Course Information

F7050 Quantum electronics - lasers and masers

Extent and Intensity

3/3/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. Mgr. Petr Vašina, Ph.D. (lecturer)
Mgr. Jan Voráč, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. Mgr. Petr Vašina, Ph.D.
Supplier department: Department of Plasma Physics and Technology – Physics Section – Faculty of Science

Timetable

Mon 17. 9. to Fri 14. 12. Tue 12:00–14:50 Fcom,01034

• Timetable of Seminar Groups:

F7050/01: Mon 17. 9. to Fri 14. 12. Wed 8:00–10:50 Fs2 6/4003

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

Study Materials
The course can also be completed outside the examination period.
The course is taught once in two years.
General note: S.

F7050 Quantum electronics - lasers and masers

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. Mgr. Petr Vašina, Ph.D. (lecturer)
Mgr. Jan Voráč, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. Mgr. Petr Vašina, Ph.D.
Supplier department: Department of Plasma Physics and Technology – Physics Section – Faculty of Science

Timetable

Mon 19. 9. to Sun 18. 12. Mon 9:00–10:50 Fs2 6/4003, Tue 15:00–16:50 F3,03015, Fri 13:00–14:50 Fs1 6/1017

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

Study Materials
The course can also be completed outside the examination period.
The course is taught once in two years.
General note: S.

F7050 Quantum electronics - lasers and masers

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. Mgr. Petr Vašina, Ph.D. (lecturer)
Mgr. Jan Voráč, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. Mgr. Petr Vašina, Ph.D.
Supplier department: Department of Plasma Physics and Technology – Physics Section – Faculty of Science

Timetable

Tue 10:00–11:50 Fs1 6/1017, Wed 10:00–11:50 Fs1 6/1017, Wed 14:00–15:50 Fs1 6/1017

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

Study Materials
The course can also be completed outside the examination period.
The course is taught once in two years.
General note: S.

F7050 Quantum electronics - lasers and masers

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)
prof. Mgr. Petr Vašina, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.
Supplier department: Department of Plasma Physics and Technology – Physics Section – Faculty of Science

Timetable

Mon 15:00–16:50 Fs1 6/1017, Tue 10:00–11:50 Fs1 6/1017, Thu 18:00–19:50 Fs1 6/1017

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, N-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

Study Materials
The course can also be completed outside the examination period.
The course is taught once in two years.
General note: S.

F7050 Quantum electronics - lasers and masers

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)
prof. Mgr. Petr Vašina, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Timetable

Mon 7:00–8:50 Fs1 6/1017, Tue 17:00–18:50 F3,03015, Fri 10:00–11:50 Fs1 6/1017

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, M-FY)
• Physics (programme PřF, N-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught annually.
General note: S.

F7050 Quantum electronics - lasers and masers

Extent and Intensity

4/2/0. 6 credit(s) (fasci plus compl plus > 4). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)
prof. Mgr. Petr Vašina, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Timetable

Mon 12:00–13:50 F1 6/1014, Tue 8:00–9:50 Fs1 6/1017, Fri 7:00–8:50 F1 6/1014

Prerequisites

F2070 Electricity and magnetism && F4100 Introduction to Microphysics
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, M-FY)
• Physics (programme PřF, N-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught annually.

F7050 Quantum electronics - lasers and masers

Extent and Intensity

4/2/0. 6 credit(s) (fasci plus compl plus > 4). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)
prof. Mgr. Petr Vašina, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Timetable

Thu 10:00–11:50 F1 6/1014, Thu 14:00–15:50 04017, Fri 9:00–10:50 F1 6/1014

Prerequisites

F6030 Quantum mechanics && F4100 Introduction to Microphysics
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, M-FY)
• Physics (programme PřF, N-FY)

Course objectives

Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasewrs. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Language of instruction

Czech

Further comments (probably available only in Czech)

Study Materials
The course can also be completed outside the examination period.
The course is taught annually.

F7050 Quantum electronics

Extent and Intensity

4/2/0. 4 credit(s) (fasci plus compl plus > 4). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)
prof. Mgr. Petr Vašina, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Timetable

Tue 15:00–16:50 Fs3,04018, Wed 7:00–8:50 F1 6/1014, Wed 11:00–12:50 F1 6/1014

Prerequisites

Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, M-FY)
• Physics (programme PřF, N-FY)

Course objectives

Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasewrs. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught annually.

