Cauchy–Born rule: Difference between revisions
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:''Not to be confused with the [[Born Rule]] in [[Quantum Mechanics]].'' |
:''Not to be confused with the [[Born Rule]] in [[Quantum Mechanics]].'' |
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The '''Cauchy–Born rule''' or '''Cauchy-Born approximation''' is a basic hypothesis used in the mathematical formulation of [[solid mechanics]] which relates the movement of atoms in a crystal to the overall deformation of the bulk solid. It states that in a crystalline solid subject to a small [[Deformation (mechanics)|strain]], the positions of the atoms within the crystal lattice follow the overall strain of the medium. The currently accepted form is [[Max Born|Max Born's]] refinement of [[Augustin-Louis Cauchy|Cauchy's]] original hypothesis which was used to derive the equations satisfied by the [[Cauchy stress tensor]]. The approximation generally holds for face-centered and body-centered [[cubic crystal system]]s. For complex lattices such as [[diamond]], however, the rule has to be modified to allow for internal degrees of freedom between the sublattices. |
The '''Cauchy–Born rule''' or '''Cauchy-Born approximation''' is a basic hypothesis used in the mathematical formulation of [[solid mechanics]] which relates the movement of atoms in a crystal to the overall deformation of the bulk solid. It states that in a crystalline solid subject to a small [[Deformation (mechanics)|strain]], the positions of the atoms within the crystal lattice follow the overall strain of the medium. The currently accepted form is [[Max Born|Max Born's]] refinement of [[Augustin-Louis Cauchy|Cauchy's]] original hypothesis which was used to derive the equations satisfied by the [[Cauchy stress tensor]]. The approximation generally holds for face-centered and body-centered [[cubic crystal system]]s. For complex lattices such as [[diamond]], however, the rule has to be modified to allow for internal degrees of freedom between the sublattices. The approximation can then be used to obtain bulk properties of crystalline materials such as stress-strain relationship. |
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For crystalline bodies of finite size, where the effect of surface stress plays a significant rule, the standard Cauchy-Born rule cannot deduce the surface properties. To overcome this limitation, Park et al. (2006) proposed a surface Cauchy-Born rule. Several modified form of the Cauchy-Born rule have been proposed to cater to crystalline bodies having special shapes. Arroyo & Belytschko (2002) proposed an exponential Cauchy Born rule for mono-layered crystalline sheets to be modeled as a two-dimensional continuum shell. Kumar et al. (2015) proposed a helical Cauchy-Born rule for modeling slender bodies (such as nano and continuum rods) as a special Cosserat continuum rod. |
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==References== |
==References== |
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*{{citation|first=J. L.|last=Ericksen|title=On the Cauchy–Born Rule|journal=[[Mathematics & Mechanics of Solids]]|date=May 2008|volume=13|pages=199–220}}. |
*{{citation|first=J. L.|last=Ericksen|title=On the Cauchy–Born Rule|journal=[[Mathematics & Mechanics of Solids]]|date=May 2008|volume=13|pages=199–220}}. |
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*{{citation|first=M.|last=Arroyo|first2=T.|last2=Belytschko|title=An atomistic-based finite deformation membrane for single layer crystalline films|journal=[[Journal of the Mechanics & Physics of Solids]]||date=Sep 2002|volume=50|pages=1941–1977}}. |
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*{{citation|first=H.S.|last=Park|first2=P.A.|last2=Klein|first3=G.J.|last3=Wagner|title=A surface Cauchy–Born model for nanoscale materials|journal=[[International Journal for Numerical Methods in Engineering]]||date=May 2008|volume=68|pages=1072-1095}}. |
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*{{citation|first=A.|last=Kumar|first2=S.|last2=Kumar|first3=P.|last3=Gupta|title=A helical Cauchy-Born rule for special Cosserat rod modeling of nano and continuum rods|journal=[[Journal of Elasticity]]||date=Dec 2015|volume=122}}. |
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{{DEFAULTSORT:Cauchy-Born Rule}} |
{{DEFAULTSORT:Cauchy-Born Rule}} |
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[[Category:Crystallography]] |
[[Category:Crystallography]] |
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Revision as of 04:06, 16 January 2016
- Not to be confused with the Born Rule in Quantum Mechanics.
The Cauchy–Born rule or Cauchy-Born approximation is a basic hypothesis used in the mathematical formulation of solid mechanics which relates the movement of atoms in a crystal to the overall deformation of the bulk solid. It states that in a crystalline solid subject to a small strain, the positions of the atoms within the crystal lattice follow the overall strain of the medium. The currently accepted form is Max Born's refinement of Cauchy's original hypothesis which was used to derive the equations satisfied by the Cauchy stress tensor. The approximation generally holds for face-centered and body-centered cubic crystal systems. For complex lattices such as diamond, however, the rule has to be modified to allow for internal degrees of freedom between the sublattices. The approximation can then be used to obtain bulk properties of crystalline materials such as stress-strain relationship.
For crystalline bodies of finite size, where the effect of surface stress plays a significant rule, the standard Cauchy-Born rule cannot deduce the surface properties. To overcome this limitation, Park et al. (2006) proposed a surface Cauchy-Born rule. Several modified form of the Cauchy-Born rule have been proposed to cater to crystalline bodies having special shapes. Arroyo & Belytschko (2002) proposed an exponential Cauchy Born rule for mono-layered crystalline sheets to be modeled as a two-dimensional continuum shell. Kumar et al. (2015) proposed a helical Cauchy-Born rule for modeling slender bodies (such as nano and continuum rods) as a special Cosserat continuum rod.
References
- Ericksen, J. L. (May 2008), "On the Cauchy–Born Rule", Mathematics & Mechanics of Solids, 13: 199–220.
- Arroyo, M.; Belytschko, T. (Sep 2002), "An atomistic-based finite deformation membrane for single layer crystalline films", Journal of the Mechanics & Physics of Solids, 50: 1941–1977
{{citation}}: Cite has empty unknown parameter:|1=(help). - Park, H.S.; Klein, P.A.; Wagner, G.J. (May 2008), "A surface Cauchy–Born model for nanoscale materials", International Journal for Numerical Methods in Engineering, 68: 1072–1095
{{citation}}: Cite has empty unknown parameter:|1=(help). - Kumar, A.; Kumar, S.; Gupta, P. (Dec 2015), "A helical Cauchy-Born rule for special Cosserat rod modeling of nano and continuum rods", Journal of Elasticity, 122
{{citation}}: Cite has empty unknown parameter:|1=(help).
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