Acoustic microscopy : fundamentals and applications / / Roman Gr. Maev |
Autore | Maev R. G (Roman Grigor'evich) |
Pubbl/distr/stampa | Weinheim, [Germany] : , : Wiley-VCH Verlag GmbH & Co. KGaA, , 2008 |
Descrizione fisica | 1 online resource (293 p.) |
Disciplina | 502.82 |
Soggetto topico | Acoustic microscopy |
Soggetto genere / forma | Electronic books. |
ISBN |
1-281-94713-X
9786611947132 3-527-62313-2 3-527-62314-0 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Acoustic Microscopy; Contents; Foreword; Preface; Introductory Comments; Introduction; 1 Scanning Acoustic Microscopy. Physical Principles and Methods. Current Development; 1.1 Basics of Acoustic Wave Propagation in Condensed Media; 1.2 Physical Principles of Scanning Acoustic Microscopy; 1.3 Acoustic Imaging Principles and Quantitative Methods of Acoustic Microscopy; 1.4 Methodological Limitations of Acoustic Microscopy; 2 Acoustic Field Structure in a Lens System of a Scanning Acoustic Microscope
2.1 Calculation of the Focal Area Structure with Due Regard for Aberrations and Absorption in a Medium2.2 The Field of a Spherical Focusing Transducer with an Arbitrary Aperture Angle; 2.3 Analysis of Acoustic Field Spatial Structure with a Spherical Acoustic Transducer; 2.4 Experimental Study of the Focal Area Structure of a Transmission Acoustic Microscope; 2.5 Formation of a Focused Beam of Bulk Acoustic Waves by a Planar System of Transducers; 2.6 About the Possibility of Using Scholte-Stoneley Waves for Surface Waves' Acoustic Microscopy 3 Output Signal Formation in a Transmission Raster Acoustic Microscope3.1 Outline of the Problem; 3.2 Transmission Acoustic Microscope: Formation of the Output Signal as a Function of Local Properties of Flat Objects. General Concepts; 3.3 General Representation of the Output Signal of the Transmission Acoustic Microscope; 3.4 Formation of the A(z) Dependence for Objects with a Small Shear Modulus; 4 Quantitative Acoustic Microscopy Based on Lateral Mechanical Scanning; 4.1 Methods of Quantitative Ultrasonic Microscopy with Mechanical Scanning: Review 4.2 Ray Models of V (z) and V (x) QSAM Systems4.3 Wave Theory of V (z) and V (x) QSAM Systems; 4.4 Angular Resolution of QSAM Systems; 4.5 Application of the V (x) QSAM System to LSAW Measurement; 4.6 Temperature Stability of the V (x) QSAM System; 5 Acoustic Microscopy and Nonlinear Acoustic Effects; 5.1 Nonlinear Acoustic Applications for Characterization of Material Microstructure; 5.1.1 Schematic of Experiment; 5.1.2 Visualization by Nonlinear Acoustic Methods; 5.1.3 Parametric Representation of Acoustic Nonlinearity 5.2 Peculiarities of Nonlinear Acoustic Effects in the Focal Area of an Acoustic Microscope5.3 Temperature Effects in the Focal Area of an Acoustic Microscope; 5.4 Effects of Radiation Pressure on Samples Examined with an Acoustic Microscope; 5.5 The Theory of Modulated Focused Ultrasound Interaction with Microscopic Entities; 5.5.1 Shell Model of a Cell; 5.5.2 Interaction of a Cell with a High-Frequency Field within the Framework of the Shell Model. Equation for the Radiation Force; 5.5.3 Oscillations of a Microparticle under the Action of a Nonlinear Force 6 Investigation of the Local Properties and Microstructure of Model Systems and Composites by the Acoustic Microscopy Methods |
Record Nr. | UNINA-9910144101003321 |
Maev R. G (Roman Grigor'evich) | ||
Weinheim, [Germany] : , : Wiley-VCH Verlag GmbH & Co. KGaA, , 2008 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|
