Explicit two-sided unique-neighbor expanders

TL;DR

This paper introduces the first explicit construction of two-sided imbalanced unique-neighbor expanders with applications to quantum code construction, using a novel tripartite line product of spectral and unique-neighbor expanders.

Contribution

It presents a new graph product and a sharp characterization of subgraphs in spectral expanders, enabling explicit constructions of bipartite graphs with strong vertex expansion properties.

Findings

Constructed infinite families of bipartite graphs with strong unique-neighbor expansion.

Achieved lossless expansion for subsets up to exponential size.

Generalized previous graph product methods for expanders.

Abstract

We study the problem of constructing explicit sparse graphs that exhibit strong vertex expansion. Our main result is the first two-sided construction of imbalanced unique-neighbor expanders, meaning bipartite graphs where small sets contained in both the left and right bipartitions exhibit unique-neighbor expansion, along with algebraic properties relevant to constructing quantum codes. Our constructions are obtained from instantiations of the tripartite line product of a large tripartite spectral expander and a sufficiently good constant-sized unique-neighbor expander, a new graph product we defined that generalizes the line product in the work of Alon and Capalbo and the routed product in the work of Asherov and Dinur. To analyze the vertex expansion of graphs arising from the tripartite line product, we develop a sharp characterization of subgraphs that can arise in bipartite spectral expanders, generalizing results of Kahale, which may be of independent interest. By picking appropriate graphs to apply our product to, we give a strongly explicit construction of an infinite family of $(d_1,d_2)$-biregular graphs $(G_n)_{n\ge 1}$ (for large enough $d_1$ and $d_2$) where all sets $S$ with fewer than a small constant fraction of vertices have $\Omega(d_1\cdot |S|)$ unique-neighbors (assuming $d_1 \leq d_2$). Additionally, we can also guarantee that subsets of vertices of size up to $\exp(\Omega(\sqrt{\log |V(G_n)|}))$ expand losslessly.