1. Motivation and statement of results

A classical theorem states that $\mathbb{R}^3$ can be decomposed as a union of disjoint unit circles. This statement may be folklore, but it seems to have been popularized by Conway and Croft, who gave a non-constructive proof using transfinite induction [Reference Conway and Croft10]. Since then, a number of fascinating questions, regarding the possibility of decomposing a fixed space as the union of disjoint copies of another space, have been studied from set theoretic, topological and geometric perspectives. A collection of decomposition questions appear in an expository article by Gardner [Reference Gardner11], whereas a collection of geometric constructions using transfinite induction can be found in [Reference Komjáth and Pach19]. Similar questions appear every so often on MathOverflow; see [20, 22–24]. It seems to be unknown whether there exists a Borel decomposition of $\mathbb{R}^3$ into unit circles; see [21].

With different topological or geometric constraints, versions of this question have appeared in a wide range of articles [Reference Bankston and McGovern2–Reference Cobb9, Reference Jonsson and Wästlund18, Reference Moussong and Simányi26, Reference Wilker31], and several explicit constructions have appeared. For example, Szulkin constructed an explicit covering of $\mathbb{R}^3$ using geometric (round) circles of varying radii, which fails to be a foliation only on the union of a countable discrete set of concentric circles [Reference Szulkin29], whereas foliations of $\mathbb{R}^3$ by topological circles were thoroughly studied by Vogt [Reference Vogt30]. Bankston and Fox [Reference Bankston and Fox1], generalizing a construction of Kakutani, gave a decomposition of $\mathbb{R}^{n+2}$ by tamely embedded, unknotted, pairwise unlinked (topological) n-spheres, but it seems unknown whether there exists any decomposition of $\mathbb{R}^{n+2}$ by unit n-spheres for n > 1.

Here, we address the existence question for continuous unit sphere decompositions of open subsets E in Euclidean space $\mathbb{R}^d$. A decomposition of E by unit n-spheres is called continuous if the map taking $p \in E$ to its containing sphere is continuous; that is, if the sphere centres and their normal spaces vary continuously with p. In this case, we say that E is fibered by unit n-spheres. Global fibrations of $\mathbb{R}^d$ by unit spheres cannot exist for topological reasons, as can be seen from the long exact sequence associated to the fibration. However, the existence question for local fibrations, has, to the authors’ surprise, turned out to be non-trivial.

A simple example of a unit circle fibration can be described as follows. Consider an open torus $\textstyle T\subset\mathbb{R}^3$ with major and minor radii both equal to 1 (the boundary of T has a singularity in the centre). The interior of this torus may be foliated by a collection of tori T_r, each with major radius 1, but with minor radii r ranging from 0 to 1. Now each individual torus admits two foliations (a left-handed one and a right-handed one) by Villarceau circles. The radius of a Villarceau circle is equal to the major radius of the torus, and hence all such circles have radius 1. Choosing the right-handed foliation on each torus yields a collection of pairwise linked unit circles which fill the interior of T. See Figure 1.

Figure 1. Fibration of a toroidal region in $\mathbb{R}^3$ by linked unit circles.

In $\S$3, we construct explicit unit n-sphere fibrations in $\mathbb{R}^{2n+1}$, for $n \in \left\{1, 3, 7 \right\}$. When n = 1 this construction produces the fibered torus described above. The dimensions of our construction are sharp, as shown by our main result:

If there exists a unit n-sphere fibration of an open region $E \subset \mathbb{R}^d$, then there exists a unit n-sphere fibration of $E \times \mathbb{R} \subset \mathbb{R}^{d+1}$, by ‘stacking’ unit n-sphere fibrations of E. Thus, it would be interesting to determine:

Question 1. Given $n \in \mathbb{N}$, do there exist d and an open subset $E \subset \mathbb{R}^d$ such that E is fibered by unit n-spheres? If so, what is the minimum such dimension d?

