The two snubbed Archimedean solids

Snub cube or
Snub cuboctahedron

Snub dodecahedron or
Snub icosidodecahedron

In geometry, a snub is an operation applied to a polyhedron. The term originates from Kepler's names of two Archimedean solids, for the snub cube (cubus simus) and snub dodecahedron (dodecaedron simum).[1]

Two chiral copies of the snub cube, as alternated (red or green) vertices of the truncated cuboctahedron.
A snub cube can be constructed from a rhombicuboctahedron by rotating the 6 blue square faces until the 12 white square faces become pairs of equilateral triangle faces.

In general, snubs have chiral symmetry with two forms: with clockwise or counterclockwise orientation. By Kepler's names, a snub can be seen as an expansion of a regular polyhedron: moving the faces apart, twisting them about their centers, adding new polygons centered on the original vertices, and adding pairs of triangles fitting between the original edges.

The terminology was generalized by Coxeter, with a slightly different definition, for a wider set of uniform polytopes.

Conway snubs

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John Conway explored generalized polyhedron operators, defining what is now called Conway polyhedron notation, which can be applied to polyhedra and tilings. Conway calls Coxeter's operation a semi-snub.[2]

In this notation, snub is defined by the dual and gyro operators, as s = dg, and it is equivalent to an alternation of a truncation of an ambo operator. Conway's notation itself avoids Coxeter's alternation (half) operation since it only applies for polyhedra with only even-sided faces.

Snubbed regular figures
Forms to snub Polyhedra Euclidean tilings Hyperbolic tilings
Names Tetrahedron Cube or
octahedron
Icosahedron or
dodecahedron
Square tiling Hexagonal tiling or
Triangular tiling
Heptagonal tiling or
Order-7 triangular tiling
Images                  
Snubbed form Conway
notation
sT sC = sO sI = sD sQ sH = sΔ 7
Image            

In 4-dimensions, Conway suggests the snub 24-cell should be called a semi-snub 24-cell because, unlike 3-dimensional snub polyhedra are alternated omnitruncated forms, it is not an alternated omnitruncated 24-cell. It is instead actually an alternated truncated 24-cell.[3]

Coxeter's snubs, regular and quasiregular

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Snub cube, derived from cube or cuboctahedron
Seed Rectified
r
Truncated
t
Alternated
h
Name Cube Cuboctahedron
Rectified cube
Truncated cuboctahedron
Cantitruncated cube
Snub cuboctahedron
Snub rectified cube
Conway notation C CO
rC
tCO
trC or trO
htCO = sCO
htrC = srC
Schläfli symbol {4,3}   or r{4,3}   or tr{4,3}  
htr{4,3} = sr{4,3}
Coxeter diagram           or           or           or      
Image        

Coxeter's snub terminology is slightly different, meaning an alternated truncation, deriving the snub cube as a snub cuboctahedron, and the snub dodecahedron as a snub icosidodecahedron. This definition is used in the naming of two Johnson solids: the snub disphenoid and the snub square antiprism, and of higher dimensional polytopes, such as the 4-dimensional snub 24-cell, with extended Schläfli symbol s{3,4,3}, and Coxeter diagram        .

A regular polyhedron (or tiling), with Schläfli symbol  , and Coxeter diagram      , has truncation defined as  , and      , and has snub defined as an alternated truncation  , and      . This alternated construction requires q to be even.

A quasiregular polyhedron, with Schläfli symbol   or r{p,q}, and Coxeter diagram     or      , has quasiregular truncation defined as   or tr{p,q}, and     or      , and has quasiregular snub defined as an alternated truncated rectification   or htr{p,q} = sr{p,q}, and     or      .

For example, Kepler's snub cube is derived from the quasiregular cuboctahedron, with a vertical Schläfli symbol  , and Coxeter diagram    , and so is more explicitly called a snub cuboctahedron, expressed by a vertical Schläfli symbol  , and Coxeter diagram    . The snub cuboctahedron is the alternation of the truncated cuboctahedron,  , and    .

Regular polyhedra with even-order vertices can also be snubbed as alternated truncations, like the snub octahedron, as  ,      , is the alternation of the truncated octahedron,  , and      . The snub octahedron represents the pseudoicosahedron, a regular icosahedron with pyritohedral symmetry.

The snub tetratetrahedron, as  , and    , is the alternation of the truncated tetrahedral symmetry form,  , and    .

