@article{Majidi_2023, title={Detection of mercaptopurine drug by T4,4,4-graphyne and the effect of applied electric field: A density functional theory study}, volume={15}, url={https://oiccpress.com/journal-of-theoretical-and-applied-physics/article/detection-of-mercaptopurine-drug-by-t444-graphyne-and-the-effect-of-applied-electric-field-a-density-functional-theory-study/}, DOI={10.30495/jtap.152104}, abstractNote={In the present work, adsorption of mercaptopurine (MP) drug on T4,4,4-graphyne sheet is examined by using density functional theory to explore the feasibility of T4,4,4-graphyne based sensor. The most stable configuration, charge transfer, adsorption energy, electronic band structures, and density of states are determined. It is found that weak physical adsorption with small charge transfer from T4,4,4-graphyne to MP drug took place. T4,4,4-graphyne sheet is an intrinsic semiconductor with a direct band gap. The energy band gap of T4,4,4-graphyne sheet is sensitive to the MP adsorption and decreases with any decrease in the concentration of the MP drug. Hence, T4,4,4-graphyne is a good candidate to detect the MP drug and its concentration. The electronic properties of T4,4,4-graphyne sheet with adsorbed MP are remarkably modulated by applying a perpendicular electric field. The results reveal that applying the electric field is a helpful method to improve the sensing performance of T4,4,4-graphyne sheet.}, number={1}, journal={Journal of Theoretical and Applied Physics}, publisher={OICC Press}, author={Majidi, Roya}, year={2023}, month={Nov.}, keywords={Band gap energy, Electronic properties, First principle study, Graphyne, Sensing property} }