Regular octahedron: Difference between revisions

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{{Short description|Polyhedron with eight triangular faces}}
{{Short description|Solid with eight equal triangular faces}}
{{Use dmy dates|date=January 2020}}
{{Use dmy dates|date=January 2020}}


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  | name = Regular octahedron
  | name = Regular octahedron
  | image = Octahedron.jpg
  | image = Octahedron.jpg
  | type = [[Deltahedron]],<br>[[Platonic solid]]
  | type = [[Bipyramid]],<br>[[Deltahedron]],<br>[[Octahedron]],<br>[[Platonic solid]],<br>[[Regular polyhedron]]
  | vertices = 6
  | vertices = 6
  | edges = 12
  | edges = 12
  | faces = 8
  | faces = 8
| schläfli = <math> \{3,4\} </math>
  | symmetry = [[octahedral symmetry]]
  | symmetry = [[octahedral symmetry]]
| dual = [[cube]]
| net = [[Image:Octahedron flat.svg|frameless|upright=1.0]]
| angle = 109.47°
| properties = [[composite polyhedron|composite]],<br>[[convex polyhedron|convex]],<br>[[isohedral]],<br>[[isogonal figure|isogonal]],<br>[[isotoxal]]
}}
}}
In [[geometry]], a '''regular octahedron''' is a [[Platonic solid]] composed of eight [[equilateral triangle]]s, four of which meet at each vertex. Regular octahedra occur in nature as [[crystal]] structures. An [[octahedron]], more generally, can be any eight-sided [[polyhedron]]; many types of irregular octahedra also exist.
In [[geometry]], a '''regular octahedron''' is a highly symmetrical type of [[octahedron]] (eight-sided [[polyhedron]]) with eight [[equilateral triangle]]s as its [[face (geometry)|faces]], four of which meet at each [[vertex (geometry)|vertex]]. It is a type of [[square bipyramid]] or [[triangular antiprism]] with equal-length [[edge (geometry)|edges]]. Regular octahedra occur in nature as [[crystal]] structures. Other types of octahedra also exist, with various amounts of symmetry.


A regular octahedron is the three-dimensional case of the more general concept of a [[cross-polytope]].
A regular octahedron is the three-dimensional case of the more general concept of a [[cross-polytope]].


== As a Platonic solid ==
== Description ==
The regular octahedron is one of the [[Platonic solid]]s, a set of [[convex polyhedron|convex polyhedra]] whose faces are [[Congruence (geometry)|congruent]] [[regular polygons]] and the same number of faces meet at each vertex.{{r|hs}} This ancient set of polyhedrons was named after [[Plato]] who, in his [[Timaeus (dialogue)|''Timaeus'']] dialogue, related these solids to [[classical element]]s, with the octahedron representing [[Wind (classical element)|wind]].{{r|cromwell}} Following its attribution with nature by Plato, [[Johannes Kepler]] in his ''[[Harmonices Mundi]]'' sketched each of the Platonic solids.{{r|cromwell}} In his ''[[Mysterium Cosmographicum]]'', Kepler also proposed the [[Solar System]] by using the Platonic solids setting into another one and separating them with six spheres resembling the six planets. The ordered solids started from the innermost to the outermost: regular octahedron, [[regular icosahedron]], [[regular dodecahedron]], [[regular tetrahedron]], and [[cube]].{{r|livio}}
 
{{multiple image
{{multiple image
  | image1 = Kepler Octahedron Air.jpg
  | image1 = Kepler Octahedron Air.jpg
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  | image2 = Mysterium Cosmographicum solar system model.jpg
  | image2 = Mysterium Cosmographicum solar system model.jpg
  | caption2 = [[Johannes Kepler|Kepler's]] Platonic solid model of the [[Solar System]]
  | caption2 = [[Johannes Kepler|Kepler's]] Platonic solid model of the [[Solar System]]
  | align = right
| image3 = Dual Cube-Octahedron.svg
  | total_width = 300
| caption3 = The dual of a regular octahedron is cube
  | align = center
  | total_width = 420
}}
}}
The regular octahedron is one of the [[Platonic solid]]s, a set of polyhedrons whose faces are [[Congruence (geometry)|congruent]] [[regular polygons]] and the same number of faces meet at each vertex.{{r|hs}} This ancient set of polyhedrons was named after [[Plato]] who, in his [[Timaeus (dialogue)|''Timaeus'']] dialogue, related these solids to nature. One of them, the regular octahedron, represented the [[classical element]] of [[Wind (classical element)|wind]].{{r|cromwell}}
A regular octahedron is the [[cross-polytope]] in 3-dimensional space. It can be oriented and scaled so that its axes align with [[Cartesian coordinate]] axes and its vertices have coordinates{{r|smith}}
 
<math display="block"> (\pm 1, 0, 0), \qquad (0, \pm 1, 0), \qquad (0, 0, \pm 1). </math>
Following its attribution with nature by Plato, [[Johannes Kepler]] in his ''[[Harmonices Mundi]]'' sketched each of the Platonic solids.{{r|cromwell}} In his ''[[Mysterium Cosmographicum]]'', Kepler also proposed the [[Solar System]] by using the Platonic solids setting into another one and separating them with six spheres resembling the six planets. The ordered solids started from the innermost to the outermost: regular octahedron, [[regular icosahedron]], [[regular dodecahedron]], [[regular tetrahedron]], and [[cube]].{{r|livio}}
Such an octahedron has edge length {{tmath|\sqrt2}}.
 
[[File:Dual Cube-Octahedron.svg|thumb|upright=0.6|The dual of a regular octahedron is cube]]
A regular octahedron is convex, meaning that for any two points within it, the [[line segment]] connecting them lies entirely within it. It is one of the eight convex [[deltahedron|deltahedra]] because all of the faces are [[equilateral triangles]].{{r|trigg}} It is a [[composite polyhedron]] made by attaching two [[equilateral square pyramid]]s.{{r|timofeenko-2010|erickson}} Its [[dual polyhedron]] is the [[cube]], and they have the same [[Point groups in three dimensions| three-dimensional symmetry groups]], the octahedral symmetry <math> \mathrm{O}_\mathrm{h} </math>.{{r|erickson}}
 
Like its dual, the regular octahedron has three properties: any two faces, two vertices, and two edges are transformed by rotation and reflection under the symmetry orbit, such that the appearance remains unchanged; these are [[isohedral]], [[isogonal figure|isogonal]], and [[isotoxal]] respectively. Hence, it is considered a [[regular polyhedron]]. Four triangles surround each vertex, so the regular octahedron is <math> 3.3.3.3 </math> by [[vertex configuration]] or <math> \{3,4\} </math> by [[Schläfli symbol]].{{r|wd}}
 
==As a square bipyramid==
[[File:Square bipyramid.png|thumb|upright=0.6|Square bipyramid]]
Many octahedra of interest are '''square bipyramids'''.{{r|oh}} A square bipyramid is a [[bipyramid]] constructed by attaching two square pyramids base-to-base. These pyramids cover their square bases, so the resulting polyhedron has eight triangular faces.{{r|trigg}}
 
A square bipyramid is said to be right if the square pyramids are symmetrically regular and both of their apices are on the line passing through the base's center; otherwise, it is oblique.{{r|polya}} The resulting bipyramid has [[Point groups in three dimensions|three-dimensional point group]] of [[dihedral group]] <math> D_{4\mathrm{h}} </math> of sixteen: the appearance is symmetrical by rotating around the axis of symmetry that passing through apices and base's center vertically, and it has mirror symmetry relative to any bisector of the base; it is also symmetrical by reflecting it across a horizontal plane.{{r|ak}} Therefore, this square bipyramid is [[face-transitive]] or isohedral.{{r|mclean}}


