Abstract
The unauthorized use of phencyclidine (PCP) has serious public health consequences, which prompts the need for new sensing approaches that are fast, sensitive and accessible. This study used Density Functional Theory (DFT) and the Quantum Theory of Atoms in Molecules (QTAIM) to examine pristine fullerene C(20) and two doped ones (AlC(19) and ZnC(19)) as new sensors for PCP. Geometry optimization and analyses of the molecular electrostatic potential (MEP), electronic properties (HOMO-LUMO gap; chemical potential, electrophilicity-based charge transfer), and sensing performance (adsorption energy, recovery time and electrical conductivity) were performed. Results illustrate that doping significantly changes the electronic and structural properties of the C(20) framework. Although pristine C(20) and ZnC(19) have limited potential, AlC(19) is promising as a multifunctional material. AlC(19) has the strongest interaction with PCP, with an adsorption energy (Eads) of -49.44 kcal.mol(-1), demonstrating excellent potential to remove PCP in adsorbed form. As an electrochemical sensor, AlC(19) showed a large increase in electrical conductivity (from 2.71 × 10(9) in the pristine AlC(19) to 2.77 × 10(9) in the AlC(19)@PCP complex) and a long recovery time after PCP binding, making it ideal for disposable sensor application (strong and irreversible binding). Furthermore, AlC₁₉ showed exceptional performance as a colorimetric sensor, exhibiting a significant shift in the UV-Vis absorption maximum (from 470 nm to 524 nm) after complexation with PCP. Both NBO and QTAIM analysis revealed that AlC(19)@PCP exhibits a very strong donor-acceptor interaction and a moderate hydrogen-bond-like character, which contributed to its strong performance. All of the above establishes that AlC(19) is an effective disposable electrochemical sensor, a colorimetric sensor, and an effective adsorbent of PCP that can be further utilized to develop a multi-functional sensing system that could allow for detection of the drug and remediation of the environment.