Biomedical and Chemical Engineering Books 2018
cambridge.org/BioChem
This catalogue contains a selection of our most recent books published on Biomedical and Chemical Engineering. Please visit our website for a full and searchable listing of all our titles in print. Cambridge University Press advances knowledge, learning and research worldwide.
Useful contacts Book Proposals: Steve Elliot: selliot@cambridge.org Elizabeth Horne: ehorne@cambridge.org All other enquiries: Telephone +44 (0) 1223 312393 Email information@cambridge.org Prices and publication dates are correct at the time of going to press but are subject to alteration without notice. Register for new publication alerts at cambridge.org/alerts Order online now at www.cambridge.org/BioChem
Biomedical and Chemical Engineering Books 2018
BIOMEDICAL ENGINEERING
CAMBRIDGE TEXTS IN This unique introductory text explains cell functions using the engineering principles of robust devices. Adopting a processbased approach to understanding cell and tissue biology, it describes the molecular and mechanical features that enable the cell to be robust in operating its various components, and explores the ways in which molecular modules respond to environmental signals to execute complex functions. The design and operation of a variety of complex functions are covered, including engineering lipid bilayers to provide fluid boundaries and mechanical controls, adjusting cell shape and forces with
CAMBRIDGE TEXTS IN BIOMEDICAL ENGINEERING Series Editors Professor W. Mark Saltzman, Yale University Professor Shu Chien, University of California, San Diego
The Cell as a Machine
Principles of Biomedical Instrumentation
Sheetz & Yu
e
Principles of Biomedical Instrumentation
San Diego
Webb
man,
9781107052734 Sheetz & Yu PPC C M Y K
CAMBRIDGE TEXTS IN
IN NEERING
1
dynamic filament networks, and DNA packaging for information retrieval and propagation. Numerous problems, case studies and application examples help readers connect theory with practice, and solutions for instructors and videos of lectures accompany the book online. Assuming only basic mathematical knowledge, this is an invaluable resource for graduate and senior undergraduate students taking single-semester courses in cell mechanics, biophysics and cell biology. Michael Sheetz is the Founding Director of the Mechanobiology Institute and a distinguished professor in the Department of Biological Sciences both at the National University of Singapore. Hanry Yu is a professor in both the Department of Physiology and the Mechanobiology Institute at the National University of Singapore. He is also the Director of the National University Health System’s research facilities in microscopy and cytometry.
BIOMEDICAL ENGINEERING
The Cell as a Machine
cambridge.org/sheetz
Andrew G. Webb
For instructor’s use: PowerPoint slides and JPEGS of figures and tables from the book Video lectures Solutions manual
Michael Sheetz and Hanry Yu
Cover illustration: four images created by Cindy Bo Zhang.
Principles of Biomedical Instrumentation
The Cell as a Machine Michael Sheetz Columbia University, New York
Andrew G. Webb Leiden University Medical Center, The Netherlands This senior undergraduate level text describes the step-by-step design process for biomedical devices, linking sensors and signal processing to the underlying physiological signals being measured. With clinical applications included throughout, and numerous end-of-chapter problems, it provides an accessible yet in-depth introduction to the field. Contents
1. Biomedical instrumentation and devices; 2. Sensors and transducers; 3. Signal filtering and amplification; 4. Data acquisition and signal processing; 5. Electrocardiography; 6. Electroencephalograpy; 7. Digital hearing aids; 8. Mobile health, wearable health technology and wireless implanted devices; 9. Safety of biomedical instruments and devices; Appendix. Safety policy documents.
