Ellipsoid packing

In geometry, ellipsoid packing is the problem of arranging identical ellipsoid throughout three-dimensional space to fill the maximum possible fraction of space.

The currently densest known packing structure for ellipsoid has two candidates, a simple monoclinic crystal with two ellipsoids of different orientations^[1] and a square-triangle crystal containing 24 ellipsoids^[2] in the fundamental cell. The former monoclinic structure can reach a maximum packing fraction around $0.77073$ for ellipsoids with maximal aspect ratios larger than ${\sqrt {3}}$ . The packing fraction of the square-triangle crystal exceeds that of the monoclinic crystal for specific biaxial ellipsoids, like ellipsoids with ratios of the axes $\alpha :{\sqrt {\alpha }}:1$ and $\alpha \in (1.365,1.5625)$ . Any ellipsoids with aspect ratios larger than one can pack denser than spheres.

References

doi:10.1103/PhysRevLett.92.255506
.

doi:10.1103/PhysRevE.95.033003
.

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Packing problems
Abstract packing

Bin

Set

Circle packing

In a circle / equilateral triangle / isosceles right triangle / square

Apollonian gasket

Circle packing theorem

Tammes problem (on sphere)

Sphere packing

Apollonian

Finite

In a sphere

In a cube

In a cylinder

Close-packing

Kissing number

Sphere-packing (Hamming) bound

Other 2-D packing

Square packing

Other 3-D packing

Tetrahedron

Ellipsoid

Puzzles

Conway

Slothouber–Graatsma

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[1] :10.1103/PhysRevLett.92.255506
.

[2] :10.1103/PhysRevE.95.033003
.

[1]

[2]

See also

References