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A Rydberg atom is an excited atom with one or more electrons that have a very high principal quantum number. These atoms have a number of peculiar properties including an exaggerated response to electric and magnetic fields,〔 〕 long decay periods and electron wavefunctions that approximate, under some conditions, classical orbits of electrons about the nuclei. The core electrons shield the outer electron from the electric field of the nucleus such that, from a distance, the electric potential looks identical to that experienced by the electron in a hydrogen atom. In spite of its shortcomings, the Bohr model of the atom is useful in explaining these properties. Classically an electron in a circular orbit of radius ''r'', about a hydrogen nucleus of charge +''e'', obeys Newton's second law: : where ''k'' = 1/(4πε0). Orbital momentum is quantized in units of ''ħ'': :. Combining these two equations leads to Bohr's expression for the orbital radius in terms of the principal quantum number, ''n'': : It is now apparent why Rydberg atoms have such peculiar properties: the radius of the orbit scales as ''n''2 (the ''n'' = 137 state of hydrogen has an atomic radius ~1 µm) and the geometric cross-section as ''n''4. Thus Rydberg atoms are extremely large with loosely bound valence electrons, easily perturbed or ionized by collisions or external fields. Because the binding energy of a Rydberg electron is proportional to 1/''r'' and hence falls off like 1/''n''2, the energy level spacing falls off like 1/''n''3 leading to ever more closely spaced levels converging on the first ionization energy. These closely spaced Rydberg states form what is commonly referred to as the ''Rydberg series''. Figure 1 shows some of the energy levels of the lowest three values of orbital angular momentum in lithium. == History == The existence of the Rydberg series was first demonstrated in 1885 when Johann Balmer discovered a simple empirical formula for the wavelengths of light associated with transitions in atomic hydrogen. Three years later the Swedish physicist Johannes Rydberg presented a generalized and more intuitive version of Balmer's formula that came to be known as the Rydberg formula. This formula indicated the existence of an infinite series of ever more closely spaced discrete energy levels converging on a finite limit. This series was qualitatively explained in 1913 by Niels Bohr with his semiclassical model of the hydrogen atom in which quantized values of angular momentum lead to the observed discrete energy levels. A full quantitative derivation of the observed spectrum was derived by Wolfgang Pauli in 1926 following development of quantum mechanics by Werner Heisenberg and others. 抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)』 ■ウィキペディアで「Rydberg atom」の詳細全文を読む スポンサード リンク
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