£69.99 | $89.99 | Hardback | 9781107113138 January 2018 | 253 x 192 x 19 mm | 230 b/w illus. | 344pp
Connecting underlying theory with real-world applications, this systematic and mathematically accessible textbook explains cell functions using the engineering principles of robust devices. It is ideal for undergraduate and graduate students taking single-semester courses in cell mechanics, biophysics and cell biology. Contents
Part I. Principle of Complex Function in Robust Machines: 1. Robust self-replicating machines shaped by evolution; 2. Complex functions of robust machines with emergent properties; 3. Integrated complex functions with dynamic feedback; 4. Cells exhibit multiple states, each with different functions; 5. Life at low Reynolds number and the mesoscale leads to stochastic phenomena. Part II. Design and Operation of Complex Functions: 6. Engineering lipid bilayers to provide fluid boundaries and mechanical controls; 7. Membrane trafficking – flow and barriers create asymmetries; 8. Signaling and cell volume control through ion transport and volume regulators; 9. Structuring a cell by cytoskeletal filaments; 10. Moving and maintaining functional assemblies with motors; 11. Microenvironment controls life, death and regeneration; 12. Adjusting cell shape and forces with dynamic filament networks; 13. DNA packaging for information retrieval and propagation; 14. Transcribing the right information and packaging for delivery; 15. Turning RNA into functional proteins and removing unwanted proteins. Part III. Coordination of Complex Functions: 16. How to approach a coordinated function – cell rigidity sensing and force generation across length scale; 17. Integration of cellular functions for decision making; 18. Moving from omnipotency to death; 19. Cancer versus regeneration – the wrong versus right response to the microenvironment.
£69.99 | $89.99 | Hardback | 9781107052734 January 2018 | 253 x 192 x 24 mm | 2 b/w illus. 136 colour illus. | 434pp
Order online at cambridge.org/BioChem
an,
n Diego
ntinuum en
tant
fessor cs
BIOMEDICAL ENGINEERING
The Dynamics of Engineered Artificial Membranes and Biosensors
SECOND EDITION
Biomechanics Concepts and Computation
Biomechanics
essor ssues ty of
Biomedical and Chemical Engineering Books 2018
CAMBRIDGE TEXTS IN
Oomens, Brekelmans, Loerakker and Baaijens
N ERING
2
of ly the ficus.
William Hoiles, Vikram Krishnamurthy and Bruce Cornell
Cees Oomens, Marcel Brekelmans Sandra Loerakker, and Frank Baaijens
Biomechanics Concepts and Computation Cees Oomens Technische Universiteit Eindhoven, The Netherlands Marcel Brekelmans Technische Universiteit Eindhoven, The Netherlands Sandra Loerakker Technische Universiteit Eindhoven, The Netherlands Frank Baaijens Technische Universiteit Eindhoven, The Netherlands Ideal for students taking biomechanics courses, this fully updated second edition integrates basic and advanced concepts of mechanics with numerical methods and biomedical applications. It includes a brand new introduction to vector and tensor calculus, dozens of new examples, exercises and solutions, and online MATLAB-based FEM code. Contents
1. Vector and tensor calculus; 2. The concepts of force and moment; 3. Static equilibrium; 4. The mechanical behaviour of fibres; 5. Fibres: time-dependent behaviour; 6. Analysis of a onedimensional continuous elastic medium; 7. Biological materials and continuum mechanics; 8. Stress in three-dimensional continuous media; 9. Motion: the time as an extra dimension; 10. Deformation and rotation, deformation rate and spin; 11. Local balance of mass, momentum and energy; 12. Constitutive modelling of solids and fluids; 13. Solution strategies for solid and fluid mechanics problems; 14. Numerical solution of one-dimensional diffusion equation; 15. The one-dimensional convection-diffusion equation; 16. The three-dimensional convection-diffusion equation; 17. Shape functions and numerical integration; 18. Infinitesimal strain elasticity problems.