The answer to this question is known for two other types of geometric fibrations, and it would not be surprising if the answer to Question 1 matches one of these described below:

A great sphere fibration is a sphere bundle with total space S^d and fibres which are great n-spheres. The standard example is the Hopf fibration of S ³ by unit circles, which arises by choosing an orthogonal complex structure on $\mathbb{R}^4$ and intersecting S ³ with all of the complex lines. Similar constructions with quaternions or octonions yield Hopf fibrations with fibres S ³ or S ⁷. Algebraic topology imposes strong restrictions on the possible dimensions of great sphere fibrations; in particular the fibres must have dimension 0, 1, 3 or 7. With this in mind, it would not be surprising if only these n could serve as the fibre dimension of a unit sphere fibration. See [Reference Gluck and Warner12–Reference Gluck, Warner and Ziller14, Reference McKay25] for more information about great sphere fibrations.

A skew fibration is a vector bundle with total space $\mathbb{R}^d$ and fibres which are pairwise skew affine n-planes. In [Reference Ovsienko and Tabachnikov27], Ovsienko and Tabachnikov showed that a skew fibration of $\mathbb{R}^d$ by n-planes exists if and only if $n \leq \rho(d-n) - 1$, where ρ is the Hurwitz–Radon function, defined as follows: Decompose $q \in \mathbb{N}$ as the product of an odd number and $2^{4a+b}$, where $0 \leq b \leq 3$, then $\rho(q) = 2^b + 8a$. It follows from unboundedness of ρ that for every n there exists d such that $\mathbb{R}^d$ may be fibered by skew affine n-planes. With this in mind, it would not be surprising if every n could serve as the fibre dimension of a unit sphere fibration. See [Reference Harrison15–Reference Harrison17, Reference Ovsienko and Tabachnikov28] for more information about skew fibrations.

Although we have found some relationships among unit sphere fibrations, great sphere fibrations and skew fibrations, we have found that the techniques used to study unit sphere fibrations are somewhat different from those used to study the other types of fibrations. For example, the collection of n-spheres in a great sphere fibration of S^d corresponds to a submanifold of $\operatorname{Gr}_{n+1}(d+1)$, and an important component of studying great sphere fibrations is understanding the topology of the Grassmann manifold. Similarly, the study of skew fibrations requires understanding the topology of the affine Grassmann and spaces of non-singular bilinear maps. By contrast, geometry plays a large role in the study of unit sphere fibrations, and it seems unlikely that their study can be completely reduced to questions of topology or linear algebra.

2. Proof of the main result

The proof of the main result uses the notion of linkedness for unit n-spheres. Recall that two disjoint topological n-spheres S ₁ and S ₂ in $\mathbb{R}^d$ are linked if S ₁ is non-trivial as an element of $\pi_n(\mathbb{R}^d - S_2)$. Linking of topological n-spheres can potentially occur in dimensions $n+2 \leq d \leq 2n+1$, but linking for unit n-spheres is much more restrictive.

Now we are prepared to prove the main result. The proof splits naturally into two separate arguments, which we record as the following two lemmas.

The final statement of Lemma 2, in the case n = 1, formalizes the intuitive idea that a 1-parameter family of unit circles cannot ‘pass through’ another unit circle in $\mathbb{R}^3$.

We prove the first lemma with a Borsuk–Ulam construction. For the second lemma we develop and apply a correspondence between unit sphere fibrations and skew fibrations.

Proof of Lemma 2

Let p be a point in the interior of E. We use the following notation: C is the unit n-sphere fibre through p, B is the open $(n+1)$-ball whose boundary is C, P is the $(n+1)$-plane containing C, and $D \subset E$ is a small $(d-n)$-dimensional disk centred at p, orthogonal to the tangent space to C at p, and small enough such that every fibre intersecting D does so transversely and exactly once; see Figure 2.

Figure 2. Fibration by unit circles: local depiction.

By compactness of C and openness of E, there exists ɛ > 0 such that the n-sphere $S \subset P$ concentric with C and of radius $1 + \varepsilon$ lies inside E. Suppose momentarily that for each $x \in S$, the fibre passing through x intersects the boundary $\partial D$ of the small transverse disk at p. This allows us to define $f \colon S \to \partial D \simeq S^{d-n-1}$ as the map which sends $x \in S$ to the intersection of the fibre through x with $\partial D$.

