Algebraic Approach to Interacting Quantum Systems

TL;DR

This paper introduces an algebraic framework for analyzing interacting quantum systems, enabling the discovery of hidden symmetries, phase diagrams, and new states of matter through exact mappings between different representations.

Contribution

It develops a systematic method using dictionaries and hierarchical languages to connect various quantum models, revealing hidden orders and unifying diverse phases.

Findings

Unveiled hidden order parameters in lattice models.

Established conditions for connecting different quantum languages.

Provided a unified description of competing and coexisting phases.

Abstract

We present an algebraic framework for interacting extended quantum systems to study complex phenomena characterized by the coexistence and competition of different states of matter. We start by showing how to connect different (spin-particle-gauge) {\it languages} by means of exact mappings (isomorphisms) that we name {\it dictionaries} and prove a fundamental theorem establishing when two arbitrary languages can be connected. These mappings serve to unravel symmetries which are hidden in one representation but become manifest in another. In addition, we establish a formal link between seemingly unrelated physical phenomena by changing the language of our model description. This link leads to the idea of {\it universality} or equivalence. Moreover, we introduce the novel concept of {\it emergent symmetry} as another symmetry guiding principle. By introducing the notion of {\it hierarchical languages}, we determine the quantum phase diagram of lattice models (previously unsolved) and unveil hidden order parameters to explore new states of matter. Hierarchical languages also constitute an essential tool to provide a unified description of phases which compete and coexist. Overall, our framework provides a simple and systematic methodology to predict and discover new kinds of orders. Another aspect exploited by the present formalism is the relation between condensed matter and lattice gauge theories through quantum link models. We conclude discussing applications of these dictionaries to the area of quantum information and computation with emphasis in building new models of computation and quantum programming languages.