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Contents |
6 |
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1 Chemical and Physical Effects of Acoustic Bubbles |
8 |
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1.1 Characteristics of Acoustic Bubbles |
9 |
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1.2 Calorimetry for Ultrasound Power Measurement |
11 |
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1.3 Chemical Effects of Acoustic Cavitation in Water |
13 |
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1.4 Relationship Between Ultrasound Power and Sonochemical Reaction |
16 |
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1.5 Relationship Between Ultrasound Frequency and Sonochemical Reaction |
18 |
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1.6 Reactions of Organic Additives with OH Radicals in Aqueous Solution |
19 |
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1.7 Chemical Effects of Acoustic Cavitation in Organic Solvents |
20 |
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1.8 Physical Effects of Acoustic Cavitation |
21 |
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References |
22 |
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2 Synthesis of Metal Nanomaterials with Chemical and Physical Effects of Ultrasound and Acoustic Cavitation |
25 |
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2.1 Pyrolysis Technique Using High-Temperature Bubbles |
25 |
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2.2 Reduction Technique Using Sonochemically Formed Reductants |
28 |
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2.3 Ultrasound-Assisted Technique |
34 |
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2.4 Sonomechanical-Assisted Metal Displacement Reduction Technique |
36 |
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2.5 Sonoelectrochemical Technique |
37 |
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2.6 Ultrasound Spray Pyrolysis Technique |
39 |
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References |
41 |
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3 Synthesis of Micro-nanoparticles Using Ultrasound-Responsive Biomolecules |
44 |
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3.1 Introduction |
44 |
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3.2 Ultrasonic Synthesis and Assembly of Protein-Shelled Microbubbles and Microcapsules |
45 |
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3.2.1 The Echogenic Properties of Lysozyme Microbubbles |
47 |
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3.3 Synthesis of Nanoparticles Using Ultrasound-Responsive Phenolic Molecules |
51 |
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References |
65 |
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