunt theory and analytical solutions of solute concentration were, however, criticized by Lee et al [ 11 ], Drenchev et al [ 12 ], and Wei et al [ 13 ]. Lu et al [ 14 ] also provided a simple thermodynamic model to describe the relationship between processing variables and the pore structure for the ordered porosity copper fabricated via directional solidification.…”

Section: Introductionmentioning

confidence: 99%

Parametric Control via the Algebraic Expression of Lotus-Type Pore Shapes in Metals

Wang,

Lee,

Wei

et al. 2024

Materials

Self Cite

View full text Add to dashboard Cite

Lotus-type porous metals, characterized by low densities, large surface areas, and directional properties, are contemporarily utilized as lightweight, catalytic, and energy-damping materials; heat sinks; etc. In this study, the effects of dimensionless working parameters on the morphology of lotus-type pores in metals during unidirectional solidification were extensively investigated via general algebraic expressions. The independent dimensionless parameters include metallurgical, transport, and geometrical parameters such as Sieverts’ law constant, a partition coefficient, the solidification rate, a mass transfer coefficient, the imposed mole fraction of a solute gas, the total pressure at the top free surface, hydrostatic pressure, a solute transport parameter, inter-pore spacing, and initial contact angle. This model accounts for transient gas pressure in the pore, affected by the solute transfer, gas, capillary, and hydrostatic pressures, and Sieverts’ laws at the bubble cap and top free surface. Solute transport across the cap accounts for solute convection at the cap and the amount of solute rejected by the solidification front into the pore. The shape of lotus-type pores can be described using a proposed fifth-degree polynomial approximation, which captures the major portions between the initial contact angle and the maximum radius at a contact angle of 90 degrees, obtained by conserving the total solute content in the system. The proposed polynomial approximation, along with its working parameters, offers profound insights into the formation and shape of lotus-type pores in metals. It systematically provides deep insights into mechanisms that may not be easily revealed with experimental studies. The prediction of a lotus-type pore shape is thus algebraically achieved in good agreement with the available experimental data and previous analytical results.

show abstract

Parametric study of lotus-type pore shape in solid subject to Henry's laws at interfaces

Lee¹,

Wei²

2023

Heliyon

Self Cite

View full text Add to dashboard Cite

Scaling of inter-pore spacing of lotus-type pores

Cited by 4 publications

References 27 publications

Interfacial physico-chemical equilibrium control of lotus-type pore formation in solid

Interfacial physico-chemical equilibrium control of lotus-type pore formation in solid

Parametric Control via the Algebraic Expression of Lotus-Type Pore Shapes in Metals

Parametric study of lotus-type pore shape in solid subject to Henry's laws at interfaces

Contact Info

Product

Resources

About