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Universal spaces for asymptotic dimension via factorization

Published online by Cambridge University Press:  20 October 2023

Jerzy Dydak
Affiliation:
Department of Mathematics, University of Tennessee, Knoxville, TN, USA and Department of Mathematics, Xi’an Technological University, No. 2, Xuefu Zhong Lu, Weiyan District, Xi’an, China e-mail: jdydak@utk.edu
Michael Levin
Affiliation:
Department of Mathematics, Ben Gurion University of the Negev, Beer Sheva 8410501, Israel e-mail: mlevine@math.bgu.ac.il
Jeremy Siegert*
Affiliation:
Department of Mathematics, Ben Gurion University of the Negev, Beer Sheva 8410501, Israel
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Abstract

The main goal of this paper is to construct universal spaces for asymptotic dimension by generalizing to the coarse context an approach to constructing universal spaces for covering dimension using a factorization result due to Mardesic.

MSC classification

Type
Article
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of The Canadian Mathematical Society

1 Introduction

In classical dimension theory, a universal space for the class of separable metric spaces of covering dimension at most n is a separable metric space of covering dimension n into which every separable metric space of dimension at most n embeds. Such spaces provide a common structure with which the embedded metric spaces can be studied. One way such universal spaces can be directly constructed was described by Menger in [Reference Menger10] where one imitates the construction of the Cantor set (a universal space for dimension $0$ ) by taking a cube in ( $2n+1$ )-dimensional Euclidean space and removing successively smaller cubes, much in the same way one removes intervals in the construction of the Cantor set. An accessible explanation of the construction can be found in [Reference Engelking5]. The resulting space is a compact subset of $\mathbb {R}^{2n+1}$ that is of covering dimension n and has the desired universal space property.

This construction of a universal space for covering dimension is very geometric, but can hardly be adjusted to the more general settings of Cohomological Dimension, Extension Theory, and Coarse Geometry. In this regard, a more efficient means of showing the existence of universal spaces for covering dimension is via a factorization result due to Mardesic in [Reference Mardešić9], specifically the following.

Theorem 1.1 (Mardesic factorization theorem)

Let $f:X\rightarrow Y$ be a map from a compact Hausdorff space X to a compact metric space Y. Then there is a compact metric space Z with $dim(Z)\leq dim(X)$ and maps $g:X\rightarrow Z$ , $h:Z\rightarrow Y$ such that f factors through g and h.

How this result is used to construct universal spaces is fairly easy to state. One takes their space X to be the Stone–Cech compactification of the disjoint union of all separable metric spaces of covering dimension at most n. Then Y is taken to be the Hilbert cube into which every separable metric space embeds. Using this embedding property, we get a map from X to Y that is an embedding on each separable metric space as a subset of X. Then the Mardesic factorization theorem yields a compact metric space Z with dimension equal to the dimension of X, n in this case. As the map from X to Y is an embedding on each separable metric space that makes up X, we have that its factor map into Z has the same property, making Z the desired universal space. A striking feature of this approach that it makes use of the Stone–Cech compactification, a space very far from being separable and metric, to get a result that belongs to separable metric topology.

In this paper, we will focus on generalizing this approach to universal spaces to the field of coarse geometry and asymptotic dimension.

The asymptotic dimension of metric spaces was introduced by Gromov in [Reference Gromov6] in order to study geometric properties of infinite discrete groups. As the small-scale structure of such spaces is trivial, the asymptotic dimension is a property of the “large-scale” or “coarse” structure of the space. Basic results surrounding asymptotic dimension are well summarized in [Reference Dranishnikov4, Reference Roe11]. In order to generalize the aforementioned approach to universal spaces to the context of asymptotic dimension, we have to replace the constituent parts used in the application of the Mardesic factorization theorem with analogs more suitable to coarse geometry. In the place of the Stone–Cech compactification of the disjoint union of separable metric spaces, we use a “wedge” construction of all separable metric spaces of a given asymptotic dimension as described at the beginning of Section 3. In place of the Hilbert cube, we use the Urysohn universal metric space. Of course, using these pieces to construct a universal space for asymptotic dimension is predicated on us first proving a large-scale analog of Mardesic’s factorization result. Specifically, we need to prove the following.

Theorem 1.2 Let $f: X \rightarrow Y$ be a coarsely continuous map from a metric space X to a separable metric space Y. Then f factors through coarsely continuous maps $g : X \rightarrow Z$ and $h : Z \rightarrow Y$ with $\mathrm {asdim} Z \leq \mathrm {asdim} X$ and Z is separable metric.

The existence of the desired universal space (Theorem 3.2) follows quickly from the above result which the majority of this paper is devoted to proving. Similarly to the above remark regarding the Stone–Cech compactification, this “coarse Mardesic” factorization theorem is an example of a result that uses nonseparable metric spaces to prove a result for separable metric spaces. Said differently, we apply this result to a nonseparable metric space to get universal spaces for separable metric spaces of a given asymptotic dimension.

Our construction of universal spaces for asymptotic dimension is not the first such construction, but appears to be the first to be done via factorization. In [Reference Dranishnikov and Zarichnyi3], Dranishnikov and Zarichnyi constructed universal spaces for proper metric spaces with bounded geometry (for an explanation of these terms, see [Reference Roe11]). Then, in [Reference Bell and Nagórko2], universal spaces for separable metric spaces were constructed. In [Reference Ma, Siegert and Dydak8] universal spaces for general proper metric spaces of asymptotic dimension zero were constructed. Finally, in [Reference Zarichnyi14], it was shown that universal spaces for general proper metric spaces of asymptotic dimension greater than or equal to one do not exist.

The outline of this paper is as follows. In the next section, we cover some basic preliminary notions in coarse geometry and the theory surrounding asymptotic dimension. The existence of universal spaces for separable metric spaces of a given asymptotic dimension is proved in Section 3 and Theorem 1.2 is proved in Section 4. As the constructions we make in Section 4 seem like they may be applicable to other coarse properties, we provide some open questions in Section 5 about the possible existence of universal spaces for asymptotic property C, finite decomposition complexity, and Yu’s coarse property A.

