рдЗрд╕ рдИ-рдмреБрдХ рдХреЗ рдмрд╛рд░реЗ рдореЗрдВ рдЬрд╛рдирдХрд╛рд░реА
As it results from the very nature of things, the spherical symmetry of the surrounding of a site in a crystal lattice or an atom in a molecule can never occur. Therefore, the eigenfunctions and eigenvalues of any bound ion or atom have to differ from those of spherically symmetric respective free ions. In this way, the most simplified concept of the crystal field effect or ligand field effect in the case of individual molecules can be introduced.
The conventional notion of the crystal field potential is narrowed to its non-spherical part only through ignoring the dominating spherical part which produces only a uniform energy shift of gravity centres of the free ion terms. It is well understood that the non-spherical part of the effective potential "seen" by open-shell electrons localized on a metal ion plays an essential role in most observed properties. Light adsorption, electron paramagnetic resonance, inelastic neutron scattering and basic characteristics derived from magnetic and thermal measurements, are only examples of a much wider class of experimental results dependent on it. The influence is discerned in all kinds of materials containing unpaired localized electrons: ionic crystals, semiconductors and metallic compounds including materials as intriguing as high-Tc superconductors, or heavy fermion systems. It is evident from the above that we deal with a widespread effect relative to all free ion terms except those which can stand the lowered symmetry, e.g. S-terms.
Despite the universality of the phenomenon, the available handbooks on solid state physics pay only marginal attention to it, merely making mention of its occurrence. Present understanding of the origins of the crystal field potential differs essentially from the pioneering electrostatic picture postulated in the twenties. The considerable development of the theory that has been put forward since then can be traced in many regular articles scattered throughout the literature. The last two decades have left their impression as well but, to the authors' best knowledge, this period has not been closed with a more extended review. This has also motivated us to compile the main achievements in the field in the form of a book.
The conventional notion of the crystal field potential is narrowed to its non-spherical part only through ignoring the dominating spherical part which produces only a uniform energy shift of gravity centres of the free ion terms. It is well understood that the non-spherical part of the effective potential "seen" by open-shell electrons localized on a metal ion plays an essential role in most observed properties. Light adsorption, electron paramagnetic resonance, inelastic neutron scattering and basic characteristics derived from magnetic and thermal measurements, are only examples of a much wider class of experimental results dependent on it. The influence is discerned in all kinds of materials containing unpaired localized electrons: ionic crystals, semiconductors and metallic compounds including materials as intriguing as high-Tc superconductors, or heavy fermion systems. It is evident from the above that we deal with a widespread effect relative to all free ion terms except those which can stand the lowered symmetry, e.g. S-terms.
Despite the universality of the phenomenon, the available handbooks on solid state physics pay only marginal attention to it, merely making mention of its occurrence. Present understanding of the origins of the crystal field potential differs essentially from the pioneering electrostatic picture postulated in the twenties. The considerable development of the theory that has been put forward since then can be traced in many regular articles scattered throughout the literature. The last two decades have left their impression as well but, to the authors' best knowledge, this period has not been closed with a more extended review. This has also motivated us to compile the main achievements in the field in the form of a book.
рд░реЗрдЯрд┐рдВрдЧ рдФрд░ рд╕рдореАрдХреНрд╖рд╛рдПрдВ
5.0
1 рд╕рдореАрдХреНрд╖рд╛
рдЗрд╕ рдИ-рдмреБрдХ рдХреЛ рд░реЗрдЯрд┐рдВрдЧ рджреЗрдВ
рд╣рдореЗрдВ рдЕрдкрдиреА рд░рд╛рдп рдмрддрд╛рдПрдВ.
рдкрдарди рдЬрд╛рдирдХрд╛рд░реА
рд╕реНрдорд╛рд░реНрдЯрдлрд╝реЛрди рдФрд░ рдЯреИрдмрд▓реЗрдЯ
Android рдФрд░ iPad/iPhone рдХреЗ рд▓рд┐рдП Google Play рдХрд┐рддрд╛рдмреЗрдВ рдРрдкреНрд▓рд┐рдХреЗрд╢рди рдЗрдВрд╕реНрдЯреЙрд▓ рдХрд░реЗрдВ. рдпрд╣ рдЖрдкрдХреЗ рдЦрд╛рддреЗ рдХреЗ рд╕рд╛рде рдЕрдкрдиреЗ рдЖрдк рд╕рд┐рдВрдХ рд╣реЛ рдЬрд╛рддрд╛ рд╣реИ рдФрд░ рдЖрдкрдХреЛ рдХрд╣реАрдВ рднреА рдСрдирд▓рд╛рдЗрди рдпрд╛ рдСрдлрд╝рд▓рд╛рдЗрди рдкрдврд╝рдиреЗ рдХреА рд╕реБрд╡рд┐рдзрд╛ рджреЗрддрд╛ рд╣реИ.
рд▓реИрдкрдЯреЙрдк рдФрд░ рдХрдВрдкреНрдпреВрдЯрд░
рдЖрдк рдЕрдкрдиреЗ рдХрдВрдкреНрдпреВрдЯрд░ рдХреЗ рд╡реЗрдм рдмреНрд░рд╛рдЙрдЬрд╝рд░ рдХрд╛ рдЙрдкрдпреЛрдЧ рдХрд░рдХреЗ Google Play рдкрд░ рдЦрд░реАрджреА рдЧрдИ рдСрдбрд┐рдпреЛ рдХрд┐рддрд╛рдмреЗрдВ рд╕реБрди рд╕рдХрддреЗ рд╣реИрдВ.
eReaders рдФрд░ рдЕрдиреНрдп рдбрд┐рд╡рд╛рдЗрд╕
Kobo рдИ-рд░реАрдбрд░ рдЬреИрд╕реА рдИ-рдЗрдВрдХ рдбрд┐рд╡рд╛рдЗрд╕реЛрдВ рдкрд░ рдХреБрдЫ рдкрдврд╝рдиреЗ рдХреЗ рд▓рд┐рдП, рдЖрдкрдХреЛ рдлрд╝рд╛рдЗрд▓ рдбрд╛рдЙрдирд▓реЛрдб рдХрд░рдХреЗ рдЙрд╕реЗ рдЕрдкрдиреЗ рдбрд┐рд╡рд╛рдЗрд╕ рдкрд░ рдЯреНрд░рд╛рдВрд╕рдлрд╝рд░ рдХрд░рдирд╛ рд╣реЛрдЧрд╛. рдИ-рд░реАрдбрд░ рдкрд░ рдХрд╛рдо рдХрд░рдиреЗ рд╡рд╛рд▓реА рдлрд╝рд╛рдЗрд▓реЛрдВ рдХреЛ рдИ-рд░реАрдбрд░ рдкрд░ рдЯреНрд░рд╛рдВрд╕рдлрд╝рд░ рдХрд░рдиреЗ рдХреЗ рд▓рд┐рдП, рд╕рд╣рд╛рдпрддрд╛ рдХреЗрдВрджреНрд░ рдХреЗ рдирд┐рд░реНрджреЗрд╢реЛрдВ рдХрд╛ рдкрд╛рд▓рди рдХрд░реЗрдВ.
