Blue, R. and Dudus, Anna A. and Uttamchandani, D. (2015) A.

Optofluidics, nominally the research area where optics and fluidics merge, is a relatively new research field and it is only in the last decade that there has been a large increase in the number.

Optical devices which incorporate liquids as a fundamental part of the structure can be traced at least as far back as the eighteenth century where rotating pools of mercury were proposed as a simple.

Nanophotonics group members working on optofluidics research. The group members below are working on optofluidics-related research in hollow-core photonic crystal fibres. For more detail, see the optofluidics research page. People specializing in this area. Academic Staff. Dr Tijmen Euser. Research Fellows. Dr Alexander Gentleman. Dr Ermanno Miele. Research Students. Jan Heck. Philipp Koehler.

Optofluidics is a research and technology area that combines the advantages of microfluidics and optics. Applications of the technology include displays, biosensors, lab-on-chip devices, lenses, and molecular imaging tools and energy. History. The idea of fluid-optical devices can be traced back.

In this paper we will focus on a sub-set of the field of optofluidics, which we call “single-mode fiber optofluidics”. Single-mode fiber optofluidics is the combination of microfluidics technology with single-mode fiber (SMF) technology to yield fiber optic devices having filtering.

This paper details progress towards the possibility of creating integrated optical devices capable of manipulating and analyzing airborne particles in the form of aerosols. We also describe work designed to look at the possibility of controlling optical cavities created using liquid aerosols using light.

International Journal of Engineering Research in Africa. Optofluidics. Paper Title Page. Blood Circulation Network Incorporation an Artificial Bone for Real Time Operation. Authors: M. Tasakorn, N. Suwanpayak, P. Preecha Yupapin Abstract: We propose the use of molecular buffers and networks for blood circulation in Haversian and Volkmanns canals to deliver the nutrient, drug and other.

It will include both original research papers and short communications, together with invited review articles, covering the different aspects from basic research and components, up to technologically-mature integrated devices for biomedical applications.

We emphasize light-sensitive synthetic biological systems that would be relevant for the integration with optofluidic devices. Next, we propose several areas for potential applications of optofluidics in synthetic biology. The integration of optofluidics and synthetic biology would have a broad impact on point-of-care diagnostics and biotechnology.

Optofluidics refers to a class of devices and techniques that combine optics and fluidics. Biophotonics has been a major application of optofluidics partially because in biology we normally use light to make measurements of entities suspended in liquids. Therefore biophotonics naturally combines fluids and optics. The same is true in the field of solar fuels where chemicals in liquid form are.

Optofluidics or micro-optofluidic systems (MOFS) is a burgeoning technology that aims to manipulate light and fluid at microscale and exploit their interaction to create highly versatile devices and integrated systems. The novelties of optofluidics are twofold. First, fluids can be used to carry substances to be analyzed in highly sensitive optical microdevices.