If the edges of a square bipyramid are all equal in length, then that square bipyramid is a regular octahedron.  
The regular octahedron's [[dual polyhedron]] is the [[cube]], and they have the same [[Point groups in three dimensions| three-dimensional symmetry groups]], the octahedral symmetry <math> \mathrm{O}_\mathrm{h} </math>.{{r|erickson}} Like its dual, the regular octahedron has three properties: any two faces, two vertices, and two edges are transformed by rotation and reflection under the symmetry orbit, such that the appearance remains unchanged; these are [[isohedral]], [[isogonal figure|isogonal]], and [[isotoxal]] respectively. Hence, it is considered a [[regular polyhedron]]. Four triangles surround each vertex, so the regular octahedron is <math> 3.3.3.3 </math> by [[vertex configuration]] or <math> \{3,4\} </math> by [[Schläfli symbol]].{{r|wd}}


== Metric properties and Cartesian coordinates ==
== Metrical properties ==
[[File:Octahedron.stl|thumb|3D model of regular octahedron]]
[[File:Octahedron.stl|thumb|3D model of regular octahedron]]
The surface area <math> A </math> of a regular octahedron can be ascertained by summing all of its eight equilateral triangles, whereas its volume <math> V </math> is twice the volume of a square pyramid; if the edge length is <math>a</math>,{{r|berman}}
The surface area <math> A </math> of a regular octahedron can be ascertained by summing all of its eight equilateral triangles, whereas its volume <math> V </math> is twice the volume of a square pyramid; if the edge length is <math>a</math>,{{r|berman}}
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</math>
</math>


The [[dihedral angle]] of a regular octahedron between two adjacent triangular faces is 109.47°. This can be obtained from the dihedral angle of an equilateral square pyramid: its dihedral angle between two adjacent triangular faces is the dihedral angle of an equilateral square pyramid between two adjacent triangular faces, and its dihedral angle between two adjacent triangular faces on the edge in which two equilateral square pyramids are attached is twice the dihedral angle of an equilateral square pyramid between its triangular face and its square base.{{r|johnson}}
The [[dihedral angle]] of a regular octahedron between two adjacent triangular faces is <math>2\arctan{\sqrt{2}}</math>, which is about 109.47°. This can be obtained from the dihedral angle of an equilateral square pyramid: its dihedral angle between two adjacent triangular faces is the dihedral angle of an equilateral square pyramid between two adjacent triangular faces, and its dihedral angle between two adjacent triangular faces on the edge in which two equilateral square pyramids are attached is twice the dihedral angle of an equilateral square pyramid between its triangular face and its square base.{{r|johnson}}
 
== As other special cases ==
 
The regular octahedron is one of the eight convex [[deltahedron|deltahedra]], polyhedra whose faces are all [[equilateral triangles]].{{r|trigg}}


An octahedron with edge length <math> \sqrt{2} </math> can be placed with its center at the origin and its vertices on the coordinate axes; the [[Cartesian coordinates]] of the vertices are:{{r|smith}}
{{multiple image
<math display="block"> (\pm 1, 0, 0), \qquad (0, \pm 1, 0), \qquad (0, 0, \pm 1). </math>
| image1 = Square bipyramid.png
| caption1 = Square bipyramid
| image2 = Square prism.svg
| caption2 = The dual of a square bipyramid, the [[square prism]]
| total_width = 320
}}
{{anchor|Square bipyramid}}A regular octahedron is a type of square [[bipyramid]],{{r|oh}} a [[composite polyhedron]] constructed by attaching two [[equilateral square pyramid]]s base-to-base.{{r|timofeenko-2010|erickson}} The [[dual polyhedron]] of a bipyramid in general is the [[prism (geometry)|prism]], and vice versa; the regular octahedron's dual, the cube, is a type of [[square prism]].{{r|sibley}}
 
{{anchor|Trigonal antiprism}}The regular octahedron is a type of trigonal [[antiprism]],{{sfnp|O'Keeffe|Hyde|2020|p=[https://books.google.com/books?id=_MjPDwAAQBAJ&pg=PA141 141]}} formed by taking a trigonal [[Prism (geometry)|prism]] with equilateral triangle bases and rectangular lateral faces, and replacing the rectangles by alternating isosceles triangles. In the case of the regular octahedron, all of the resulting faces are congruent equilateral triangles.
 
The regular octahedron can also be considered a [[rectification (geometry)|rectified]] tetrahedron, sometimes called a '''tetratetrahedron''' (by analogy to the [[cuboctahedron]] and [[icosidodecahedron]]); if alternate faces are considered to have different types (e.g. different colors or orientations), the octahedron can be considered a type of [[quasiregular polyhedron]], a polyhedron in which two different types of polygonal faces alternate around each vertex.{{r|maekawa}} It exists in a sequence of symmetries of quasiregular polyhedra and tilings with [[vertex configuration]]s (3.''n'')<sup>2</sup>, progressing from tilings of the sphere to the Euclidean plane and into the hyperbolic plane. With [[orbifold notation]] symmetry of *''n''32 all of these tilings are [[Wythoff construction]]s within a [[fundamental domain]] of symmetry, with generator points at the right angle corner of the domain.{{r|coxeter|huson}}
{{Quasiregular3 small table}}


== Graph ==
== Graph ==
[[File:Complex tripartite graph octahedron.svg|class=skin-invert-image|thumb|upright=0.8|The graph of a regular octahedron]]
[[File:Complex tripartite graph octahedron.svg|class=skin-invert-image|thumb|upright=0.8|The graph of a regular octahedron]]
The [[Skeleton (topology)|skeleton]] of a regular octahedron can be represented as a [[Graph (discrete mathematics)|graph]] according to [[Steinitz's theorem]], provided the graph is [[Planar graph|planar]]&mdash;its edges of a graph are connected to every vertex without crossing other edges&mdash;and [[k-vertex-connected graph|3-connected graph]]&mdash;its edges remain connected whenever two of more three vertices of a graph are removed.{{r|grunbaum-2003|ziegler}} Its graph called the '''octahedral graph''', a [[Platonic graph]].{{r|hs}}
The [[Graph of a polytope|skeleton]] of a regular octahedron is the (undirected) [[Undirected graph|graph]] formed by its vertices and edges. [[Steinitz's theorem]] guarantees that the this graph can be drawn [[Planar graph|with no edge crossing another]], and all remaining vertices [[k-vertex-connected graph|remain connected]] when any two are removed.{{r|grunbaum-2003|ziegler}} Its graph called the '''octahedral graph''', a [[Platonic graph]].{{r|hs}}


The octahedral graph can be considered as [[Tripartite graph|complete tripartite graph]] <math> K_{2,2,2} </math>, a graph partitioned into three independent sets each consisting of two opposite vertices.{{r|negami}} More generally, it is a [[Turán graph]] <math> T_{6,3} </math>.
The octahedral graph can be considered as [[Tripartite graph|complete tripartite graph]] <math> K_{2,2,2} </math>, a graph partitioned into three independent sets, each consisting of two opposite vertices.{{r|negami}} Additionally, it is a [[Turán graph]] <math> T_{6,3} </math>.


