Difference between revisions of "Lattice:Packing fraction"
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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: | 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: | ||
:<math>\phi = \frac{ N 4 \pi R^3 } { 3 v_{\mathrm{cell}} }</math> | :<math>\phi = \frac{ N 4 \pi R^3 } { 3 v_{\mathrm{cell}} }</math> | ||
− | For a | + | For a cubic [[unit cell]] of edge-length ''a'': |
:<math>\phi = \frac{ N 4 \pi R^3 } { 3 a^3 }</math> | :<math>\phi = \frac{ N 4 \pi R^3 } { 3 a^3 }</math> | ||
===Examples=== | ===Examples=== |
Revision as of 10:02, 18 June 2014
The packing fraction (or particle volume fraction) for a lattice is given by:
Where N is the number of particles per unit cell (which has volume ). For a sphere, the volume is so:
For a cubic unit cell of edge-length a:
Examples
For a FCC lattice, the packing fraction is 0.740:
- Nearest-neighbor distance:
- Assuming spherical particles of radius R:
- Particle volume fraction:
- Maximum volume fraction: when
For a BCC lattice, the packing fraction is 0.680:
- Nearest-neighbor distance:
- Assuming spherical particles of radius R:
- Particle volume fraction:
- Maximum volume fraction: when
For a diamond lattice, the packing fraction is 0.340:
- Nearest-neighbor distance:
- Assuming spherical particles of radius R:
- Particle volume fraction:
- Maximum volume fraction: when