Information-Powered Engines

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This book presents the experimental development of an information-powered engine inspired by the famous thought experiment, Maxwell's demon, to understand its potential to produce energy for practical purposes. The development of an engine based on Maxwell's demon was for a long time inconceivable, but technological advances have led to novel investigations into theoretical and practical applications. 
The built information engine consists of a micron-sized glass bead trapped in a tightly focused laser beam. It rectifies the bead's Brownian motion by controlling the laser's position and generates a unidirectional motion against gravity without doing any work, thus converting thermal heat into stored gravitational potential energy. A theoretical model based on a spring-mass system describes the engine's dynamics and was then used to find optimum parameters to improve the engine's performance. Experimentally implementing these optimization strategies led to engine output powers comparable to those measured in biological motors. 
This book also highlights performance improvements made in the presence of measurement noise and presents important guiding principles to design information engines to operate in non-equilibrium environments. By focusing on practical applications, the book overall aims to broaden the scope of information-engine investigations. 

Inhaltsverzeichnis

Chapter 1. Introduction.- Chapter 2. Theory background.- Chapter 3. Experimental Apparatus.- Chapter 4. High-performance information engine.- Chapter 5. Trajectory control using an information engine.- Chapter 6. Bayesian information engine.- Chapter 7. Information engine in a nonequilibrium bath.- Chapter 8. Identifying information engines.- Chapter 9. Conclusion.

Über den Autor / die Autorin

Dr. Tushar K. Saha obtained a BS-MS Dual degree in Physics from the Indian Institute of Science Education and Research, Kolkata, India, in 2017. Then he joined Prof. John Bechhoefer' s research group at Simon Fraser University, where he completed his PhD in Physics in 2022. Currently, he is pursuing his passion for developing optical sensing products at MKS Instruments Inc.