2 Preliminaries

We say that a map $f : X \rightarrow Y$ between metric spaces is coarsely continuous if f sends uniformly bounded covers in X to uniformly bounded families in Y. Maps $f,g : X \rightarrow Y$ are coarsely close if there is $r>0$ such that $f(x)$ and $g(x)$ are such that the distance between $f(x)$ and $g(x)$ is less than r for all $x \in X$ . A coarsely continuous map $ f : X\rightarrow Y$ is a coarse equivalence if there is a coarsely continuous map $g : Y \rightarrow X$ such that $g\circ f$ and $f\circ g$ are coarsely close to the identity maps of X and Y, respectively. A map $f : X \rightarrow Y$ is a coarse embedding if f is a coarse equivalence between X and $f(X)$ . Note that a coarsely continuous map $f: X\rightarrow Y$ is a coarse embedding if and only if the preimages of uniformly bounded covers of Y are uniformly bounded in X. We recall that the asymptotic dimension of a metric space X is bounded by n, written $\mathrm {asdim} X \leq n$ , if for every $r>0$ there is a uniformly bounded cover of X that splits into $n+1$ families of r-disjoint sets. All the spaces are assumed to be metric.

Let $\mathcal {F}$ be a family of subsets of X. By the star $\mathrm {st} (A, \mathcal {F})$ of a subset A of X, we denote the union of A with all the sets $F \in \mathcal {F}$ meeting A, and $\mathrm {st} \mathcal {F}$ stands for the cover of X consisting of $\mathrm {st} (x, {\mathcal {F}})$ for all $ x \in X$ . We say that $\mathcal {F}$ separates subsets A and B of X if $\mathrm {st}(A, {\mathcal {F}})$ does not meet B.

For a metric space $(X,d)$ and a subset $A\subset X$ , we denote by ${\Bbb B}(A,r)$ the set of points at distance at most r from A. We say that a subset B of X is r-close to A if in $B \subset {\Bbb B}(A,r)$ .

Proposition 2.1 Let X be a metric space with $\mathrm {asdim} X \leq n$ . Then, for every $r>0$ , there is a uniformly bounded cover of X which has a Lebesgue number r and which splits into $n+1$ families of r-disjoint sets. Moreover, if b is a base point in X, then we can assume that ${\Bbb B}(b,r)$ is contained in an element of each family of this splitting.

Proof Let $\mathcal {F}$ be a uniformly bounded cover of X that splits into families ${\mathcal {F}}_j, 1\leq j \leq n+1,$ of $(3r)$ -disjoint sets. Then the families ${\mathcal {F}}^{\prime }_j=\{{\Bbb B}(F,r): F \in {\mathcal {F}}_j \}$ are r-disjoint and form the cover ${\mathcal {F}}'={\mathcal {F}}^{\prime }_1 \cup \dots \cup {\mathcal {F}}^{\prime }_{n+1}$ whose Lebesgue number is r.

Now, suppose b is a base point of X. Define ${\mathcal {F}}^{\prime \prime }_j$ to be the family consisting of elements of ${\mathcal {F}}^{\prime }_j $ not intersecting $B(b,2r)$ and one extra element being the union of $B(b,r)$ with the elements of ${\mathcal {F}}^{\prime }_j$ intersecting $B(b, 2r)$ . Then the cover ${\mathcal {F}}"={\mathcal {F}}^{\prime \prime }_1 \cup \dots \cup {\mathcal {F}}^{\prime \prime }_{n+1}$ satisfies the second conclusion of the proposition.

Definition 2.1 Let X be a metric space of $\mathrm {asdim}\leq n$ . A sequence $\mathcal {F}$ of covers ${\mathcal {F}}_i, i\in {\Bbb N},$ of X is said to witness $\mathrm {asdim} \leq n$ if ${\mathcal {F}}_{i}$ is $R_{i}$ -bounded, $r_i$ is a Lebesgue number of ${\mathcal {F}}_{i}$ , and ${\mathcal {F}}_{i}$ splits into the union of $n+1$ families ${\mathcal {F}}_{ij}, 1\leq j \leq n+1$ , of $ r_i$ -disjoint sets with $ r_{i+1}> (100i +1)R_{i}$ and $R_i> r_i$ . We will say that $\mathcal {F}$ is guided by the pairs $(R_i, r_i)$ . For a pointed space X with a base point b, the sequence $\mathcal {F}$ is said to respect the base point if ${\Bbb B}(b, r_i)$ is contained in an element of ${\mathcal {F}}_{ij}$ for every j.

Remark For the results presented in this section and the following one, it is sufficient to assume $r_{i+1}> 2R_i$ . The inequality $r_{i+1}> (100i+1)R_i$ will be used in the last section for proving the factorization theorem.

Definition 2.2 Let X be a set. A sequence $\mathcal {F}$ of covers ${\mathcal {F}}_i, i \in {\Bbb N},$ of X is said to define $\mathrm {asdim} \leq n$ if $\mathrm {st} {\mathcal {F}}_i$ refines ${\mathcal {F}}_{i+1}$ , ${\mathcal {F}}_{i}$ splits into the union of $n+1$ families ${\mathcal {F}}_{ij}, 1\leq j \leq n+1,$ of disjoint sets, the sets of ${\mathcal {F}}_{i+1, j}$ are separated by ${\mathcal {F}}_i$ and for every $x,y \in X$ there is i such that $y \in \mathrm {st} (x, {\mathcal {F}}_i )$ . We say that $\mathcal {F}$ separates the points of a subset Z of X if ${\mathcal {F}}_1$ separates the points of Z.

Proposition 2.2 (i) A metric space of $\mathrm {asdim} \leq n$ admits a sequence of covers witnessing $\mathrm {asdim} \leq n$ . A pointed metric space of $\mathrm {asdim} \leq n$ admits a sequence of covers witnessing $\mathrm {asdim} \leq n$ and respecting the base point.

(ii) A sequence of covers witnessing $\mathrm {asdim} \leq n$ is also a sequence defining $\mathrm {asdim} \leq n$ .

Proof (i) follows from Proposition 2.1.

(ii) follows from the definitions of families witnessing $\mathrm {asdim}\leq n$ and defining $\mathrm {asdim} \leq n$ .

Proposition 2.3 Let ${\mathcal {F}}$ be a sequence of covers ${\mathcal {F}}_i$ of a set X with the splittings ${\mathcal {F}}_{ij}$ such that $\mathcal {F}$ defines $\mathrm {asdim} \leq n$ . For $x, y \in X$ , set $d_{\mathcal {F}}(x,y) $ to be the maximal i such that ${\mathcal {F}}_i$ separates x and y if such i exists and $d_{\mathcal {F}}(x,y)=0$ otherwise. Then, for a subset $Z\subset X$ separated by ${\mathcal {F}}$ , we have: ${}$

(i) $d_{\mathcal {F}}$ is a metric on Z.