The octahedral graph is [[k-vertex-connected graph|4-connected]], meaning that it takes the removal of four vertices to disconnect the remaining vertices. It is one of only four 4-connected [[simplicial polytope|simplicial]] [[well-covered graph|well-covered]] polyhedra, meaning that all of the [[maximal independent set]]s of its vertices have the same size. The other three polyhedra with this property are the [[pentagonal dipyramid]], the [[snub disphenoid]], and an irregular polyhedron with 12 vertices and 20 triangular faces.{{r|fhnp}}
The octahedral graph is [[k-vertex-connected graph|4-connected]], meaning that it takes the removal of four vertices to disconnect the remaining vertices. It is one of only four 4-connected [[simplicial polytope|simplicial]] [[well-covered graph|well-covered]] polyhedra, meaning that all of the [[maximal independent set]]s of its vertices have the same size. The other three polyhedra with this property are the [[pentagonal dipyramid]], the [[snub disphenoid]], and an irregular polyhedron with 12 vertices and 20 triangular faces.{{r|fhnp}}


== Related figures ==
== Other related figures ==
[[File:Compound of two tetrahedra.png|right|thumb|upright=0.8|The octahedron represents the central intersection of two tetrahedra]]
{{multiple image
The interior of the [[polyhedral compound|compound]] of two dual [[tetrahedra]] is an octahedron, and this compound&mdash;called the [[stella octangula]]&mdash;is its first and only [[stellation]].{{sfnp|Cromwell|1997|p=171, 261}} Correspondingly, a regular octahedron is the result of cutting off from a regular tetrahedron, four regular tetrahedra of half the linear size (i.e. [[Rectification (geometry)|rectifying]] the tetrahedron). The vertices of the octahedron lie at the midpoints of the edges of the tetrahedron, and in this sense it relates to the tetrahedron in the same way that the [[cuboctahedron]] and [[icosidodecahedron]] relate to the other Platonic solids.
| image1 = Compound of two tetrahedra.png
| caption1 = The regular octahedron represents the [[Stellated octahedron|central intersection of two tetrahedra]]
| image2 = Truncatedoctahedron.svg
| caption2 = The [[truncated octahedron]] by removing the vertices of a regular octahedron
| image3 = Diamant1.gif
| caption3 = The [[triakis octahedron]] by attaching triangular pyramids on each face
| total_width = 500
}}
The interior of the [[polyhedral compound|compound]] of two dual [[tetrahedra]] is an octahedron, and this compound&mdash;called the [[stella octangula]]&mdash;is its first and only [[stellation]].{{sfnp|Cromwell|1997|p=171, 261}} Correspondingly, a regular octahedron is the result of cutting off from a regular tetrahedron, four regular tetrahedra of half the linear size (i.e. [[Rectification (geometry)|rectifying]] the tetrahedron). The vertices of the octahedron lie at the midpoints of the edges of the tetrahedron, and in this sense, it relates to the tetrahedron in the same way that the [[cuboctahedron]] and [[icosidodecahedron]] relate to the other Platonic solids.
 
Several constructions of polyhedra commence from the regular octahedron. The [[truncated octahedron]] is an [[Archimedean solid]], constructed by removing all of the regular octahedron's vertices, resulting in six squares and eight hexagons, leaving out six square pyramids.{{r|diudea}} The [[triakis octahedron]] is a [[Catalan solid]], the [[Kleetope]] of a regular octahedron, by attaching triangular pyramids onto its faces, [[Topology|topologically]] similar to the stellated octahedron.{{r|bpv}} The uniform [[tetrahemihexahedron]] is a [[tetrahedral symmetry]] [[faceting]] of the regular octahedron, sharing [[edge arrangement|edge]] and [[vertex arrangement]]. It has four of the triangular faces and three central squares.{{r|pmtsgsd}}


One can also divide the edges of an octahedron in the ratio of the [[golden ratio|golden mean]] to define the vertices of a [[regular icosahedron]]. This is done by first placing vectors along the octahedron's edges such that each face is bounded by a cycle, then similarly partitioning each edge into the golden mean along the direction of its vector. Five octahedra define any given icosahedron in this fashion, and together they define a ''regular compound''. A regular icosahedron produced this way is called a ''snub octahedron''.{{r|kappraff}}
One can also divide the edges of an octahedron in the ratio of the [[golden ratio|golden mean]] to define the vertices of a [[regular icosahedron]]. This is done by first placing vectors along the octahedron's edges such that each face is bounded by a cycle, then similarly partitioning each edge into the golden mean along the direction of its vector. Five octahedra define any given icosahedron in this fashion, and together they define a regular compound. A regular icosahedron produced this way is called a "snub octahedron".{{r|kappraff}}


{{anchor|Trigonal antiprism}}The regular octahedron can be considered as the [[antiprism]], a [[Prism (geometry)|prism]] like polyhedron in which lateral faces are replaced by alternating equilateral triangles. It is also called ''trigonal antiprism''.{{sfnp|O'Keeffe|Hyde|2020|p=[https://books.google.com/books?id=_MjPDwAAQBAJ&pg=PA141 141]}} Therefore, it has the property of [[Quasiregular polyhedron|quasiregular]], a polyhedron in which two different polygonal faces are alternating and meet at a vertex.{{r|maekawa}}
{{multiple image
| total_width = 360
| image1 = HC P1-P3.png
| caption1 = [[Tetrahedral-octahedral honeycomb]] by regular octahedra and tetrahedra
| image2 = Rectified cubic honeycomb.jpg
| caption2 = [[Rectified cubic honeycomb]] by regular octahedra and cuboctahedra
}}
Regular octahedra and regular tetrahedra can be alternated to form a vertex, edge, and face-uniform [[tessellation of space]], which is named [[tetrahedral-octahedral honeycomb]].{{sfnp|Posamentier et al.|2022|p=[https://books.google.com/books?id=DGxYEAAAQBAJ&pg=PA233 232&ndash;234]}} [[R. Buckminster Fuller]] in the 1950s applied these alternating polyhedra as a [[space frame]], which developed the strongest building structure for resisting [[cantilever]] stresses.{{r|mp}} Another honeycomb is tesselating the regular octahedra alternately with [[cuboctahedron|cuboctahedra]], named the [[rectified cubic honeycomb]].{{sfnp|Posamentier et al.|2022|p=[https://books.google.com/books?id=DGxYEAAAQBAJ&pg=PA235 234&ndash;235]}}
 
A regular octahedron is a [[n-ball|3-ball]] in the [[Taxicab geometry|Manhattan ({{math|''ℓ''}}{{sub|1}}) metric]].
 
