Energy Aspects of Acoustic Cavitation and Sonochemistry
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Energy Aspects of Acoustic Cavitation and Sonochemistry
Fundamentals and Engineering
Kerboua, Kaouther; Hamdaoui, Oualid
Elsevier - Health Sciences Division
08/2022
388
Mole
Inglês
9780323919371
15 a 20 dias
450
Descrição não disponível.
Part I
The single acoustic cavitation
bubble as an energetic system:
qualitative and quantitative
assessments 1
1. Single acoustic cavitation bubble and
energy concentration concept 3
2. The energy forms and energy
conversion 23
3. Physical effects and associated
energy release 35
4. Sonochemical reactions, when, where
and how: Modelling approach 49
5. Sonochemical reactions, when, where
and how: Experimental approach 77
Part II
The bubble population:
an analytic view into mutual
forces and allied energy exchange 97
6. The Bjerknes forces and acoustic
radiation energy 99
7. Nonlinear oscillations and resonances
of the acoustic bubble and the
mechanisms of energy dissipation 109
8. Damping mechanisms of oscillating
gas/vapor bubbles in liquids 131
Part III
Ultrasound assisted processes,
sonochemical reactors and
energy efficiency 155
10. Efficiency assessment and mapping
of cavitational activities in
sonochemical reactors 157
11. Sources of dissipation: An outlook into
the effects of operational conditions 183
12. Mechanistic issues of energy
efficiency of an ultrasonic process:
Role of free and dissolved gas 193
13. Simulation of sonoreators accounting
for dissipated power 219
14. Technological designs and energy
efficiency: The optimal paths 249
Part IV
Green, sustainable and benign
by design process? The place
and perspective of ultrasound
assisted processes and
sonochemistry in industrial
applications based on energy
efficiency 263
15. Acoustic cavitation and sonochemistry
in industry: State of the art 265
16. Crystallization of pharmaceutical
compounds: Process Intensification
using ultrasonic irradiations -
Experimental approach 279
17. Sonochemical degradation of
fluoroquinolone and ss-lactam
antibiotics - A view on
transformations, degradation
efficiency, and consumed energy 287
18. The use of ultrasonic treatment in
technological processes of complex
processing of industrial waste:
Energetic insights 299
19. The sonochemical and ultrasoundassisted
production of hydrogen:
energy efficiency for the generation
of an energy carrier 313
20. Future trends and promising
applications of industrial
sonochemical processes 329
21. Raising challenges of ultrasound-assisted
processes and sonochemistry
in industrial applications based on
energy efficiency 349
The single acoustic cavitation
bubble as an energetic system:
qualitative and quantitative
assessments 1
1. Single acoustic cavitation bubble and
energy concentration concept 3
2. The energy forms and energy
conversion 23
3. Physical effects and associated
energy release 35
4. Sonochemical reactions, when, where
and how: Modelling approach 49
5. Sonochemical reactions, when, where
and how: Experimental approach 77
Part II
The bubble population:
an analytic view into mutual
forces and allied energy exchange 97
6. The Bjerknes forces and acoustic
radiation energy 99
7. Nonlinear oscillations and resonances
of the acoustic bubble and the
mechanisms of energy dissipation 109
8. Damping mechanisms of oscillating
gas/vapor bubbles in liquids 131
Part III
Ultrasound assisted processes,
sonochemical reactors and
energy efficiency 155
10. Efficiency assessment and mapping
of cavitational activities in
sonochemical reactors 157
11. Sources of dissipation: An outlook into
the effects of operational conditions 183
12. Mechanistic issues of energy
efficiency of an ultrasonic process:
Role of free and dissolved gas 193
13. Simulation of sonoreators accounting
for dissipated power 219
14. Technological designs and energy
efficiency: The optimal paths 249
Part IV
Green, sustainable and benign
by design process? The place
and perspective of ultrasound
assisted processes and
sonochemistry in industrial
applications based on energy
efficiency 263
15. Acoustic cavitation and sonochemistry
in industry: State of the art 265
16. Crystallization of pharmaceutical
compounds: Process Intensification
using ultrasonic irradiations -
Experimental approach 279
17. Sonochemical degradation of
fluoroquinolone and ss-lactam
antibiotics - A view on
transformations, degradation
efficiency, and consumed energy 287
18. The use of ultrasonic treatment in
technological processes of complex
processing of industrial waste:
Energetic insights 299
19. The sonochemical and ultrasoundassisted
production of hydrogen:
energy efficiency for the generation
of an energy carrier 313
20. Future trends and promising
applications of industrial
sonochemical processes 329
21. Raising challenges of ultrasound-assisted
processes and sonochemistry
in industrial applications based on