F7050 Quantum electronics

Extent and Intensity

4/2/0. 4 credit(s) (fasci plus compl plus > 4). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)
prof. RNDr. Jan Janča, DrSc. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Timetable

Mon 11:00–12:50 F1 6/1014, Wed 10:00–11:50 F1 6/1014, Wed 16:00–17:50 F1 6/1014

Prerequisites

Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, M-FY)
• Physics (programme PřF, N-FY)

Course objectives

Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasewrs. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught annually.

F7050 Quantum electronics

Extent and Intensity

4/2/0. 4 credit(s) (fasci plus compl plus > 4). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)
prof. RNDr. Jan Janča, DrSc. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Timetable

Mon 9:00–11:50 F1 6/1014

Prerequisites

Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, M-FY)
• Physics (programme PřF, N-FY)

Course objectives

Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasewrs. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught annually.

F7050 Quantum electronics

Extent and Intensity

4/2/0. 4 credit(s) (fasci plus compl plus > 4). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)
prof. RNDr. Jan Janča, DrSc. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Prerequisites

Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, M-FY)
• Physics (programme PřF, N-FY)

Course objectives

Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasewrs. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught annually.
The course is taught: every week.

F7050 Quantum electronics

Extent and Intensity

4/2/0. 4 credit(s) (fasci plus compl plus > 4). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Prerequisites

Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, M-FY)
• Physics (programme PřF, N-FY)

Course objectives

Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasewrs. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Language of instruction

Czech

Further Comments

The course can also be completed outside the examination period.
The course is taught annually.
The course is taught: every week.

F7050 Quantum electronics

Extent and Intensity

4/2/0. 6 credit(s). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Prerequisites

Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, M-FY)
• Physics (programme PřF, N-FY)

Course objectives

Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasewrs. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Language of instruction

Czech

Further Comments

The course can also be completed outside the examination period.
The course is taught annually.
The course is taught: every week.

F7050 Quantum electronics

Extent and Intensity

4/2/0. 6 credit(s). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Prerequisites

Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, M-FY)
• Physics (programme PřF, N-FY)

Course objectives

Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasewrs. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Language of instruction

Czech

Further Comments

The course can also be completed outside the examination period.
The course is taught annually.
The course is taught: every week.

F7050 Quantum electronics

Extent and Intensity

4/2/0. 6 credit(s). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Prerequisites

Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, M-FY)
• Physics (programme PřF, N-FY)

Syllabus

• Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasewrs. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Language of instruction

Czech

Further Comments

The course is taught annually.
The course is taught: every week.

F7050 Quantum electronics - lasers and masers

The course is not taught in Autumn 2024

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).
In-person direct teaching

Teacher(s)

prof. Mgr. Petr Vašina, Ph.D. (lecturer)

Guaranteed by

prof. Mgr. Petr Vašina, Ph.D.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. Mgr. Petr Vašina, Ph.D.
Supplier department: Department of Plasma Physics and Technology – Physics Section – Faculty of Science

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Learning outcomes

After completing the course, the student will be able to:
-describe spectral lines using spectral terms, use selection rules for atoms with more electrons, describe basic shapes of spectral lines
-describe the basic physical principles of light amplification or attenuation when passing through a laser system;
-describe the differences, advantages and disadvantages of a two-, three- and four-level laser system;
-describe currently used lasers and masers;

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

recommended literature
• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught once in two years.
The course is taught: every week.
General note: S.

F7050 Quantum electronics - lasers and masers

The course is not taught in Autumn 2023

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. Mgr. Petr Vašina, Ph.D. (lecturer)

Guaranteed by

prof. Mgr. Petr Vašina, Ph.D.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. Mgr. Petr Vašina, Ph.D.
Supplier department: Department of Plasma Physics and Technology – Physics Section – Faculty of Science

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Learning outcomes

After completing the course, the student will be able to:
-describe spectral lines using spectral terms, use selection rules for atoms with more electrons, describe basic shapes of spectral lines
-describe the basic physical principles of light amplification or attenuation when passing through a laser system;
-describe the differences, advantages and disadvantages of a two-, three- and four-level laser system;
-describe currently used lasers and masers;

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

recommended literature
• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught once in two years.
The course is taught: every week.
General note: S.