== Other appearances ==
 
{{glossary}}
{{term|Nature and science}}
{{defn|[[Image:Fluorite octahedron.jpg|thumb|upright=0.6|[[Fluorite]] with octahedral structure]]
<p>The natural crystals with octahedral structures are commonly discovered in [[diamond]],{{r|wells}} [[alum]],{{r|glr}} and [[fluorite]]. The plates of [[kamacite]] alloy in [[octahedrite]] [[meteorites]] are arranged paralleling the eight faces of an octahedron. Many metal ions [[Coordination chemistry|coordinate]] six ligands in an octahedral or [[Jahn–Teller effect|distorted]] octahedral configuration. [[Widmanstätten pattern]]s in [[nickel]]-[[iron]] [[crystal]]s.
</p>
 
<p>[[Octahedral molecular geometry]] is a chemical molecule resembling a regular octahedron in [[stereochemistry]]. This structure has a [[main-group element]] without an active [[lone pair]], which can be described by a model that predicts the geometry of molecules known as [[VSEPR theory]].{{r|phh}}
</p>
 
<p>If each edge of an octahedron is replaced by a one-[[ohm (unit)|ohm]] [[resistor]], the resistance between opposite vertices is <math display="inline"> \frac{1}{2} </math> ohm, and that between adjacent vertices <math display="inline"> \frac{5}{12} </math> ohm.{{r|klein}}
</p>
}}


[[Tetrahedral-octahedral honeycomb|Octahedra and tetrahedra]] can be alternated to form a vertex, edge, and face-uniform [[tessellation of space]]. This and the regular tessellation of [[cube]]s are the only such [[uniform honeycomb]]s in 3-dimensional space.
{{term|Popular culture}}
{{defn|[[Image:Rubiks snake octahedron.jpg|thumb|Two identically formed [[Rubik's Snake]]s can approximate an octahedron.]]
<p>In [[roleplaying game]]s, this solid is known as a "d8", one of the more common [[dice#Polyhedral dice|polyhedral dice]].{{r|br}}
</p>
}}


The uniform [[tetrahemihexahedron]] is a [[tetrahedral symmetry]] [[faceting]] of the regular octahedron, sharing [[edge arrangement|edge]] and [[vertex arrangement]]. It has four of the triangular faces, and 3 central squares.
{{term|Music theory}}
{{defn|The [[hexany]] is the octahedron's [[orthogonal projection]]. Six musical notes can be arranged on the vertices of an octahedron in such a way that each edge represents a consonant dyad and each face represents a consonant triad.{{r|terumi}}
</p>
}}


A regular octahedron is a [[n-ball|3-ball]] in the [[Taxicab geometry|Manhattan ({{math|''ℓ''}}{{sub|1}}) metric]].
{{glossary end}}


== Characteristic orthoscheme ==
== Characteristic orthoscheme ==
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|align=center|<small><math>\tfrac{\pi}{2}</math></small>
|align=center|<small><math>\tfrac{\pi}{2}</math></small>
|-
|-
!align=right|𝝉{{Efn|{{Harv|Coxeter|1973}} uses the greek letter 𝝓 (phi) to represent one of the three ''characteristic angles'' 𝟀, 𝝓, 𝟁 of a regular polytope. Because 𝝓 is commonly used to represent the [[golden ratio]] constant ≈ 1.618, for which Coxeter uses 𝝉 (tau), we reverse Coxeter's conventions, and use 𝝉 to represent the characteristic angle.|name=reversed greek symbols}}
!align=right|𝝉{{Efn|{{Harv|Coxeter|1973}} uses the Greek letter 𝝓 (phi) to represent one of the three ''characteristic angles'' 𝟀, 𝝓, 𝟁 of a regular polytope. Because 𝝓 is commonly used to represent the [[golden ratio]] constant ≈ 1.618, for which Coxeter uses 𝝉 (tau), we reverse Coxeter's conventions and use 𝝉 to represent the characteristic angle.|name=reversed greek symbols}}
|align=center|<small><math>1</math></small>
|align=center|<small><math>1</math></small>
|align=center|<small>45°</small>
|align=center|<small>45°</small>
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|align=center|
|align=center|
|}
|}
If the octahedron has edge length 𝒍 = 2, its characteristic tetrahedron's six edges have lengths <small><math>\sqrt{\tfrac{4}{3}}</math></small>, <small><math>1</math></small>, <small><math>\sqrt{\tfrac{1}{3}}</math></small> around its exterior right-triangle face (the edges opposite the ''characteristic angles'' 𝟀, 𝝉, 𝟁),{{Efn|name=reversed greek symbols}} plus <small><math>\sqrt{2}</math></small>, <small><math>1</math></small>, <small><math>\sqrt{\tfrac{2}{3}}</math></small> (edges that are the ''characteristic radii'' of the octahedron). The 3-edge path along orthogonal edges of the orthoscheme is <small><math>1</math></small>, <small><math>\sqrt{\tfrac{1}{3}}</math></small>, <small><math>\sqrt{\tfrac{2}{3}}</math></small>, first from an octahedron vertex to an octahedron edge center, then turning 90° to an octahedron face center, then turning 90° to the octahedron center. The orthoscheme has four dissimilar right triangle faces. The exterior face is a [[30-60-90 triangle|90-60-30 triangle]] which is one-sixth of an octahedron face. The three faces interior to the octahedron are: a [[45-45-90 triangle|45-90-45 triangle]] with edges <small><math>1</math></small>, <small><math>\sqrt{2}</math></small>, <small><math>1</math></small>, a right triangle with edges <small><math>\sqrt{\tfrac{1}{3}}</math></small>, <small><math>1</math></small>, <small><math>\sqrt{\tfrac{2}{3}}</math></small>, and a right triangle with edges <small><math>\sqrt{\tfrac{4}{3}}</math></small>, <small><math>\sqrt{2}</math></small>, <small><math>\sqrt{\tfrac{2}{3}}</math></small>.
If the octahedron has edge length 𝒍 = 2, its characteristic tetrahedron's six edges have lengths <small><math>\sqrt{\tfrac{4}{3}}</math></small>, <small><math>1</math></small>, <small><math>\sqrt{\tfrac{1}{3}}</math></small> around its exterior right-triangle face (the edges opposite the ''characteristic angles'' 𝟀, 𝝉, 𝟁),{{Efn|name=reversed greek symbols}} plus <small><math>\sqrt{2}</math></small>, <small><math>1</math></small>, <small><math>\sqrt{\tfrac{2}{3}}</math></small> (edges that are the ''characteristic radii'' of the octahedron). The 3-edge path along orthogonal edges of the orthoscheme is <small><math>1</math></small>, <small><math>\sqrt{\tfrac{1}{3}}</math></small>, <small><math>\sqrt{\tfrac{2}{3}}</math></small>, first from an octahedron vertex to an octahedron edge center, then turning 90° to an octahedron face center, then turning 90° to the octahedron center. The orthoscheme has four dissimilar right triangle faces. The exterior face is a [[30-60-90 triangle|90-60-30 triangle]], which is one-sixth of an octahedron face. The three faces interior to the octahedron are: a [[45-45-90 triangle|45-90-45 triangle]] with edges <small><math>1</math></small>, <small><math>\sqrt{2}</math></small>, <small><math>1</math></small>, a right triangle with edges <small><math>\sqrt{\tfrac{1}{3}}</math></small>, <small><math>1</math></small>, <small><math>\sqrt{\tfrac{2}{3}}</math></small>, and a right triangle with edges <small><math>\sqrt{\tfrac{4}{3}}</math></small>, <small><math>\sqrt{2}</math></small>, <small><math>\sqrt{\tfrac{2}{3}}</math></small>.


