The Fluid Dynamics of Cell Motility

Eric Lauga (University of Cambridge)

$75.95

Paperback

Not in-store but you can order this
How long will it take?

Availability Information

We source books from suppliers in Australia and overseas. For books we don't currently have in stock, the time it takes to get them from our suppliers can vary widely - from a few days to a few months - so we check each book with each supplier to determine the expected time it will take to be supplied to us.

We then advise you accordingly. If the time taken to get any book is too long for you, you can let us know and we will cancel or adjust your order, and refund as required.

To find out the anticipated arrival time for specific items prior to ordering, please contact us by phone or email:

Phone +61 2 9264 3111, or 1800 4 BOOKS (1800 4 26657) if outside Sydney:
option 1 Abbey's Bookshop (Crime, History, Science, Kids & more) • info@abbeys.com.au
option 2 Language Book Centre (ESL & Foreign Languages) • language@abbeys.com.au
option 3 Galaxy Bookshop (Sci-fi, Fantasy, Romance, Graphic Novels) • sf@galaxybooks.com.au

QTY:

English

Cambridge University Press
05 November 2020

Biomedical engineering; Fluid mechanics; Biophysics; Cellular biology (cytology)

Series: Cambridge Texts in Applied Mathematics

Fluid dynamics plays a crucial role in many cellular processes, including the locomotion of cells such as bacteria and spermatozoa. These organisms possess flagella, slender organelles whose time periodic motion in a fluid environment gives rise to motility. Sitting at the intersection of applied mathematics, physics and biology, the fluid dynamics of cell motility is one of the most successful applications of mathematical tools to the understanding of the biological world. Based on courses taught over several years, it details the mathematical modelling necessary to understand cell motility in fluids, covering phenomena ranging from single-cell motion to instabilities in cell populations. Each chapter introduces mathematical models to rationalise experiments, uses physical intuition to interpret mathematical results, highlights the history of the field and discusses notable current research questions. All mathematical derivations are included for students new to the field, and end-of-chapter exercises help consolidate understanding and practise applying the concepts.

By: Eric Lauga (University of Cambridge)
Imprint: Cambridge University Press
Country of Publication: United Kingdom
Dimensions: Height: 244mm, Width: 170mm, Spine: 18mm
Weight: 750g
ISBN: 9781316626702
ISBN 10: 1316626709
Series: Cambridge Texts in Applied Mathematics
Pages: 410
Publication Date: 05 November 2020
Audience: Professional and scholarly , College/higher education , Undergraduate , Primary
Format: Paperback
Publisher's Status: Active

Part I. Fundamentals: 1. Biological background; 2. The fluid dynamics of microscopic locomotion; 3. The waving sheet model; 4. The squirmer model; Part II. Cellular locomotion: 5. Flagella and the physics of viscous propulsion; 6. Hydrodynamics of slender filaments; 7. Waving of eukaryotic flagella; 8. Rotation of bacterial flagellar filaments; 9. Flows and stresses induced by cells; Part III. Interactions: 10. Swimming cells in flows; 11. Self-propulsion and surfaces; 12. Hydrodynamic synchronisation; 13. Diffusion and noisy swimming; 14. Hydrodynamics of collective locomotion; 15. Locomotion and transport in complex fluids; References; Index.

Eric Lauga is Professor of Applied Mathematics at the University of Cambridge and a Fellow of Trinity College, Cambridge. He is the author, or co-author, of over 170 publications in the field of fluid mechanics, biophysics and soft matter. He is a recipient of a CAREER Award from the US National Science Foundation (2008), and of three awards from the American Physical Society: the Andreas Acrivos Dissertation Award in Fluid Dynamics (2006), the François Frenkiel Award for Fluid Mechanics (2015) and the Early Career Award for Soft Matter Research (2018). Lauga is a Fellow of the American Physical Society.