Octahedral number

Last updated October 29, 2024

In number theory, an octahedral number is a figurate number that represents the number of spheres in an octahedron formed from close-packed spheres. The $n$ th octahedral number $O_{n}$ can be obtained by the formula:^[1]

Properties and applications

The octahedral numbers have a generating function

{\frac {z(z+1)^{2}}{(z-1)^{4}}}=\sum _{n=1}^{\infty }O_{n}z^{n}=z+6z^{2}+19z^{3}+\cdots .

Sir Frederick Pollock conjectured in 1850 that every positive integer is the sum of at most 7 octahedral numbers.^[2] This statement, the Pollock octahedral numbers conjecture, has been proven true for all but finitely many numbers.^[3]

In chemistry, octahedral numbers may be used to describe the numbers of atoms in octahedral clusters; in this context they are called magic numbers.^[4]^[5]

Relation to other figurate numbers

Square pyramids

An octahedral packing of spheres may be partitioned into two square pyramids, one upside-down underneath the other, by splitting it along a square cross-section. Therefore, the $n$ th octahedral number $O_{n}$ can be obtained by adding two consecutive square pyramidal numbers together:^[1]

O_{n}=P_{n-1}+P_{n}.

Tetrahedra

If $O_{n}$ is the $n$ th octahedral number and $T_{n}$ is the $n$ th tetrahedral number then

O_{n}+4T_{n-1}=T_{2n-1}.

This represents the geometric fact that gluing a tetrahedron onto each of four non-adjacent faces of an octahedron produces a tetrahedron of twice the size.

Another relation between octahedral numbers and tetrahedral numbers is also possible, based on the fact that an octahedron may be divided into four tetrahedra each having two adjacent original faces (or alternatively, based on the fact that each square pyramidal number is the sum of two tetrahedral numbers):

O_{n}=T_{n}+2T_{n-1}+T_{n-2}.

Cubes

If two tetrahedra are attached to opposite faces of an octahedron, the result is a rhombohedron.^[6] The number of close-packed spheres in the rhombohedron is a cube, justifying the equation

O_{n}+2T_{n-1}=n^{3}.

Centered squares

The difference between two consecutive octahedral numbers is a centered square number:^[1]

O_{n}-O_{n-1}=C_{4,n}=n^{2}+(n-1)^{2}.

Therefore, an octahedral number also represents the number of points in a square pyramid formed by stacking centered squares; for this reason, in his book Arithmeticorum libri duo (1575), Francesco Maurolico called these numbers "pyramides quadratae secundae".^[7]

The number of cubes in an octahedron formed by stacking centered squares is a centered octahedral number, the sum of two consecutive octahedral numbers. These numbers are

1, 7, 25, 63, 129, 231, 377, 575, 833, 1159, 1561, 2047, 2625, ... (sequence A001845 in the OEIS )

given by the formula

O_{n}+O_{n-1}={\frac {(2n-1)(2n^{2}-2n+3)}{3}}

for n = 1, 2, 3, ...

History

The first study of octahedral numbers appears to have been by René Descartes, around 1630, in his De solidorum elementis. Prior to Descartes, figurate numbers had been studied by the ancient Greeks and by Johann Faulhaber, but only for polygonal numbers, pyramidal numbers, and cubes. Descartes introduced the study of figurate numbers based on the Platonic solids and some of the semiregular polyhedra; his work included the octahedral numbers. However, De solidorum elementis was lost, and not rediscovered until 1860. In the meantime, octahedral numbers had been studied again by other mathematicians, including Friedrich Wilhelm Marpurg in 1774, Georg Simon Klügel in 1808, and Sir Frederick Pollock in 1850.^[8]

Related Research Articles

<span class="mw-page-title-main">Cube</span> Solid object with six equal square faces

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In geometry, an octahedron is a polyhedron with eight faces. One special case is the regular octahedron, a Platonic solid composed of eight equilateral triangles, four of which meet at each vertex. Regular octahedra occur in nature as crystal structures. Many types of irregular octahedra also exist, including both convex and non-convex shapes.

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<span class="mw-page-title-main">Tetrahedral number</span> Polyhedral number representing a tetrahedron

A tetrahedral number, or triangular pyramidal number, is a figurate number that represents a pyramid with a triangular base and three sides, called a tetrahedron. The $n$ th tetrahedral number, $Te n$ , is the sum of the first $n$ triangular numbers, that is,

In mathematics, a pyramid number, or square pyramidal number, is a natural number that counts the stacked spheres in a pyramid with a square base. The study of these numbers goes back to Archimedes and Fibonacci. They are part of a broader topic of figurate numbers representing the numbers of points forming regular patterns within different shapes.

In geometry, the 16-cell is the regular convex 4-polytope (four-dimensional analogue of a Platonic solid) with Schläfli symbol {3,3,4}. It is one of the six regular convex 4-polytopes first described by the Swiss mathematician Ludwig Schläfli in the mid-19th century. It is also called C₁₆, hexadecachoron, or hexdecahedroid [sic?].

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The tetragonal disphenoid tetrahedral honeycomb is a space-filling tessellation in Euclidean 3-space made up of identical tetragonal disphenoidal cells. Cells are face-transitive with 4 identical isosceles triangle faces. John Horton Conway calls it an oblate tetrahedrille or shortened to obtetrahedrille.