£49.99 | $64.99 | Hardback | 9781107163720 February 2018 | 253 x 193 x 22 mm | 280 b/w illus. 6 tables 151 exercises | 420pp
The Dynamics of Engineered Artificial Membranes and Biosensors William Hoiles University of British Columbia, Vancouver Vikram Krishnamurthy Cornell University, New York Bruce Cornell University of Technology, Sydney Combining synthesis with mathematical modelling, this is a state-of-the-art guide to building artificial membranes for biological devices. Supported by numerous case studies and molecular dynamics simulation code, it provides a powerful toolkit for researchers, students and professionals in bioengineering, biophysics and electrical engineering. Contents
Part I. Background: 1. Motivation and outline; 2. Biochemistry for engineers: a short primer; 3. Engineered artificial membranes. Part II. Building Engineered Membranes, Devices and Experimental Results: 4. Formation of engineered tethered membranes; 5. Ion-channel switch biosensor; 6. Physiochemical membrane platforms; 7. Experimental measurement methods for engineered membranes. Part III. Dynamic Models for Artificial Membranes: Atoms-to-Device: 8. Reaction-rate constrained models for engineered membranes; 9. Reactionrate constrained models for the ICS biosensor; 10. Diffusion constrained continuum models of engineered membranes; 11. Electroporation models in engineered artificial membranes; 12. Electroporation measurements in engineered membranes; 13. Electrophysiological response of ion channels and cells; 14. Coarse-grained molecular dynamics; 15. All-atom molecular dynamics simulation models; 16. Closing summary for part III: from atoms to device; Appendices: Appendix A. Elementary primer on partial differential equations (PDE); Appendix B. Tutorial on coarse-grained molecular dynamics with peptides.
£74.99 | $105.00 | Hardback | 9781108423502 Planned for April 2018 | 247 x 174 mm | 161 b/w illus. 16 tables | 474pp
Order online at cambridge.org/BioChem
SECOND EDITION
“David Venerus and Hans Christian Öttinger are second to none in their understanding of transport phenomena.” Dick Bedeaux, Professor, Department of Chemistry, National Technical University of Norway
Biomedical Instrumentation
A Modern Course in
Transport Phenomena
“Venerus and Öttinger offer an intellectually courageous new approach to transport phenomena that is truly based on molecular concepts, and that incorporates fifty years of progress in molecular sciences in a manner that is both rigorous and highly relevant for modern engineering and scientific applications.” Juan J. de Pablo, Liew Family Professor of Molecular Engineering, Institute for Molecular Engineering, University of Chicago This advanced text presents a unique approach to studying transport phenomena. Bringing together concepts from both chemical engineering and physics, it makes extensive use of nonequilibrium thermodynamics, discusses kinetic theory, and sets out the tools needed to describe the physics of interfaces and boundaries. More traditional topics such as diffusive and convective transport of momentum, energy and mass are also covered. This is an ideal text for advanced courses in transport phenomena, and for researchers looking to expand their knowledge of the subject.
THE TECHNOLOGY OF PATIENT CARE
BARBARA L. CHRISTE
Venerus and Öttinger
“This collaborative effort between a physicist and an engineer offers a comprehensive discussion that combines traditional material in transport phenomena with thermodynamics. This is particularly evident in the presentation of interfacial transport phenomena, which is a most valuable contribution by this book.” Gerald G. Fuller, Fletcher Jones II Professor, Department of Chemical Engineering, Stanford University
I N T RODUC T ION TO
Also included: • Novel applications such as complex fluids, transport at interfaces and biological systems • Approximately 250 exercises with solutions (included separately) designed to enhance understanding and reinforce key concepts • End-of-chapter summaries
9781107129207: Venerus and Öttinger: PPC: C M Y K
or
Biomedical Instrumentation
t,
INTRODUCTION TO
on ding ith
CHRISTE
th
ns
M
Biomedical and Chemical Engineering Books 2018
David C. Venerus is a Professor of Chemical Engineering in the Department of Chemical and Biological Engineering at Illinois Institute of Technology in Chicago. His research interests are in the areas of transport phenomena in soft matter, polymer science and the rheology of complex fluids. Professor Venerus has received numerous teaching awards both within the Department and College of Engineering at Illinois Institute of Technology. He is a member of the American Institute of Chemical Engineers and of the Society of Rheology. Hans Christian Öttinger is Professor of Polymer Physics at the ETH Zürich. His main research interest is in developing a general framework of nonequilibrium thermodynamics as a tool for describing dissipative classical and quantum systems. He is the author of Stochastic Processes in Polymeric Fluids (1996), Beyond Equilibrium Thermodynamics (2005) and A Philosophical Approach to Quantum Field Theory (Cambridge, 2017).
