Utkal University, Odisha, Physics Semester 4, Elements of Modern Physics Syllabus

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Unit - 1 Atomic Spectra And Models
Unit 1
Atomic Spectra and Models
1.1 Atomic Spectra and Models Inadequacy of classical physics
1.2 Brief review of black body radiation
1.3 Photoelectric effect.
1.4 Compton effect
1.5 Dual nature of radiation wave nature of particles
1.6 Atomic spectra
1.7 Line spectra of hydrogen atom
1.8 RitsRydberg combination principle
1.9 Alpha particle scattering Rutherford scattering formula.
1.10 Rutherford model of atom and its limitations
1.11 Atomic Model Bohrs Model of Hydrogen atom
1.12 Explanation of atomic spectra
1.13 Correction for finite mass of the nucleus
1.14 Bohr correspondence principle
1.15 Limitations of Bohr model.
1.16 Discrete energy exchange by atom
1.17 Frank hertz experiment
1.18 Sommerfeld’s modification of Bohr’s theory.
Unit 1
Atomic Spectra and Models
1.1 Atomic Spectra and Models Inadequacy of classical physics
Unit 1
Atomic Spectra and Models
Unit 1
Atomic Spectra and Models
1.1 Atomic Spectra and Models Inadequacy of classical physics
1.2 Brief review of black body radiation
1.3 Photoelectric effect.
1.4 Compton effect
1.5 Dual nature of radiation wave nature of particles
1.6 Atomic spectra
1.7 Line spectra of hydrogen atom
1.8 RitsRydberg combination principle
1.9 Alpha particle scattering Rutherford scattering formula.
1.10 Rutherford model of atom and its limitations
1.11 Atomic Model Bohrs Model of Hydrogen atom
1.12 Explanation of atomic spectra
1.13 Correction for finite mass of the nucleus
1.14 Bohr correspondence principle
1.15 Limitations of Bohr model.
1.16 Discrete energy exchange by atom
1.17 Frank hertz experiment
1.18 Sommerfeld’s modification of Bohr’s theory.
Unit - 2 Wave Packet
Unit 2
Wave Packet
2.1 Superposition of waves
2.2 Phase velocity and group velocity
2.3 Wave packets
2.4 Gaussian wave packet Spatial distribution of wave packet
2.5 Localization of wave packet in time
2.6 Time development of a wave packet
2.7 Wave particle duality
2.8 Complementarity.
2.9 Wave Particle Duality De Broglie hypothesis
2.10 Experimental confirmation of matter wave.
2.11 Davisson Germer experiment.
2.12 Velocity of de Broglie wave.
2.13 Wave particle duality
2.14 Uncertainty Principle Heisenberg Uncertainty Principle
2.15 Illustration of the principle through experiment of gamma ray microscope and electron
2.16 Diffraction through a slit.
2.17 Estimation of ground state energy of harmonic oscillator and hydrogen atom
2.18 Non existence of electron in the nucleus
2.19 Uncertainty and complementarities.
Unit 2
Wave Packet
2.1 Superposition of waves
2.2 Phase velocity and group velocity
2.3 Wave packets
2.4 Gaussian wave packet Spatial distribution of wave packet
2.5 Localization of wave packet in time
2.6 Time development of a wave packet
2.7 Wave particle duality
2.8 Complementarity.
2.9 Wave Particle Duality De Broglie hypothesis
2.10 Experimental confirmation of matter wave.
2.11 Davisson Germer experiment.
2.12 Velocity of de Broglie wave.
2.13 Wave particle duality
2.14 Uncertainty Principle Heisenberg Uncertainty Principle
2.15 Illustration of the principle through experiment of gamma ray microscope and electron
Unit 2
Wave Packet
2.1 Superposition of waves
2.2 Phase velocity and group velocity
2.3 Wave packets
2.4 Gaussian wave packet Spatial distribution of wave packet
2.5 Localization of wave packet in time
2.6 Time development of a wave packet
2.7 Wave particle duality
2.8 Complementarity.
2.9 Wave Particle Duality De Broglie hypothesis
2.10 Experimental confirmation of matter wave.
2.11 Davisson Germer experiment.
2.12 Velocity of de Broglie wave.
2.13 Wave particle duality
2.14 Uncertainty Principle Heisenberg Uncertainty Principle
2.15 Illustration of the principle through experiment of gamma ray microscope and electron
2.16 Diffraction through a slit.
2.17 Estimation of ground state energy of harmonic oscillator and hydrogen atom
2.18 Non existence of electron in the nucleus
2.19 Uncertainty and complementarities.
Unit 2
Wave Packet
2.1 Superposition of waves
2.2 Phase velocity and group velocity
2.3 Wave packets
2.4 Gaussian wave packet Spatial distribution of wave packet
2.5 Localization of wave packet in time
2.6 Time development of a wave packet
2.7 Wave particle duality
2.8 Complementarity.
2.9 Wave Particle Duality De Broglie hypothesis
2.10 Experimental confirmation of matter wave.
2.11 Davisson Germer experiment.
2.12 Velocity of de Broglie wave.
2.13 Wave particle duality
2.14 Uncertainty Principle Heisenberg Uncertainty Principle
2.15 Illustration of the principle through experiment of gamma ray microscope and electron
2.16 Diffraction through a slit.
2.17 Estimation of ground state energy of harmonic oscillator and hydrogen atom
2.18 Non existence of electron in the nucleus
2.19 Uncertainty and complementarities.
Unit - 3 Nuclear Physics- I
Unit 3
Nuclear Physics I
3.1 Size and structure of atomic nucleus and its relation with atomic weight
3.2 Impossibility of an electron being in the nucleus as a consequence of the uncertainty principle
3.3 Nature of the nuclear force
3.4 NZ graph
3.5 Liquid drop model semi empirical mass formula and binding energy
3.6 Nuclear shell model and magic numbers
Unit 3
Nuclear Physics I
3.1 Size and structure of atomic nucleus and its relation with atomic weight
3.2 Impossibility of an electron being in the nucleus as a consequence of the uncertainty principle
3.3 Nature of the nuclear force
3.4 NZ graph
3.5 Liquid drop model semi empirical mass formula and binding energy
3.6 Nuclear shell model and magic numbers
Unit - 4 Nuclear Physics- II
Unit 4
Nuclear Physics II
4.1 Radioactivity
4.2 Stability of the nucleus
4.3 Law of radioactive decay
4.4 Mean life and half life alpha decay
4.5 Beta decay energy released
4.6 Spectrum and paulis prediction of neutrino
4.7 Gamma ray emission energy momentum conservation electron positron pair creation by gamma photons in the vicinity of a nucleus
4.8 Fission and fusion mass deficit
4.9 Relativity and generation of energy
4.10 Fission nature of fragments and emission of neutrons
4.11 Nuclear reactor slow neutron interacting with Uranium 235
4.12 Fusion and thermos nuclear reactions driving stellar energy
Unit 4
Nuclear Physics II
4.1 Radioactivity
4.2 Stability of the nucleus
4.3 Law of radioactive decay
4.4 Mean life and half life alpha decay
4.5 Beta decay energy released
4.6 Spectrum and paulis prediction of neutrino
4.7 Gamma ray emission energy momentum conservation electron positron pair creation by gamma photons in the vicinity of a nucleus
4.8 Fission and fusion mass deficit
4.9 Relativity and generation of energy
4.10 Fission nature of fragments and emission of neutrons
4.11 Nuclear reactor slow neutron interacting with Uranium 235
4.12 Fusion and thermos nuclear reactions driving stellar energy
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Other Subjects of Semester-4
Mathematical physics-iii
Digital systems and applications
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