{{Short description|Archimedean solid with 38 faces}} {{infobox polyhedron | name = Snub cube | image = {{multiple image|border=infobox | image1 = Snub hexahedron, left (green).png | image2 = Snub hexahedron, right (green).png | total_width = 320 }} | caption = Snub cube, left-chiral and right-chiral | type = Archimedean solid | faces = 38 | edges = 60 | vertices = 24 | symmetry = Rotational octahedral symmetry <math> \mathrm{O} </math> | angle = triangle-to-triangle: 153.23° <br> triangle-to-square: 142.98° | dual = Pentagonal icositetrahedron | properties = convex, chiral | vertex_figure = Polyhedron snub 6-8 left vertfig.svg | net = Polyhedron snub 6-8 left net.svg }} In geometry, the '''snub cube''', or '''snub cuboctahedron''', is an Archimedean solid with 38 faces: 6 squares and 32 equilateral triangles. It has 60 edges and 24 vertices. Kepler first named it in Latin as ''cubus simus'' in 1619 in his Harmonices Mundi.{{r|cbg}} H. S. M. Coxeter, noting it could be derived equally from the octahedron as the cube, called it '''snub cuboctahedron''', with a vertical extended Schläfli symbol <math>s \scriptstyle\begin{Bmatrix} 4 \\ 3 \end{Bmatrix}</math>, and representing an alternation of a truncated cuboctahedron, which has Schläfli symbol <math>t \scriptstyle\begin{Bmatrix} 4 \\ 3 \end{Bmatrix}</math>.
The snub cube, like the snub dodecahedron, is chiral, which means it does not equal its mirror image; it has two equally valid forms.
== Construction == The snub cube can be generated by taking the six faces of the cube, pulling them outward so they no longer touch, then giving them each a small rotation on their centers (all clockwise or all counter-clockwise) until the spaces between can be filled with equilateral triangles.{{r|holme}}
thumb|left|150px|Process of snub cube's construction by rhombicuboctahedron The snub cube may also be constructed from a rhombicuboctahedron. It started by twisting its square face (in blue), allowing its triangles (in red) to be automatically twisted in opposite directions, forming other square faces (in white) to be skewed quadrilaterals that can be filled in two equilateral triangles.{{sfnp|Conway|Burgiel|Goodman-Struss|2008|p=287–288}}
The snub cube can also be derived from the truncated cuboctahedron by the process of alternation. 24 vertices of the truncated cuboctahedron form a polyhedron topologically equivalent to the snub cube; the other 24 form its mirror-image. The resulting polyhedron is vertex-transitive but not uniform. {{multiple image | align = center | total_width = 450 | image1 = Polyhedron great rhombi 6-8 subsolid snub left maxmatch.png | image2 = Polyhedron great rhombi 6-8 max.png | image3 = Polyhedron great rhombi 6-8 subsolid snub right maxmatch.png | footer = Uniform alternation of a truncated cuboctahedron }}
=== Cartesian coordinates === Cartesian coordinates for the vertices of a snub cube are all the even permutations of <math display="block"> \left(\pm 1, \pm \frac{1}{t}, \pm t \right), </math> with an even number of plus signs, along with all the odd permutations with an odd number of plus signs, where <math> t \approx 1.83929 </math> is the tribonacci constant.{{r|collins}} Taking the even permutations with an odd number of plus signs, and the odd permutations with an even number of plus signs, gives a different snub cube, the mirror image. Taking them together yields the compound of two snub cubes.
This snub cube has edges of length <math>\alpha = \sqrt{2+4t-2t^2}</math>, a number which satisfies the equation <math display="block">\alpha^6-4\alpha^4+16\alpha^2-32=0, </math> and can be written as <math display="block">\begin{align} \alpha &= \sqrt{\frac{4}{3}-\frac{16}{3\beta}+\frac{2\beta}{3}}\approx1.609\,72 \\ \beta &= \sqrt[3]{26+6\sqrt{33}}. \end{align}</math> To get a snub cube with unit edge length, divide all the coordinates above by the value ''α'' given above.