3
A Modern Course in
Transport Phenomena
Online Resources www.cambridge.org/venerus&öttinger Xxxxxxxxxxx
D. C. Venerus H. C. Öttinger
ISBN 978-1-107-12920-7 Cover image: David C. Venerus Cover design: Andrew Ward
9 781 1 07 1 29207 >
Introduction to Biomedical Instrumentation
A Modern Course in Transport Phenomena
The Technology of Patient Care
David C. Venerus Illinois Institute of Technology
Barbara L. Christe Indiana University–Purdue University, Indianapolis This fully updated second edition is the ideal guide for biomedical engineering technicians looking to increase their understanding of the medical technology involved in patient care. It incorporates recent changes in healthcare, regulations, standards and technology, and includes new chapters on patient safety and the electronic medical record. Contents
1. A career in the HTM profession; 2. Patient safety; 3. NFPA and other guidelines; 4. Device testing; 5. In the workplace; 6. Electrodes, sensors, signals, and noise; 7. The heart; 8. Cardiac assist devices; 9. Blood pressure; 10. Respiration and respiratory therapy; 11. The brain and its activity; 12. The intensive care unit; 13. The operating room; 14. Imaging; 15. Clinical laboratory equipment; 16. Intravenous pumps and other pumps; 17. Electronic medical record and IT; 18. Miscellaneous devices and topics
£49.99 | $69.99 | Hardback | 9781107185012 December 2017 | 235 x 156 x 16 mm | 244pp
Hans Christian Öttinger ETH Zürich, Switzerland This text presents a novel approach to the subject of transport phenomena fully integrated with nonequilibrium thermodynamics and kinetic theory. With rigorous treatment of interfaces and modern applications, this is an ideal text for advanced courses in transport phenomena, and for researchers looking to expand their knowledge of the subject. Contents
1. Approach to transport phenomena; 2. The diffusion equation; 3. Brownian dynamics; 4. Equilibrium thermodynamics; 5. Balance equations; 6. Forces and fluxes; 7. Measuring transport coefficients; 8. Pressure-driven flow; 9. Heat exchangers; 10. Gas absorption; 11. Driven separations; 12. Complex fluids; 13. Thermodynamics of interfaces; 14. Interfacial balance equations; 15. Interfacial force-flux relations; 16. Polymer processing; 17. Transport around a sphere; 18 Bubble growth and dissolution; 19. Semi-conductor processing; 20. Equilibrium statistical mechanics; 21. Kinetic theory of gases; 22. Kinetic theory of polymeric liquids; 23. Transport in porous media; 24. Transport in biological systems; 25. Microbead rheology; 26. Dynamic light scattering; Appendix A: thermodynamic relations; Appendix B: differential operations in coordinate form.
£74.99 | $99.99 | Hardback | 9781107129207 March 2018 | 254 x 180 x 28 mm | 534pp
Order online at cambridge.org/BioChem
4
Biomedical and Chemical Engineering Books 2018
Michael D. Graham, University of WisconsinMadison
dorfman Solutions manual Downloadable MATLAB code PowerPoint slides and jpegs of all figures from the book
Kevin D. Dorfman and Prodromos Daoutidis
Cover designed by Zoe Naylor
Prodromos Daoutidis is Professor and Executive Officer in the Department of Chemical Engineering and Materials Science at the University of Minnesota. He is the recipient of the National Science Foundation CAREER Award, the Process Systems Enterprise Model Based Innovation Prize, the Ted Peterson Award of the American Institute of Chemical Engineers, the McKnight Land Grant Professorship, the Ray D. Johnson / Mayon Plastics Professorship, and the Shell Chair. He has been a Humphrey Institute Policy fellow, and has co-authored 2 research monographs and over 220 papers.
Numerical Methods with Chemical Engineering Applications
Numerical Methods with Chemical Engineering Applications
Kevin D. Dorfman is Professor of Chemical Engineering and Materials Science at the University of Minnesota. He is a recipient of the Colburn Award of the American Institute of Chemical Engineers, the Defense Advanced Research Projects Agency Young Investigator Award, a Packard Fellowship, the National Science Foundation CAREER Award, and both the Dreyfus New Faculty and Teacher-Scholar Awards. He has co-authored over 100 papers.