Seed Truncated
t
Alternated
h
Name Octahedron Truncated octahedron Snub octahedron
Conway notation O tO htO or sO
Schläfli symbol {3,4} t{3,4} ht{3,4} = s{3,4}
Coxeter diagram                  
Image      

Coxeter's snub operation also allows n-antiprisms to be defined as   or  , based on n-prisms   or  , while   is a regular n-hosohedron, a degenerate polyhedron, but a valid tiling on the sphere with digon or lune-shaped faces.

Snub hosohedra, {2,2p}
Image                
Coxeter
diagrams
     
     
     
     
     
     
     
     
     
     
     
     
     ...
     ...
     
     
Schläfli
symbols
s{2,4} s{2,6} s{2,8} s{2,10} s{2,12} s{2,14} s{2,16}... s{2,∞}
sr{2,2}
 
sr{2,3}
 
sr{2,4}
 
sr{2,5}
 
sr{2,6}
 
sr{2,7}
 
sr{2,8}...
 ...
sr{2,∞}
 
Conway
notation
A2 = T A3 = O A4 A5 A6 A7 A8... A∞

The same process applies for snub tilings:

Triangular tiling
Δ
Truncated triangular tiling
Snub triangular tiling
htΔ = sΔ
{3,6} t{3,6} ht{3,6} = s{3,6}
                 
     

Examples

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Snubs based on {p,4}
Space Spherical Euclidean Hyperbolic
Image                
Coxeter
diagram
                                          ...     
Schläfli
symbol
s{2,4} s{3,4} s{4,4} s{5,4} s{6,4} s{7,4} s{8,4} ...s{∞,4}
Quasiregular snubs based on r{p,3}
Conway
notation
Spherical Euclidean Hyperbolic
Image                
Coxeter
diagram
                                          ...     
Schläfli
symbol
sr{2,3} sr{3,3} sr{4,3} sr{5,3} sr{6,3} sr{7,3} sr{8,3} ...sr{∞,3}
               
Conway
notation
A3 sT sC or sO sD or sI sΗ or sΔ
Quasiregular snubs based on r{p,4}
Space Spherical Euclidean Hyperbolic
Image                
Coxeter
diagram
                                          ...     
Schläfli
symbol
sr{2,4} sr{3,4} sr{4,4} sr{5,4} sr{6,4} sr{7,4} sr{8,4} ...sr{∞,4}
               
Conway
notation
A4 sC or sO sQ

Nonuniform snub polyhedra

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Nonuniform polyhedra with all even-valance vertices can be snubbed, including some infinite sets; for example:

Snub bipyramids sdt{2,p}
 
Snub square bipyramid
 
Snub hexagonal bipyramid
Snub rectified bipyramids srdt{2,p}
 
Snub antiprisms s{2,2p}
Image        ...
Schläfli
symbols
ss{2,4} ss{2,6} ss{2,8} ss{2,10}...
ssr{2,2}
 
ssr{2,3}
 
ssr{2,4}
 
ssr{2,5}...
 

Coxeter's uniform snub star-polyhedra

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Snub star-polyhedra are constructed by their Schwarz triangle (p q r), with rational ordered mirror-angles, and all mirrors active and alternated.

Snubbed uniform star-polyhedra
 
s{3/2,3/2}
         
 
s{(3,3,5/2)}
    
 
sr{5,5/2}
     
 
s{(3,5,5/3)}
    
 
sr{5/2,3}
       
 
sr{5/3,5}
       
 
s{(5/2,5/3,3)}
    
 
sr{5/3,3}
       
 
s{(3/2,3/2,5/2)}
 
s{3/2,5/3}
       

Coxeter's higher-dimensional snubbed polytopes and honeycombs

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In general, a regular polychoron with Schläfli symbol  , and Coxeter diagram        , has a snub with extended Schläfli symbol  , and        .

A rectified polychoron   = r{p,q,r}, and         has snub symbol   = sr{p,q,r}, and        .

Examples

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Orthogonal projection of snub 24-cell

There is only one uniform convex snub in 4-dimensions, the snub 24-cell. The regular 24-cell has Schläfli symbol,  , and Coxeter diagram        , and the snub 24-cell is represented by  , Coxeter diagram        . It also has an index 6 lower symmetry constructions as   or s{31,1,1} and     , and an index 3 subsymmetry as   or sr{3,3,4}, and         or      .

The related snub 24-cell honeycomb can be seen as a   or s{3,4,3,3}, and          , and lower symmetry   or sr{3,3,4,3} and           or        , and lowest symmetry form as   or s{31,1,1,1} and      .

A Euclidean honeycomb is an alternated hexagonal slab honeycomb, s{2,6,3}, and         or sr{2,3,6}, and         or sr{2,3[3]}, and      .