(ii) ${\mathcal {F}}_{i+1}$ restricted to Z is i-bounded and has a Lebesgue number $i-1$ , ${\mathcal {F}}_{i+1, j}$ restricted to Z is $(i-1)$ -disjoint, and, as a result, $\mathrm {asdim} Z \leq n$ (everything here with respect to $d_{\mathcal {F}}$ ).

(iii) If $\mathcal {F}$ is a sequence witnessing $\mathrm {asdim} \leq n$ for a metric space $(X,d)$ , then d and $d_{\mathcal {F}}$ are coarsely equivalent on Z.

Proof (i) The only thing needed to be checked is the triangle inequality. Take $x,y, z \in Z$ . Clearly, we may assume that $i=d_{\mathcal {F}}(x,z)\geq d_{\mathcal {F}}(z, y) \geq 1$ . Then $x, y \in \mathrm {st}(z, {\mathcal {F}}_{i+1})$ and hence x and y are contained in an element of ${\mathcal {F}}_{i+2}$ and therefore $d_{\mathcal {F}}(x,y)\leq i+1$ . Thus, $d_{\mathcal {F}}(x,y)\leq d_{\mathcal {F}}(x,z)+d_{\mathcal {F}}(z,y)$ .

(ii) follows from the definition of $d_{\mathcal {F}}$ and the definition of a family defining ${\mathrm {asdim} \leq n}$ .

(iii) Take a uniformly bounded cover $\mathcal {B}$ of Z with respect to $d_{\mathcal {F}}$ . By (ii), $\mathcal {B}$ refines ${\mathcal {F}}_i$ for some i and therefore $\mathcal {B}$ is uniformly bounded with respect to d. A similar argument also works in the other direction.

3 Universal space

Let $(X^{\alpha }, d^{\alpha })$ be a collection of separable metric spaces with $\mathrm {asdim} \leq n$ representing, up to coarse equivalence, all the separable metric spaces with $\mathrm {asdim} \leq n$ . In each $X^{\alpha }$ , we fix a base point $b^{\alpha }$ and, by (i) of Proposition 2.2, take a sequence ${\mathcal {F}}^{\alpha }$ of covers ${\mathcal {F}}_i^{\alpha } $ of $X^{\alpha }$ with the splittings ${\mathcal {F}}^{\alpha }_{ij}$ that witnesses $\mathrm {asdim} \leq n$ , respects the base point $b^{\alpha }$ and guided by the pairs $(R_i^{\alpha }, r_i^{\alpha })$ . Replacing $X^{\alpha }$ by a coarsely equivalent subset, we may assume that ${\mathcal {F}}^{\alpha }$ separates the points of $X^{\alpha }$ .

Denote by $X=\vee X^{\alpha }$ the wedge sum of the spaces $X^{\alpha }$ with the base point $b \in X$ obtained by identifying the base points of all $X^{\alpha }$ . We consider each $X^{\alpha }$ as a subset of X and denote by ${\mathcal {F}}$ the sequence of covers $\mathcal {F}_i$ of X with the splittings ${\mathcal {F}}_{ij}$ defined as follows: ${\mathcal {F}}_{ij}$ is the union of ${\mathcal {F}}^{\alpha }_{ij}$ for all $\alpha $ where the sets containing the base point b being replaced by their union.

Proposition 3.1 In the above setting, the following holds:

(i) $\mathcal {F}$ is a sequence of covers of X defining $\mathrm {asdim} \leq n$ and separating the points of X, and hence, by (i) and (ii) of Proposition 2.3, we have $\mathrm {asdim} (X, d_{\mathcal {F}})\leq n$ .

(ii) Each $(X^{\alpha }, d^{\alpha })$ is coarsely embedded into $(X, d_{\mathcal {F}})$ .

(iii) If a function $ f : X \rightarrow Y$ to a metric space Y isometrically embeds each $X^{\alpha }$ into Y with respect to $d_{\mathcal {F}}$ , then f is coarsely continuous.

Proof (i) Since ${\mathcal {F}}^{\alpha }$ separates the points of $X^{\alpha }$ , we get that ${ \mathcal {F}}^{\alpha }_1$ consists of singletons. Then ${\mathcal {F}}_1$ consists of singletons as well and therefore ${\mathcal {F}}$ separates the points of X.

Let $x^{\alpha } \in X^{\alpha }$ and $x^\beta \in X^\beta $ , and let i be such that $x^{\alpha } \in {\Bbb B}(b^{\alpha }, r^{\alpha }_i)$ and $x^\beta \in {\Bbb B}(b^\beta , r_i^\beta )$ . Then $x^{\alpha }$ and $x^\beta $ are contained in an element of ${\mathcal {F}}_i$ because ${\mathcal {F}}^{\alpha }$ and ${\mathcal {F}}^\beta $ respect the base points.

Thus, to show that ${\mathcal {F}}$ defines $\mathrm {asdim} \leq n$ , we only need to show that ${\mathcal {F}}_i$ refines ${\mathcal {F}}_{i+1}$ and separates ${\mathcal {F}}_{i+1, j}$ . Take a point $x \in X$ and consider the following cases.

Case 1: $b \notin \mathrm {st}(x, {\mathcal {F}}_i)$ . Then, for $X^{\alpha }$ such that $x \in X^{\alpha }$ , we have that the sets of ${\mathcal {F}}_i$ containing x are exactly the sets of ${\mathcal {F}}^{\alpha }_i$ containing x. By (ii) of Proposition 2.2, ${\mathcal {F}}^{\alpha }_i$ is also defining $\mathrm {asdim} \leq n$ , and hence $\mathrm {st}(x, {\mathcal {F}}^{\alpha }_i)$ is contained in an element of ${\mathcal {F}}^{\alpha }_{i+1}$ and no element of ${\mathcal {F}}^{\alpha }_i$ containing x meets disjoint elements of ${\mathcal {F}}^{\alpha }_{i+1, j}$ for every j. Since ${\mathcal {F}}_i$ restricted to $X^{\alpha }$ coincides with ${\mathcal {F}}^{\alpha }_i$ , we get that $\mathrm {st}(x, {\mathcal {F}}_i)$ is contained in an element of ${\mathcal {F}}_{i+1}$ and no element of ${\mathcal {F}}_i$ containing x meets disjoint elements of ${\mathcal {F}}_{i+1, j}$ for every j.

