Virial stress

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In mechanics, virial stress is a measure of stress on an atomic scale for homogeneous systems. The name is derived Template:Ety: "Virial is then derived from Latin as well, stemming from the word Template:Lang (plural of Template:Lang) meaning forces."^[1] The expression of the (local) virial stress can be derived as the functional derivative of the free energy of a molecular system with respect to the deformation tensor.^[2]

The instantaneous volume averaged virial stress is given by

$${\displaystyle {\tau }_{ij}=\frac{1}{\mathrm{\Omega }}\sum _{k\in \mathrm{\Omega }}[-m^{(k)}(u_i^{(k)}-{\overline{u}}_i)(u_j^{(k)}-{\overline{u}}_j)+\frac{1}{2}\sum _{\ell \in \mathrm{\Omega }}(x_i^{(\ell )}-x_i^{(k)})f_j^{(k\ell )}]}$$ where

• ${\displaystyle k}$ and ${\displaystyle \ell }$ are atoms in the domain,
• ${\displaystyle \mathrm{\Omega }}$ is the volume of the domain,
• ${\displaystyle m^{(k)}}$ is the mass of atom Template:Mvar,
• ${\displaystyle u_i^{(k)}}$ is the Template:Mvar-th component of the velocity of atom Template:Mvar,
• ${\displaystyle {\overline{u}}_j}$ is the Template:Mvar-th component of the average velocity of atoms in the volume,
• ${\displaystyle x_i^{(k)}}$ is the Template:Mvar-th component of the position of atom Template:Mvar, and
• ${\displaystyle f_i^{(k\ell )}}$ is the Template:Mvar-th component of the force applied on atom Template:Mvar by atom Template:Mvar.

At zero kelvin, all velocities are zero so we have $${\displaystyle {\tau }_{ij}=\frac{1}{2\mathrm{\Omega }}\sum _{k,\ell \in \mathrm{\Omega }}(x_i^{(\ell )}-x_i^{(k)})f_j^{(k\ell )}}$$

This can be thought of as follows. The Template:Math component of stress is the force in the Template:Math-direction divided by the area of a plane perpendicular to that direction. Consider two adjacent volumes separated by such a plane. The 11-component of stress on that interface is the sum of all pairwise forces between atoms on the two sides.

The volume averaged virial stress is then the ensemble average of the instantaneous volume averaged virial stress.

In a three dimensional, isotropic system, at equilibrium the "instantaneous" atomic pressure is usually defined as the average over the diagonals of the negative stress tensor:

$${\displaystyle {𝒫}_{at}=-\frac{1}{3}Tr(\tau ).}$$

The pressure then is the ensemble average of the instantaneous pressure^[3] $${\displaystyle P_{at}=⟨{𝒫}_{at}⟩.}$$ This pressure is the average pressure in the volume Template:Math.

It's worth noting that some articles and textbook^[3] use a slightly different but equivalent version of the equation

$${\displaystyle {\tau }_{ij}=\frac{1}{\mathrm{\Omega }}\sum _{k\in \mathrm{\Omega }}[-m^{(k)}(u_i^{(k)}-{\overline{u}}_i)(u_j^{(k)}-{\overline{u}}_j)-\frac{1}{2}\sum _{\ell \in \mathrm{\Omega }}{x}_i^{(k\ell )}{f}_j^{(k\ell )}]}$$

where ${\displaystyle x_i^{(k\ell )}}$ is the Template:Mvar-th component of the vector oriented from the Template:Mvar-th atoms to the Template:Mvar-th calculated via the difference

$${\displaystyle x_i^{k\ell }=x_i^{(k)}-x_i^{(\ell )}}$$

Both equation being strictly equivalent, the definition of the vector can still lead to confusion.

The virial pressure can be derived, using the virial theorem and splitting forces between particles and the container^[4] or, alternatively, via direct application of the defining equation ${\displaystyle P=-\frac{\partial F(N,V,T)}{\partial V}}$ and using scaled coordinates in the calculation.

If the system is not homogeneous in a given volume the above (volume averaged) pressure is not a good measure for the pressure. In inhomogeneous systems the pressure depends on the position and orientation of the surface on which the pressure acts. Therefore, in inhomogeneous systems a definition of a local pressure is needed.^[5] As a general example for a system with inhomogeneous pressure you can think of the pressure in the atmosphere of the earth which varies with height.

The (local) instantaneous virial stress is given by:^[2]

$${\displaystyle {\tau }_{ab}(\overrightarrow{r})=-{\displaystyle \sum _{i=1}^N}\delta (\overrightarrow{r}-{\overrightarrow{r}}^{(i)})[m^{(i)}{u}_a^{(i)}{u}_b^{(i)}+\frac{1}{2}{\displaystyle \sum _{j=1,j\ne i}^N}{({\overrightarrow{r}}^{(i)}-{\overrightarrow{r}}^{(j)})}_a{\overrightarrow{f}}_b^{(ij)}],}$$

The virial pressure can be measured via the formulas above or using volume rescaling trial moves.^[6]

• Virial theorem

Template:Reflist

• Physical Interpretation of the volume averaged Virial Stress
• Template:Cite book
• 2017 edition (second): Template:Cite book
• Python and Fortran code examples for Computer Simulation of Liquids
• Template:Cite journal