Dorfman and Daoutidis
9781107135116 Dorfman & Daoutidis PPC C M Y K
“… a welcome addition to the undergraduate chemical engineering textbook literature.”
Designed primarily for undergraduates, but also graduates and practitioners, this textbook integrates numerical methods and programming with applications from chemical engineering. Combining mathematical rigor with an informal writing style, it thoroughly introduces the theory underlying numerical methods, its translation into MATLAB programs, and its use for solving realistic problems. Specific topics covered include accuracy, convergence and numerical stability, as well as stiffness and ill-conditioning. MATLAB codes are developed from scratch, and their implementation is explained in detail, all while assuming limited programming knowledge. All scripts employed are downloadable, and built-in MATLAB functions are discussed and contextualized. Numerous examples and homework problems - from simple questions to extended case studies - accompany the text, allowing students to develop a deep appreciation for the range of real chemical engineering problems that can be solved using numerical methods. This is the ideal resource for a single-semester course on numerical methods, as well as other chemical engineering courses taught over multiple semesters.
Mathematical Modelling and Simulation in Chemical Engineering
Numerical Methods with Chemical Engineering Applications
M. Chidambaram Indian Institute of Technology, Madras
Kevin D. Dorfman University of Minnesota
A useful guide explaining principles of mathematical modelling with a focus on useful case studies. It offers detailed discussion on model development of simple and complex systems, sensitivity analysis and optimization methods. Numerous review questions and MATLAB/Scilab problems make it beneficial to students.
Prodromos Daoutidis University of Minnesota
Contents
List of tables; List of figures; Preface; 1. Introduction to mathematical modelling; 2. Model development for simple systems; 3. Model development for complex systems; 4. Analytical solutions of model equations; 5. Numerical solutions of model equations; 6. Modelling and simulation: case studies; 7. Discrimination of mathematical models; 8. Sensitivity analysis; 9. Optimization methods; 10. Simulation using MATLAB/Scilab; 11. Model based control; References; Index.
£69.99 | $89.99 | Hardback | 9781108470407 March 2018 | 234 x 191 mm | 380pp
Aimed primarily at chemical engineering undergraduates, this textbook covers the theory underlying numerical methods, its translation into MATLAB programs, and its use for solving realistic problems. Mathematically rigorous, yet accessible and assuming limited programming knowledge, it includes numerous examples and end-of-chapter homework problems, and is accompanied by an online solutions manual and downloadable MATLAB code. Contents
1. Mathematical modeling and structured programming; 2. Linear algebraic equations; 3. Nonlinear algebraic equations; 4. Initial value problems; 5. Dynamical systems; 6. Boundary value problems; 7. Partial differential equations; 8. Interpolation and integration; Appendix A. MATLAB tutorial; Appendix B. Determinant of a matrix.
£71.99 | $89.99 | Hardback | 9781107135116 January 2017 | 253 x 195 x 28 mm | 135 b/w illus. 12 tables | 511pp
Order online at cambridge.org/BioChem
DEEN
s in hould will
Biomedical and Chemical Engineering Books 2018
5
WILLIAM M. DEEN
s
gineers,
th
nd .