Case 2: $b \in \mathrm {st}(x, {\mathcal {F}}_i)$ . Recall that ${\mathcal {F}}^{\alpha }$ witnesses $\mathrm {asdim} \leq n$ . Then, since $r^{\alpha }_{i+1}> 2R^{\alpha }_i$ , we have that $\mathrm {st}(x, {\mathcal {F}}_i )$ is contained in the union of the balls ${\Bbb B}(b^{\alpha }, r^{\alpha }_{i+1})$ for all $\alpha $ and this union in its turn is contained in an element of ${\mathcal {F}}_{i+1, j}$ for every j because each ${\mathcal {F}}^{\alpha }$ respects the base point. Thus, we get that $\mathrm {st}(x, {\mathcal {F}}_i)$ is contained in an element of ${\mathcal {F}}_{i+1}$ and no element of ${\mathcal {F}}_i$ containing x meets disjoint elements of ${\mathcal {F}}_{i+1, j}$ for every j.

(ii) follows from (iii) of Proposition 2.3 and the fact that ${\mathcal {F}}_i$ restricted to $X^{\alpha }$ coincides with ${\mathcal {F}}^{\alpha }_i$ .

(iii) Consider $F \in {\mathcal {F}}_i$ . By (ii) of Proposition 2.3, ${\mathcal {F}}_i$ is $(i-1)$ -bounded with respect to $d_{\mathcal {F}}$ . If F does not contain b, then F is contained in some $X^{\alpha }$ and therefore $\mathrm {diam} f(F)=\mathrm {diam} F \leq i-1$ . If F does contain b, then F is contained in the union of the elements of $ {\mathcal {F}}^{\alpha }_i$ containing b for all $\alpha $ and therefore $\mathrm {diam} f(F) \leq 2(i-1)$ . Thus, $f({\mathcal {F}}_i)$ is uniformly bounded. Moreover, by (ii) of Proposition 2.3, any uniformly bounded cover of $(X, d_{\mathcal {F}})$ refines ${\mathcal {F}}_i$ for some i and, hence, f is coarsely continuous.

Theorem 3.2 (Bell–Nagórko [Reference Bell and Nagórko2])

For every n, there is a separable metric space of $asdim = n$ which is universal for separable metric spaces of $asdim\leq n$ (i.e., it contains a coarsely equivalent copy of every separable metric space of $asdim\leq n$ ).

Proof Consider the space X from Proposition 3.1 and assume that X is equipped with the metric $d_{\mathcal {F}}$ . Let ${\Bbb U}$ be the Urysohn space [Reference Urysohn12]. Recall that each separable metric space isometrically embeds into ${\Bbb U}$ and ${\Bbb U}$ is homogeneous by isometries. Then one can define isometric embeddings $f^{\alpha }: X^{\alpha } \rightarrow {\Bbb U}$ (with respect to $d_{\mathcal {F}}$ restricted to $X^{\alpha }$ ) sending all the base points $b^{\alpha }$ to the same point in ${\Bbb U}$ and this way to define a function $f : X \rightarrow {\Bbb U}$ that isometrically embeds each $X^{\alpha } \subset X$ into ${\Bbb U}$ (with respect to $d_{\mathcal {F}}$ ). By (iii) of Proposition 3.1, f is coarsely continuous. Apply Theorem 1.2 to factorize f through coarsely continuous maps $g : X \rightarrow Z$ and $h: Z \rightarrow {\Bbb U}$ with Z being separable metric with $\mathrm {asdim} Z \leq \mathrm {asdim} X$ . Recall that, by (i) of Proposition 3.1, $\mathrm {asdim} X \leq n$ and hence $\mathrm {asdim} Z \leq n$ .

Since f coarsely (even isometrically) embeds $X^{\alpha }$ into ${\Bbb U}$ , we get that g coarsely embeds $X^{\alpha }$ into Z. Indeed, if ${\mathcal {B}}$ is a uniformly bounded cover of Z, then $h(\mathcal {B}) $ is uniformly bounded in ${\Bbb U}$ and, hence, the cover $g^{-1}({\mathcal {B}})$ is a uniformly bounded on $X^{\alpha }$ since $g^{-1}({\mathcal {B}})$ and $f^{-1}(h(\mathcal {B}))$ coincide on $X^{\alpha }$ and $f^{-1}(h({\mathcal {B}}))$ is uniformly bounded on $X^{\alpha }$ with respect to $d_{\mathcal {F}}$ . Finally, note that, by (ii) of Proposition 3.1, the metrics $d^{\alpha }$ and $d_{\mathcal {F}}$ are coarsely equivalent on $X^{\alpha }$ and this shows that Z is a universal space for separable metric spaces of $\mathrm {asdim} \leq n$ .

4 Factorization theorem

We actually prove the following more general result obviously implying Theorem 1.2.

Theorem 4.1 Let $f: X \rightarrow Y$ be a coarsely continuous map of metric spaces, and let $\mathrm {w} X$ denote the topological weight of the space X. Then f factors through coarsely continuous maps $g : X \rightarrow Z$ and $h : Z \rightarrow Y$ with $\mathrm {asdim} Z \leq \mathrm {asdim} X$ and $\mathrm {w} Z \leq \mathrm {w} Y$ .

Let us first make the following observation.

Proposition 4.2 Let $f : X \rightarrow Y$ , $g: X \rightarrow Z$ , and $h: Z \rightarrow Y$ be coarsely continuous maps of metric spaces such that f and $h \circ g$ are coarsely close and $\mathrm {w} Y$ is infinite. Then there is a metric space $Z' $ and coarsely continuous maps $g' : X \rightarrow Z'$ and $h' : Z' \rightarrow Y$ such that $\mathrm {asdim} Z' \leq \mathrm {asdim} Z$ , $\mathrm {w} Z' \leq \max \{ \mathrm {w} Z, \mathrm {w} Y \}$ and $f=h' \circ g'$ .

Proof Set $Z'= \{ (f(x), g(x)) : x \in X \} \subset Y \times Z$ and consider $Z'$ with the metric inherited from $Y \times Z$ and defined as the maximum of the distances between the coordinates. Define $g' : X \rightarrow Z'$ by $g'(x)=(f(x), g(x)), x \in X$ and let $h' : Z' \rightarrow Y$ and $\pi : Z' \rightarrow Z$ be the projections. Clearly, $g', h'$ , and $\pi $ are coarsely continuous, $f=h' \circ g'$ , and $\mathrm {w} Z' \leq \max \{ \mathrm {w} Z, \mathrm {w} Y \}$ .

