London, : Imperial College Press, c2010

1-282-76003-3

9786612760037

1-84816-468-8

1 online resource (423 p.)

KirbyA. R

GunningA. P

570.282

Atomic force microscopy

Biology - Technique

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

CONTENTS; Acknowledgements; CHAPTER 1 AN INTRODUCTION; CHAPTER 2 APPARATUS; 2.1. The atomic force microscope; 2.2. Piezoelectric scanners; 2.3. Probes and cantilevers; 2.3.1. Cantilever geometry; 2.3.2. Tip shape; 2.3.3. Tip functionality; 2.4. Sample holders; 2.4.1. Liquid cells; 2.5. Detection methods; 2.5.1. Optical detectors: laser beam deflection; 2.5.2. Optical detectors: interferometry; 2.5.3. Electrical detectors: electron tunneling; 2.5.4. Electrical detectors: capacitance; 2.5.5. Electrical detectors: piezoelectric cantilevers; 2.6. Control systems; 2.6.1. AFM electronics

2.6.2. Operation of the electronics 2.6.3. Feedback control loops; 2.6.4. Design limitations; 2.6.5. Enhancing the performance of large scanners; 2.7. Vibration isolation: thermal and mechanical; 2.8. Calibration; 2.8.1. Piezoelectric scanner non-linearity; 2.8.2. Tip related factors: convolution; 2.8.3. Calibration standards; 2.8.4. Tips for scanning a calibration specimen; 2.9. Integrated AFMs; 2.9.1. Combined AFM-light microscope (AFM-LM); 2.9.2. 'Submarine' AFM - the combined AFM - Langmuir Trough; 2.9.3. Combined AFM-surface plasmon resonance (AFM-SPR); 2.9.4. Cryo-AFM; References

Useful information sources CHAPTER 3 BASIC PRINCIPLES; 3.1. Forces;

3.1.1. The Van der Waals force and force-distance curves; 3.1.2. The electrostatic force; 3.1.3. Capillary and adhesive forces; 3.1.4. Double layer forces; 3.2. Imaging modes; 3.2.1. Contact dc mode; 3.2.2. Ac modes: Tapping and non-contact; Tapping in air; Tapping under liquid; True, non-contact ac mode; Tuning the cantilever; Influence of drive frequency; 3.2.3. Deflection mode; 3.3. Image types; 3.3.1. Topography; 3.3.2. Frictional force; 3.3.3. Phase; 3.4. Substrates; 3.4.1. Mica; 3.4.2. Glass; 3.4.3. Graphite

3.5. Common problems 3.5.1. Thermal drift; 3.5.2. Multiple tip effects; 3.5.3. The 'pool' artifact; 3.5.4. Optical interference on highly reflective samples; 3.5.5. Sample roughness; 3.5.6. Sample mobility; 3.5.7. Imaging under liquid; 3.6. Getting started; 3.6.1. DNA; 3.6.2. Troublesome large samples; 3.7. Image optimisation; 3.7.1. Grey levels and colour tables; 3.7.2. Brightness and contrast; 3.7.3. High and low pass filtering; 3.7.4. Normalisation and plane fitting; 3.7.5. Despike; 3.7.6. Fourier filtering; 3.7.7. Correlation averaging; 3.7.8. Stereographs and anaglyphs

3.7.9. Do your homework! References; CHAPTER 4 MACROMOLECULES; 4.1. Imaging methods; 4.1.1. Tip adhesion, molecular damage and displacement; 4.1.2. Depositing macromolecules onto substrates; 4.1.3. Metal coated samples; 4.1.4. Imaging in air; 4.1.5. Imaging under non-aqueous liquids; 4.1.6. Binding molecules to the substrate; 4.1.7. Imaging under water or buffers; 4.2. Nucleic acids: DNA; 4.2.1. Imaging DNA; 4.2.2. DNA conformation, size and shape; 4.2.3. DNA-protein interactions; 4.2.4. Location and mapping of specific sites; 4.2.5. Chromosomes; 4.3. Nucleic acids: RNA; 4.4. Polysaccharides

4.4.1. Imaging polysaccharides

Atomic force microscopy (AFM) is part of a range of emerging microscopic methods for biologists which offer the magnification range of both the light and electron microscope, but allow imaging under the ""natural"" conditions usually associated with the light microscope. To biologists, AFM offers the prospect of high resolution images of biological material, images of molecules and their interactions even under physiological conditions, and the study of molecular processes in living systems. This book provides a realistic appreciation of the advantages and limitations of the technique and the