If $d \leq 2n$, i.e. if $d-n -1 \lt n$, then by the Borsuk–Ulam theorem, there exists x such that $f(x) = f(-x)$, and so the fibres through x and −x intersect. Since x and −x are distance $2 + 2\varepsilon$ apart, their containing fibres are different and hence do not intersect, a contradiction.

Now let $d = 2n+1$. Since linkedness is preserved by homotopy, there is a dichotomy: all fibres passing through $\partial D$ are linked with C, or all fibres are unlinked with C. We assume all fibres are unlinked and derive a contradiction. Since C is unlinked with the fibre through $x \in S$, and since $x \in S$ lies in the exterior of $C \subset P$, then by Lemma 1, the fibre through x does not intersect B. In particular, the image of f misses the point $\partial D \cap B$. Therefore, f may be considered as a map $S^n \to \mathbb{R}^n$, and the Borsuk–Ulam theorem applies in the same way.

Now we address the assumption that for each $x \in S$, the fibre passing through x intersects the boundary $\partial D$ of the small transverse disk at p. This need not occur, and so we modify the definition of S as follows. Since D is chosen to correspond to a local trivialization, the fibres passing through D generate a foliated neighbourhood $U \subset E$ of the fibre C, and the fibres passing through $\partial D$ form a fibered topological torus $T = S^{d-n-1} \times S^n$ which serves as the boundary of U. For $q \in C$, following fibres from $\partial D$ yields a homeomorphism between $\partial D$ and the boundary of a topological $(d-n)$-dimensional disk D_q which is transverse to C at q (explicitly, D_q is the intersection of U with the $(d-n)$-plane orthogonal to the tangent space T_qC). Now let x be the point on the line segment $D_q \cap P$ which is farthest from the centre c of C. By compactness of $\partial D_q$, this line segment intersects $\partial D_q$ in finitely many points, and the line segment intersects $\partial D_q$ at least once on each side of q, since C lies in the interior connected component of $\mathbb{R}^d - T$. Therefore x is well-defined, and moreover it varies continuously with q. Said differently, if δ_q represents the maximum distance from $D_q \cap P$ to c, then $x = c + \delta_q q$. The map $q \mapsto c + \delta_q q = x$ is a homeomorphism from C onto its image Sʹ, and the proof goes through with this topological n-sphere Sʹ in place of the geometric sphere S.

3. Example

In this section, we construct an example of a unit n-sphere fibration of $\mathbb{R}^{2n+1}$ for $n \in \left\{1, 3, 7 \right\}$. The construction was inspired by the relationship between unit sphere fibrations and skew fibrations exhibited in the proof of Lemma 3.

Example 1. We construct an example of a unit sphere fibration for n = 3. The same construction works for n = 1 and n = 7 with complex numbers or octonions in place of quaternions. Write $\mathbb{R}^7 = \mathbb{R}^4 \times \mathbb{R}^3$ and for each $(y,0) \in \mathbb{R}^4 \times \mathbb{R}^3$, let P_y be the 3-plane spanned by $(iy,1,0,0)$, $(jy,0,1,0)$, $(ky, 0, 0, 1)$, where $\left\{i, j, k \right\}$ represents a basis of the imaginary unit quaternions. Let Q_y be the 4-plane which passes through y and is orthogonal to P_y, and let S_y be the unit 3-sphere in Q_y centred at y. Now the centre map $y \mapsto (y,0) \in \mathbb{R}^7$ and the normal map $y \mapsto Q_y$ are continuous, and therefore the assignment $y \mapsto S_y$ defines a continuous unit sphere fibration provided that no two spheres intersect.

We will show that for distinct $y,z$ with $|y|,|z| \lt 1$, S_y and S_z do not intersect.