==Uniform colorings and symmetry==
=== Notes ===
There are 3 [[uniform coloring]]s of the octahedron, named by the triangular face colors going around each vertex: 1212, 1112, 1111.
{{notelist}}
 
The octahedron's [[symmetry group]] is O<sub>h</sub>, of order 48, the three dimensional [[hyperoctahedral group]].  This group's [[subgroup]]s include D<sub>3d</sub> (order 12), the symmetry group of a triangular [[antiprism]]; '''D<sub>4h</sub>''' (order 16), the symmetry group of a square [[bipyramid]]; and T<sub>d</sub> (order 24), the symmetry group of a [[Octahedron#Tetratetrahedron|rectified tetrahedron]]. These symmetries can be emphasized by different colorings of the faces.
{| class=wikitable
!Name
!Octahedron
![[Rectification (geometry)|Rectified]] [[tetrahedron]]<br>(Tetratetrahedron)
!Triangular [[antiprism]]
!Square [[bipyramid]]
!Rhombic fusil
|- align=center
!Image<br>(Face coloring)
|[[File:Uniform polyhedron-43-t2.png|100px]]<br>(1111)
|[[File:Uniform polyhedron-33-t1.svg|100px]]<br>(1212)
|[[File:Trigonal antiprism.png|100px]]<br>(1112)
|[[File:Square bipyramid.png|100px]]<br>(1111)
|[[File:Rhombic bipyramid.png|100px]]<br>(1111)
|- align=center
![[Coxeter diagram]]
|{{CDD|node_1|3|node|4|node}}
|{{CDD|node_1|3|node|4|node_h0}} = {{CDD|node_1|split1|nodes}}
|{{CDD|node_h|2x|node_h|6|node}}<br>{{CDD|node_h|2x|node_h|3|node_h}}
|{{CDD|node_f1|2x|node_f1|4|node}}
|{{CDD|node_f1|2x|node_f1|2x|node_f1}}
|- align=center
![[Schläfli symbol]]
|{3,4}
|r{3,3}
|s{2,6}<br>sr{2,3}
|ft{2,4}<br>{ } + {4}
|ftr{2,2}<br>{ } + { } + { }
|- align=center
![[Wythoff symbol]]
| 4 {{pipe}} 3 2
| 2 {{pipe}} 4 3
| 2 {{pipe}} 6 2 <br> {{pipe}} 2 3 2
| ||
|- align=center
![[List of spherical symmetry groups|Symmetry]]
|O<sub>h</sub>, [4,3], (*432)
|T<sub>d</sub>, [3,3], (*332)
|D<sub>3d</sub>, [2<sup>+</sup>,6], (2*3)<br>D<sub>3</sub>, [2,3]<sup>+</sup>, (322)
|D<sub>4h</sub>, [2,4], (*422)
|D<sub>2h</sub>, [2,2], (*222)
|- align=center
![[Group order|Order]]
|48
|24
|12<br>6
|16
|8
|}
 
==In the physical world==
 
===In nature===
[[Image:Fluorite octahedron.jpg|thumb|[[Fluorite]] octahedron.]]
* Natural crystals of [[diamond]], [[alum]] or [[fluorite]] are commonly octahedral, as the space-filling [[tetrahedral-octahedral honeycomb]].
* The plates of [[kamacite]] alloy in [[octahedrite]] [[meteorites]] are arranged paralleling the eight faces of an octahedron.
* Many metal ions [[Coordination chemistry|coordinate]] six ligands in an octahedral or [[Jahn–Teller effect|distorted]] octahedral configuration.
* [[Widmanstätten pattern]]s in [[nickel]]-[[iron]] [[crystal]]s
 
===In art and culture===
[[Image:Rubiks snake octahedron.jpg|thumb|Two identically formed [[Rubik's Snake]]s can approximate an octahedron.]]
* Especially in [[roleplaying game]]s, this solid is known as a "d8", one of the more common [[dice#Polyhedral dice|polyhedral dice]].<ref>{{cite book
| title = Dungeons & Dragons For Dummies
| first1 = Bill | last1 = Slavicsek
| first2 = Richard | last2 = Baker
| year = 2005
| isbn = 9780764599248
| publisher = Wiley
}}</ref>
* If each edge of an octahedron is replaced by a one-[[ohm (unit)|ohm]] [[resistor]], the resistance between opposite vertices is {{sfrac|1|2}} ohm, and that between adjacent vertices {{sfrac|5|12}} ohm.<ref>{{cite journal |last=Klein |first=Douglas J. |year=2002 |title=Resistance-Distance Sum Rules |journal=Croatica Chemica Acta |volume=75 |issue=2 |pages=633–649 |url=http://jagor.srce.hr/ccacaa/CCA-PDF/cca2002/v75-n2/CCA_75_2002_633_649_KLEIN.pdf |access-date=30 September 2006 |archive-url=https://web.archive.org/web/20070610165115/http://jagor.srce.hr/ccacaa/CCA-PDF/cca2002/v75-n2/CCA_75_2002_633_649_KLEIN.pdf |archive-date=10 June 2007 |url-status=dead }}</ref>
* The [[hexany]] is the octahedron's [[orthogonal projection]]. Six musical notes can be arranged on the vertices of an octahedron in such a way that each edge represents a consonant dyad and each face represents a consonant triad.<ref>{{cite book
| title = Microtonality and the Tuning Systems of Erv Wilson
| first = Terumi | last = Narushima
| year = 2018
| publisher = Taylor & Francis
| url = https://books.google.com/books?id=VmkPEAAAQBAJ&pg=PA151
| page = 151&ndash;155
| isbn = 978-1-317-51343-8 }}</ref>
 
===Tetrahedral octet truss===
A [[space frame]] of alternating tetrahedra and half-octahedra derived from the [[Tetrahedral-octahedral honeycomb]] was invented by [[Buckminster Fuller]] in the 1950s. It is commonly regarded as the strongest building structure for resisting [[cantilever]] stresses.
 
===Tetratetrahedron===
The regular octahedron can also be considered a ''[[rectification (geometry)|rectified]] tetrahedron'' – and can be called a ''tetratetrahedron''. This can be shown by a 2-color face model. With this coloring, the octahedron has [[tetrahedral symmetry]].
 
Compare this truncation sequence between a tetrahedron and its dual:
{{Tetrahedron family}} <!-- This template shows too many figures. It needs replacing with the simple set described in the text -->
 
The above shapes may also be realized as slices orthogonal to the long diagonal of a [[tesseract]]. If this diagonal is oriented vertically with a height of 1, then the first five slices above occur at heights ''r'', {{sfrac|3|8}}, {{sfrac|1|2}}, {{sfrac|5|8}}, and ''s'', where ''r'' is any number in the range {{nowrap|0 < ''r'' ≤ {{sfrac|1|4}}}}, and ''s'' is any number in the range {{nowrap|{{sfrac|3|4}} ≤ ''s'' < 1}}.
 
The octahedron as a ''tetratetrahedron'' exists in a sequence of symmetries of quasiregular polyhedra and tilings with [[vertex configuration]]s (3.''n'')<sup>2</sup>, progressing from tilings of the sphere to the Euclidean plane and into the hyperbolic plane. With [[orbifold notation]] symmetry of *''n''32 all of these tilings are [[Wythoff construction]]s within a [[fundamental domain]] of symmetry, with generator points at the right angle corner of the domain.<ref>{{cite book |last=Coxeter |first=H.S.M. |author-link=Harold Scott MacDonald Coxeter |title-link=Regular Polytopes (book) |title=Regular Polytopes |edition=Third |date=1973 |publisher=Dover |isbn=0-486-61480-8 |at=Chapter V: The Kaleidoscope, Section: 5.7 Wythoff's construction}}</ref><ref>{{citation |last=Huson |first=Daniel H. |title= Two Dimensional Symmetry Mutation |date=September 1998 |url=https://www.researchgate.net/publication/2422380}}</ref>
{{Quasiregular3 small table}}
 
===Trigonal antiprism===
As a trigonal [[antiprism]], the octahedron is related to the hexagonal dihedral symmetry family.
{{Hexagonal dihedral truncations}}
 
{{UniformAntiprisms}}
 
===Other related polyhedra===
Truncation of two opposite vertices results in a [[square bifrustum]].
 
The octahedron can be generated as the case of a 3D [[superellipsoid]] with all exponent values set to 1.


