Optical Micromanipulation of Soft Materials: Applications in Devices and Technologies

TL;DR

Optical micromanipulation, utilizing focused laser beams, is a versatile tool for studying and manipulating soft materials, enabling insights into their mechanical, structural, and chemical properties, and facilitating device development.

Contribution

This paper provides a comprehensive overview of optical micromanipulation techniques, including fundamental theories, design considerations, and recent advancements in applications and device integration.

Findings

Effective force measurement at mesoscopic scales

Application in probing soft matter properties

Development of soft-matter-based devices

Abstract

Since its invention by Arthur Ashkin and colleagues at Bell Labs in the 1970s, optical micromanipulation, also known as optical tweezers or laser tweezers, has evolved remarkably to become one of the most convenient and versatile tools for studying soft materials, including biological systems. Arthur Ashkin received the Nobel Prize in Physics in 2018 for enabling these extraordinary scientific advancements. Essentially, a focused laser beam is used to apply and measure minuscule forces from a few piconewtons to femtonewtons by utilizing light-matter interaction at mesoscopic length scales. Combined with advanced microscopy and position-sensing techniques, optical micromanipulations enable us to investigate diverse aspects of functional soft materials. These include studying mechanical responses through force-elongation measurements, examining the structural properties of complex fluids employing microrheology, analyzing chemical compositions using spectroscopy, and sorting cells through single-cell analysis. Furthermore, it is utilized in various soft-matter-based devices, such as laser scissors and optical motors in microfluidic channels. This chapter presents an overview of optical micromanipulation techniques by describing fundamental theories and explaining the design considerations of conventional single-trap and dual-trap setups as well as recent improvisations. We further discuss their capabilities and applications in probing exotic soft-matter systems and in developing widely utilized devices and technologies based on functional soft materials.