467241 Adsorption Process Modeling for the Recovery of Uranium from Seawater

Tuesday, November 15, 2016: 10:10 AM
Sutter (Hilton San Francisco Union Square)
Austin Ladshaw1, Sotira Yiacoumi1 and Costas Tsouris2, (1)Civil and Environmental Engineering, Georgia Institute of Technology, Atlanta, GA, (2)Energy and Transportation Science Division, Oak Ridge National Laboratory, Oak Ridge, TN

One of the world’s rising global issues is how to meet the necessary energy demands of tomorrow without destroying the resources and environment of today. This challenge is being met by research into solar and wind energy, biofuels, and nuclear power. To facilitate the use of nuclear power in place of more traditional fossil-energy sources requires the utilization of the ocean as a new source of uranium. Adsorption technology can be employed to farm uranium from seawater in order to provide a new, untapped source of fuel for nuclear power. The ocean has the potential to provide a vast amount of uranium to add to the nuclear fuel cycle, as it contains nearly 1000 times more uranium than conventional mines. However, the average concentration of that resource is roughly 3.3 ppb, which presents a technological challenge. Recently, significant effort has been focused on the utilization of amidoxime ligands for selective removal of uranium from seawater, but there are still many other environmental factors such as pH, temperature, competing ions, and current flows that further complicate the design of a capture system. The realization of the ocean uranium recovery system will require an advanced understanding of the physicochemical processes involved, as well as a set of engineering modeling tools to aid in the process design. An advanced modeling framework coupled with detailed, high-resolution adsorption process models is being developed in order to give engineers a reliable design tool for the implementation of a seawater-capture system. These models are based on state-of-the-art linear and non-linear solver routines and are being designed specifically for generality and flexibility. Building of the framework in this manner allows us to branch off and develop more specific models for a particular system of interest, while also allowing the basic framework to be applicable to a wider variety of adsorption systems.

Extended Abstract: File Not Uploaded
See more of this Session: Advances in a Sustainable Nuclear Fuel Cycle
See more of this Group/Topical: Nuclear Engineering Division - See also ICE