== See also ==
== See also ==
* [[Octahedral number]]
* [[25 great circles of the spherical octahedron]], arrangement of [[great circles]] within a spherical octahedron;
* [[Centered octahedral number]]
* [[Centered octahedral number]], [[figurate number]] that counts the points of a three-dimensional integer lattice that lie inside a regular octahedron centered at the origin;
* [[Triakis octahedron]]
* [[Disdyakis dodecahedron|Hexakis octahedron]], another polyhedron's construction involving the regular octahedron's commencement;
* [[Disdyakis dodecahedron|Hexakis octahedron]]
* [[Octahedral number]], [[figurate number]] that represents the number of spheres in a regular octahedron formed from [[close-packed spheres]];
* [[Truncated octahedron]]
* [[Octahedral sphere]], spherical shape of a cross-polytope;
* [[Octahedral molecular geometry]]
* [[Skewb Diamond]], an octahedral version of [[Rubik's cube]]
* [[Octahedral sphere]]
* [[Superellipsoid]], a solid whose horizontal sections are of the same squareness.
 
== Notes ==
{{notelist}}


== References ==
== References ==
{{reflist|refs=
<references>
 
<ref name=ak>{{cite book
| last1 = Alexander | first1 = Daniel C.
| last2 = Koeberlin | first2 = Geralyn M.
| year = 2014
| title = Elementary Geometry for College Students
| url = https://books.google.com/books?id=EN_KAgAAQBAJ&pg=PA403
| edition = 6th
| publisher = Cengage Learning
| page = 403
| isbn = 978-1-285-19569-8
}}</ref>
 
<ref name=berman>{{cite journal
<ref name=berman>{{cite journal
  | last = Berman | first = Martin
  | last = Berman | first = Martin
Line 318: Line 251:
  | doi = 10.1016/0016-0032(71)90071-8
  | doi = 10.1016/0016-0032(71)90071-8
  | mr = 290245
  | mr = 290245
}}</ref>
<ref name=bpv>{{cite book
| last1 = Brigaglia | first1 = Aldo
| last2 = Palladino | first2 = Nicla
| last3 = Vaccaro | first3 = Maria Alessandra
| editor1-last = Emmer | editor1-first = Michele
| editor2-last = Abate | editor2-first = Marco
| contribution = Historical notes on star geometry in mathematics, art and nature
| doi = 10.1007/978-3-319-93949-0_17
| pages = 197–211
| publisher = Springer International Publishing
| title = Imagine Math 6: Between Culture and Mathematics
| year = 2018| isbn = 978-3-319-93948-3
| hdl = 10447/325250
| hdl-access = free
}}</ref>
<ref name=br>{{cite book
| title = Dungeons & Dragons For Dummies
| first1 = Bill | last1 = Slavicsek
| first2 = Richard | last2 = Baker
| year = 2005
| isbn = 9780764599248
| publisher = Wiley
}}</ref>
<ref name=coxeter>{{cite book
| last = Coxeter | first = H.S.M. | author-link = Harold Scott MacDonald Coxeter
| title-link = Regular Polytopes (book)
| title = Regular Polytopes
| edition = 3rd
| year = 1973
| publisher = [[Dover Publications]]
| isbn = 0-486-61480-8
| at =Chapter V: The Kaleidoscope, Section: 5.7 Wythoff's construction
}}</ref>
}}</ref>


Line 327: Line 296:
  | url = https://archive.org/details/polyhedra0000crom/page/55
  | url = https://archive.org/details/polyhedra0000crom/page/55
  | page = 55
  | page = 55
| isbn = 978-0-521-55432-9
| isbn = 978-0-521-55432-9
  }}</ref>
}}</ref>
 
<ref name=diudea>{{cite book
| last = Diudea | first = M. V.
| year = 2018
  | title = Multi-shell Polyhedral Clusters
| series = Carbon Materials: Chemistry and Physics
| volume = 10
| publisher = [[Springer Science+Business Media|Springer]]
| isbn = 978-3-319-64123-2
| doi = 10.1007/978-3-319-64123-2
| url = https://books.google.com/books?id=p_06DwAAQBAJ&pg=PA39
| page = 39
}}</ref>


<ref name=erickson>{{cite book
<ref name=erickson>{{cite book
Line 355: Line 337:
  | doi-access = free
  | doi-access = free
}}</ref>
}}</ref>
<ref name=glr>{{cite book
| last1 = Glusker | first1 = Jenny P.
| last2 = Lewis | first2 = Mitchell
| last3 = Rossi | first3 = Miriam
| year = 1994
| title = Crystal Structure Analysis for Chemists and Biologists
| url = https://books.google.com/books?id=O-wMN9CSeP0C&pg=PA45
| page = 45
| publisher = [[John Wiley & Sons]]
| isbn = 978-0-471-18543-7
}}</ref>


<ref name=grunbaum-2003>{{citation
<ref name=grunbaum-2003>{{citation
Line 379: Line 373:
  | url = https://books.google.com/books?id=b2fjR81h6yEC&pg=PA252
  | url = https://books.google.com/books?id=b2fjR81h6yEC&pg=PA252
  | page = 252
  | page = 252
}}</ref>
<ref name=huson>{{cite web
| last = Huson | first = Daniel H.
| title =  Two Dimensional Symmetry Mutation
| date = September 1998
| url = https://www.researchgate.net/publication/2422380
}}</ref>
}}</ref>


Line 402: Line 403:
  | url = https://books.google.com/books?id=tz76s0ZGFiQC&pg=PA475
  | url = https://books.google.com/books?id=tz76s0ZGFiQC&pg=PA475
  | page = 475
  | page = 475
| isbn = 978-981-281-139-4
| isbn = 978-981-281-139-4
}}</ref>
}}</ref>
 
<ref name=klein>{{cite journal |last=Klein |first=Douglas J. |year=2002 |title=Resistance-Distance Sum Rules |journal=Croatica Chemica Acta |volume=75 |issue=2 |pages=633–649 |url=http://jagor.srce.hr/ccacaa/CCA-PDF/cca2002/v75-n2/CCA_75_2002_633_649_KLEIN.pdf |access-date=30 September 2006 |archive-url=https://web.archive.org/web/20070610165115/http://jagor.srce.hr/ccacaa/CCA-PDF/cca2002/v75-n2/CCA_75_2002_633_649_KLEIN.pdf |archive-date=10 June 2007 |url-status=dead }}</ref>


<ref name=livio>{{cite book
<ref name=livio>{{cite book
Line 428: Line 431:
}}</ref>
}}</ref>


<ref name=mclean>{{cite journal
<ref name=mp>{{cite book
  | last = McLean | first = K. Robin
  | last1 = Miura | first1 = Koryo
  | year = 1990
  | last2 = Pellegrino | first2 = Sergio
  | title = Dungeons, dragons, and dice
  | year = 2020
  | journal = The Mathematical Gazette
  | doi = 10.1017/9781139048569
  | volume = 74 | issue = 469 | pages = 243–256
  | isbn = 9781139048569
  | doi = 10.2307/3619822
| title = Forms and Concepts for Lightweight Structures
  | jstor = 3619822
  | url = https://books.google.com/books?id=v9LQDwAAQBAJ&pg=PA28
  | s2cid = 195047512
  | page = 28
  | publisher = [[Cambridge University Press]]
}}</ref>
}}</ref>