Let us show that $\pi $ is a coarse embedding. Take a uniformly bounded cover $\mathcal {B}$ of Z. Then, since $h({\mathcal {B}})$ is uniformly bounded and f and $h\circ g$ are coarsely close, we get that $f(g^{-1}({\mathcal {B}}))$ is uniformly bounded as well. Note that $\pi ^{-1}(B)\subset f(g^{-1}(B)) \times B $ for every $B \in \mathcal {B}$ and hence $\pi ^{-1}({\mathcal {B}})$ is uniformly bounded. This implies that $\pi $ is a coarse embedding and hence $\mathrm {asdim} Z' \leq \mathrm {asdim} Z$ .

Proof of Theorem 4.1

The theorem is trivial if $\mathrm {w} Y$ is finite, so we may assume that $\mathrm {w} Y$ is infinite. Let $\mathrm {asdim} X \leq n$ . Fix a base point b in X. Take a sequence ${\mathcal {F}}^X$ of covers ${\mathcal {F}}^X_i$ of X with splittings ${\mathcal {F}}^X_{ij}$ guided by the pairs $(R_i, r_i)$ and witnessing $\mathrm {asdim} \leq n$ . For each i, take a uniformly bounded cover ${\mathcal {F}}^Y_i$ of Y that is refined by $f({\mathcal {F}}^X_i)$ with the cardinality of ${\mathcal {F}}^Y_i$ bounded by $\mathrm {w} Y$ and define ${\mathcal {F}}^0_{ij}$ as a collection of disjoint subsets of X such that each element of ${\mathcal {F}}^0_{ij}$ is a union of elements of ${\mathcal {F}}^X_{ij}$ contained in an element of $f^{-1}({\mathcal {F}}_i^Y)$ , each set of ${\mathcal {F}}^X_{ij}$ is contained in some element of ${\mathcal {F}}^0_{ij}$ and no element of ${\mathcal {F}}^X_{ij}$ is contained in different elements of ${\mathcal {F}}^0_{ij}$ . Note that $f({\mathcal {F}}_{ij}^0)$ refines ${\mathcal {F}}^Y_i$ .

We will construct by induction collections ${\mathcal {F}}^p_{ij}, p \in {\Bbb N},$ of subsets of X satisfying the following conditions (the families ${\mathcal {F}}^p$ and ${\mathcal {F}}^p_i$ below are determined in the standard way by ${\mathcal {F}}^p_{ij}$ , namely, ${\mathcal {F}}^p_i$ is the union of the families ${\mathcal {F}}^p_{ij}$ for $1\leq j \leq n+1$ and ${\mathcal {F}}^p$ is the sequence of the covers ${\mathcal {F}}^p_i$ of X):

( $\dagger 1$ ) The cardinality of ${\mathcal {F}}^p_{ij}$ is bounded by $\mathrm {w} Y$ .

( $\dagger 2$ ) The elements of ${\mathcal {F}}^p_{ij}$ are disjoint, each element of ${\mathcal {F}}^p_{ij}$ is a union of elements of ${\mathcal {F}}^X_{ij}$ , and each element of ${\mathcal {F}}^X_{ij}$ is contained in some element of ${\mathcal {F}}^p_{ij}$ .

( $\dagger 3$ ) ${\mathcal {F}}^{p+1}_{ij}$ and ${\mathcal {F}}^p_{ij}$ restricted to ${\Bbb B}(b, ir_{i+p})$ coincide and ${\mathcal {F}}^{p+1}_{ij}$ refines ${\mathcal {F}}^p_{ij}$ .

( $\dagger 4$ ) $\mathrm {st}{\mathcal {F}}^{p+1}_{i}$ refines ${\mathcal {F}}^p_{i+1}$ .

( $\dagger 5$ ) The elements of ${\mathcal {F}}^p_{i+1,j}$ are separated by ${\mathcal {F}}^{p+1}_{i}$ .

Clearly, the relevant properties hold for ${\mathcal {F}}^0$ . Assume that the construction is completed for ${\mathcal {F}}^p_{i}$ with $p+i=m$ and proceed to $m+1$ in the following order ${\mathcal {F}}^0_{m+1}, {\mathcal {F}}^1_m, {\mathcal {F}}^2_{m-1}, \dots , {\mathcal {F}}^m_1$ . Recall that ${\mathcal {F}}^0_{m+1}$ is already defined and assume that ${\mathcal {F}}^0_{m+1}, \dots ,{\mathcal {F}}_{i+1}^{m-i}$ are already constructed. We will construct ${\mathcal {F}}_{i}^{m-i+1}$ as follows. Denote $p=m-i$ .

Let $1\leq j, t \leq n+1$ , and let a set A be the union of some elements of ${\mathcal {F}}^X_{ij}$ . By splitting A by ${\mathcal {F}}^{p }_{i+1, t }$ , we mean replacing A by the family of disjoint subsets of X which is the union of the following collections.

Collection 1: the union of the elements of ${\mathcal {F}}^X_{ij}$ contained in A and intersecting ${\Bbb B}(b, ir_m)$ (Collection 1 consists of only one set).

Collection 2: for each element F of ${\mathcal {F}}^{p}_{i+1, t}$ , take the union of the elements of ${\mathcal {F}}^X_{ij}$ which are contained in both A and F and which were not used in constructing Collection 1 (by ( $\dagger 1$ ) the cardinality of Collection 2 is bounded by $\mathrm {w} Y$ ).

Collection 3: for each element F of ${\mathcal {F}}^{p}_{i+1, t}$ , take the union of the elements of ${\mathcal {F}}^X_{ij}$ which are contained in A and $(r_{i+1}/10)$ -close to F and which were not used in constructing Collections 1 and 2 (by ( $\dagger 1$ ) the cardinality of Collection 3 is bounded by $\mathrm {w} Y$ , and the elements of Collection $3$ are disjoint because ( $\dagger 2$ ) implies that ${\mathcal {F}}^{p}_{i+1,t}$ is $r_{i+1}$ -disjoint).

Collection 4: the union of the elements of ${\mathcal {F}}^X_{ij}$ contained in A and that were not used in constructing Collections 1–3 (Collection 4 consists of only one set).