I NTRO DUC TI O N TO
ncepts, t is the
C H EM IC AL E NG I N E E R I NG FLU I D M EC HAN IC S
e of e , eds,
ng w,
I NTRODUC TION TO
CHEMIC AL E NGINE E RING FLUID MECHANIC S C A M BR IDGE SER IE S I N CH EMIC A L ENGI N EER I NG
Introduction to Chemical Engineering Fluid Mechanics William M. Deen Massachusetts Institute of Technology Series: Cambridge Series in Chemical Engineering
Designed for introductory undergraduate courses in fluid mechanics for chemical engineers, this textbook illustrates the fundamental concepts and analytical strategies using a range of modern applications and worked examples. It includes traditional design calculations and guidance on predicting the flow properties of novel devices and systems. Contents
Preface; Table of contents; Lists of symbols. Part I. Use of Experimental Data: 1. Properties, dimensions, and scales; 2. Pipe flow: friction factor and pressure drop; 3. Drag, particles, and porous media. Part II. Fundamentals of Fluid Dynamics: 4. Fluid statics: pressure, gravity, and surface tension; 5. Fluid kinematics; 6. Stress and momentum. Part III. Microscopic Analysis: 7. Unidirectional flow; 8. Approximations for viscous flows; 9. Laminar flow with inertia; 10. Turbulent flow. Part IV. Macroscopic Analysis: 11. Macroscopic balances for mass, momentum, and energy; 12. Pipe flow: entrance effects, fittings, and compressibility; Appendix A. Vectors, tensors, and coordinate systems.
£64.99 | $125.00 | Hardback | 9781107123779 October 2016 | 254 x 180 x 23 mm | 192 b/w illus. 24 tables | 392pp
Thermodynamics with Chemical Engineering Applications Elias I. Franses Purdue University, Indiana Series: Cambridge Series in Chemical Engineering
Master the principles of thermodynamics, and understand their practical real-world applications, with this undergraduate textbook, developed to provide students of chemical engineering and chemistry with a deep, intuitive understanding. Includes over 500 openended study questions, over 150 homework problems, clear standards for measuring student progress, and password-protected solutions for instructors. Contents
1. Introduction and synopsis; 2. Problems and concepts at the interface of mechanics and thermodynamics; 3. Phases, interfaces, dispersions, and the first three principles of thermodynamics; 4. Internal energy, the First Law, heat, conservation of total energy; 5. Equations of state for one-component and multicomponent systems; 6. Applications of the mass and energy balances and the equations of state to several classes of thermodynamic problems; 7. The Second Law, absolute temperature, entropy definition and calculation, and entropy inequality; 8. Further implications of the Second Law. Introduction of Helmholtz free energy, Gibbs free energy, chemical potential, and applications to phase equilibria, heat transfer and mass transfer; 9. Thermodynamic fugacity, thermodynamic activity, and other thermodynamic functions (U, H, S, A, G, μi) of ideal and nonideal solutions; 10. Vapor-liquid equilibria (VLE) with applications to distillation; 11. Gas-liquid equilibria (GLE) and applications to gas absorption or desorption; 12. Applications to liquid-liquid equilibria and liquid-liquid extraction; 13. Osmosis, osmotic pressure, osmotic equilibrium, and reverse osmosis; 14. Third Law and molecular basis of the Second and Third Laws; 15. Some special implications and applications of the First and Second Laws; 16. Chemical reaction equilibria: one reaction; 17. Chemical reaction equilibria: two or more reactions occurring simultaneously; 18. Applications of thermodynamics to energy engineering and environmental engineering.
£77.00 | $132.00 | Hardback | 9781107069756 October 2014 | 255 x 192 x 26 mm | 466pp
Order online at cambridge.org/BioChem
6
Biomedical and Chemical Engineering Books 2018
With this unique and comprehensive text, readers will gain the quantitative tools needed to engineer the particulate processes and products that are ubiquitous in modern life. Covering a series of particle and particulate delivery form design processes, with emphasis on design and operation to control particle attributes, and supported by many worked examples, it is essential reading for students and practitioners. Topics covered include a range of particle design processes such as crystallization and precipitation, granulation, grinding, aerosol processes, and spray drying, as well as forms of delivery such as granules, tablets, dry powders, and aerosols. Readers will learn from real-world examples how the primary particle properties and the structure and properties of the delivery form can lead to high-performance products, ranging from pharmaceuticals, consumer goods and foods, to specialty chemicals, paints, agricultural chemicals, and minerals. Jim Litster is Professor of Chemical and Pharmaceutical Engineering at the University of Sheffield. His research area is Particulate Products and Processes, and he is an international leading expert on wet granulation with over 30 years of experience in the field. In recognition of his contribution to the field, he was elected a Fellow of the Australian Academy of Technological Sciences and Engineering in 2010, was awarded the Thomas Barron Award in Fluid–Particle Systems from the American Institute of Chemical Engineers in 2012, and the Pharmaceutical Discovery, Development and Manufacturing Forum Award from the American Institute of Chemical Engineers in 2015.