Line 466: Line 470:
}}</ref>
}}</ref>


<ref name=polya>{{cite book
<ref name=pmtsgsd>{{cite book
  | last = Polya | first = G.
  | last1 = Posamentier | first1 = Alfred S.
  | year = 1954
| last2 = Maresch | first2 = Guenter
  | title = Mathematics and Plausible Reasoning: Induction and analogy in mathematics
| last3 = Thaller | first3 = Bernd
  | url = https://books.google.com/books?id=-TWTcSa19jkC&pg=PA138
| last4 = Spreitzer | first4 = Christian
  | page = 138
| last5 = Geretschlager | first5 = Robert
  | publisher = Princeton University Press
| last6 = Stuhlpfarrer | first6 = David
| isbn = ((0-691-02509-6))<!-- isbn ok, goes to later reprint of same edition by same publisher -->
| last7 = Dorner | first7 = Christian
  | year = 2022
  | title = Geometry In Our Three-dimensional World
| publisher = [[World Scientific]]
| isbn = 9789811237126
  | url = https://books.google.com/books?id=DGxYEAAAQBAJ&pg=PA268
  | pages = 267&ndash;268
  | ref = {{harvid|Posamentier et al.|2022}}
}}</ref>
}}</ref>
<ref name=phh>{{cite book
| last1 = Petrucci | first1 = Ralph H.
| last2 = Harwood | first2 = William S.
| last3 = Herring | first3 = F. Geoffrey
| title = General Chemistry: Principles and Modern Applications
| volume = 1
| year = 2002
| url = https://books.google.com/books?id=EZEoAAAAYAAJ&pg=PA413
| pages = 413–414
| publisher = [[Prentice Hall]]
| isbn = 978-0-13-014329-7
}} See Table 11.1.</ref>


<ref name=radii>{{harvtxt|Coxeter|1973}} Table I(i), pp. 292–293. See the columns labeled <math>{}_0\!\mathrm{R}/\ell</math>, <math>{}_1\!\mathrm{R}/\ell</math>, and <math>{}_2\!\mathrm{R}/\ell</math>, Coxeter's notation for the circumradius, midradius, and inradius, respectively, also noting that Coxeter uses <math>2\ell</math> as the edge length (see p. 2).</ref>
<ref name=radii>{{harvtxt|Coxeter|1973}} Table I(i), pp. 292–293. See the columns labeled <math>{}_0\!\mathrm{R}/\ell</math>, <math>{}_1\!\mathrm{R}/\ell</math>, and <math>{}_2\!\mathrm{R}/\ell</math>, Coxeter's notation for the circumradius, midradius, and inradius, respectively, also noting that Coxeter uses <math>2\ell</math> as the edge length (see p. 2).</ref>
<ref name=sibley>{{cite book
| last = Sibley | first = Thomas Q.
| year = 2015
| title = Thinking Geometrically: A Survey of Geometries
| publisher = Mathematical Association of American
| page = 53
| url = https://books.google.com/books?id=EUh2CgAAQBAJ&pg=PA53
| isbn =978-1-939512-08-6
}}</ref>


<ref name=smith>{{cite book
<ref name=smith>{{cite book
Line 486: Line 520:
  | publisher = [[John Wiley & Sons]]
  | publisher = [[John Wiley & Sons]]
  | isbn = 978-1-118-03103-2
  | isbn = 978-1-118-03103-2
}}</ref>
<ref name=terumi>{{cite book
| title = Microtonality and the Tuning Systems of Erv Wilson
| first = Terumi | last = Narushima
| year = 2018
| publisher = Taylor & Francis
| url = https://books.google.com/books?id=VmkPEAAAQBAJ&pg=PA151
| page = 151&ndash;155
| isbn = 978-1-317-51343-8
}}</ref>
}}</ref>


Line 521: Line 565:
  | isbn = 978-3-642-01898-5
  | isbn = 978-3-642-01898-5
  | doi = 10.1007/978-3-642-01899-2
  | doi = 10.1007/978-3-642-01899-2
}}</ref>
<ref name=wells>{{cite book
| last = Wells | first = Alexander Frank
| year = 1984
| title = Structural Inorganic Chemistry
| url = https://books.google.com/books?id=uR77AAAAQBAJ&pg=PA127
| page = 127
| publisher = [[Oxford University Press]]
| edition = 5th
| isbn = 978-0-19-965763-6
}}</ref>
}}</ref>


Line 534: Line 589:
  | year = 1995
  | year = 1995
}}</ref>
}}</ref>
 
</references>
}}


== External links ==
== External links ==

Latest revision as of 13:18, 18 November 2025

Template:Short description Template:Use dmy dates

Script error: No such module "Infobox".Template:Template other In geometry, a regular octahedron is a highly symmetrical type of octahedron (eight-sided polyhedron) with eight equilateral triangles as its faces, four of which meet at each vertex. It is a type of square bipyramid or triangular antiprism with equal-length edges. Regular octahedra occur in nature as crystal structures. Other types of octahedra also exist, with various amounts of symmetry.

A regular octahedron is the three-dimensional case of the more general concept of a cross-polytope.

Description

The regular octahedron is one of the Platonic solids, a set of convex polyhedra whose faces are congruent regular polygons and the same number of faces meet at each vertex.Template:R This ancient set of polyhedrons was named after Plato who, in his Timaeus dialogue, related these solids to classical elements, with the octahedron representing wind.Template:R Following its attribution with nature by Plato, Johannes Kepler in his Harmonices Mundi sketched each of the Platonic solids.Template:R In his Mysterium Cosmographicum, Kepler also proposed the Solar System by using the Platonic solids setting into another one and separating them with six spheres resembling the six planets. The ordered solids started from the innermost to the outermost: regular octahedron, regular icosahedron, regular dodecahedron, regular tetrahedron, and cube.Template:R

Template:Multiple image A regular octahedron is the cross-polytope in 3-dimensional space. It can be oriented and scaled so that its axes align with Cartesian coordinate axes and its vertices have coordinatesTemplate:R (±1,0,0),(0,±1,0),(0,0,±1). Such an octahedron has edge length Template:Tmath.

The regular octahedron's dual polyhedron is the cube, and they have the same three-dimensional symmetry groups, the octahedral symmetry Oh.Template:R Like its dual, the regular octahedron has three properties: any two faces, two vertices, and two edges are transformed by rotation and reflection under the symmetry orbit, such that the appearance remains unchanged; these are isohedral, isogonal, and isotoxal respectively. Hence, it is considered a regular polyhedron. Four triangles surround each vertex, so the regular octahedron is 3.3.3.3 by vertex configuration or {3,4} by Schläfli symbol.Template:R

Metrical properties

File:Octahedron.stl
3D model of regular octahedron

The surface area A of a regular octahedron can be ascertained by summing all of its eight equilateral triangles, whereas its volume V is twice the volume of a square pyramid; if the edge length is a,Template:R A=23a23.464a2,V=132a30.471a3. The radius of a circumscribed sphere ru (one that touches the octahedron at all vertices), the radius of an inscribed sphere ri (one that tangent to each of the octahedron's faces), and the radius of a midsphere rm (one that touches the middle of each edge), are:Template:R ru=22a0.707a,ri=66a0.408a,rm=12a=0.5a.