Now, split the elements of ${\mathcal {F}}^p_{ij}$ by ${\mathcal {F}}^{p }_{i+1, 1}$ , split the elements of the resulting family by ${\mathcal {F}}^{p }_{i+1, 2}$ , and proceed by induction to the last splitting by ${\mathcal {F}}^{p }_{i+1, n+1}$ to finally get the family which we denote by ${\mathcal {F}}^{p+1}_{ij}$ . The construction is completed.

Claim 4.3 All the $\dagger $ -conditions hold.

We will prove Claim 4.3 later. Let us show now how to derive from Claim 4.3 the proof of the factorization theorem. Condition ( $\dagger 3$ ) implies that there is a unique collection ${\mathcal {F}}_{ij}$ of subsets of X such that ${\mathcal {F}}_{ij}$ coincides with ${\mathcal {F}}^p_{ij}$ on the ball ${\Bbb B}(b, ir_{i+p})$ for every p. Condition ( $\dagger 2$ ) implies that ${\mathcal {F}}_{ij}$ is a family of disjoint sets such that ${\mathcal {F}}_i={\mathcal {F}}_{i, 1} \cup \dots \cup {\mathcal {F}}_{i, n+1}$ covers X. Let $\mathcal {F}$ be the sequence of the covers ${\mathcal {F}}_i$ with the splittings ${\mathcal {F}}_{ij}$ .

Claim 4.4 (i) ${\mathcal {F}}^X_i$ refines ${\mathcal {F}}_i$ and ${\mathcal {F}}_i$ refines ${\mathcal {F}}^p_i$ for every p.

(ii) ${\mathcal {F}}$ defines $\mathrm {asdim} \leq n$ .

Proof (i) follows from ( $\dagger 2$ ) and ( $\dagger 3$ ).

(ii) Since ${\mathcal {F}}^X$ is a sequence witnessing $\mathrm {asdim} \leq n$ , any pair of points is contained in an element of ${\mathcal {F}}^X_i$ for some i. Then, by ( $\dagger 1$ ), this pair is contained in an element of ${\mathcal {F}}^p_i$ for every p and hence, by ( $\dagger 3$ ), in an element of ${\mathcal {F}}_i$ . Thus, in order to show that ${\mathcal {F}}$ defines $\mathrm {asdim} \leq n$ , we only need to show that $\mathrm {st} {\mathcal {F}}_i$ refines ${\mathcal {F}}_{i+1}$ and ${\mathcal {F}}_i$ separates ${\mathcal {F}}_{i+1,j}$ .

Take a point $x \in X$ . By ( $\dagger 3$ ) and ( $\dagger 4$ ), for every p, there is $F^p \in {\mathcal {F}}_{i+1}$ such that $\mathrm {st}(x, {\mathcal {F}}_i) \cap {\Bbb B}(b, ir_{i+p}) \subset F^p \cap {\Bbb B}(b, ir_{i+p})$ . Note that x belongs to at most $n+1$ elements of ${\mathcal {F}}_{i+1}$ and hence there is F in ${\mathcal {F}}_{i+1}$ such that $F=F^p$ for infinitely many p and then $\mathrm {st}(x, {\mathcal {F}}_i) \subset F$ . Thus, $\mathrm {st} {\mathcal {F}}_i$ refines ${\mathcal {F}}_{i+1}$ .

The property that ${\mathcal {F}}_i$ separates ${\mathcal {F}}_{i+1,j}$ follows from ( $\dagger 3$ ) and ( $\dagger 5$ ).

Let Z be a maximal subset of X separated by ${\mathcal {F}}_1$ . Define a function $g: X \rightarrow Z$ by sending $x \in X$ to a point $z \in Z$ such that $x \in \mathrm {st}(z, {\mathcal {F}}_1)$ . Consider Z with the metric $d_{\mathcal {F}}$ determined by ${\mathcal {F}}$ as described in Proposition 2.3.

Claim 4.5 We have that $\mathrm {w} Z \leq \mathrm {w} Y$ , $\mathrm {asdim} Z \leq n$ , the functions $g: X \rightarrow Z$ and $h=f|Z : Z \rightarrow Y$ are coarsely continuous (everything here with respect to $d_{\mathcal {F}}$ ), and f and $h\circ g$ are coarsely close.

Proof Since ${\mathcal {F}}_1$ separates the points of Z, we get that ${\mathcal {F}}_1$ restricted to Z consists of singletons and therefore the cardinality of Z is bounded by the cardinality of ${\mathcal {F}}_1$ . Then, since ${\mathcal {F}}_1$ restricted to ${\Bbb B}(b, r_{1+p})$ coincides with ${\mathcal {F}}^p_1$ for every p, we get by ( ${\dagger 1}$ ) that the cardinality of ${\mathcal {F}}_1$ is bounded by $\mathrm {w} Y$ and hence $\mathrm {w} Z \leq \mathrm {w} Y$ . The property $\mathrm {asdim} \leq n$ follows from (ii) of Proposition 2.3.

Let us show that g is coarsely continuous. Take $F\in {\mathcal {F}}^X_i$ and $x_1, x_2 \in F$ and let ${z_1=g(x_1)}$ and $z_2=g(x_2)$ . Then $x_1 \in \mathrm {st}(z_1, {\mathcal {F}}_1)$ and $x_2 \in \mathrm {st}(z_2, {\mathcal {F}}_1)$ . By (ii) of Claim 4.4, $ x_1 \in \mathrm {st}(z_1, {\mathcal {F}}_i)$ and $x_2 \in \mathrm {st}(z_2, {\mathcal {F}}_i)$ and then $F \subset \mathrm {st}(z_1, {\mathcal {F}}_{i+1})$ and $F \subset \mathrm {st}(z_2, {\mathcal {F}}_{i+1})$ . Therefore, by (ii) of Proposition 2.3, $z_1$ and $z_2$ are $(i+1)$ -close with respect to $d_{\mathcal {F}}$ . Thus, $g({\mathcal {F}}^X_i)$ is uniformly bounded with respect to $d_{\mathcal {F}}$ and hence g is coarsely continuous.

Let us show that h is coarsely continuous. Recall that $f({\mathcal {F}}^0_i)$ refines ${\mathcal {F}}^Y_i$ . Then, by (i) of Claim 4.4, ${\mathcal {F}}_i$ refines ${\mathcal {F}}^0_i$ and we get that $f({\mathcal {F}}_i)$ is uniformly bounded and hence, again by (ii) of Proposition 2.3, h is coarsely continuous.

