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Nanomaterial Characterization Providing various properties of nanomaterials and the various methods available for their characterization
Over the course of the last few decades, research activity on nanomaterials has gained considerable press coverage. The use of nanomaterials has meant that consumer products can be made lighter, stronger, esthetically more pleasing, and less expensive. The significant role of nanomaterials in improving the quality of life is clear, resulting in faster computers, cleaner energy production, target-driven pharmaceuticals, and better construction materials. It is not surprising, therefore, that nanomaterial research has really taken off, spanning across different scientific disciplines from material science to nanotoxicology. A critical part of any nanomaterial research, however, is the need to characterize physicochemical properties of the nanomaterials, which is not a trivial matter.
Nanomaterial Characterization: An Introduction is dedicated to understanding the key physicochemical properties and their characterization methods. Each chapter begins by giving an overview of the topic before a case study is presented. The purpose of the case study is to demonstrate how the reader may make use of the background information presented to them and show how this can be translated to solve a nanospecific application scenario. Thus, it will be useful for researchers in helping them design experimental investigations. The book begins with a general overview of the subject, thus giving the reader a solid foundation to nanomaterial characterization.
Nanomaterial Characterization: An Introduction features:
Methods to handle and visualize multidimensional nanomaterial characterization data
The book is written in such a way that both students and experts in other fields of science will find the information useful, whether they are in academia, industry, or regulation, or those whose analytical background may be limited.There is also an extensive list of references associated with every chapter to encourage further reading.
Auteur
Ratna Tantra is a Senior Scientist at National Physical Laboratory (NPL), UK. She has been at NPL for 14 years and worked on numerous projects in the field of nanoscience. Her multidisciplinary background was useful, allowing an expansion of her research portfolio in the area of nanomaterial characterization in different scientific disciplines, for example, surface-enhanced Raman spectroscopy and nanotoxicology. Before joining NPL, she was a research associate at Imperial College London, then University of Glasgow. She got her PhD in electrochemistry from University College London. She is a Chartered Scientist, Chartered Chemist, and member of the Royal Society of Chemistry.
Contenu
List of Contributors xv
Editor's Preface xix
1 Introduction 1
1.1 Overview 1
1.2 Properties Unique to Nanomaterials 3
1.3 Terminology 4
1.3.1 Nanomaterials 4
1.3.2 Physicochemical Properties 7
1.4 Measurement of Good Practice 8
1.4.1 Method Validation 8
1.4.2 Standard Documents 13
1.5 Typical Methods 16
1.5.1 Sampling 16
1.5.2 Dispersion 19
1.6 Potential Errors Due to Chosen Methods 20
1.7 Summary 20
Acknowledgments 21
References 21
2 Nanomaterial Syntheses 25
2.1 Introduction 25
2.2 Bottom-Up Approach 26
2.2.1 Arc-Discharge 26
2.2.2 Inert-Gas Condensation 26
2.2.3 Flame Synthesis 27
2.2.4 Vapor-Phase Deposition 27
2.2.5 Colloidal Synthesis 27
2.2.6 Biologically synthesized nanomaterials 28
2.2.7 Microemulsion Synthesis 28
2.2.8 Sol-Gel Method 29
2.3 Synthesis: Top-Down Approach 29
