Stabilization of Preternatural Barium Oxidation States as an Unexpected Byproduct of β-Decay: Discovery of a New Halide Semiconductor Alloy

AS Fuhr and DG Abrecht and C Weber and BG Sumpter, JOURNAL OF PHYSICAL CHEMISTRY C, 129, 20100-20111 (2025).

DOI: 10.1021/acs.jpcc.5c05485

Cs-137 has a wide range of roles in the nuclear industry. The solid material, safely encapsulated in CsCl as (CsCl)-Cs-137, is stored as fission product waste from nuclear power production and legacy waste from nuclear weapons production; it has also served as a radiation source in food and sewage irradiators as well as medical devices. However, because of the solubility of the chloride salt and the relatively high specific activity of Cs-137, damaged or broken capsules can lead to severe radiological accidents. Safe capsule design and material recycling are complicated by the unclear structural evolution during beta-decay, which remains ambiguous due to the differing oxidation states of Cs (1+) and Ba (2+). Here, we use first-principles calculations to investigate the evolving structure-property relationships of Cs1-xBaxCl during beta-decay. Despite the well- established 2+ formal oxidation state of alkali-earth metals, we find that Ba1+ can be stabilized in the form of a mixed-valence alloy at low concentrations. Specifically, we identify three regimes for the beta- decay of Cs-137 into CsCl: Ba-doped CsCl (Ba <= 14%), wherein Ba has the expected 2+ oxidation state; Cs-Ba-Cl alloys, where Ba has a mix of the usual Ba2+ and highly unusual Ba1+ oxidation state in the form of a quasi-disordered mixed-valence alloy (Ba = 25%); and phase separation into a CsCl + BaCl2 + Ba (m) mechanical mixture, where Ba reverts to its expected 2+ oxidation state (Ba > 25%). Surprisingly, the Cs0.75Ba0.25Cl mixed-valence alloy is a narrow indirect band gap semiconductor (1.05 eV) despite the insulating nature of both CsCl and BaCl2. It also exhibits strongly excitonic polarized optical properties, has glass-like ultralow thermal conductivity (directional average of 0.21 W/mK at 300 K), and shows greater resistance to deformation under both tensile and volumetric strengths compared with the original CsCl structure (e.g., shear and Young's modulus of 9.04 and 31.62 GPa, respectively). These findings imply that transmutation of Cs-137 leads to highly unusual chemical bonding that stabilizes Ba1+ in local regions of the quasi- disordered Cs0.25Ba0.75Cl, resulting in anomalous physical properties. Moreover, this discovery provides valuable insight for safe nuclear waste capsule design, which can aid in preventing environmental or human exposure to radioactive materials.

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