Jérôme Faist
Quantum Cascade Lasers
Jérôme Faist
Quantum Cascade Lasers
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This book describes the physics, fabrication technology, and applications of the quantum cascade laser.
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This book describes the physics, fabrication technology, and applications of the quantum cascade laser.
Produktdetails
- Produktdetails
- Verlag: Oxford University Press, USA
- Seitenzahl: 322
- Erscheinungstermin: 21. März 2018
- Englisch
- Abmessung: 248mm x 173mm x 20mm
- Gewicht: 629g
- ISBN-13: 9780198795889
- ISBN-10: 0198795882
- Artikelnr.: 48140567
- Verlag: Oxford University Press, USA
- Seitenzahl: 322
- Erscheinungstermin: 21. März 2018
- Englisch
- Abmessung: 248mm x 173mm x 20mm
- Gewicht: 629g
- ISBN-13: 9780198795889
- ISBN-10: 0198795882
- Artikelnr.: 48140567
Jérôme Faist was born in Switzerland and obtained his Ph.D. in Physics in 1989 from the Swiss Institute of Technology in Lausanne. He then worked successively at IBM Rueschlikon (1989-91) and Bell Laboratories (1991-97). He was nominated full professor in the physics institute of the University of Neuchâtel (1997) and then in the ETH Zurich (2007). His key contribution to the development of the quantum cascade laser was recognized by a number of awards that include the National Swiss Latsis Prize 2002.
1: Quantum devices
2: Technology
3: Electronic states in semiconductor quantum wells
4: Optical transitions
5: Intersubband scattering processes
6: Mid-infrared waveguides
7: Active region design
8: Short wavelengths QCLs
9: Terahertz QCL
10: Mode control
11: Device properties and characterization
12: Transport models
13: Dynamical properties
14: Applications
Appendix A: Designs
1: Quantum devices
2: Technology
3: Electronic states in semiconductor quantum wells
4: Optical transitions
5: Intersubband scattering processes
6: Mid-infrared waveguides
7: Active region design
8: Short wavelengths QCLs
9: Terahertz QCL
10: Mode control
11: Device properties and characterization
12: Transport models
13: Dynamical properties
14: Applications
Appendix A: Designs
2: Technology
3: Electronic states in semiconductor quantum wells
4: Optical transitions
5: Intersubband scattering processes
6: Mid-infrared waveguides
7: Active region design
8: Short wavelengths QCLs
9: Terahertz QCL
10: Mode control
11: Device properties and characterization
12: Transport models
13: Dynamical properties
14: Applications
Appendix A: Designs
1: Quantum devices
2: Technology
3: Electronic states in semiconductor quantum wells
4: Optical transitions
5: Intersubband scattering processes
6: Mid-infrared waveguides
7: Active region design
8: Short wavelengths QCLs
9: Terahertz QCL
10: Mode control
11: Device properties and characterization
12: Transport models
13: Dynamical properties
14: Applications
Appendix A: Designs
1: Quantum devices
2: Technology
3: Electronic states in semiconductor quantum wells
4: Optical transitions
5: Intersubband scattering processes
6: Mid-infrared waveguides
7: Active region design
8: Short wavelengths QCLs
9: Terahertz QCL
10: Mode control
11: Device properties and characterization
12: Transport models
13: Dynamical properties
14: Applications
Appendix A: Designs
1: Quantum devices
2: Technology
3: Electronic states in semiconductor quantum wells
4: Optical transitions
5: Intersubband scattering processes
6: Mid-infrared waveguides
7: Active region design
8: Short wavelengths QCLs
9: Terahertz QCL
10: Mode control
11: Device properties and characterization
12: Transport models
13: Dynamical properties
14: Applications
Appendix A: Designs
2: Technology
3: Electronic states in semiconductor quantum wells
4: Optical transitions
5: Intersubband scattering processes
6: Mid-infrared waveguides
7: Active region design
8: Short wavelengths QCLs
9: Terahertz QCL
10: Mode control
11: Device properties and characterization
12: Transport models
13: Dynamical properties
14: Applications
Appendix A: Designs
1: Quantum devices
2: Technology
3: Electronic states in semiconductor quantum wells
4: Optical transitions
5: Intersubband scattering processes
6: Mid-infrared waveguides
7: Active region design
8: Short wavelengths QCLs
9: Terahertz QCL
10: Mode control
11: Device properties and characterization
12: Transport models
13: Dynamical properties
14: Applications
Appendix A: Designs