The dihedral angle of a regular octahedron between two adjacent triangular faces is 2arctan2, which is about 109.47°. This can be obtained from the dihedral angle of an equilateral square pyramid: its dihedral angle between two adjacent triangular faces is the dihedral angle of an equilateral square pyramid between two adjacent triangular faces, and its dihedral angle between two adjacent triangular faces on the edge in which two equilateral square pyramids are attached is twice the dihedral angle of an equilateral square pyramid between its triangular face and its square base.Template:R

As other special cases

The regular octahedron is one of the eight convex deltahedra, polyhedra whose faces are all equilateral triangles.Template:R

Template:Multiple image Script error: No such module "anchor".A regular octahedron is a type of square bipyramid,Template:R a composite polyhedron constructed by attaching two equilateral square pyramids base-to-base.Template:R The dual polyhedron of a bipyramid in general is the prism, and vice versa; the regular octahedron's dual, the cube, is a type of square prism.Template:R

Script error: No such module "anchor".The regular octahedron is a type of trigonal antiprism,Template:Sfnp formed by taking a trigonal prism with equilateral triangle bases and rectangular lateral faces, and replacing the rectangles by alternating isosceles triangles. In the case of the regular octahedron, all of the resulting faces are congruent equilateral triangles.

The regular octahedron can also be considered a rectified tetrahedron, sometimes called a tetratetrahedron (by analogy to the cuboctahedron and icosidodecahedron); if alternate faces are considered to have different types (e.g. different colors or orientations), the octahedron can be considered a type of quasiregular polyhedron, a polyhedron in which two different types of polygonal faces alternate around each vertex.Template:R It exists in a sequence of symmetries of quasiregular polyhedra and tilings with vertex configurations (3.n)2, progressing from tilings of the sphere to the Euclidean plane and into the hyperbolic plane. With orbifold notation symmetry of *n32 all of these tilings are Wythoff constructions within a fundamental domain of symmetry, with generator points at the right angle corner of the domain.Template:R Template:Quasiregular3 small table

Graph

File:Complex tripartite graph octahedron.svg
The graph of a regular octahedron

The skeleton of a regular octahedron is the (undirected) graph formed by its vertices and edges. Steinitz's theorem guarantees that the this graph can be drawn with no edge crossing another, and all remaining vertices remain connected when any two are removed.Template:R Its graph called the octahedral graph, a Platonic graph.Template:R

The octahedral graph can be considered as complete tripartite graph K2,2,2, a graph partitioned into three independent sets, each consisting of two opposite vertices.Template:R Additionally, it is a Turán graph T6,3.

The octahedral graph is 4-connected, meaning that it takes the removal of four vertices to disconnect the remaining vertices. It is one of only four 4-connected simplicial well-covered polyhedra, meaning that all of the maximal independent sets of its vertices have the same size. The other three polyhedra with this property are the pentagonal dipyramid, the snub disphenoid, and an irregular polyhedron with 12 vertices and 20 triangular faces.Template:R

Other related figures

Template:Multiple image The interior of the compound of two dual tetrahedra is an octahedron, and this compound—called the stella octangula—is its first and only stellation.Template:Sfnp Correspondingly, a regular octahedron is the result of cutting off from a regular tetrahedron, four regular tetrahedra of half the linear size (i.e. rectifying the tetrahedron). The vertices of the octahedron lie at the midpoints of the edges of the tetrahedron, and in this sense, it relates to the tetrahedron in the same way that the cuboctahedron and icosidodecahedron relate to the other Platonic solids.

Several constructions of polyhedra commence from the regular octahedron. The truncated octahedron is an Archimedean solid, constructed by removing all of the regular octahedron's vertices, resulting in six squares and eight hexagons, leaving out six square pyramids.Template:R The triakis octahedron is a Catalan solid, the Kleetope of a regular octahedron, by attaching triangular pyramids onto its faces, topologically similar to the stellated octahedron.Template:R The uniform tetrahemihexahedron is a tetrahedral symmetry faceting of the regular octahedron, sharing edge and vertex arrangement. It has four of the triangular faces and three central squares.Template:R

One can also divide the edges of an octahedron in the ratio of the golden mean to define the vertices of a regular icosahedron. This is done by first placing vectors along the octahedron's edges such that each face is bounded by a cycle, then similarly partitioning each edge into the golden mean along the direction of its vector. Five octahedra define any given icosahedron in this fashion, and together they define a regular compound. A regular icosahedron produced this way is called a "snub octahedron".Template:R

Template:Multiple image Regular octahedra and regular tetrahedra can be alternated to form a vertex, edge, and face-uniform tessellation of space, which is named tetrahedral-octahedral honeycomb.Template:Sfnp R. Buckminster Fuller in the 1950s applied these alternating polyhedra as a space frame, which developed the strongest building structure for resisting cantilever stresses.Template:R Another honeycomb is tesselating the regular octahedra alternately with cuboctahedra, named the rectified cubic honeycomb.Template:Sfnp

A regular octahedron is a 3-ball in the [[Taxicab geometry|Manhattan (Template:Math1) metric]].

Other appearances

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Characteristic orthoscheme

Like all regular convex polytopes, the octahedron can be dissected into an integral number of disjoint orthoschemes, all of the same shape characteristic of the polytope. A polytope's characteristic orthoscheme is a fundamental property because the polytope is generated by reflections in the facets of its orthoscheme. The orthoscheme occurs in two chiral forms which are mirror images of each other. The characteristic orthoscheme of a regular polyhedron is a quadrirectangular irregular tetrahedron.

The faces of the octahedron's characteristic tetrahedron lie in the octahedron's mirror planes of symmetry. The octahedron is unique among the Platonic solids in having an even number of faces meeting at each vertex. Consequently, it is the only member of that group to possess, among its mirror planes, some that do not pass through any of its faces. The octahedron's symmetry group is denoted B3. The octahedron and its dual polytope, the cube, have the same symmetry group but different characteristic tetrahedra.

The characteristic tetrahedron of the regular octahedron can be found by a canonical dissectionTemplate:Sfn of the regular octahedron Template:Coxeter–Dynkin diagram which subdivides it into 48 of these characteristic orthoschemes Template:Coxeter–Dynkin diagram surrounding the octahedron's center. Three left-handed orthoschemes and three right-handed orthoschemes meet in each of the octahedron's eight faces, the six orthoschemes collectively forming a trirectangular tetrahedron: a triangular pyramid with the octahedron face as its equilateral base, and its cube-cornered apex at the center of the octahedron.Template:Sfn

Characteristics of the regular octahedronTemplate:Sfn
edge arc dihedral
𝒍 2 90° π2 109°28Template:Prime π2ψ
𝟀 431.155 54°44Template:Prime8Template:Pprime π2κ 90° π2
𝝉Template:Efn 1 45° π4 60° π3
𝟁 130.577 35°15Template:Prime52Template:Pprime κ 45° π4
0R/l 21.414
1R/l 1
2R/l 230.816
κ 35°15Template:Prime52Template:Pprime arc sec 32

If the octahedron has edge length 𝒍 = 2, its characteristic tetrahedron's six edges have lengths 43, 1, 13 around its exterior right-triangle face (the edges opposite the characteristic angles 𝟀, 𝝉, 𝟁),Template:Efn plus 2, 1, 23 (edges that are the characteristic radii of the octahedron). The 3-edge path along orthogonal edges of the orthoscheme is 1, 13, 23, first from an octahedron vertex to an octahedron edge center, then turning 90° to an octahedron face center, then turning 90° to the octahedron center. The orthoscheme has four dissimilar right triangle faces. The exterior face is a 90-60-30 triangle, which is one-sixth of an octahedron face. The three faces interior to the octahedron are: a 45-90-45 triangle with edges 1, 2, 1, a right triangle with edges 13, 1, 23, and a right triangle with edges 43, 2, 23.

Notes

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See also

References

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External links

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