The biochemical behavior and mechanism of uranium(Ⅵ) bioreduction induced by natural Bacillus thuringiensis.

For a broader understanding of uranium migration affected by microorganisms in natural anaerobic environment, the bioreduction of uranium(Ⅵ) (U(Ⅵ)) was revealed in Bacillus thuringiensis, a dominant bacterium strain with potential of uranium-tolerant isolated from uranium contaminated soil. The reduction behavior was systematically investigated by the quantitative analysis of U(Ⅳ) in bacteria, and mechanism was inferred from the pathway of electron transmission. Under anaerobic conditions, appropriate biomass and sodium lactate as electron donor, reduction behavior of U(Ⅵ) induced by B.

Unusual uranium biomineralization induced by green algae: Behavior investigation and mechanism probe.

As a biosorbent, algae are frequently used for the biotreatment or bioremediation of water contaminated by heavy metal or radionuclides. However, it is unclear that whether or not the biomineralization of these metal or radionuclides can be induced by algae in the process of bioremediation and what the mechanism is. In this work, Ankistrodsemus sp.

The dynamic behavior and mechanism of uranium (VI) biomineralization in Enterobacter sp. X57.

The important role of microbes in the biomineralization and migration behavior of uranium in the field of environmental chemistry has been well emphasized in previous work. However, limited work on mineralization processes of indigenous microorganism has prevented us from a deeper understanding of the process and mechanisms of uranium biomineralization. In this work, the dynamic process and mechanism of uranium biomineralization in Enterobacter sp.

Rapid solidification of Sr-contaminated soil by consecutive microwave sintering: mechanism and stability evaluation.

Consecutive microwave sintering is a method proposed in this study to dispose soil contaminated by Sr during a nuclear accident by rapidly solidifying the contaminated soil. The results show that soil contaminated with 20 wt% SrSO and 30 wt% SrSO can be completely solidified by microwave sintering at 1100-1200 and 1300 ℃, respectively, for 30 min. Sr was found to be cured into slawsonite (SrAlSiO) and glass structures.

Heavy-ion irradiation effects on uranium-contaminated soil for nuclear waste.

In the field of radioactive waste immobilization, the investigation of irradiation stability is of considerable importance. In this study, uranium-contaminated soil samples were irradiated by 1.5 MeV Xe ions with fluences ranging from 1 × 10 to 1 × 10 ions/cm.

Low-sintering-temperature borosilicate glass to immobilize silver-coated silica-gel with different iodine loadings.

To better deal with the radioactive iodine generated during the development of nuclear energy, BO, BiO, ZnO, and SiO were used to sinter borosilicate glass for the immobilization of iodine. The effect of BO on glass formation was discussed by changing the molar ratio of BO in the matrix. When BO content is 50 mol% and sintering temperature is 600 ℃, the amorphous degree of quaternary glass is the highest.

Heavy-ion irradiation effects on UO incorporated GdZrO waste forms.

In this research, the heavy-ion irradiation effects of U-bearing GdZrO ceramics were explored for nuclear waste immobilization. UO was designed to be incorporated into GdZrO from two different routes in the form of (GdU)(ZrU)O (x = 0.1, 0.

Rapid immobilization of simulated radioactive soil waste by microwave sintering.

A rapid and efficient method is particularly necessary in the timely disposal of seriously radioactive contaminated soil. In this paper, a series of simulated radioactive soil waste containing different contents of neodymium oxide (3-25wt.%) has been successfully vitrified by microwave sintering at 1300°C for 30min.