Theoretical stability assessment of uranyl phosphates and apatites: selection of amendments for in situ remediation of uranium.

Addition of an amendment or reagent to soil/sediment is a technique that can decrease mobility and reduce bioavailability of uranium (U) and other heavy metals in the contaminated site. According to data from literature and results obtained in field studies, the general mineral class of apatites was selected as a most promising amendment for in situ immobilization/remediation of U. In this work we presented theoretical assessment of stability of U(VI) in four apatite systems (hydroxyapatite (HAP), North Carolina Apatite (NCA), Lisina Apatite (LA), and Apatite II) in order to determine an optimal apatite soil amendment which could be used for in situ remediation of uranium. In this analysis we used a theoretical criterion which is based on calculation of the ion-ion interaction potential, representing the main term of the cohesive energy of the matrix/pollutant system. The presented results of this analysis indicate (i) that the mechanism of immobilization of U by natural apatites depends on their chemical composition and (ii) that all analyzed apatites represent, from the point of view of stability, promising materials which could be used in field remediation of U-contaminated sites.

The use of fixatives for response to a radiation dispersal devise attack--a review of the current (2009) state-of-the-art.

Radiation dispersal devices (RDDs), or dirty bombs, are terrorist weapons designed to scatter radioactive materials in large urban areas. Although the main intent of a RDD is to produce general panic and chaos, other impacts such as health, environmental, property and economical damage may also occur. Although one certain method of reducing health risks from a RDD event is to remove the radioactive contaminants from the environment immediately, rapid cleanup after a RDD event may be impossible in many cases. However, preventing the migration of the radioactive contaminant is crucial. Although it may be necessary to allow the contaminant to remain in place, preventing its migration is still essential. Fixatives can reduce or eliminating migration potential of a contaminant introduced by a RDD. This paper reviews the significance of fixatives in response to a RDD event and some of the products which have been identified for such a purpose. Many of the products are promising for application. However, many reports lack quantitative information to allow for effective comparative evaluation. Further, key parameters, such as shelf life and product toxicity, are not typically evaluated. We recommend that standardized performance parameters be established to allow for better comparative evaluation.