Solar Sails, Optical Tweezers, and Other Light-Driven Machines

TL;DR

This paper reviews how electromagnetic radiation interacts with matter, enabling applications like optical trapping, micro-machines, and solar sails through radiation forces and momentum transfer.

Contribution

It provides a comprehensive overview of the physical principles behind light-driven devices and their diverse applications in micro- and macro-scale systems.

Findings

Radiation forces enable trapping and manipulation of micro-objects.

Electromagnetic momentum transfer drives micro-machines and solar sails.

Conservation of energy and momentum underpins light-matter interactions.

Abstract

Electromagnetic waves carry energy, linear momentum, and angular momentum. When light (or other electromagnetic radiation) interacts with material media, both energy and momentum are usually exchanged. The force and torque experienced by material bodies in their interactions with the electromagnetic field are such that the energy as well as the linear and angular momenta of the overall system (i.e., the system of field plus matter) are conserved. Radiation forces are now used routinely to trap and manipulate small objects such as glass or plastic micro-beads and biological cells, to drive micro- and nano-machines, and to contemplate interstellar travel with the aid of solar sails. We discuss the properties of the electromagnetic field that enable such wide-ranging applications.