Light Driven Micromachines

Nonfiction, Science & Nature, Technology, Lasers, Nanotechnology, Electronics, Microelectronics
Cover of the book Light Driven Micromachines by George K. Knopf, Kenji Uchino, CRC Press
View on Amazon View on AbeBooks View on Kobo View on B.Depository View on eBay View on Walmart
Author: George K. Knopf, Kenji Uchino ISBN: 9781351001267
Publisher: CRC Press Publication: March 29, 2018
Imprint: CRC Press Language: English
Author: George K. Knopf, Kenji Uchino
ISBN: 9781351001267
Publisher: CRC Press
Publication: March 29, 2018
Imprint: CRC Press
Language: English

In Light Driven Micromachines, the fundamental principles and unique characteristics of light driven material structures, simple mechanisms and integrated machines are explored. Very small light driven systems provide a number of interesting features and unique design opportunities because streams of photons deliver energy into the system and provide the control signal used to regulate the response of the micron sized device. Through innovative material design and clever component fabrication, these optically powered tiny machines can be created to perform mechanical work when exposed to varying light intensity, wavelength, phase, and/or polarization. 

The book begins with the scientific background necessary to understand the nature of light and how light can initiate physical movement by inducing material deformation or altering the surrounding environment to impose micro-forces on the actuating mechanisms. The impact of physical size on the performance of light driven mechanisms and machines is discussed, and the nature of light–material interactions is reviewed. These interactions enable very small objects and mechanical components to be trapped and manipulated by a focused light beam, or produce local temperature gradients that force certain materials to undergo shape transformation. Advanced phase transition gels, polymers, carbon-based films and piezoelectric ceramics that exhibit direct light-to-mechanical energy conversion are examined from the perspective of designing optically driven actuators and mechanical systems. The ability of light to create photothermal effects that drive microfluidic processes and initiate the phase transformation of temperature sensitive shape memory materials are also explored in the book.

This compendium seeks to inspire the next generation of scientists and engineers by presenting the fundamental principles of this emerging interdisciplinary technology and exploring how the properties of light can be exploited for microfluidic, microrobotic, biomedical and space applications.

View on Amazon View on AbeBooks View on Kobo View on B.Depository View on eBay View on Walmart

In Light Driven Micromachines, the fundamental principles and unique characteristics of light driven material structures, simple mechanisms and integrated machines are explored. Very small light driven systems provide a number of interesting features and unique design opportunities because streams of photons deliver energy into the system and provide the control signal used to regulate the response of the micron sized device. Through innovative material design and clever component fabrication, these optically powered tiny machines can be created to perform mechanical work when exposed to varying light intensity, wavelength, phase, and/or polarization. 

The book begins with the scientific background necessary to understand the nature of light and how light can initiate physical movement by inducing material deformation or altering the surrounding environment to impose micro-forces on the actuating mechanisms. The impact of physical size on the performance of light driven mechanisms and machines is discussed, and the nature of light–material interactions is reviewed. These interactions enable very small objects and mechanical components to be trapped and manipulated by a focused light beam, or produce local temperature gradients that force certain materials to undergo shape transformation. Advanced phase transition gels, polymers, carbon-based films and piezoelectric ceramics that exhibit direct light-to-mechanical energy conversion are examined from the perspective of designing optically driven actuators and mechanical systems. The ability of light to create photothermal effects that drive microfluidic processes and initiate the phase transformation of temperature sensitive shape memory materials are also explored in the book.

This compendium seeks to inspire the next generation of scientists and engineers by presenting the fundamental principles of this emerging interdisciplinary technology and exploring how the properties of light can be exploited for microfluidic, microrobotic, biomedical and space applications.

More books from CRC Press

Cover of the book Cooperative Control of Multi-Agent Systems by George K. Knopf, Kenji Uchino
Cover of the book Diamond Turn Machining by George K. Knopf, Kenji Uchino
Cover of the book Applied Thermodynamics by George K. Knopf, Kenji Uchino
Cover of the book Fiber Optic Sensors by George K. Knopf, Kenji Uchino
Cover of the book Linux with Operating System Concepts by George K. Knopf, Kenji Uchino
Cover of the book A Concise Introduction to Programming in Python by George K. Knopf, Kenji Uchino
Cover of the book Tubular Structures XVI by George K. Knopf, Kenji Uchino
Cover of the book Optics Manufacturing by George K. Knopf, Kenji Uchino
Cover of the book Water Hyacinth by George K. Knopf, Kenji Uchino
Cover of the book An Introduction to Health and Safety Law by George K. Knopf, Kenji Uchino
Cover of the book Handbook of Optomechanical Engineering by George K. Knopf, Kenji Uchino
Cover of the book Experimental Hydraulics: Methods, Instrumentation, Data Processing and Management by George K. Knopf, Kenji Uchino
Cover of the book Fluorescence Imaging and Biological Quantification by George K. Knopf, Kenji Uchino
Cover of the book Nutritional Aspects Of Aging by George K. Knopf, Kenji Uchino
Cover of the book Cannabis by George K. Knopf, Kenji Uchino
We use our own "cookies" and third party cookies to improve services and to see statistical information. By using this website, you agree to our Privacy Policy