Abstract
Atomic models of high-Z multicharged ions are extremely complex and require experimental validation. One way to do so is to crosscheck the predicted wavelengths of resonance transitions in He- and Li-like ions against precise spectroscopic measurements that use the spectral lines of H-like ions for spectra calibration; these reference data can be modeled with outstanding precision. However, for elements with Z of at least 15, it is quite difficult to create a hot dense plasma with a large concentration of H-like charge states. To mitigate this issue, the suggestion here is to use as laser targets particular minerals comprising elements with moderate (between 15 and 30) and low (less than 15) Z, with emission from the latter delivering perfect reference lines over a whole range of He- and Li-like moderate-Z emission under examination. This approach is implemented to measure the wavelengths of resonance transitions (1snp → 1s2 for n = 2, 3) in He-like K ions and their dielectronic satellites by irradiating plates of orthoclase (KAlSi3O8) with 0.5-kJ subnanosecond laser pulses. X-ray spectra of the laser-generated plasma contain the investigated lines of highly charged K ions together with precisely known reference lines of H-like Al and Si atoms. The K-shell spectral line wavelengths are measured with a precision of around 0.3 mÅ.
Highlights
X-ray spectroscopy is used widely for laser plasma diagnostics1–3 and is suitable for investigating inertial thermonuclear plasmas
One way to do so is to crosscheck the predicted wavelengths of resonance transitions in He- and Li-like ions against precise spectroscopic measurements that use the spectral lines of H-like ions for spectra calibration; these reference data can be modeled with outstanding precision
This approach is implemented to measure the wavelengths of resonance transitions (1snp → 1s2 for n 2, 3) in He-like K ions and their dielectronic satellites by irradiating plates of orthoclase (KAlSi3O8) with 0.5-kJ subnanosecond laser pulses
Summary
X-ray spectroscopy is used widely for laser plasma diagnostics and is suitable for investigating inertial thermonuclear plasmas For this diagnostic tool to be applicable, one must know the spectroscopic parameters of various multicharged ions, among which the most important are the wavelengths of radiative transitions. The accuracy of the wavelength measurement is independent of FSSR parameters such as the dispersive-crystal interplanar spacing and geometry (degree of sphericity) and is affected only by the signal-to-noise ratio of the detected signal and the natural width of the crystal rocking curve, which results in additional line broadening Such an approach has been used for high-precision measurements of the spectral-line wavelengths of Kr multicharged ions.. Two cases are considered below: the first anticipates an application involving an α-quartz crystal, and the second a mica crystal
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