The Laser and Its Applications in Science, Technology, and Medicine |
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Page 31
... quantum mechanics is that not just a single probability density P ( r , 0,0 ) defines the possible orbital motions of atomic electrons . In fact there are a large number of discrete probability densities Pi ( r , 0,0 ) which correspond ...
... quantum mechanics is that not just a single probability density P ( r , 0,0 ) defines the possible orbital motions of atomic electrons . In fact there are a large number of discrete probability densities Pi ( r , 0,0 ) which correspond ...
Page 33
... quantum mechanics to calculate the energies E ; of the quantum states of the ... number n because the energy expression ( 2.7 ) contains only the radial ... quantum numbers l ( l = 0 ) and m ( m = 0 ) . Spectroscopists refer to states ...
... quantum mechanics to calculate the energies E ; of the quantum states of the ... number n because the energy expression ( 2.7 ) contains only the radial ... quantum numbers l ( l = 0 ) and m ( m = 0 ) . Spectroscopists refer to states ...
Page 38
... number n , but also on the angular momentum quantum number & , and indeed magnetic effects give a ( usually small ) dependence on the quantum number m . A very important consideration in many - electron atoms and molecules is the Pauli ...
... number n , but also on the angular momentum quantum number & , and indeed magnetic effects give a ( usually small ) dependence on the quantum number m . A very important consideration in many - electron atoms and molecules is the Pauli ...
Contents
THE CHARACTERISTICS OF LASER LIGHT | 1 |
STATES OF ATOMS AND MOLECULES | 28 |
PRINCIPLES OF LASER ACTION | 66 |
7 other sections not shown
Common terms and phrases
absorption applications argon atom or molecule band cavity cell Chapter CO2 laser coefficient coherence collision components cross section crystal curve diagram diatomic molecules difference droplets dye laser electric field electronic energy emitted energy levels etalon example excited Figure fluorescence frequency given illustrated in Fig impurities intensity ion laser irradiation isotopes laser beam laser operation laser output laser pulse laser transitions lifetime light wave line width material measurement membrane mirror mode molecular orbitals N₂ N2-CO2 laser Nd:YAG laser nuclear Nuclear potential energy nuclei occurs optical oscillator particles phase photodeposition photon polarization population inversion potential energy probability density pumping quantum mechanics quantum number radiation radiative Raman scattering Rayleigh scattering reaction region resonator ruby laser schematic selective semiconductor shown in Fig silicon sources spatial species spectrum spontaneous emission stimulated emission surface surgery techniques temperature tion transverse transverse mode tunable vibrational energy wavelength welding