Description |
1 online resource (321 pages) |
|
text txt rdacontent |
|
computer c rdamedia |
|
online resource cr rdacarrier |
Contents |
ch. 1 Introduction -- ch. 2 Safety -- General Laboratory Procedure -- Personal Safety Equipment -- References -- ch. 3 Common Analytical Techniques for Nanoscale Materials -- Principles of Electron Microscopy -- Transmission Electron Microscopy -- Sample Preparation for Tem -- Scanning Electron Microscopy -- Sample Preparation in Sem -- Scanning Tunnelling Microscopy -- Atomic Force Microscopy -- Powder X-Ray Diffraction -- UV-Visible Spectroscopy -- Dynamic Light Scattering and Zeta Potential MeasurementBet Surface Area Measurement -- References -- ch. 4 Chemical Techniques -- The SOL-GEL Process -- Coating Nanomaterials Using the Sol Gel Method -- Using Sol Gel Dip Coating to form Thin Films, Thin Porous Films and Replicas -- Replication of Oddly Shaped Morphologies Using Sol Gel Techniques -- Mesoporous Inorganic Powders -- Aerogels and Supercritical Drying -- Applications of Aerogels -- Monoliths and Glasses Containing Functional Biological Materials -- Growing Zinc Oxide Nanorods -- Cadmium Sulfide, Selenide and Telluride Quantum Dots -- Making Gold and Silver ColloidsFerrofluids -- Allotropes of Carbon -- Metal Organic Frameworks -- References -- ch. 5 Physical Techniques -- Chemical Vapour Deposition -- Atomic Layer Deposition -- Photolithography Patterning -- Making Wire Tips for Scanning Tunnelling Microscopy -- References -- ch. 6 Biological Nanotechnology -- Cloning and Gene Expression to Produce Proteins in Escherichia Coli -- DNA Origami? -- Keeping Bacteria Long Term in a Glycerol Stock -- Testing the Minimum Inhibitory Concentration of an Antibiotic -- References -- Index. |
Bibliography |
Includes bibliographical references and index. |
Summary |
The peculiarities of materials at the nanoscale demand an interdisciplinary approach which can be difficult for students and researchers who are trained predominantly in a single field. A chemist might not have experience at working with cell cultures or a physicist may have no idea how to make the gold colloid they need for calibrating an atomic force microscope. The interdisciplinary approach of the book will help you to€quickly synthesize information from multiple perspectives. Nanoscience research is also characterized by rapid movement within disciplines. The amount of time it take. |
Note |
Print version record. |
Subject |
Nanostructured materials.
|
|
Nanotechnology -- Experiments.
|
|
Nanoscience.
|
|
Nanoparticles.
|
|
Semiconductors.
|
|
Nanostructures |
|
Nanoparticles |
|
Semiconductors |
|
Nanomatériaux.
|
|
Nanosciences.
|
|
Nanoparticules.
|
|
Semi-conducteurs.
|
|
Nanotechnologie -- Expériences.
|
|
semiconductor.
|
|
TECHNOLOGY & ENGINEERING -- Electronics -- Semiconductors.
|
|
TECHNOLOGY & ENGINEERING -- Electronics -- Solid State.
|
|
Nanoparticles
|
|
Nanoscience
|
|
Nanostructured materials
|
|
Semiconductors
|
Other Form: |
Print version: Collins, Andrew. Nanotechnology Cookbook : Practical, Reliable and Jargon-free Experimental Procedures. Burlington : Elsevier Science, ©2012 9780080971728 |
ISBN |
9780080971728 (electronic bk.) |
|
0080971725 (electronic bk.) |
|
9780080971735 (electronic bk.) |
|
0080971733 (electronic bk.) |
Standard No. |
AU@ 000049617953 |
|
CHBIS 009942997 |
|
CHVBK 303584068 |
|
DEBBG BV042316777 |
|
DEBSZ 368578852 |
|
NZ1 14676295 |
|
NZ1 15192411 |
|