Physics:Rule of mixtures

In materials science, a general rule of mixtures is a weighted mean used to predict various properties of a composite material .^[2][3][4] It provides a theoretical upper- and lower-bound on properties such as the elastic modulus, ultimate tensile strength, thermal conductivity, and electrical conductivity.^[4] In general there are two models, one for axial loading (Voigt model),^[3][5] and one for transverse loading (Reuss model).^[3][6]

In general, for some material property ${\displaystyle E}$ (often the elastic modulus^[2]), the rule of mixtures states that the overall property in the direction parallel to the fibers may be as high as

${\displaystyle E_c=f{E}_f+(1-f)E_m}$

where

• ${\displaystyle f=\frac{V_f}{V_f+V_m}}$ is the volume fraction of the fibers
• ${\displaystyle E_f}$ is the material property of the fibers
• ${\displaystyle E_m}$ is the material property of the matrix

It is a common mistake to believe that this is the upper-bound modulus for Young's modulus. The real upper-bound Young's modulus is larger than ${\displaystyle E_c}$ given by this formula. Even if both constituents are isotropic, the real upper bound is ${\displaystyle E_c}$ plus a term in the order of square of the difference of the Poisson's ratios of the two constituents.^[1]

The inverse rule of mixtures states that in the direction perpendicular to the fibers, the elastic modulus of a composite can be as low as

${\displaystyle E_c={(\frac{f}{E_f}+\frac{1-f}{E_m})}^{-1}.}$

If the property under study is the elastic modulus, this quantity is called the lower-bound modulus, and corresponds to a transverse loading.^[3]

Consider a composite material under uniaxial tension ${\displaystyle {\sigma }_{\mathrm{\infty }}}$. If the material is to stay intact, the strain of the fibers, ${\displaystyle {ϵ}_f}$ must equal the strain of the matrix, ${\displaystyle {ϵ}_m}$. Hooke's law for uniaxial tension hence gives

${\displaystyle \frac{{\sigma }_f}{E_f}={ϵ}_f={ϵ}_m=\frac{{\sigma }_m}{E_m}}$

(1)

where ${\displaystyle {\sigma }_f}$, ${\displaystyle E_f}$, ${\displaystyle {\sigma }_m}$, ${\displaystyle E_m}$ are the stress and elastic modulus of the fibers and the matrix, respectively. Noting stress to be a force per unit area, a force balance gives that

${\displaystyle {\sigma }_{\mathrm{\infty }}=f{\sigma }_f+(1-f){\sigma }_m}$

(2)

where ${\displaystyle f}$ is the volume fraction of the fibers in the composite (and ${\displaystyle 1-f}$ is the volume fraction of the matrix).

If it is assumed that the composite material behaves as a linear-elastic material, i.e., abiding Hooke's law ${\displaystyle {\sigma }_{\mathrm{\infty }}=E_c{ϵ}_c}$ for some elastic modulus of the composite ${\displaystyle E_c}$ and some strain of the composite ${\displaystyle {ϵ}_c}$, then equations 1 and 2 can be combined to give

${\displaystyle E_c{ϵ}_c=f{E}_f{ϵ}_f+(1-f)E_m{ϵ}_m.}$

Finally, since ${\displaystyle {ϵ}_c={ϵ}_f={ϵ}_m}$, the overall elastic modulus of the composite can be expressed as^[7]

${\displaystyle E_c=f{E}_f+(1-f)E_m.}$

Now let the composite material be loaded perpendicular to the fibers, assuming that ${\displaystyle {\sigma }_{\mathrm{\infty }}={\sigma }_f={\sigma }_m}$. The overall strain in the composite is distributed between the materials such that

${\displaystyle {ϵ}_c=f{ϵ}_f+(1-f){ϵ}_m.}$

The overall modulus in the material is then given by

${\displaystyle E_c=\frac{{\sigma }_{\mathrm{\infty }}}{{ϵ}_c}=\frac{{\sigma }_f}{f{ϵ}_f+(1-f){ϵ}_m}={(\frac{f}{E_f}+\frac{1-f}{E_m})}^{-1}}$

since ${\displaystyle {\sigma }_f=E{ϵ}_f}$, ${\displaystyle {\sigma }_m=E{ϵ}_m}$.^[7]

Similar derivations give the rules of mixtures for

• mass density:$${\displaystyle {\rho }_c={\rho }_f\cdot f+{\rho }_M\cdot (1-f)}$$ where f is the atomic percent of fiber in the mixture.
• ultimate tensile strength:$${\displaystyle {(\frac{f}{{\sigma }_{UTS,f}}+\frac{1-f}{{\sigma }_{UTS,m}})}^{-1}\le {\sigma }_{UTS,c}\le f{\sigma }_{UTS,f}+(1-f){\sigma }_{UTS,m}}$$
• thermal conductivity:$${\displaystyle {(\frac{f}{k_f}+\frac{1-f}{k_m})}^{-1}\le k_c\le f{k}_f+(1-f)k_m}$$
• electrical conductivity:$${\displaystyle {(\frac{f}{{\sigma }_f}+\frac{1-f}{{\sigma }_m})}^{-1}\le {\sigma }_c\le f{\sigma }_f+(1-f){\sigma }_m}$$

When considering the empirical correlation of some physical properties and the chemical composition of compounds, other relationships, rules, or laws, also closely resembles the rule of mixtures:

• Amagat's law – Law of partial volumes of gases
• Gladstone–Dale equation – Optical analysis of liquids, glasses and crystals
• Kopp's law – Uses mass fraction
• Kopp–Neumann law – Specific heat for alloys
• Vegard's law – Crystal lattice parameters

• Rule of mixtures calculator

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