On the Phenomenology and Mechanics of Super Plastic Flow in Advanced Structural Materials

Juan Daniel Muñoz-Andrade

doi:10.4028/www.scientific.net/MSF.551-552.147

Paper Titles

Tool Thermal Behavior in SPF Environment
p.111

Analysis of Different Specimen Geometries for Tensile Tests in Superplastic Conditions for an Aluminium Alloy
p.123

Forming Limit Diagrams for AA5083 under SPF and QPF Conditions
p.129

Mechanisms of Microsuperplasticity
p.135

On the Phenomenology and Mechanics of Super Plastic Flow in Advanced Structural Materials
p.147

Superplastic Deformation Mechanism of a Zn-Al Eutectoid Alloy
p.153

Study on the Interface Characteristic of Superplastic Diffusion Bonding Joint of Dissimilar Steels
p.157

Superplastic Forming and Diffusion Bonding for Four-Layer Sheets Structure of Nickel-Base Superalloy
p.163

Influence of Diffusion Bonding for Superplasticity Magnesium Alloys with the Fore and Post Treatment
p.169

HomeMaterials Science ForumMaterials Science Forum Vols. 551-552On the Phenomenology and Mechanics of Super...

On the Phenomenology and Mechanics of Super Plastic Flow in Advanced Structural Materials

Abstract:

In connection with ancient and recent view on cosmology, it is interesting to note that our universe could be a spherical crystal and it moves as a crystal in a relative position with others spherical universes, where the Burgers vector for cellular dislocations dynamics is the Hubble length: λH=1.32x1026m. The expansion process of this polycrystalline spatially extended system obey the hyperbolic granular flow, which it is due to an accelerated motion manifested during the deformation process of super plastic advanced structural universes in a similar behaviour of super plastic advanced structural materials. Consequently, in this work the phenomenology and mechanics of super plastic flow are analyzed in the context of the unified interpretation of Hubble flow, plastic flow and super plastic flow, where the combination of fundamentals constants with the natural Planck length, allows obtain in a closed agreement with the Orowan equation the magnitude of the nature Burgers vector of dislocation in the cosmic structure for the universe as follow: 1.62 10 . 35 3 0 x m c H G b P − ⊥ ⊥ ⊥ = = = = h λ ρ ν Where, b⊥ = magnitude of the nature Burgers vector for the universe (b⊥ = 1.62x10-35m), λP = Planck length (λP = 1.62x10-35m), H0 = the Hubble parameter (H0=70 (km/sec)/Mpc = 2.26854593 x10-18s-1), ρ⊥ = dislocation density (ρ⊥ = 1.273x1011 dislocations/m2) in the universe. ν⊥ = the recession velocity of galaxies related with dislocations dynamics in the cosmic structure (ν⊥ = 1100x103 m/s, it is the recession velocity of the Virgo super cluster at 16 Mpc distance). h = h / 2π . Here h = the Planck constant (h = 6.6262x10-34 Joule-s), G = the Newtonian constant (G = 6.67259x10-11 m3/kg s2) and c = the speed of light (c = 299 792 458 m/s) [1-3].

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Materials Science Forum (Volumes 551-552)

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147-152

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https://doi.org/10.4028/www.scientific.net/MSF.551-552.147

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Online since:

July 2007

Authors:

Juan Daniel Muñoz-Andrade

Keywords:

Cosmic Structure, Creep, Dislocation Dynamics, Hubble Flow, Hyperbolic Flow, Planck Length, Plastic Flow, Super Plastic Flow

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References

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