(95a) Evaluating Metal Organic Frameworks as Smart Nanoporous Preconcentrators for Explosive Sensing | AIChE

(95a) Evaluating Metal Organic Frameworks as Smart Nanoporous Preconcentrators for Explosive Sensing

Authors 

Xiong, R. - Presenter, University of Tennessee
Luna, J. P. - Presenter, University of Tennessee
Keffer, D. J. - Presenter, University of Tennessee, Knoxville
Nicholson, D. M. - Presenter, Oak Ridge National Laboratory
Mcihalkova, A. - Presenter, Jackson State University
Petrova, T. - Presenter, Jackson State University
Leszczynski, J. - Presenter, Jackson State University
Odbadrakh, K. - Presenter, West Virginia University
Lewis, J. P. - Presenter, West Virginia University


In order for explosive molecules to be detected, the amount delivered to a sensor must exceed its detection threshold. Pre-concentrators facilitate this process by extracting explosive molecules from the atmosphere and delivering them to sensors in amounts required for reliable detection. Current pre-concentrators are not very selective and hence deliver material that is predominately contaminant. With the ability to tailor Metal Organic Frameworks (MOFs), there is hope that a pre-concentrator can be designed to selectively adsorb explosive molecules in the presence of contaminants. In order to test the feasibility of selectively pre-concentrating explosive molecules for detection, molecular simulations of RDX within IRMOFs (IRMOF-1, IRMOF-3, IRMOF-10, IRMOF-10 with amine group) were performed with and without contaminants. The simulations give new insight into the competitive nature of the adsorption and the binding of the explosive molecules to the framework. Adsorption isotherms, mobility of the RDX within the framework, the occupancy of each type of cage within the unit cell, and the framework's effect on the configuration of the explosive molecules were investigated by grand canonical Monte Carlo (GCMC) and molecular dynamics (MD).