== Properties == For a snub cube with edge length <math>a</math>, its surface area and volume are:{{r|berman}} <math display="block"> A = \left(6+8\sqrt{3}\right)a^2 \approx 19.856a^2, \qquad V = \frac{8t+6}{3\sqrt{2(t^2-3)}}a^3 \approx 7.889a^3. </math>
{{multiple image | image1 = Snub cube.stl | image2 = Mirrored snub cube.stl | footer = 3D model of a snub cube and its mirror }} The snub cube is an Archimedean solid, meaning it is a highly symmetric and semi-regular polyhedron, and two or more different regular polygonal faces meet in a vertex.{{r|diudea}} It is chiral, meaning there are two distinct forms whenever being mirrored. Therefore, the snub cube has the rotational octahedral symmetry <math> \mathrm{O} </math>.{{r|kocakoca|cromwell}} The polygonal faces that meet for every vertex are four equilateral triangles and one square, and the vertex figure of a snub cube is <math> 3^4 \cdot 4 </math>. The dual polyhedron of a snub cube is pentagonal icositetrahedron, a Catalan solid.{{r|williams}} This is also chiral: In the notation of David McCooey for the two chiral forms of each polyhedron, the dual of a dextro snub cube is a laevo pentagonal icositetrahedron and the dual of a laevo snub cube is a dextro pentagonal icositetrahedron.<ref>{{multiref |{{harvnb|McCooey|2015|at=[https://dmccooey.com/polyhedra/LsnubCube.html Snub cube (laevo)]}} |{{harvnb|McCooey|2015|at=[https://dmccooey.com/polyhedra/RpentagonalIcositetrahedron.html Pentagonal icositetrahedron (dextro)]}} |{{harvnb|McCooey|2015|at=[https://dmccooey.com/polyhedra/RsnubCube.html Snub cube (dextro)]}} |{{harvnb|McCooey|2015|at=[https://dmccooey.com/polyhedra/LpentagonalIcositetrahedron.html Pentagonal icositetrahedron (laevo)]}}}}</ref>
== Graph == thumb|The graph of a snub cube The skeleton of a snub cube can be represented as a graph with 24 vertices and 60 edges, an Archimedean graph.{{r|rw}}
== Appearance == A snub cube is at the fountain of California Institute of Technology.{{r|cockram}}
In the study of supramolecular chemistry, the snub cube is an application of an artificial polyhedron to mimic the structure of viral capsids and a protein of ferritin.{{r|wu2025}}
==References== <references> <ref name=berman>{{cite journal | last = Berman | first = Martin | year = 1971 | title = Regular-faced convex polyhedra | journal = Journal of the Franklin Institute | volume = 291 | issue = 5 | pages = 329–352 | doi = 10.1016/0016-0032(71)90071-8 | mr = 290245 }}</ref>
<ref name=cbg>{{cite book | last1 = Conway | first1 = John H. | last2 = Burgiel | first2 = Heidi | last3 = Goodman-Struss | first3 = Chaim | year = 2008 | title = The Symmetries of Things | page = 287 | url = https://books.google.com/books?id=Drj1CwAAQBAJ&pg=PA287 | publisher = CRC Press | isbn = 978-1-4398-6489-0 }}</ref>
<ref name=cockram>{{cite book | last = Cockram | first = Bernice | year = 2020 | title = In Focus Sacred Geometry: Your Personal Guide | publisher = Wellfleet Press | isbn = 978-1-57715-225-5 | url = https://books.google.com/books?id=jrITEAAAQBAJ&pg=PA52 | page = 52 }}</ref>
<ref name=collins>{{cite book | last = Collins | first = Julian | year = 2019 | title = Numbers in Minutes | url = https://books.google.com/books?id=azKKDwAAQBAJ&pg=PA96 | page = 36–37 | publisher = Hachette | isbn = 978-1-78747-730-8 }}</ref>
