Structural and electronic properties of H2, CO, CH4, NO, and NH3 adsorbed onto Al12Si12 nanocages using density functional theory

In this study, the adsorption of gases (CH4, CO, H2, NH3, and NO) onto Al12Si12 nanocages was theoretically investigated using density functional theory. For each type of gas molecule, two different adsorption sites above the Al and Si atoms on the cluster surface were explored. We performed geometry optimization on both the pure nanocage and nanocages after gas adsorption and calculated their adsorption energies and electronic properties. The geometric structure of the complexes changed slightly following gas adsorption. We show that these adsorption processes were physical ones and observed that NO adsorbed onto Al12Si12 had the strongest adsorption stability. The E g (energy band gap) value of the Al12Si12 nanocage was 1.38 eV, indicating that it possesses semiconductor properties. The E g values of the complexes formed after gas adsorption were all lower than that of the pure nanocage, with the NH3–Si complex showing the greatest decrease in E g. Additionally, the highest occupied molecular orbital and the lowest unoccupied molecular orbital were analyzed according to Mulliken charge transfer theory. Interaction with various gases was found to remarkably decrease the E g of the pure nanocage. The electronic properties of the nanocage were strongly affected by interaction with various gases. The E g value of the complexes decreased due to the electron transfer between the gas molecule and the nanocage. The density of states of the gas adsorption complexes were also analyzed, and the results showed that the E g of the complexes decreased due to changes in the 3p orbital of the Si atom. This study theoretically devised novel multifunctional nanostructures through the adsorption of various gases onto pure nanocages, and the findings indicate the promise of these structures for use in electronic devices.

[1]  Y. Mary,et al.  Theoretical study of glycoluril by highly symmetrical magnesium oxide Mg12O12 nanostructure: adsorption, detection, SERS enhancement, and electrical conductivity study , 2022, Journal of Molecular Modeling.

[2]  M. S. Villanueva,et al.  In-silico study of the adsorption of H2, CO and CO2 chemical species on (TiO2)n n=15-20 clusters: The (TiO2)19 case as candidate promising. , 2022, Journal of molecular graphics & modelling.

[3]  A. Mendoza‐Wilson,et al.  Relative Populations and IR Spectra of Cu38 Cluster at Finite Temperature Based on DFT and Statistical Thermodynamics Calculations , 2022, Frontiers in Chemistry.

[4]  L. Tan,et al.  Growth mechanism, electronic properties and spectra of aluminum clusters. , 2021, Spectrochimica acta. Part A, Molecular and biomolecular spectroscopy.

[5]  K. Ayub,et al.  Extremely large static and dynamic nonlinear optical response of small superalkali clusters NM3M' (M, M'=Li, Na, K). , 2021, Journal of molecular graphics & modelling.

[6]  Karla F. Andriani,et al.  Ab initio investigation of the role of the d-states occupation on the adsorption properties of H2, CO, CH4 and CH3OH on the Fe13, Co13, Ni13 and Cu13 clusters. , 2021, Physical chemistry chemical physics : PCCP.

[7]  E. Chigo-Anota,et al.  Quantum-mechanical assessment of the adsorption of nitric oxide molecules on the magnetic carbon nitride (C36N24)− fullerene , 2021, Structural Chemistry.

[8]  S. Khan,et al.  Endohedral metallofullerene electrides of Ca12O12 with remarkable nonlinear optical response , 2021, RSC advances.

[9]  A. Soltani,et al.  Novel gamma arsenene nanosheets as sensing medium for vomiting agents: A first-principles research , 2020 .

[10]  A. Mansha,et al.  Designing Novel Zn-Decorated Inorganic B12P12 Nanoclusters with Promising Electronic Properties: A Step Forward toward Efficient CO2 Sensing Materials , 2020, ACS omega.

[11]  M. Rezaei-Sameti,et al.  The capability of the pristine and (Sc, Ti) doped Be12O12 nanocluster to detect and adsorb of Mercaptopyridine molecule: A first principle study , 2020 .

[12]  Shahid Hussain,et al.  Adsorption of Phosgene Gas on Pristine and Copper-Decorated B12N12 Nanocages: A Comparative DFT Study , 2020, ACS omega.

[13]  V. Nagarajan,et al.  Acrylonitrile vapor adsorption studies on armchair arsenene nanoribbon based on DFT study , 2019, Applied Surface Science.

[14]  A. Bautista-Hernández,et al.  Effect of Chemical Order in the Structural Stability and Physicochemical Properties of B12N12 Fullerenes , 2019, Scientific Reports.

