Innovative Design Approach: While activated alumina has been shown to remove up to 95% of As(V), it is not an effective As(III) sorbent. At Lafayette College, faculty and students across disciplines have worked to develop a low-cost and reliable point-of-entry technology to effectively remove forms of inorganic arsenic from groundwater sources of drinking water. The technology is a composite sorbent, iron-enhanced activated alumina (IEAA). IEAA has proven to successfully remove arsenic to below 10 ppb. The work proposed in this study is divided into two parts: (1) the optimization the IEAA and (2) the design and construction of a working small-scale system for removing arsenic from drinking water.
Relationship to P3: Arsenic groundwater contamination is a global concern as evidenced by the millions who suffer from arsenic poisoning. The promise of this IEAA technology is its reliability and low cost, both of which are required by the many communities worldwide that are currently seeking relief from arsenic-contaminated groundwater in a sustainable manner.
Evaluation and Implementation: One student team will repeat IEAA column sorption tests and material characterization tests to further validate previous results. Another student team will use state-of-the-art spectroscopic methods including synchrotron-based techniques at the National Synchrotron Light Source to study the surface of the IEAA and the surface mechanisms involved in the removal of As(III) and As(V) from source water. Arsenic analysis of the residual material will be evaluated. Results of all tests will be used by another student team to design and build a pilot system for arsenic remediation.