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A centered octahedral number or Haüy octahedral number is a figurate number that counts the points of a three-dimensional integer lattice that lie inside an octahedron centered at the origin. The same numbers are special cases of the Delannoy numbers, which count certain two-dimensional lattice paths. The Haüy octahedral numbers are named after René Just Haüy.

A dodecahedral number is a figurate number that represents a dodecahedron. The nth dodecahedral number is given by the formula

An icosahedral number is a figurate number that represents an icosahedron. The nth icosahedral number is given by the formula

Pollock's conjectures are closely related conjectures in additive number theory. They were first stated in 1850 by Sir Frederick Pollock, better known as a lawyer and politician, but also a contributor of papers on mathematics to the Royal Society. These conjectures are a partial extension of the Fermat polygonal number theorem to three-dimensional figurate numbers, also called polyhedral numbers.

In three-dimensional hyperbolic geometry, an ideal polyhedron is a convex polyhedron all of whose vertices are ideal points, points "at infinity" rather than interior to three-dimensional hyperbolic space. It can be defined as the convex hull of a finite set of ideal points. An ideal polyhedron has ideal polygons as its faces, meeting along lines of the hyperbolic space.

Descartes on Polyhedra: A Study of the "De solidorum elementis" is a book in the history of mathematics, concerning the work of René Descartes on polyhedra. Central to the book is the disputed priority for Euler's polyhedral formula between Leonhard Euler, who published an explicit version of the formula, and Descartes, whose De solidorum elementis includes a result from which the formula is easily derived.

In geometry, a Blind polytope is a convex polytope composed of regular polytope facets. The category was named after the German couple Gerd and Roswitha Blind, who described them in a series of papers beginning in 1979. It generalizes the set of semiregular polyhedra and Johnson solids to higher dimensions.

References

1 2 3 Conway, John Horton; Guy, Richard K. (1996), The Book of Numbers, Springer-Verlag, p. 50, ISBN 978-0-387-97993-9 .
↑ Dickson, L. E. (2005), Diophantine Analysis, History of the Theory of Numbers, vol. 2, New York: Dover, pp. 22–23, ISBN 9780821819357 .
↑ Elessar Brady, Zarathustra (2016), "Sums of seven octahedral numbers", Journal of the London Mathematical Society, Second Series, 93 (1): 244–272, arXiv: 1509.04316 , doi:10.1112/jlms/jdv061, MR 3455791, S2CID 206364502
↑ Teo, Boon K.; Sloane, N. J. A. (1985), "Magic numbers in polygonal and polyhedral clusters" (PDF), Inorganic Chemistry, 24 (26): 4545–4558, doi:10.1021/ic00220a025, archived from the original (PDF) on 2012-03-13, retrieved 2011-04-08.
↑ Feldheim, Daniel L.; Foss, Colby A. (2002), Metal nanoparticles: synthesis, characterization, and applications, CRC Press, p. 76, ISBN 978-0-8247-0604-3 .
↑ Burke, John G. (1966), Origins of the science of crystals, University of California Press, p. 88.
↑ Tables of integer sequences Archived 2012-09-07 at archive.today from Arithmeticorum libri duo, retrieved 2011-04-07.
↑ Federico, Pasquale Joseph (1982), Descartes on Polyhedra: A Study of the "De solidorum elementis", Sources in the History of Mathematics and Physical Sciences, vol. 4, Springer, p. 118

External links

Weisstein, Eric W., "Octahedral Number", MathWorld

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[bon-1] 1 2 3 Conway, John Horton; Guy, Richard K. (1996), The Book of Numbers, Springer-Verlag, p. 50, ISBN 978-0-387-97993-9 .

[2] Dickson, L. E. (2005), Diophantine Analysis, History of the Theory of Numbers, vol. 2, New York: Dover, pp. 22–23, ISBN 9780821819357 .

[3] Elessar Brady, Zarathustra (2016), "Sums of seven octahedral numbers", Journal of the London Mathematical Society, Second Series, 93 (1): 244–272, arXiv: 1509.04316 , doi:10.1112/jlms/jdv061, MR 3455791, S2CID 206364502

[4] Teo, Boon K.; Sloane, N. J. A. (1985), "Magic numbers in polygonal and polyhedral clusters" (PDF), Inorganic Chemistry, 24 (26): 4545–4558, doi:10.1021/ic00220a025, archived from the original (PDF) on 2012-03-13, retrieved 2011-04-08.

[nano-5] Feldheim, Daniel L.; Foss, Colby A. (2002), Metal nanoparticles: synthesis, characterization, and applications, CRC Press, p. 76, ISBN 978-0-8247-0604-3 .

[6] Burke, John G. (1966), Origins of the science of crystals, University of California Press, p. 88.

[7] Tables of integer sequences Archived 2012-09-07 at archive.today from Arithmeticorum libri duo, retrieved 2011-04-07.

[8] Federico, Pasquale Joseph (1982), Descartes on Polyhedra: A Study of the "De solidorum elementis", Sources in the History of Mathematics and Physical Sciences, vol. 4, Springer, p. 118

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