Acoustic microscopy : fundamentals and applications / / Roman Gr. Maev |
Autore | Maev R. G (Roman Grigor'evich) |
Pubbl/distr/stampa | Weinheim, [Germany] : , : Wiley-VCH Verlag GmbH & Co. KGaA, , 2008 |
Descrizione fisica | 1 online resource (293 p.) |
Disciplina | 502.82 |
Soggetto topico | Acoustic microscopy |
ISBN |
1-281-94713-X
9786611947132 3-527-62313-2 3-527-62314-0 |
Formato | Materiale a stampa |
Livello bibliografico | Monografia |
Lingua di pubblicazione | eng |
Nota di contenuto |
Acoustic Microscopy; Contents; Foreword; Preface; Introductory Comments; Introduction; 1 Scanning Acoustic Microscopy. Physical Principles and Methods. Current Development; 1.1 Basics of Acoustic Wave Propagation in Condensed Media; 1.2 Physical Principles of Scanning Acoustic Microscopy; 1.3 Acoustic Imaging Principles and Quantitative Methods of Acoustic Microscopy; 1.4 Methodological Limitations of Acoustic Microscopy; 2 Acoustic Field Structure in a Lens System of a Scanning Acoustic Microscope
2.1 Calculation of the Focal Area Structure with Due Regard for Aberrations and Absorption in a Medium2.2 The Field of a Spherical Focusing Transducer with an Arbitrary Aperture Angle; 2.3 Analysis of Acoustic Field Spatial Structure with a Spherical Acoustic Transducer; 2.4 Experimental Study of the Focal Area Structure of a Transmission Acoustic Microscope; 2.5 Formation of a Focused Beam of Bulk Acoustic Waves by a Planar System of Transducers; 2.6 About the Possibility of Using Scholte-Stoneley Waves for Surface Waves' Acoustic Microscopy 3 Output Signal Formation in a Transmission Raster Acoustic Microscope3.1 Outline of the Problem; 3.2 Transmission Acoustic Microscope: Formation of the Output Signal as a Function of Local Properties of Flat Objects. General Concepts; 3.3 General Representation of the Output Signal of the Transmission Acoustic Microscope; 3.4 Formation of the A(z) Dependence for Objects with a Small Shear Modulus; 4 Quantitative Acoustic Microscopy Based on Lateral Mechanical Scanning; 4.1 Methods of Quantitative Ultrasonic Microscopy with Mechanical Scanning: Review 4.2 Ray Models of V (z) and V (x) QSAM Systems4.3 Wave Theory of V (z) and V (x) QSAM Systems; 4.4 Angular Resolution of QSAM Systems; 4.5 Application of the V (x) QSAM System to LSAW Measurement; 4.6 Temperature Stability of the V (x) QSAM System; 5 Acoustic Microscopy and Nonlinear Acoustic Effects; 5.1 Nonlinear Acoustic Applications for Characterization of Material Microstructure; 5.1.1 Schematic of Experiment; 5.1.2 Visualization by Nonlinear Acoustic Methods; 5.1.3 Parametric Representation of Acoustic Nonlinearity 5.2 Peculiarities of Nonlinear Acoustic Effects in the Focal Area of an Acoustic Microscope5.3 Temperature Effects in the Focal Area of an Acoustic Microscope; 5.4 Effects of Radiation Pressure on Samples Examined with an Acoustic Microscope; 5.5 The Theory of Modulated Focused Ultrasound Interaction with Microscopic Entities; 5.5.1 Shell Model of a Cell; 5.5.2 Interaction of a Cell with a High-Frequency Field within the Framework of the Shell Model. Equation for the Radiation Force; 5.5.3 Oscillations of a Microparticle under the Action of a Nonlinear Force 6 Investigation of the Local Properties and Microstructure of Model Systems and Composites by the Acoustic Microscopy Methods |
Record Nr. | UNINA-9910830382103321 |
Maev R. G (Roman Grigor'evich) | ||
Weinheim, [Germany] : , : Wiley-VCH Verlag GmbH & Co. KGaA, , 2008 | ||
Materiale a stampa | ||
Lo trovi qui: Univ. Federico II | ||
|