Precise measurement of the thermal and stellar 54Fe(n, γ)55Fe cross sections via AMS

Abstract

The detection of long-lived radionuclides through ultra-sensitive single atom counting via accelerator mass spectrometry (AMS) offers opportunities for precise measurements of neutron capture cross sections, e.g. for nuclear astrophysics. The technique represents a truly complementary approach, completely independent of previous experimental methods. The potential of this technique is highlighted at the example of the 54Fe(n, γ)55Fe reaction. Following a series of irradiations with neutrons from cold and thermal to keV energies, the produced long-lived 55Fe nuclei (t1/2=2.744(9) yr) were analyzed at the Vienna Environmental Research Accelerator (VERA). A reproducibility of about 1% could be achieved for the detection of 55Fe, yielding cross section uncertainties of less than 3%. Thus, the new data can serve as anchor points to time-of-flight experiments. We report significantly improved neutron capture cross sections at thermal energy (σth=2.300.07 b) as well as for a quasi-Maxwellian spectrum of kT=25 keV (σ=30.31.2 mb) and for En=48153 keV (σ= 6.010.23 mb). The new experimental cross sections have been used to deduce improved Maxwellian average cross sections in the temperature regime of the common s-process scenarios. The astrophysical impact is discussed using stellar models for low-mass AGB stars.