Abstract
It is now well known that matter may be trapped by optical fields with high intensity gradients. Once trapped, it is then possible to manipulate microscopic particles using such optical fields, in so-called optical tweezers. Such optical trapping and tweezing systems have found widespread application across diverse fields in science, from applied biology to fundamental physics. In this article we outline the design and construction of an optical trapping and tweezing system, and show how the resulting interaction of the laser light with microscopic particles may be understood in terms of the transfer of linear and angular momentum of light. We demonstrate experimentally the use of our optical tweezing configuration for the measurement of microscopic forces and torques. In particular, we make use of digital holography to create so-called vortex laser beams, capable of transferring orbital angular momentum to particles. The use of such novel laser beams in an optical trapping and tweezing set-up allows for the control of biological species at the single-cell level.
Highlights
Microscopic forces are generally difficult to quantify as their effects are not experienced at the macro level
Optical tweezing is an accurate and non-invasive method of measuring microscopic forces and the torques experienced by microparticles, providing numerous applications within fields such as biology,[1,2,3,4] microfluidics[5,6] and aerosol dynamics.[7]
An optical tweezer is formed by tightly focusing a laser beam through an objective lens of high numerical aperture onto a particle
Summary
Affiliations: 1National Laser Centre, CSIR, Pretoria, South Africa 2School of Physics, University of the Witwatersrand, Johannesburg, South Africa 3School of Physics, University of KwaZulu-Natal, Durban, South Africa. It is possible to manipulate microscopic particles using such optical fields, in so-called optical tweezers. In this article we outline the design and construction of an optical trapping and tweezing system, and show how the resulting interaction of the laser light with microscopic particles may be understood in terms of the transfer of linear and angular momentum of light. We make use of digital holography to create so-called vortex laser beams, capable of transferring orbital angular momentum to particles. The use of such novel laser beams in an optical trapping and tweezing set-up allows for the control of biological species at the single-cell level
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