First note that for distinct y and z, the linear span of P_y and P_z is 6-dimensional. Therefore, the affine 4-planes Q_y and Q_z intersect in precisely a line $\ell$, and it is enough to check that $S_y \cap \ell$ and $S_z \cap \ell$ do not intersect. Note that $\ell$ contains the origin, and it is easy to check, by taking inner products with the basis vectors of P_y and P_z, that $\ell$ has direction:

\begin{equation*} v = (y-z,- \langle iy, z \rangle, - \langle jy,z \rangle, - \langle ky, z \rangle). \end{equation*}

For future convenience, we compute,

(3.1)\begin{align} |v|^2 = |y-z|^2 + \langle iy, z \rangle^2 + \langle jy,z \rangle^2 + \langle ky, z \rangle^2 = |y-z|^2 + |z|^2|y|^2 - \langle y,z \rangle^2, \end{align}

where we have used the Parseval identity together with the fact that $\left\{y, iy, jy, ky \right\}$ forms an orthogonal basis of $\mathbb{R}^4$. The nearest point on $\ell$ to the point y is:

\begin{equation*} c_y = \frac{\langle y, v \rangle }{|v|^2} v = \frac{\langle y, y-z \rangle}{|v|^2} v, \end{equation*}

and the squared distance from y to c_y is:

\begin{equation*} d_y^2 = \langle y - c_y, y - c_y \rangle = |y|^2 - 2\langle y, c_y \rangle + |c_y|^2 = |y|^2 - \frac{\langle y, y-z \rangle^2}{|v|^2}. \end{equation*}

Now, the intersection points of S_y with $\ell$ are the points $c_y \pm r_y \frac{v}{|v|}$, where $r_y = \sqrt{1 - d_y^2}$. Let d represent the distance from c_y to c_z. Then

\begin{equation*} d = |c_y - c_z| = \frac{|y-z|^2}{|v|}. \end{equation*}

To check that S_y and S_z do not intersect, we must show that $c_y \pm r_y\frac{v}{|v|} \neq c_z \pm r_z\frac{v}{|v|}$. For this, it suffices to show that $d \lt r_y + r_z \lt \min\left\{2r_y + d, 2r_z + d \right\}$; see Figure 3.

Figure 3. Two non-intersecting spheres centred at y and z; the red points represent $c_y \pm r_y\frac{v}{|v|}$, and the blue points represent $c_z \pm r_z\frac{v}{|v|}$.

Proof. The inequality in part (a) can be written explicitly:

\begin{equation*} \frac{|y-z|^2}{|v|} \lt \sqrt{1 - |y|^2 + \frac{\langle y, y-z \rangle^2}{|v|^2}} + \sqrt{1 - |z|^2 + \frac{\langle z, y-z \rangle^2}{|v|^2}}, \end{equation*}

or

(3.2)\begin{align} |y-z|^2 \lt \sqrt{|v|^2 - |v|^2|y^2| + \langle y, y - z \rangle^2} + \sqrt{|v|^2 - |v|^2|z^2| + \langle z, y - z \rangle^2}. \end{align}

Since $|y| \lt 1$, we have

\begin{equation*} 0 \lt |v|^2-|v|^2|y|^2, \end{equation*}

therefore,

\begin{equation*} \langle y, y-z \rangle^2 \lt |v|^2 - |v|^2|y^2| + \langle y, y - z \rangle^2, \end{equation*}

and so,

(3.3)\begin{align} \langle y, y-z \rangle \lt \sqrt{|v|^2 - |v|^2|y^2| + \langle y, y - z \rangle^2}. \end{align}

Similarly,

(3.4)\begin{align} -\langle z, y-z \rangle \lt \sqrt{|v|^2 - |v|^2|z^2| + \langle z, y - z \rangle^2}. \end{align}

Now, summing (3.3) and (3.4) yields (3.2).