 

Another Euclidean (scaliform) honeycomb is an alternated square slab honeycomb, s{2,4,4}, and         or sr{2,41,1} and      :

 

The only uniform snub hyperbolic uniform honeycomb is the snub hexagonal tiling honeycomb, as s{3,6,3} and        , which can also be constructed as an alternated hexagonal tiling honeycomb, h{6,3,3},        . It is also constructed as s{3[3,3]} and    .

Another hyperbolic (scaliform) honeycomb is a snub order-4 octahedral honeycomb, s{3,4,4}, and        .

See also

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Polyhedron operators
Seed Truncation Rectification Bitruncation Dual Expansion Omnitruncation Alternations
                                                           
                   
t0{p,q}
{p,q}
t01{p,q}
t{p,q}
t1{p,q}
r{p,q}
t12{p,q}
2t{p,q}
t2{p,q}
2r{p,q}
t02{p,q}
rr{p,q}
t012{p,q}
tr{p,q}
ht0{p,q}
h{q,p}
ht12{p,q}
s{q,p}
ht012{p,q}
sr{p,q}

References

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  1. ^ Kepler, Harmonices Mundi, 1619
  2. ^ Conway, (2008) p.287 Coxeter's semi-snub operation
  3. ^ Conway, 2008, p.401 Gosset's Semi-snub Polyoctahedron
  • Coxeter, Harold Scott MacDonald; Longuet-Higgins, M. S.; Miller, J. C. P. (1954). "Uniform polyhedra". Philosophical Transactions of the Royal Society of London. Series A. Mathematical and Physical Sciences. 246 (916). The Royal Society: 401–450. Bibcode:1954RSPTA.246..401C. doi:10.1098/rsta.1954.0003. ISSN 0080-4614. JSTOR 91532. MR 0062446. S2CID 202575183.401-450&rft.date=1954&rft_id=https://api.semanticscholar.org/CorpusID:202575183#id-name=S2CID&rft_id=info:bibcode/1954RSPTA.246..401C&rft_id=info:doi/10.1098/rsta.1954.0003&rft.issn=0080-4614&rft_id=https://www.jstor.org/stable/91532#id-name=JSTOR&rft_id=https://mathscinet.ams.org/mathscinet-getitem?mr=0062446#id-name=MR&rft.aulast=Coxeter&rft.aufirst=Harold Scott MacDonald&rft.au=Longuet-Higgins, M. S.&rft.au=Miller, J. C. P.&rfr_id=info:sid/en.wikipedia.org:Snub (geometry)" class="Z3988">
  • Coxeter, H.S.M. Regular Polytopes, (3rd edition, 1973), Dover edition, ISBN 0-486-61480-8 (pp. 154–156 8.6 Partial truncation, or alternation)
  • Kaleidoscopes: Selected Writings of H.S.M. Coxeter, edited by F. Arthur Sherk, Peter McMullen, Anthony C. Thompson, Asia Ivic Weiss, Wiley-Interscience Publication, 1995, ISBN 978-0-471-01003-6 [1], Googlebooks [2]
    • (Paper 17) Coxeter, The Evolution of Coxeter–Dynkin diagrams, [Nieuw Archief voor Wiskunde 9 (1991) 233–248]
    • (Paper 22) H.S.M. Coxeter, Regular and Semi Regular Polytopes I, [Math. Zeit. 46 (1940) 380–407, MR 2,10]
    • (Paper 23) H.S.M. Coxeter, Regular and Semi-Regular Polytopes II, [Math. Zeit. 188 (1985) 559–591]
    • (Paper 24) H.S.M. Coxeter, Regular and Semi-Regular Polytopes III, [Math. Zeit. 200 (1988) 3–45]
  • Coxeter, The Beauty of Geometry: Twelve Essays, Dover Publications, 1999, ISBN 978-0-486-40919-1 (Chapter 3: Wythoff's Construction for Uniform Polytopes)
  • Norman Johnson Uniform Polytopes, Manuscript (1991)
    • N.W. Johnson: The Theory of Uniform Polytopes and Honeycombs, Ph.D. Dissertation, University of Toronto, 1966
  • John H. Conway, Heidi Burgiel, Chaim Goodman-Strauss, The Symmetries of Things 2008, ISBN 978-1-56881-220-5
  • Weisstein, Eric W. "Snubification". MathWorld.
  • Richard Klitzing, Snubs, alternated facetings, and Stott–Coxeter–Dynkin diagrams, Symmetry: Culture and Science, Vol. 21, No.4, 329–344, (2010) [3]