Selection of short-lived isotopes for activation analysis with respect to sensitivity

Abstract

During the last decade the use of short-lived isotopes in activation analysis has exploded, owing to the application of high resolution gamma-ray spectrometry. Complex spectra can in fact be resolved without the need for chemical separations. The application of cyclic activation-counting enables the use of isotopes with half-lives below 10 seconds. These short-lived isotopes can be produced by different activation processes. As neutron sources one can distinguish reactors, generators for 14 MeV or high energy machines such as cyclotrons and isotopic neutron sources. High energy photons can be produced by interaction of an energetic electron beam with a target, giving rise to an intense bremsstrahlung spectrum with maximum energy from 10 up to 70 MeV. While these photons induce several types of threshold reactions, lower energetic photons are used for resonance activation producing metastable isomers. More and more also charged particles (p, d,3He, α) are being used as projectiles to produce radioactive isotopes that can be measured in activation analysis. In the present paper a concise compilation is made of the nuclear reactions, applicable in activation analysis of minor or trace constituents using gamma emitting isotopes with half-lived smaller than 1 hour. Activations of all naturally occurring elements, except the noble gases, with Z values ranging from 9 to 92 have been considered. The reactions resulting in the most sensitive gammaspectroscopic determinations have been selected and are tabulated per element, together with the appropriate cross section and the resonance integral if significant for neutron reactions, the cross section at the giant resonance energy for the photon and at the maximum of the excitation function for the charged particle reactions and the threshold energy for all threshold reactions. For each isotope produced the half-life and the major gamma-ray energy is given. Finally calculated or experimental sensitivities have been compiled from a number of references, as the emission rate per second of the most intense gamma-ray, at the end of a 1 minute irradiation under well-defined circumstances for 1 microgram of the element. When cyclic activation has been applied it is indicated. These data are provided for more than 200 nuclear reactions. It appears that the majority of the 70 elements constacred can in some way be determined with a high sensitivity after such a short irradiation. Only for the elements Tm and Tb no reaction yielding a short-lived isotope with a reasonable sensitivity could be found. Both elements can however very sensitively be determined after a longer neutron irradiation. For a number of elements activation analysis by means of the middle-long-lived isotopes (2 hours to 3 days) is the most sensitive even after a 1 minute irradiation and immediate count (Mn, Ga, As, Sr, Ru, La, Eu, Ho, Lu, Os and Au). But for all other elements the highest gamma emission rate results from isotopes with half-lives shorter than 1 hour. Extremely high counting rates are obtained after thermal reactor neutron activation for Na, Sc, V, Co, Se, Rh, Ag, In, Eu, Dy, Er and Hf. For a number of elements the selectivity of the analysis can however largely be enhanced by irradiation under Cd-cover. High σ0 ratios exist in fact for activation of medium and high Z elements such as Nb, Rb, Rh, Sn, Sb, Ba, Ce, Lu, Ta, Os, Hg and U. For some elements activation with reactor fission neutrons or 14 MeV neutrons provides an interesting sensitivity for a threshold reaction or the production of an isomer (F, Si, P, Cl, Ca, Cr, Se, Y, Ba, Ce, Pr, Bi, Pb). Cyclic activation and counting of very short-lived isotopes has been applied advantageously in the ng to μg range for a number of elements. Also cyclic activation with a 14 MeV generator has recently been studied. Low energy photon activation analysis allows selective production of metastable isomers of Se, Br, Ag, Er, Hf, Ir and Au, while high energetic photon production analysis yields high specific activities for elements such as K, Cr, Se, Br, Mo, Pr, Nd, Ho and allows interesting determinations of Mg, Cl, Si, Cr, Fe, Zr and Pb. Also charged particle activation can be used with surprisingly high sensitivity for some medium and high Z elements (Cr, Y, Se, Br, Zr, Mo, La, Ta, V). The intensity of the irradiation is in these cases mostly only limited by the properties of the sample itself, such as heat transfer and matrix activity. Examples of the compilation will be discussed and applications shown.