F7050 Quantum electronics - lasers and masers

The course is not taught in Autumn 2022

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. Mgr. Petr Vašina, Ph.D. (lecturer)

Guaranteed by

prof. Mgr. Petr Vašina, Ph.D.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. Mgr. Petr Vašina, Ph.D.
Supplier department: Department of Plasma Physics and Technology – Physics Section – Faculty of Science

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Learning outcomes

After completing the course, the student will be able to:
-describe spectral lines using spectral terms, use selection rules for atoms with more electrons, describe basic shapes of spectral lines
-describe the basic physical principles of light amplification or attenuation when passing through a laser system;
-describe the differences, advantages and disadvantages of a two-, three- and four-level laser system;
-describe currently used lasers and masers;

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

recommended literature
• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught once in two years.
The course is taught: every week.
General note: S.

F7050 Quantum electronics - lasers and masers

The course is not taught in autumn 2021

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. Mgr. Petr Vašina, Ph.D. (lecturer)

Guaranteed by

prof. Mgr. Petr Vašina, Ph.D.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. Mgr. Petr Vašina, Ph.D.
Supplier department: Department of Plasma Physics and Technology – Physics Section – Faculty of Science

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Learning outcomes

After completing the course, the student will be able to:
-describe spectral lines using spectral terms, use selection rules for atoms with more electrons, describe basic shapes of spectral lines
-describe the basic physical principles of light amplification or attenuation when passing through a laser system;
-describe the differences, advantages and disadvantages of a two-, three- and four-level laser system;
-describe currently used lasers and masers;

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

recommended literature
• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught once in two years.
The course is taught: every week.
General note: S.

F7050 Quantum electronics - lasers and masers

The course is not taught in Autumn 2020

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. Mgr. Petr Vašina, Ph.D. (lecturer)

Guaranteed by

prof. Mgr. Petr Vašina, Ph.D.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. Mgr. Petr Vašina, Ph.D.
Supplier department: Department of Plasma Physics and Technology – Physics Section – Faculty of Science

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught once in two years.
The course is taught: every week.
General note: S.

F7050 Quantum electronics - lasers and masers

The course is not taught in Autumn 2019

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. Mgr. Petr Vašina, Ph.D. (lecturer)
Mgr. Jan Voráč, Ph.D. (seminar tutor)

Guaranteed by

prof. Mgr. Petr Vašina, Ph.D.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. Mgr. Petr Vašina, Ph.D.
Supplier department: Department of Plasma Physics and Technology – Physics Section – Faculty of Science

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught once in two years.
The course is taught: every week.
General note: S.

F7050 Quantum electronics - lasers and masers

The course is not taught in autumn 2017

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. Mgr. Petr Vašina, Ph.D. (lecturer)
Mgr. Jan Voráč, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. Mgr. Petr Vašina, Ph.D.
Supplier department: Department of Plasma Physics and Technology – Physics Section – Faculty of Science

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught once in two years.
The course is taught: every week.
General note: S.

F7050 Quantum electronics - lasers and masers

The course is not taught in Autumn 2015

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. Mgr. Petr Vašina, Ph.D. (lecturer)
Mgr. Jan Voráč, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. Mgr. Petr Vašina, Ph.D.
Supplier department: Department of Plasma Physics and Technology – Physics Section – Faculty of Science

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught once in two years.
The course is taught: every week.
General note: S.

F7050 Quantum electronics - lasers and masers

The course is not taught in Autumn 2013

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)
prof. Mgr. Petr Vašina, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.
Supplier department: Department of Plasma Physics and Technology – Physics Section – Faculty of Science

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught once in two years.
The course is taught: every week.
General note: S.

F7050 Quantum electronics - lasers and masers

The course is not taught in Autumn 2011

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)
prof. Mgr. Petr Vašina, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, N-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught once in two years.
The course is taught: every week.
General note: S.

F7050 Quantum electronics - lasers and masers

The course is not taught in Autumn 2009

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)
prof. Mgr. Petr Vašina, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Prerequisites

F2070 Electricity and magnetism && F4100 Introduction to Microphysics
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, M-FY)
• Physics (programme PřF, N-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught annually.
The course is taught: every week.
General note: S.

F7050 Quantum electronics - lasers and masers

The information about the term Autumn 2011 - acreditation is not made public

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)
prof. Mgr. Petr Vašina, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, M-FY)
• Physics (programme PřF, N-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught annually.
The course is taught: every week.
General note: S.