2.3.1 Mechanical Milling 29
2.3.2 Laser Ablation 30
2.4 Bottom-Up and Top-Down: Lithography 30
2.5 Bottom-Up or Top-Down? Case Example: Carbon Nanotubes (CNTs) 30
2.6 Particle Growth: Theoretical Considerations 32
2.6.1 Nucleation 32
2.6.2 Particle Growth and Growth Kinetics 33
2.6.2.1 Diffusion-Limited Growth 33
2.6.2.2 Ostwald Ripening 34
2.7 Case Study: Microreactor for the Synthesis of Gold Nanoparticles 34
2.7.1 Introduction 34
2.7.2 Method 36
2.7.2.1 Materials 36
2.7.2.2 Protocol: Nanoparticles Batch Synthesis 37
2.7.2.3 Protocol: Nanoparticle Synthesis via Continuous Flow Microfluidics 37
2.7.2.4 Protocol: Nanoparticles Synthesis via Droplet-Based Microfluidics 38
2.7.2.5 Protocol: Dynamic Light Scattering 38
2.7.3 Results Interpretation and Conclusion 39
2.8 Summary 42
Acknowledgments 43
References 43
3 Reference Nanomaterials 49
3.1 Definition, Development, and Application Fields 49
3.2 Case Studies 50
3.2.1 Silica Nanomaterial as Potential Reference Material to Establish Possible Size Effects on Mechanical Properties 50
3.2.1.1 Introduction 50
3.2.1.2 Findings So Far 53
3.2.2 Silica Nanomaterial as Potential Reference Material in Nanotoxicology 55
3.3 Summary 57
Acknowledgments 58
References 58
4 Particle Number Size Distribution 63
4.1 Introduction 63
4.2 Measuring Methods 65
4.2.1 Particle Tracking Analysis 65
4.2.2 Resistive Pulse Sensing 67
4.2.3 Single Particle Inductively Coupled Plasma Mass Spectrometry 69
4.2.4 Electron Microscopy 71
4.2.5 Atomic Force Microscopy 73
4.3 Summary of Capabilities of the Counting Techniques 74
4.4 Experimental Case Study 74
4.4.1 Introduction 74
4.4.2 Method 76
4.4.3 Results and Interpretation 76
4.4.4 Conclusion 77
4.5 Summary 78
References 78
5 Solubility Part 1: Overview 81
5.1 Introduction 82
5.2 Separation Methods 84
5.2.1 Filtration, Centrifugation, Dialysis, and Ultrafiltration 84
5.2.2 Ion Exchange 85
5.2.3 High-Performance Liquid Chromatography, Electrophoresis, Field Flow Fractionation 87
5.3 Quantification Methods: Free Ions (And Labile Fractions) 90
5.3.1 Electrochemical Methods 90
5.3.2 Colorimetric Methods 93
5.4 Quantification Methods to Measure Total Dissolved Species 94
5.4.1 Indirect Measurements 94
5.4.2 Direct Measurements 95
5.5 Theoretical Modeling Using Speciation Software 96
5.6 Which Method? 97
5.7 Case Study: Miniaturized Capillary Electrophoresis with Conductivity Detection to Determine Nanomaterial Solubility 99
5.7.1 Introduction 99
5.7.2 Method 100
5.7.2.1 Materials 100
5.7.2.2 Dispersion Protocol 100
5.7.2.3 Instrumentation: CE-Conductivity Device 100
5.7.2.4 CE-Conductivity Microchip: Measurement Protocol 101
5.7.2.5 Protocol: To Assess the Feasibility of Measuring the Zn2+ (from ZnO Nanomaterial) Signal above the Fish Medium Background 102
5.7.2.6 Protocol: To Assess Data Variability between Different Microchips 102
5.7.3 Results and Interpretation 103
5.7.3.1 Study 1: Assessing Feasibility of the CE-Conductivity Microchip to Detect Free Zn2+ Arising from Dispersion of ZnO in Fish Medium 103
5.7.3.2 Study 2: Assessing Performance of Microchips Using Reference Test Material 103
5.7.4 Conclusion 105
5.8 Summary 105
Acknowledgments 105
References 106
6 Solubility Part 2: Colorimetry 117
6.1 Introduction 117
6.2 Materials and Method 119
6.2.1 Materials 119
6.2.2 Mandatory Protocol: NanoGenotox Dispersion for Nanomaterials 119
6.2.3 Mandatory Protocol: Simulated In Vitro Digestion Model 120
6.2.4 Colorimetry Analysis 121
6.2.5 SEM Analysis 122
6.3 Results and Interpretation 123
6.4 Conclusion 127
Acknowledgments 128
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