<ref name=cromwell>{{cite book | last = Cromwell | first = Peter R. | title = Polyhedra | year = 1997 | url = https://archive.org/details/polyhedra0000crom/page/386/mode/1up | publisher = Cambridge University Press | isbn = 978-0-521-55432-9 | page = 386 }}</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 | 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=holme>{{cite book | last = Holme | first = A. | year = 2010 | title = Geometry: Our Cultural Heritage | publisher = Springer | url = https://books.google.com/books?id=zXwQGo8jyHUC&pg=PA99 | page = 99 | isbn = 978-3-642-14441-7 | doi = 10.1007/978-3-642-14441-7 }}</ref>
<ref name=kocakoca>{{cite book | last1 = Koca | first1 = M. | last2 = Koca | first2 = N. O. | year = 2013 | title = Mathematical Physics: Proceedings of the 13th Regional Conference, Antalya, Turkey, 27–31 October 2010 | contribution = Coxeter groups, quaternions, symmetries of polyhedra and 4D polytopes | contribution-url = https://books.google.com/books?id=ILnBkuSxXGEC&pg=PA49 | page = 49 | publisher = World Scientific }}</ref>
<ref name=rw>{{cite book | last1 = Read | first1 = R. C. | last2 = Wilson | first2 = R. J. |author-link2=Robin Wilson (mathematician) | title = An Atlas of Graphs | publisher = Oxford University Press | year = 1998 | page = 269 }}</ref>
<ref name=williams>{{cite book | last = Williams | first = Robert | authorlink = Robert Williams (geometer) | year = 1979 | title = The Geometrical Foundation of Natural Structure: A Source Book of Design | page = 85 | publisher = Dover Publications, Inc. | isbn = 978-0-486-23729-9 | url = https://archive.org/details/geometricalfound00will }}</ref>
<ref name=wu2025>{{cite journal | title = Dynamic supramolecular snub cubes | first1 = Huang | last1 = Wu | first2 = Yu | last2 = Wang | first3 = Luka | last3 = Đorđević | first4 = Pramita | last4 = Kundu | first5 = Surojit | last5 = Bhunia | first6 = Aspen X.-Y. | last6 = Chen | first7 = Liang | last7 = Feng | first8 = Dengke | last8 = Shen | first9 = Wenqi | last9 = Liu | first10 = Long | last10 = Zhang | first11 = Bo | last11 = Song | first12 = Guangcheng | last12 = Wu | first13 = Bai-Tong | last13 = Liu | first14 = Moon Young | last14 = Yang | first15 = Yong | last15 = Yang | first16 = Charlotte L. | last16 = Stern | first17 = Samuel I. | last17 = Stupp | first18 = William A. | last18 = Goddard III | first19 = Wenping | last19 = Hu | first20 = J. Fraser | last20 = Stoddart | journal = Nature | volume = 637 | pages = 347–353 | year = 2025 | doi = 10.1038/s41586-024-08266-3) }}</ref>
</references> *{{cite journal |last=Jayatilake |first=Udaya |title=Calculations on face and vertex regular polyhedra |journal=Mathematical Gazette |date=March 2005 |volume=89 |issue=514 |pages=76–81|doi=10.1017/S0025557200176818 |s2cid=125675814 }} *{{cite web |last=McCooey |first=David I. |date=2015 |title=Visual Polyhedra |url=https://dmccooey.com/polyhedra/index.html |access-date=8 December 2025}}
==External links== *{{mathworld2 |urlname=SnubCube |title=Snub cube |urlname2=ArchimedeanSolid |title2=Archimedean solid}} **{{mathworld |urlname=SnubCubicalGraph |title=Snub cubical graph}} *{{KlitzingPolytopes|polyhedra.htm|3D convex uniform polyhedra|s3s4s - snic}} *[http://www.mathconsult.ch/showroom/unipoly/ The Uniform Polyhedra] *[http://www.georgehart.com/virtual-polyhedra/vp.html Virtual Reality Polyhedra] The Encyclopedia of Polyhedra *[http://www.dr-mikes-math-games-for-kids.com/polyhedral-nets.html?net=KPFQTjUF59q9qFlmEqGmbfyT4Ykrpg7vn7pPKHBbttGwDk2Z6dABBNQuTy7b46U3TTtKxWPq6lgrdE2qYMNpS5ceb5Ie9K4gQt25UcMlwmW6OKK3HtK2QvnmOLGTZFLfHD7hM4GN1modJYJ5PjowXOUDwYnjnCRQFA0vsrVIwFkFiIy7Pi9foWycmqdJAnWMMpuCxwRrcdA49hnAjViEzr&name=Snub+Cube#applet Editable printable net of a Snub Cube with interactive 3D view]
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