[15]  K. Sapag,et al.  DFT study of hydrogen adsorption on Ni/graphene , 2018, Applied Surface Science.

[16]  Hongshan Chen,et al.  Prediction of the electron redundant Si n N n fullerenes , 2018 .

[17]  A. Rad,et al.  Ni adsorption on Al12P12 nano-cage: A DFT study , 2016 .

[18]  M. Arasu,et al.  Structural, morphological and optical properties of MgO nanoparticles for antibacterial applications , 2016 .

[19]  J. Pires,et al.  Computational studies of the Ca12O12, Ti12O12, Fe12O12 and Zn12O12 nanocage clusters , 2015 .

[20]  Elham Tahmasebi,et al.  The influence of alkali metals (Li, Na and K) interaction with Be12O12 and Mg12O12 nanoclusters on their structural, electronic and nonlinear optical properties: A theoretical study , 2015 .

[21]  Jun Li,et al.  Observation of an all-boron fullerene. , 2014, Nature chemistry.

[22]  R. Rozas,et al.  Evaluating the hydrogen chemisorption and physisorption energies for nitrogen-containing single-walled carbon nanotubes with different chiralities: a density functional theory study , 2014, Structural Chemistry.

[23]  A. A. Peyghan,et al.  Electronic, energetic, and structural properties of C- and Si-doped Mg12O12 nano-cages , 2013 .

[24]  J. Beheshtian,et al.  Selective function of Al12N12 nano-cage towards NO and CO molecules , 2012 .

[25]  Chandima Gomes,et al.  Hydrogen as an energy carrier: Prospects and challenges , 2012 .

[26]  J. Beheshtian,et al.  B12N12 Nano-cage as Potential Sensor for NO2 Detection , 2012 .

[27]  J. Beheshtian,et al.  A comparative study on the B12N12, Al12N12, B12P12 and Al12P12 fullerene-like cages , 2012, Journal of Molecular Modeling.

[28]  Iris M. Oppel,et al.  A salicylbisimine cage compound with high surface area and selective CO2/CH4 adsorption. , 2011, Angewandte Chemie.

[29]  Andreas Züttel,et al.  Hydrogen: the future energy carrier , 2008, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[30]  Ibrahim Dincer,et al.  A review on solar-hydrogen/fuel cell hybrid energy systems for stationary applications , 2009 .

[31]  Can Xu,et al.  Structural and electronic properties of hydrated MgO nanotube clusters , 2009 .

[32]  Weijun Zhang,et al.  Study of NO adsorption on activated carbons , 2008 .

[33]  Noel M. O'Boyle,et al.  cclib: A library for package‐independent computational chemistry algorithms , 2008, J. Comput. Chem..

[34]  V. Pokropivny,et al.  Electronic structure and the infrared absorption and Raman spectra of the semiconductor clusters C24, B12N12, Si12C12, Zn12O12, and Ga12N12 , 2007 .

[35]  G. Scuseria,et al.  Gaussian 03, Revision E.01. , 2007 .

[36]  N. Martín New challenges in fullerene chemistry. , 2006, Chemical communications.

[37]  M. Prato,et al.  Chemistry of carbon nanotubes. , 2006, Chemical reviews.

[38]  A. Goldberg,et al.  DFT study of hydrogen adsorption on Al13 clusters , 2005 .

[39]  Takeo Oku,et al.  Formation and atomic structure of B12N12 nanocage clusters studied by mass spectrometry and cluster calculation , 2004 .

[40]  Hongjie Dai,et al.  Carbon nanotubes: opportunities and challenges , 2002 .

[41]  Hiromichi Kataura,et al.  Optical properties of fullerene and non-fullerene peapods , 2002 .

[42]  G. S. Oleinik,et al.  Boron Nitride Analogs of Fullerenes (the Fulborenes), Nanotubes, and Fullerites (the Fulborenites) , 2000 .

[43]  Douglas L. Strout,et al.  Structure and Stability of Boron Nitrides: Isomers of B12N12 , 2000 .

[44]  François Diederich,et al.  Supramolecular fullerene chemistry , 1999 .

[45]  D. Cazorla-Amorós,et al.  Characterization of Activated Carbon Fibers by CO 2 Adsorption , 1996 .

[46]  N. Goroff Mechanism of Fullerene Formation , 1996 .

[47]  A. Becke Density-functional thermochemistry. , 1996 .

[48]  A. Becke Density-functional thermochemistry. III. The role of exact exchange , 1993 .

[49]  H. Kroto,et al.  C 60 Buckminsterfullerene , 1990 .

[50]  S. C. O'brien,et al.  C60: Buckminsterfullerene , 1985, Nature.