Let us finally show that f and $h \circ g$ are coarsely close. Take a point $x \in X$ and let $z=g(x)$ . Since $x \in \mathrm {st} (z, {\mathcal {F}}_1)$ , ${\mathcal {F}}_1$ refines ${\mathcal {F}}^0_1$ and $f({\mathcal {F}}^0_1)$ refines ${\mathcal {F}}^Y_1$ , we get that $f(x)$ and $h(g(x))=f(z)$ are contained in an element of ${\mathcal {F}}^Y_1$ and hence f and $h\circ g$ are coarsely close.

Thus, Theorem 1.2 follows from Claim 4.5 and Proposition 4.2. The only thing left is the following.

Proof of Claim 4.3

Conditions ( $\dagger 1$ ), ( $\dagger 2$ ), and ( $\dagger 3$ ) obviously follow from the construction. So the only conditions we need to verify are ( $\dagger 4$ ) and ( $\dagger 5$ ) for ${\mathcal {F}}^{p+1}_i$ assuming that all the $\dagger $ -conditions hold for all the covers constructed before ${\mathcal {F}}^{p+1}_i$ . Recall that $m=p+i$ . Note that, by ( $\dagger 2$ ),

(*) $r_{i+1}$ is a Lebesgue number of ${\mathcal {F}}^p_{i+1}$ and

(**) ${\mathcal {F}}^p_{i+1,t}$ is $r_{i+1}$ -disjoint for every t.

Also, recall that

(***) ${\mathcal {F}}^X_i$ is $R_i$ -bounded with $ (100i+1)R_i< r_{i+1}$ (in particular $R_i < r_{1+1}/10$ ).

Fix a point $x \in X$ . We will say that x satisfies ( $\dagger 4$ ) if $\mathrm {st}( x, {\mathcal {F}}^{p+1}_i)$ is contained in an element of ${\mathcal {F}}^p_{i+1}$ , and we will say that x satisfies ( $\dagger 5$ ) if for every j no element of ${\mathcal {F}}^{p+1}_i$ containing x meets disjoint elements of ${\mathcal {F}}^p_{i+1,j}$ one of which contains x. Note that if every point of X satisfies ( $\dagger 4$ ) and ( $\dagger 5$ ), then ${\mathcal {F}}^{p+1}_i$ satisfies ( $\dagger 4$ ) and ( $\dagger 5$ ) as well.

Let E be an element of ${\mathcal {F}}^{p+1}_i$ . Recall that E is constructed from an element of ${\mathcal {F}}^p_i$ by a sequence of splittings by the families ${\mathcal {F}}^p_{i, 1}, \dots {\mathcal {F}}^p_{i, n+1}$ . On each step of this construction, we create four collections (Collections 1–4). Only one of these collections has an element containing E, and we will refer to this collection as the collection refined by E. We will refer to the step of splitting by ${\mathcal {F}}^p_{i, t}$ in the construction of E as step t. For given x and t, we assume throughout the proof that

( $\diamond $ ) E is an element of $\mathcal {F}^{p+1}_{i}$ that contains x, $\mathcal {E}$ is the collection refined by E created on step t of the construction of E, and $E_{\mathcal {E}}$ is the unique element of $\mathcal {E}$ that contains E.

Consider the following cases.

Case 1: $\mathrm {st}( x, {\mathcal {F}}^X_i)$ does not meet ${\Bbb B}(b, ir_m)$ .

We will show that x satisfies ( $\dagger 4$ ). By (*) and (***), take an element $F \in {\mathcal {F}}^p_{i+1, t}$ containing $\mathrm {st}( x, {\mathcal {F}}^X_i)$ . Having x and t chosen, we let E, $\mathcal {E}$ , and $E_{\mathcal {E}}$ be as in $(\diamond )$ . By the assumption of Case 1, $\mathcal {E}$ cannot be Collection 1. Then ${\mathcal {E}}$ must be Collection 2 with $E_{\mathcal {E}} \subset F$ . Thus, $E \subset F$ and hence x satisfies ( $\dagger 4$ ).

Now, we will show that x satisfies ( $\dagger 5$ ). Fix any t and suppose F is an element of ${\mathcal {F}}^p_{i+1, t}$ containing x. Having x and t chosen, we let E, $\mathcal {E}$ , and $E_{\mathcal {E}}$ be as in $(\diamond )$ . By the assumption of Case 1, ${\mathcal {E}}$ is not Collection 1. Then, by (**) and (***), ${\mathcal {E}}$ must be either Collection 2 or Collection 3 and then $E_{\mathcal {E}}$ is either contained in F or $(r_{i+1}/10)$ -close to F. Hence, by (**), $E_{\mathcal {E}}$ meets no element of ${\mathcal {F}}^p_{i+1, t}$ different from F. Thus, x satisfies ( $\dagger 5$ ).

Case 2: $\mathrm {st}( x, {\mathcal {F}}^X_i)$ does meet ${\Bbb B}(b, ir_m)$ and $p=0$ . Note that in this case $m=i$ and hence $2(ir_m + 2R_i )< r_{i+1}/10$ .

We will show that x satisfies ( $\dagger 4$ ). By (*), take an element $F \in {\mathcal {F}}^p_{i+1,t}$ containing $ {\Bbb B}(b, ir_m +2R_i)$ . Then, by (***), $\mathrm {st}(x, {\mathcal {F}}^X_i)\subset F$ . Having x and t chosen, we let E, $\mathcal {E}$ , and $E_{\mathcal {E}}$ be as in $(\diamond )$ . If ${\mathcal {E}}$ is Collection 1, then, again by (***), $ E_{\mathcal {E}} \subset {\Bbb B}(b, ir_m +2R_i)$ and hence $ E_{\mathcal {E}} \subset F$ . If $\mathcal {E}$ is not Collection 1, then, since $\mathrm {st}(x, {\mathcal {F}}^X_i)\subset F$ , the only option left is that $\mathcal {E}$ is Collection 2 and hence $ E_{\mathcal {E}} \subset F$ . Thus, x satisfies ( $\dagger 4$ ).

