Detection mechanism of perovskite BFO (111) membrane for FOX-7 and TATB gases: molecular-scale insight into sensing ultratrace explosives

Perovskite bismuth ferrite-BFO (1 1 1) membranes, as potential-sensitive electrochemical sensors, are investigated for the detection of high-energy-density materials by molecular dynamics (MD) and density functional theory (DFT) calculations. For the detection mechanism of the sensitive 1, 1-diamino-2, 2-dinitroethylene (FOX-7) gases, both a cation bridge and electrostatic models can be used to explain the STM signatures as 0.02-0.04 V (single) and 0.03 similar to 0.05 V (coverage) over a wide range (0-0.1 V) of bias voltages. For insensitive 1, 3, 5-triamino-2, 4, 6-trinitrobenzene (TATB) gases interacting with the surface of a BFO (1 1 1) membrane, the charge signature can be as high as 0.08 V (coverage: 0.06 V). Analysis indicates a significant difference from the detection mechanism observed for FOX-7 gases; that is, the molecularly intact bidentate bridge configuration with only -NO2- bonds binds to both Fe and Bi atoms. These differences are attributed so that the surface O2- of BFO will capture a part of the surface electron of the -NO2 group, creating a 2p-hole defect (h(+)) which annihilates a spinning upward (up arrow) Fe3+, forming a spinning downward (down arrow) Fe2+. The - NO2 electron decreases 0.35 e (single FOX-7; coverage FOX-7: 0.24 e) and 0.56 e (single TATB; coverage TATB: 0.06 e). Such a system could open up new ideas in the design and application of BFO-based sensors.