energy efficiency 349
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
Energy forms; energy conversion; energy efficiency; single acoustic cavitation bubble; bubble population; sonochemical reactors; ultrasound assisted processes; industrial applications
Part I
The single acoustic cavitation
bubble as an energetic system:
qualitative and quantitative
assessments 1
1. Single acoustic cavitation bubble and
energy concentration concept 3
2. The energy forms and energy
conversion 23
3. Physical effects and associated
energy release 35
4. Sonochemical reactions, when, where
and how: Modelling approach 49
5. Sonochemical reactions, when, where
and how: Experimental approach 77
Part II
The bubble population:
an analytic view into mutual
forces and allied energy exchange 97
6. The Bjerknes forces and acoustic
radiation energy 99
7. Nonlinear oscillations and resonances
of the acoustic bubble and the
mechanisms of energy dissipation 109
8. Damping mechanisms of oscillating
gas/vapor bubbles in liquids 131
Part III
Ultrasound assisted processes,
sonochemical reactors and
energy efficiency 155
10. Efficiency assessment and mapping
of cavitational activities in
sonochemical reactors 157
11. Sources of dissipation: An outlook into
the effects of operational conditions 183
12. Mechanistic issues of energy
efficiency of an ultrasonic process:
Role of free and dissolved gas 193
13. Simulation of sonoreators accounting
for dissipated power 219
14. Technological designs and energy
efficiency: The optimal paths 249
Part IV
Green, sustainable and benign
by design process? The place
and perspective of ultrasound
assisted processes and
sonochemistry in industrial
applications based on energy
efficiency 263
15. Acoustic cavitation and sonochemistry
in industry: State of the art 265
16. Crystallization of pharmaceutical
compounds: Process Intensification
using ultrasonic irradiations -
Experimental approach 279
17. Sonochemical degradation of
fluoroquinolone and ss-lactam
antibiotics - A view on
transformations, degradation
efficiency, and consumed energy 287
18. The use of ultrasonic treatment in
technological processes of complex
processing of industrial waste:
Energetic insights 299
19. The sonochemical and ultrasoundassisted
production of hydrogen:
energy efficiency for the generation
of an energy carrier 313
20. Future trends and promising
applications of industrial
sonochemical processes 329
21. Raising challenges of ultrasound-assisted
processes and sonochemistry
in industrial applications based on
energy efficiency 349
The single acoustic cavitation
bubble as an energetic system:
qualitative and quantitative
assessments 1
1. Single acoustic cavitation bubble and
energy concentration concept 3
2. The energy forms and energy
conversion 23
3. Physical effects and associated
energy release 35
4. Sonochemical reactions, when, where
and how: Modelling approach 49
5. Sonochemical reactions, when, where
and how: Experimental approach 77
Part II
The bubble population:
an analytic view into mutual
forces and allied energy exchange 97
6. The Bjerknes forces and acoustic
radiation energy 99
7. Nonlinear oscillations and resonances
of the acoustic bubble and the
mechanisms of energy dissipation 109
8. Damping mechanisms of oscillating
gas/vapor bubbles in liquids 131
Part III
Ultrasound assisted processes,
sonochemical reactors and
energy efficiency 155
10. Efficiency assessment and mapping
of cavitational activities in
sonochemical reactors 157
11. Sources of dissipation: An outlook into
the effects of operational conditions 183
12. Mechanistic issues of energy
efficiency of an ultrasonic process:
Role of free and dissolved gas 193
13. Simulation of sonoreators accounting
for dissipated power 219
14. Technological designs and energy
efficiency: The optimal paths 249
Part IV
Green, sustainable and benign
by design process? The place
and perspective of ultrasound
assisted processes and
sonochemistry in industrial
applications based on energy
efficiency 263
15. Acoustic cavitation and sonochemistry
in industry: State of the art 265
16. Crystallization of pharmaceutical
compounds: Process Intensification
using ultrasonic irradiations -
Experimental approach 279
17. Sonochemical degradation of
fluoroquinolone and ss-lactam
antibiotics - A view on
transformations, degradation
efficiency, and consumed energy 287
18. The use of ultrasonic treatment in
technological processes of complex
processing of industrial waste:
Energetic insights 299
19. The sonochemical and ultrasoundassisted
production of hydrogen:
energy efficiency for the generation
of an energy carrier 313
20. Future trends and promising
applications of industrial
sonochemical processes 329
21. Raising challenges of ultrasound-assisted
processes and sonochemistry
in industrial applications based on
energy efficiency 349
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