F7050 Quantum electronics - lasers and masers

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)
prof. Mgr. Petr Vašina, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, M-FY)
• Physics (programme PřF, N-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught annually.
The course is taught: every week.
General note: S.

F7050 Quantum electronics - lasers and masers

Extent and Intensity

4/2/0. 4 credit(s) (fasci plus compl plus > 4). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)
prof. Mgr. Petr Vašina, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.

Prerequisites

Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, M-FY)
• Physics (programme PřF, N-FY)

Course objectives

Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasewrs. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught annually.
The course is taught: every week.

F7050 Quantum electronics - lasers and masers

The course is not taught in spring 2012 - acreditation

The information about the term spring 2012 - acreditation is not made public

Extent and Intensity

4/2/0. 5 credit(s) (plus extra credits for completion). Type of Completion: zk (examination).

Teacher(s)

prof. RNDr. Jan Janča, DrSc. (lecturer)
prof. Mgr. Petr Vašina, Ph.D. (seminar tutor)

Guaranteed by

prof. RNDr. Jan Janča, DrSc.
Department of Plasma Physics and Technology – Physics Section – Faculty of Science
Contact Person: prof. RNDr. Jan Janča, DrSc.
Supplier department: Department of Plasma Physics and Technology – Physics Section – Faculty of Science

Prerequisites

( F2070 Electricity and magnetism && F4100 Introduction to Microphysics )||( F2050 Electricity and magnetism && F4050 Introduction to Microphysics )
Atomic, nuclear and particle physics. Quantum mechanics. Theory of elmg. field.

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Physics (programme PřF, B-FY)
• Physics (programme PřF, N-FY)

Course objectives

Lecture enclosed the history and development of quantum electronics and optics. Introduction to radiospectroscopy. Spectrum of atomic hydrogen. Rabi method of magnetic moment measurements.Atoms with equivalent electrons.Theoretical fundamentals and first successfull experimental results are presented. The function of nearly all practically used lasers and masers are thorougly described. The principles of NMR medical diagostic is explained in the last lectures. Hierarchy of atomic and molecular terms. Dipole iradiation. Transition probabilities. Back-Goudsmit effect and fine structure of spectral lines. Form faktor and width of spectral lines. Quantum system as an amplifier of stimulated emission of radiation. Threshold conditions for population inversion. Quantum gain and quality of optical resonator. Einstein kinetic equation. Saturation of absoption and amplification.Three level and four level quantum systems. Lasers on solid states. Optical resonators and irradiation systems. Ruby and neodymum laser. Gaseous lasers. Laser He-Ne, argon and CO2. Dye and chemical lasers. Impulse lasers. Lasers on free electrons. Generation of giant pulses. Mode locking. Semiconductor lasers. Lasers in science and technology. Pseudovibronic spectrum of NH3 and maser on NH3. Electron and nuclear spin resonance. NMR tomography. Masers on paramagnetic materials. Fundamental non-linear effects in quantum electronics. Generation of second and third harmonics. Prametric generation of light. Multiphoton absorption.

Syllabus

• Radiospectroscopic methods. Quantun teory of radiation. Transition probabilities. Quantum ansamble as amplifier of stimulated emission. Profile of spectral lines. Optical resonators. Saturation of amplification. Gas lasers. Lasers on solidstate materials. Lasers with modulated quality (giant pulses). Semiconductor lasers. Electron spin and nuclear paramagnetic resonance. Masers.

Literature

• YARIV, Amnon. Quantum electronics. 3rd ed. New York: John Wiley & Sons, 1989, xx, 676. ISBN 0471609978. info
• SVELTO, Orazio. Principy lazerov. 2. perer. i dop. izd. Moskva: Mir, 1984, 395 s. info
• YARIV, Amnon. Kvantovaja elektronika. Edited by Jakov Izrailevič Chanin. Izd. 2-oje. Moskva: Sovetskoje radio, 1980, 487 s. info
• SVELTO, Orazio. Fizika lazerov. Moskva: Mir, 1979, 373 s. info
• Advances in quantum electronics. Edited by D. W. Goodwin. London: Academic Press, 1970, xii, 274. info

Teaching methods

Oral lecture and theoretical exercise.

Assessment methods

Lectures and exercites. Written and oral examination.

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.
The course is taught once in two years.
The course is taught: every week.
General note: S.

• Enrolment Statistics (recent)