Design and Processing of
Design and Processing of PARTICULATE PRODUCTS
Gasification, Reforming, and Chemical Syntheses
JIM LITSTER
LITSTER
9781107007376 Lister PPC C M Y K
CHEMICAL LOOPING PARTIAL OXIDATION
PARTICULATE PRODUCTS
LIANG-SHIH FAN Cover designed by Zoe Naylor
Chemical Looping Partial Oxidation
Design and Processing of Particulate Products
Gasification, Reforming, and Chemical Syntheses
Jim Litster University of Sheffield
Liang-Shih Fan Ohio State University The first comprehensive guide to the principles and techniques of chemical looping partial oxidation, written by a pioneer in the field. With detailed coverage of metal oxide development, reactor design, and process systems analysis, it is ideal for researchers, professionals and students in chemical, energy, and environmental engineering.
Winner, 2017 Choice Award for Outstanding Academic Title
A unique text providing comprehensive coverage of fundamental particle science, processing and technology. Including quantitative tools, real-world case studies and end-of-chapter problems, it is ideal for students in engineering and applied sciences, as well as for practitioners in a range of industries manufacturing particulate products. Contents
1. Overview; 2. Metal oxide oxygen carriers; 3. Oxidative coupling of methane; 4. Syngas generation; 5. Catalytic metal oxide and applications; 6. Process simulations and technoeconomic analyses.
1. Introduction; 2. Particle characterization and particle property distributions; 3. The population balance; 4. Crystallization and precipitation; 5. Particle size reduction; 6. Aerosol processes; 7. Spray drying and spray cooling; 8. Wet granulation; 9. Strength, breakage and attrition of particulate delivery forms; 10. Dispersion, disintegration and dissolution.
£99.99 | $125.00 | Hardback | 9781107194397
£64.99 | $99.99 | Hardback | 9781107007376
October 2017 | 253 x 178 x 26 mm | 470pp
December 2016 | 257 x 180 x 20 mm | 157 b/w illus. 38 tables | 340pp
Contents
Order online at cambridge.org/BioChem
Biomedical and Chemical Engineering Books 2018
Roger-Marc Nicoud is the founder and former CEO of Novasep, which has installed over 2000 chromatographic units worldwide and pioneered the use of large-scale continuous chromatographic processes in the life science industry. He is President of École Nationale Supérieure des Industries Chimiques (ENSIC), and in 2014, founded Ypso-Facto (www.ypsofacto.com).
CHROMATOGRAPHIC PROCESSES
Bubble and Foam Chemistry
With an emphasis on real-world problems and applications, stepby-step modeling design guidelines, and detailed exercises for selfassessment, this is a must-have guide for practitioners and researchers working in chemical, biochemical, food, and pharmaceutical engineering.
Bubble and Foam Chemistry
NICOUD
9781107082366 Nicoud PPC C M Y K
Robert J. Pugh
Addressing all aspects of the design, modeling, and simulation of chromatographic processes, this result-oriented primer provides a practical guide to all the necessary approaches, methodologies, and tools. Beginning with key definitions and concepts, it builds up from the simplest to the most complex situations, including multicomponent systems, non-uniform velocity profiles, bed instability, particle size distributions, and the influence of complex environments on chromatographic process design. In addition to covering classical approaches, it introduces efficient tools for investigating chromatographic processes, such as the “Russian-Lego” approach for linear systems, phenomenological models, and specific shortcuts for deriving the key properties of industrial processes.
7
Roger-Marc Nicoud
CHROMATOGRAPHIC PROCESSES Modeling, Simulation, and Design
Robert J. Pugh
Bubble and Foam Chemistry
Chromatographic Processes
Robert J. Pugh Nottingham Trent University
Modeling, Simulation, and Design Roger-Marc Nicoud Ypso-Facto, Nancy, France
Combining academic and industrial viewpoints, this is the definitive stand-alone resource for researchers, students and industrialists. With the latest on foam research, test methods and realworld applications, it provides straightforward answers to why foaming occurs, how it can be avoided, and how different degrees of antifoaming can be achieved. Contents
This result-oriented primer provides a practical guide to key approaches, methodologies and tools for designing, modelling and simulating chromatographic processes. With an emphasis on real-world applications, this is a must-have for practitioners and researchers working in chemical, biochemical, food and pharmaceutical engineering.
Preface; Symbols; 1. Basic principles and concepts; 2. The nature and properties of foaming surfactants; 3. Soap bubbles and foam films; 4. Processes in foaming; 5. The generation of bubbles and foams; 6. The coalescence of bubbles in surfactant solutions; 7. The stability/instability of bubbles and foams; 8. Particle stabilized bubbles and foams; 9. Foaming in non aqueous liquids; 10. Antifoaming and defoaming; 11. Bubble size measurements and foam test methods; 12. Developments in foam research.
Contents
£59.99 | $94.99 | Hardback | 9781107090576
£98.00 | $154.00 | Hardback | 9781107082366
September 2016 | 252 x 180 x 23 mm | 307 b/w illus. 7 tables | 444pp
April 2015 | 254 x 182 x 34 mm | 163 b/w illus. | 672pp
1. An approach to modeling chromatographic processes; 2. Linear chromatography: the Russian Lego; 3. Nonlinear chromatography: equilibrium theory; 4. Fluid-solid phase equilibria; 5. Mass transfer; 6. Hydrodynamics of chromatographic columns; 7. Simulating chromatographic columns; 8. Counter-current systems; 9. Presentation of chromatographic modes and their optimization; 10. Addressing a few industrial problems; 11. Conclusion.
Order online at cambridge.org/BioChem
8
Biomedical and Chemical Engineering Books 2018
GET FUNDED
Arthur McClelland and Max Mankin
An Insider’s Guide to Building An Academic Research Program
ROBERT J. TRE W
OPTICAL MEASUREMENTS FOR SCIENTISTS AND ENGINEERS A PRACTICAL GUIDE
Get Funded An Insider’s Guide to Building An Academic Research Program
Optical Measurements for Scientists and Engineers A Practical Guide
Robert J. Trew North Carolina State University
Arthur McClelland Harvard University, Massachusetts
Learn the key principles involved in building an externally funded research program and understand the intricacies of the funding process with this practical guide. Including step-by-step advice on how to build successful relationships with program managers, it is ideal for new faculty members in engineering, the sciences and mathematics.
Max Mankin Harvard University, Massachusetts
Contents
1. Introduction; 2. A brief history of research funding in the United States; 3. The academic recruitment process: position announcement through performance reviews; 4. Getting started and marketing your research; 5. Know where the money is; 6. Making contact and communicating with program managers and program directors; 7. The proposal; 8. Cautions and other concerns; 9. You’re on your way
An accessible, introductory text explaining how to select and use optical spectroscopy and microscopy techniques. Providing step-by-step instructions, practical lab tips, and descriptions of common optical components, this comprehensive resource is ideal for graduate students, researchers and professionals who use or teach optical measurements. Contents
1. Introduction; 2. Introduction to common optical components; 3. Spectroscopy; 4. Optical imaging; 5. Notes on how to design and build optical setups in the lab; 6. Appendices.
£25.99 | $32.99 | Paperback | 9781107657199
£69.99 | $89.99 | Hardback | 9781107173019
April 2017 | 235 x 157 x 21 mm | 290pp
April 2018 | 246 x 189 mm | 224 b/w illus. 6 tables | 320pp
Order online at cambridge.org/BioChem
The new home of academic content Bringing together over 34,000 ebooks and 380 journals Fast, intuitive user-centric design Fully responsive Powerful search functionality
cambridge.org/core
S I G N U P TO
Cambridge Alerts for regular updates and to receive 20% off your next online purchase
www.cambridge.org/alerts
For information about our privacy and data protection policy, please visit: http://uk.cambridge.org/privacy