Spheres

Topological
* Annulus conjecture: If S and S' are two disjoint locally flat (n−1)-spheres in Sⁿ, the closure of the region between them is homeomorphic to Sⁿ⁻¹ × [0,1].
* Smith conjecture (theorem): The background is that the set of fixed points of a periodic homeomorphism S³ → S³ is ≅ S¹; Then this circle cannot be knotted; It has been shown to be true if the homeomorphism is smooth enough.
* Hopf's pinching problem: The question whether a compact, simply connected manifold with suitably pinched curvature is topologically a sphere.
* Spherical space: A manifold of the type Sⁿ/H, with H a finite group acting freely on Sⁿ.
@ References: Peterson AJP(79)dec [visualizing]; Morgan & Bass ed-84 [Smith conjecture]; Szczęsny et al IJGMP(09)-a0810 [classification of mappings in same dimension]; Barmak & Minian math/06 [finite spaces with the same homotopy groups as the spheres]; Brendle & Schoen BAMS(11) [Hopf's pinching problem and the Differentiable Sphere Theorem]; Enríquez-Rojo et al a2105 [algebra of vector fields, deformations and extensions of Diff(S²)].
> Special cases: see 2-manifolds; 3-manifolds; Hopf Fibration; types of manifolds [parallelizable].
> Related topics and results: see Brouwer Theorem; euler number; Smale Conjecture.

Metric > s.a. Hopf Sphere Theorem; integration; laplacian; spherical harmonics; spherical symmetry; trigonometry [spherical].
* Circle, S¹: A possible parametrization is x = ±(t²−1)/(t²+1), y = 2t/(t²+1); covers half the circle for t ∈ [−∞,∞].
* Sets of circles: Some interesting arrangements of circles in the Euclidean plane are the Apollonian circles (> see Wikipedia page); > s.a. fractals.
* Sphere, S²: The scalar curvature of a unit 2-sphere is R = 2; If a is the radius of the sphere (as embedded in flat space), the circumference of a circle of radius r on the sphere, and the surface area of the spherical cap enclosed by it are, respectively,

C(r) = 2π a sin(r/a) ,   A(r) = 2π r² [1−cos(r/a)] .

(For an approximation, cut 1 triangle out of hexagons and paste together to get an icosahedron; Add 1 triangle to get a pseudosphere).
* Complex dyad on S²: There can be no non-vanishing vector field on S², let alone an orthonormal dyad in the ordinary sense, but a complex dyad (m^a, m*^a) satisfying m^a · m_a = 0, m*^a · m*_a = 0, m^a · m*_a = 1, can be defined by (θ^a and φ^a are unit vectors)

m^a = 2^−1/2 exp{iφ cosθ}(θ^a + i φ^a) ,   m*^a = 2^−1/2 exp{−iψ cosθ}(θ^a − i φ^a) .

* S³: The Ricci tensor of a unit 3-sphere is R_ψψ = 2, R_θθ = 2 sin²ψ, R_φφ = 2 sin²ψ sin²θ, and the scalar curvature R = 6; In a 3-sphere of radius of curvature a, the volume of a ball of radius r is

V(B³) = 4π a³ {\(1\over2\)arcsin(r/a) − (r/2a) [1 − (r/a)²]^1/2} ≈ (4π r³/3) [1 + O(r/a)²] .

* Sⁿ: Area and scalar curvature of (n−1)-surface, and volume of interior n-ball:

S(Sⁿ) = 2π^(n+1)/2 / Γ[(n+1)/2] ;   R(Sⁿ) = n(n−1) ;
V(Bⁿ) = S(Sⁿ⁻¹)/n = 2π^n/2/[nΓ(n/2)] = (2π)^n/2/n!!  for n even ,  2(2π)^(n−1)/2/n!!  for n odd.

@ General references: Dowker CQG(90) [volume-preserving diffeomorphisms on S³]; Abdel-Khalek mp/00 [S⁷]; Boya et al RPMP(03)mp/02 [volumes].
@ Related topics: Chen & Lin JDG(01) [scalar curvature]; Schueth JDG(01) [S⁵, isospectral]; Joachim & Wraith BAMS(08) [curvature of exotic spheres]; Brauchart & Grabner JCompl(15)-a1407 [spherical designs and minimal-energy point configurations].
> Online resources: J C Polking's spherical site [geometry]; John Baez's pages on rolling balls and circles (2012).

Shere Packings
* Kepler's conjecture: In \(\mathbb R\)³, the usual packing (which fills about 74% of the total available space) is the tightest one; The proof given in 1998 by Thomas Hales (after a proof "outline" published in 1993 by W-Y Hsiang) relied on computer use; In 2004 Annals of Mathematics, after an exhausting reviewing process (editor MacPherson likened it to proofreading a phone book), decided to publish the analytical parts only, while the rest will be published in DCG.
* Random or amorphous packing: Packing fractions are only about 64% of the total available space (this is for spheres, while spheroids – like M&Ms – can randomly pack more densely to fill between 68 to 71% of the total available space, and cigar-shaped ellipsoids could be randomly packed with a density of almost 74%).
* Apollonian or osculatory arrangement: An arrangement of d-dimensional spheres, each one of which touches d + 1 others.
@ General references: Moraal JPA(94); Weaire 99 [I]; Hales AM(05) [proof of Kepler's conjecture + resources]; Aste & Weaire 08 [I].
@ Random packings: Shlosman & Tsfasman mp/00; Radin JSP(08) [phase transition]; Kallus PRE(13)-a1305 [Monte Carlo approach to the d-dimensional lattice sphere packing problem].

Other Structures and Related Spaces > s.a. complex structures; differentiable manifolds [exotic Sⁿ]; lie groups; quaternions; Trinion.
@ Monge metric: Życzkowski & Słomczyński JPA(01)qp/00 [and quantum states]; > s.a. types of distances.

main page – abbreviations – journals – comments – other sites – acknowledgements
send feedback and suggestions to bombelli at olemiss.edu – modified 31 may 2031