Selective Capturing and Sensing Performance of M2CO2 (M = Sc, Ti, V) MXenes Toward Hydrogen Cyanide: A First-Principles Modeling

Chúng tôi vui mừng thông báo rằng TS. Lê Nguyễn Minh Thông và các đồng nghiệp gần đây đã xuất bản công trình của họ có tựa đề “Selective Capturing and Sensing Performance of M2CO2 (M = Sc, Ti, V) MXenes Toward Hydrogen Cyanide: A First-Principles Modeling" trên tạp chí Advanced Theory and Simulations

Tóm tắt:

This work reports the high selection and performance of early transition-metal-based MXenes toward the detection of hydrogen cyanide (HCN), studied by first-principles density functional theory (DFT) calculations. On the pristine M₂C (M = Sc, Ti, V), HCN molecules are strongly chemisorptive to surface sites via ionic bonds with adsorption energies ranging from −3.50 to −4.40 eV. The charge density difference plot exhibits a charge accumulation around the C─H bond of HCN after adsorption, leading to its pronounced elongation. On the functionalized M₂CO₂ surfaces, HCN molecules prefer binding to Sc₂CO₂ via electrostatic interaction with a monodentate configuration and a high binding energy of 0.85 eV, much greater than that on other surfaces, relying on the distinguishing termination pattern of the host structure. Sc₂CO₂ shows a relatively long recovery time of ≈235 s at room temperature, however, a high sensitivity of 306% is obtained, which is much superior to that on other investigated surfaces. A slight reduction in bandgap, i.e., 0.072 eV, originating from the down-shift of both bonding and anti-bonding states, is the key to this distinctive performance. Ab initio molecular dynamics (AIMD) simulations reveal the stability of adsorbed HCN on the Sc₂CO₂ surface within the studied timescale at room temperature.