Linking diffusive fields to virtual waves as their propagative duals

TL;DR

This paper explores the relationship between diffusive fields and virtual waves, demonstrating how virtual wave concepts can improve internal imaging resolution in non-destructive testing and biomedical applications.

Contribution

It introduces a method to use locally computed virtual waves from diffusive signals for enhanced image reconstruction, bridging diffusive and propagative wave descriptions.

Findings

Improved spatial resolution in thermography.

Enhanced image reconstruction in atom probe tomography.

Demonstrated reversibility of virtual waves in diffusive media.

Abstract

In non-destructive and biomedical imaging, spatial patterns inside a sample are imaged without destroying it. Therefore, propagating waves, including electromagnetic or ultrasonic signals, or even diffuse heat are generated or modified by these internal patterns and transmit this structural information to the sample surface. There, the signals can be detected, and an image of the internal structure can be reconstructed from the measured signals. The amount of information about the interior of the sample that can be obtained from the detected signals at the sample surface is significantly influenced by the propagation from the internal structure to the surface. In the real world, all signal propagation is more or less irreversible. The entropy generated during propagation corresponds to the loss of information. In an idealized model, such propagating waves, called virtual waves, are described by the wave equation. They remain valid solutions of this equation when the direction of time is reversed, thus exhibiting reversibility and showing no entropy production and therefore no loss of information during propagation. We have used the locally computed virtual waves from the measured diffusive surface signals for image reconstruction using established time-of-flight methods from ultrasound or RADAR imaging. This improves the spatial resolution in thermography and compensates for the dispersion of quantum wave packets in atom probe tomography.