Difference between revisions of "Lattice:Packing fraction"

Revision as of 17:44, 3 June 2014

The packing fraction (or particle volume fraction) for a lattice is given by:

\phi ={\frac {NV_{\mathrm {particle} }}{v_{\mathrm {cell} }}}

Where N is the number of particles per unit cell (which has volume $v_{\mathrm {cell} }$ ). For a sphere, the volume is $V=4\pi R^{3}/3$ so:

\phi ={\frac {N4\pi R^{3}}{3v_{\mathrm {cell} }}}

For a cubic cell:

\phi ={\frac {N4\pi R^{3}}{3a^{3}}}

For a FCC lattice, the packing fraction is 0.740:

Nearest-neighbor distance: $d_{nn}={\sqrt {2}}a/2$
Assuming spherical particles of radius R:
- Particle volume fraction: $\phi =16\pi R^{3}/\left(3a^{3}\right)$
- Maximum volume fraction: $\phi _{max}=\pi {\sqrt {2}}/6\approx 0.740$ when $R=a/(2{\sqrt {2}})$

For a BCC lattice, the packing fraction is 0.680:

Nearest-neighbor distance: $d_{nn}={\sqrt {3}}a/2$
Assuming spherical particles of radius R:
- Particle volume fraction: $\phi =8\pi R^{3}/\left(3a^{3}\right)$
- Maximum volume fraction: $\phi _{max}=\pi {\sqrt {3}}/8\approx 0.680$ when $R=a{\sqrt {3}}/4$

For a diamond lattice, the packing fraction is 0.340:

Nearest-neighbor distance: $d_{nn}={\sqrt {3}}a/4\approx 0.433a$
Assuming spherical particles of radius R:
- Particle volume fraction: $\phi =32\pi R^{3}/\left(3a^{3}\right)$
- Maximum volume fraction: $\phi _{max}=\pi {\sqrt {3}}/16\approx 0.340$ when $R=a{\sqrt {3}}/8$

@@ Line 1: / Line 1: @@
-The '''packing fraction''' (or particle volume fraction) for a lattice is given by:
+The '''packing fraction''' (or particle volume fraction) for a [[lattice]] is given by:
 :<math>\phi = \frac{ N V_{\mathrm{particle}} } { v_{\mathrm{cell}} }</math>
 Where ''N'' is the number of particles per unit cell (which has volume <math>v_{\mathrm{cell}}</math>). For a sphere, the volume is <math>V=4\pi R^3/3</math> so: