This book focuses on structural characterisation techniques for porous materials. Covering a range of techniques, including gas sorption, mercury porosimetry, thermoporometry, NMR and imaging methods, this practical guide presents the basic theory behind each characterisation technique, and discusses the practicalities of the experimental and data analysis approaches needed for complex industrial samples. The book shows readers how to approach characterising a particular sort of material for the first time and then how to develop a strategy for more in-depth analysis. It also demonstrates how to determine the best techniques for solving particular problems, and describes methods of obtaining the required information, as well as the limitations of various methods. It particularly highlights a scientific approach involving parameter validation and simple acquisition.
Featuring examples taken from case studies of real-world industrial materials, this book is intended for industrial practitioners and researchers. It provides a manual of potential techniques and answers questions concerning porous materials that arise in areas such as the catalyst industry, the oil and gas sector, batteries, fuel cells, tissue engineering scaffolds and drug delivery devices.
By:
Sean Patrick Rigby
Imprint: Springer Nature Switzerland AG
Country of Publication: Switzerland
Edition: 1st ed. 2020
Dimensions:
Height: 235mm,
Width: 155mm,
Weight: 454g
ISBN: 9783030474201
ISBN 10: 3030474208
Pages: 203
Publication Date: 16 May 2021
Audience:
Professional and scholarly
,
Undergraduate
Format: Paperback
Publisher's Status: Active
Chapter 1: Introduction 1.1 Aims of this book 1.2 Porous materials 1.3 Characterisation science 1.4 What is a pore? 1.5 Void space descriptors 1.6 Structure Chapter 2: Gas sorption 2.1 Basic theory 2.2 Nature of experiment 2.3 What can I find out with this method? 2.4 Conclusions Chapter 3: Mercury porosimetry 3.1 Basic theory 3.2 Nature of experiment 3.3 What can I find out with this method? 3.4 Conclusions Chapter 4: Thermoporometry and Scattering 4.1 Thermoporometry 4.2 Scattering 4.3 Conclusions Chapter 5: NMR and microscopy methods 5.1 Theory of NMR and imaging techniques 5.2 Nature of experiments 5.3 What can I find out with these methods? Chapter 6: Hybrid methods 6.1 Background 6.2 Utilisation of network effects in pore characterisation 6.3 Combined mercury porosimetry and thermoporometry 6.4 Integrated gas sorption and mercury porosimetry 6.5 Combined MRI and gas sorption 6.6 Combined CXT and gas adsorption 6.7 Integrated NMR cryodiffusometry and relaxometry, combined with gas sorption 6.8 Combined CXT and liquid metal intrusion 6.9 Serial gas sorption with different adsorptives 6.10 Scattering methods and mercury porosimetry 6.11 Combined CXT, MRI and mercury porosimetry 6.12 Conclusions Chapter 7: Structural characterisation in absorbent and catalyst design 7.1 Special considerations for industrial materials 7.2 Relating pore structure to raw material properties and fabrication method 7.3 Relating mass transport to pore structure 7.4 Understanding product activity and selectivity 7.5 Conclusions Chapter 8: Structural characterisation in engineering geology 8.1 Special considerations for natural porous systems 8.2 Predicting permeability, reservoir producibility and bound volume index 8.3 Characterising multi-scale, hierarchical porous structures 8.4 Conclusions
Dr. Sean Patrick Rigby completed his Ph.D. at the University of Cambridge. He then worked as a Product Research Manager and Process Engineer for ICI Synetix (formerly Katalco) for four years, where he developed new adsorbents and managed the Catalyst Characterisation laboratory. Dr Rigby then moved to the University of Bath, UK, where he worked as an academic for ten years, before moving to the University of Nottingham, where he is currently Professor of Chemical Engineering and Director of the GeoEnergy Research Centre. Dr. Rigby is a Fellow of the IChemE and Chartered Engineer, a Fellow of the Geological Society, and Fellow of IUPAC.