Now, let us show that x satisfies ( $\dagger 5$ ). Fix any t and suppose F is an element of ${\mathcal {F}}^p_{i+1, t}$ containing x. Having x and t chosen, we let E, $\mathcal {E}$ , and $E_{\mathcal {E}}$ be as in $(\diamond )$ . If $\mathcal {E}$ is Collection 1, then $E_{\mathcal {E}} $ is contained in ${\Bbb B}(b, ir_m +2R_i)$ and hence $E_{\mathcal {E}}$ is $(r_{i+1}/10)$ -close to F. If $\mathcal {E}$ is either Collection 2 or Collection 3, and then in both cases $E_{\mathcal {E}}$ is $(r_{i+1}/10)$ -close to F. By (**) and (***), $\mathcal {E}$ cannot be Collection 4. Thus, by (**), $E_{\mathcal {E}}$ cannot meet an element of ${\mathcal {F}}^p_{i+1, t}$ different from F and therefore x satisfies ( $\dagger 5$ ).

Case 3: $\mathrm {st}( x, {\mathcal {F}}^X_i)$ does meet ${\Bbb B}(b, ir_m)$ and $p>0$ . Note that then, by (***), $\mathrm {st}( x, {\mathcal {F}}^X_i) \subset {\Bbb B}(b, (i+1)r_m)$ .

Let us show that x satisfies ( $\dagger 4$ ). By the inductive assumption for ( $\dagger 4$ ), $\mathrm {st} {\mathcal {F}}^p_i$ refines ${\mathcal {F}}^{p-1}_{i+1}$ . Then, by ( $\dagger 3$ ), there is $F\in {\mathcal {F}}^{p}_{i+1}$ such that

( $\bullet $ ) $\mathrm {st}(x, {\mathcal {F}}^p_i) \cap {\Bbb B}(b,( i+1)r_m ) \subset F \cap {\Bbb B}(b,( i+1)r_m ) $ .

Note that then, by (***) and ( $\dagger 2$ ), we also have $\mathrm {st}(x, {\mathcal {F}}^X_i) \subset F$ . Suppose $F \in {\mathcal {F}}^p_{i+1, t}$ . Having x and t chosen, we let E, $\mathcal {E}$ , and $E_{\mathcal {E}}$ be as in $(\diamond )$ . If ${\mathcal {E}}$ is Collection 1, then $E_{\mathcal {E}} \subset {\Bbb B}(b, (i+1)r_m)$ and, then by ( $\dagger 3$ ), E is contained in an element of ${\mathcal {F}}^p_i $ , and hence, by ( $\bullet $ ), $ E \subset F$ . If $\mathcal {E}$ is not Collection 1, then, since $\mathrm {st}(x, {\mathcal {F}}^X_i) \subset F$ , the only option left is that ${\mathcal {E}}$ is Collection 2 and hence $E_{\mathcal {E}} \subset F$ . Thus, x satisfies ( $\dagger 4$ ).

Now, we will show that x satisfies ( $\dagger 5$ ). Fix any t and suppose F is an element of ${\mathcal {F}}^p_{i+1, t}$ containing x. Having x and t chosen, we let E, $\mathcal {E}$ , and $E_{\mathcal {E}}$ be as in $(\diamond )$ . If $\mathcal {E}$ is Collection 1, then $E_{\mathcal {E}} \subset {\Bbb B}(b, (i+1)r_m)$ and, hence by ( $\dagger 3$ ), E is contained in an element of ${\mathcal {F}}^p_i$ . Thus, by the inductive assumption for ( $\dagger 5$ ), E cannot meet disjoint elements of ${\mathcal {F}}^{p-1}_{i+1, t}$ and hence, by ( $\dagger 3$ ), E cannot meet disjoint elements of ${\mathcal {F}}^{p}_{i+1, t}$ as well. If ${\mathcal {E}}$ is Collection 2 or Collection 3, then $E_{\mathcal {E}}$ is $(r_{i+1}/10)$ -close to F and, by (**), $E_{\mathcal {E}}$ cannot meet disjoint elements of ${\mathcal {F}}^{p}_{i+1, t}$ . By (**) and (***), $\mathcal {E}$ cannot be collection 4. Thus, F is the only element ${\mathcal {F}}^p_{i+1, t}$ that E meets and therefore x satisfies ( $\dagger 5$ ).

Thus, every point of X satisfies ( $\dagger 4$ ) and ( $\dagger 5$ ) and the claim is proved.

5 Coarse property C and finite decomposition complexity

Yu’s result in [Reference Yu13] that proper metric spaces that admit uniform embeddings into Hilbert space satisfy the Novikov conjecture inspired many to seek out sufficient conditions for this same property. Yu showed that spaces with finite asymptotic dimension have this property, but there are also known examples of spaces with infinite asymptotic dimension that also have this property. Thus, properties weaker than finite asymptotic dimension that still imply the existence of uniform embeddings into Hilbert spaces have been sought out and explored. One such property is asymptotic property C, described by Dranishnikov in [Reference Dranishnikov4]. The property is related to the property of having finite asymptotic dimension. Indeed, metric spaces with finite asymptotic dimension have asymptotic property C. Its similarity with having finite asymptotic dimension leads us to the main goal of this section, which is to ask if the methods for constructing universal spaces for asymptotic dimension can be extended to coarse property C.

Below is the general definition for coarse property C (the general version of asymptotic property C for coarse spaces) as given by Bell, Moran, and Nagorko in [Reference Bell, Moran and Nagórko1].

Definition 5.1 A metric space X has coarse property C if for any sequence $\{L_{i}\}_{i\in \mathbb {N}}$ of uniformly bounded covers such that $L_{i}$ refines $L_{i+1}$ , there is an n and a finite sequence $\mathcal {U}^{1},\mathcal {U}^{2},\ldots ,\mathcal {U}^{n}$ of families of subsets of X such that:

  1. (1) $\mathcal {U}=\bigcup _{i=1}^{n}\mathcal {U}^{i}$ covers X;

  2. (2) each $\mathcal {U}^{i}$ is uniformly bounded; and

  3. (3) each $\mathcal {U}^{i}$ is $L_{i}$ -disjoint.

We then ask the following.

Question (i) Is there a (not necessarily separable) metric space X that has coarse property C and contains a coarsely equivalent copy of each separable metric spaces with coarse property C?

(ii) Let $f : X \rightarrow Y$ be a coarsely continuous map from a metric space X with coarse property C to a separable metric space Y. Does f factor through a separable metric space with coarse property C?

We end by noting that there are other properties one might also want to try constructing universal spaces for using the methods of this paper. These include finite decomposition complexity [Reference Guentner, Tessera and Guoliang7] and coarse property A [Reference Yu13].

Footnotes

The second and third authors were supported by the Israel Science Foundation (Grant No. 2196/20) and the Institute of Mathematics of the Polish Academy of Sciences where the main results were obtained during their visits in 2021–2022.

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