Geometric Visualizations of Quantum Mixed States and Density Matrices

TL;DR

This paper introduces geometric visualizations of quantum states, including mixed states and density matrices, extending the Bloch sphere concept to higher dimensions to aid understanding and simplify calculations in quantum mechanics.

Contribution

It extends geometric representations of quantum states beyond qubits to qudits and infinite dimensions, enhancing intuition and simplifying algebraic computations.

Findings

Visualizations for superpositions, mixtures, and decoherence

Geometric interpretation of state purity and metrics

Extension of Bloch sphere to higher dimensions and infinite space

Abstract

This paper presents an introduction to geometric representations of quantum states in which each distinct quantum state, pure and mixed, corresponds to a unique point in a Euclidean space. Beginning with a review of some underappreciated properties of the most commonly used geometric representation, the Bloch sphere visualization of qubit states, we show how concepts, algorithms, and spatial relations viewable on this geometric representation can be extended to representations of qudit states of any finite quantum dimension $d$ and on to the infinite-dimensional limit. A primary goal of the work is helping the reader develop a visual intuition of these spaces, which can complement the understanding of the algebraic formalism of quantum mechanics for learners, teachers, and researchers at any level. Particular emphasis is given both to understanding states in a basis-independent way and to understanding how probability amplitudes and density matrix elements used to algebraically represent states in a particular basis correspond to line segments and angles in the geometric representations. In addition to providing visualizations for such concepts as superpositions, mixtures, decoherence, and measurement, we demonstrate how the representations can be used to substitute simple geometrical calculations for more cumbersome linear algebra ones, which may be of particular use in introducing mixed states and density matrices to beginning quantum students at an early stage. The work concludes with the geometrical interpretation of some commonly used metrics such as the purity of states and their relation to real, Euclidean vectors in the infinite-dimensional limit of the space, which contains all lower-dimensional qudit spaces as subspaces.