Optical measurement of the isotope shifts and hyperfine and superhyperfine interactions of Nd in the solid state

Abstract

We report the observation of optically resolved isotope, hyperfine, and superhyperfine structure in the spectrum of (Formula presented) ions in (Formula presented) isotopically pure in (Formula presented) This observation was made on the (Formula presented) transition of (Formula presented) ions present as impurities at ppm levels. The optical linewidths of the transitions of the even mass number isotopes, (Formula presented) and (Formula presented) are only 45 MHz which makes it very easy to resolve the isotope shift of 115 MHz/unit mass. The hyperfine structure of the two odd mass number isotopes, (Formula presented) and (Formula presented) are resolved and the hyperfine parameters are determined in both the ground and electronically excited states. Some of the transitions have linewidths as narrow as 10 MHz. These are the narrowest optical inhomogeneous linewidths observed in solids. In addition, each even isotope line is split by 30 MHz. The observed splitting is assigned to a superhyperfine coupling between (Formula presented) and its nearest-neighbor fluorine nuclei. Here, a superhyperfine splitting has been resolved in an optical spectrum. The optical line shapes for the even isotopes are calculated as the sum of all transitions between the superhyperfine components (Formula presented) with its eight nearest-neighbor F nuclei) of the ground and excited electronic states, considering both magnetic dipole-dipole (including spin-transfer contributions) and contact interactions. The results are in quantitative agreement with experiment. © 1998 The American Physical Society.