The inequality in part (b) can be written explicitly:

\begin{equation*} \sqrt{1 - |z|^2 + \frac{\langle z, y-z \rangle^2}{|v|^2}} \lt \sqrt{1 - |y|^2 + \frac{\langle y, y-z \rangle^2}{|v|^2}} + \frac{|y-z|^2}{|v|}. \end{equation*}

Multiplying by $|v|$ and using (3.1) yields:

\begin{equation*} \sqrt{|y-z|^2 - |z|^2(|y|^2|z|^2 - \langle y, z \rangle^2)} \lt \sqrt{|y-z|^2 - |y|^2(|y|^2|z|^2 - \langle y, z \rangle^2)} + |y-z|^2. \end{equation*}

Squaring both sides and rearranging, we obtain the inequality:

(3.5)\begin{align} (|y|^2-|z|^2)(|y|^2|z|^2 - \langle y, z \rangle^2) \lt 2\sqrt{|y-z|^2 - |y|^2(|y|^2|z|^2 - \langle y, z \rangle^2)}|y-z|^2 + |y-z|^4. \end{align}

For convenience let $a = |y|$, $b=|z|$ and $c = \cos \theta$, where θ is the angle between y and z. We write

\begin{align*} 0 & \geq -(a-bc)^2-(ac-b)^2 \\ & = -a^2-b^2-a^2c^2-b^2c^2+4abc \\ & = (a^2+b^2)(1-c^2) -2(a^2-2abc+b^2)\\ & \geq (a^3b^2+a^2b^3)(1-c^2)-2(a^2-2abc+b^2), \hspace{.2in} \mbox{since } a,b \lt 1. \end{align*}

Now, we may assume a > b, since otherwise (3.5) is immediate. Then, multiplying the previous inequality by a − b yields:

\begin{align*} 0 & \geq (a-b)(a^3b^2+a^2b^3)(1-c^2)-2(a-b)(a^2-2abc+b^2) \\ & = (a^4b^2-a^2b^4)(1-c^2) - 2(a-b)(a^2-2abc+b^2). \end{align*}

Therefore,

\begin{align*} (a^4b^2-a^2b^4)(1-c^2)& \leq 2(a-b)(a^2-2abc+b^2) \\ & = 2(a-b)|y-z|^2 \\ & = 2\sqrt{a^2-2ab+b^2}|y-z|^2 \\ & \leq 2\sqrt{a^2-ab(1+2c-c^2)+b^2}|y-z|^2, \hspace{.5in} \mbox{since } -1 \leq c \leq 1,\\ & = 2\sqrt{a^2 - 2abc + b^2 -ab(1-c^2)}|y-z|^2\\ & \leq 2\sqrt{a^2 - 2abc + b^2 -a^4b^2(1-c^2)}|y-z|^2\\ & = 2\sqrt{|y-z|^2 -a^4b^2(1-c^2)}|y-z|^2\\ & \lt 2\sqrt{|y-z|^2 -a^4b^2(1-c^2)}|y-z|^2 + |y-z|^4, \end{align*}

and this is (3.5).

Part (c) is similar.

4. History

Questions regarding the possibility of fibering an open set in $\mathbb{R}^3$ by unit circles were raised by the first named author (DA) as a graduate student at UC Berkeley circa 1970. No one questioned had answers, but in the early 1990s DA discovered the fibering of the toroidal region depicted in Figure 1 (he called this region a ‘bialy’ in reference to the bagel-like cuisine). He gave a series of talks on his findings, which were published in a 1993 technical report ‘Hoops in $\mathbb{R}^3$’, though he later retracted this report after discovering an error.

In 2019, the other three authors (OA) were introduced to this type of problem at Carnegie Mellon, when colleague Anton Bernshteyn posed to them the existence question for Borel coverings of $\mathbb{R}^3$ by unit circles. OA became interested in the continuous case, and a literature search resulted in only a single finding: a 1995 blog post by Evelyn Sander, which she wrote to summarize a 1994 talk by DA at UIUC. Her post mentioned the announced results of DA, but OA were unable to extract any formal proofs, though through this post they did learn the importance of linkedness and the potential relationship to division algebras. They were unable to access the technical report nor find any contact information for DA.

OA later discovered that a mutual colleague had contact information for DA. OA shared a draft of this article and learned that DA also knew (though had not published) proofs of some of these results. This led to the present collaboration, which we hope provides some closure to a 50 year old question – though of course many interesting questions remain!