Improved sensing characteristics of methane over ZnO nano sheets upon implanting defects and foreign atoms substitution
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Tanveer Hussain | Rajeev Ahuja | Sudip Chakraborty | Vittaya Amornkitbamrung | R. Ahuja | S. Chakraborty | V. Amornkitbamrung | T. Hussain | T. Kaewmaraya | Thanayut Kaewmaraya | Mehwish Khan | Muhammad Shafiq Islam | Mehwish Khan | M. S. Islam
[1] H. Monkhorst,et al. SPECIAL POINTS FOR BRILLOUIN-ZONE INTEGRATIONS , 1976 .
[2] Gianfranco Vidali,et al. Potentials of physical adsorption , 1991 .
[3] G. Kresse,et al. Ab initio molecular dynamics for liquid metals. , 1993 .
[4] Hafner,et al. Ab initio molecular-dynamics simulation of the liquid-metal-amorphous-semiconductor transition in germanium. , 1994, Physical review. B, Condensed matter.
[5] Blöchl,et al. Projector augmented-wave method. , 1994, Physical review. B, Condensed matter.
[6] Burke,et al. Generalized Gradient Approximation Made Simple. , 1996, Physical review letters.
[7] Yicheng Lu,et al. Epitaxial ZnO piezoelectric thin films for saw filters , 1999 .
[8] Naoto Koshizaki,et al. Sensing characteristics of ZnO-based NOx sensor , 2000 .
[9] Yiying Wu,et al. Room-Temperature Ultraviolet Nanowire Nanolasers , 2001, Science.
[10] Tiancheng Wang,et al. Oxygen sensing characteristics of individual ZnO nanowire transistors , 2004 .
[11] Z. Fan,et al. ZnO nanowire field-effect transistor and oxygen sensing property , 2004 .
[12] Chenglu Lin,et al. Fabrication and ethanol sensing characteristics of ZnO nanowire gas sensors , 2004 .
[13] Zhiyong Fan,et al. Gate-refreshable nanowire chemical sensors , 2005 .
[14] B. Delley,et al. Gas-phase-dependent properties of Sn O 2 (110), (100), and (101) single-crystal surfaces: Structure, composition, and electronic properties , 2005 .
[15] U. Diebold,et al. The surface and materials science of tin oxide , 2005 .
[16] David P. Norton,et al. Hydrogen and ozone gas sensing using multiple ZnO nanorods , 2005 .
[17] Jiaqiang Xu,et al. Gas sensing properties of ZnO nanorods prepared by hydrothermal method , 2005 .
[18] Jenshan Lin,et al. Hydrogen-selective sensing at room temperature with ZnO nanorods , 2005 .
[19] Caihong Wang,et al. Detection of H2S down to ppb levels at room temperature using sensors based on ZnO nanorods , 2006 .
[20] F. Trani,et al. Influence of surface and subsurface defects on the behavior of the rutile TiO2(110) surface , 2006 .
[21] Xiao Wei Sun,et al. Hydrothermally grown oriented ZnO nanorod arrays for gas sensing applications , 2006 .
[22] W. Ching,et al. Density-functional calculation of methane adsorption on graphite (0001) , 2006 .
[23] X. W. Sun,et al. Enzymatic glucose biosensor based on ZnO nanorod array grown by hydrothermal decomposition , 2006 .
[24] Jian Zhang,et al. Ammonia sensing characteristics of ZnO nanowires studied by quartz crystal microbalance , 2006 .
[25] Stefan Grimme,et al. Semiempirical GGA‐type density functional constructed with a long‐range dispersion correction , 2006, J. Comput. Chem..
[26] Eric Henderson,et al. Microfabricated "Biomolecular Ink Cartridges"—Surface patterning tools (SPTs) for the printing of multiplexed biomolecular arrays , 2006 .
[27] C. N. R. Rao,et al. Room temperature hydrogen and hydrocarbon sensors based on single nanowires of metal oxides , 2007 .
[28] Hailong Lu,et al. Size Dependence of Gas Sensitivity of ZnO Nanorods , 2007 .
[29] Xiaobo Chen,et al. Titanium dioxide nanomaterials: synthesis, properties, modifications, and applications. , 2007, Chemical reviews.
[30] Wei Gao,et al. Photoluminescence properties of ZnO films grown by wet oxidation: Effect of processing , 2008 .
[31] D. Ninno,et al. Density functional study of oxygen vacancies at the SnO 2 surface and subsurface sites , 2008, 0804.3460.
[32] A. Iacomino,et al. Structural, electronic, and surface properties of anatase TiO2 nanocrystals from first principles , 2008 .
[33] S. Ciraci,et al. A First-Principles Study of Zinc Oxide Honeycomb Structures , 2009, 0907.3070.
[34] A. Iacomino,et al. DFT Study on Anatase TiO2 Nanowires: Structure and Electronic Properties As Functions of Size, Surface Termination, and Morphology , 2010 .
[35] Dong Xiang,et al. Metal Oxide Gas Sensors: Sensitivity and Influencing Factors , 2010, Sensors.
[36] Ho Won Jang,et al. One-Dimensional Oxide Nanostructures as Gas-Sensing Materials: Review and Issues , 2010, Sensors.
[37] Matthias Witte,et al. Methane adsorption on graphene from first principles including dispersion interaction , 2011 .
[38] G. Cantele,et al. First-Principles Calculations of Clean and Defected ZnO Surfaces , 2012 .
[39] Jinlong Yang,et al. Tunable Magnetism in a Nonmetal-Substituted ZnO Monolayer: A First-Principles Study , 2012 .
[40] Chang-wen Zhang,et al. First-principles study on ferromagnetism in two-dimensional ZnO nanosheet , 2012 .
[41] G. Ankonina,et al. Bio‐Inspired Band Gap Engineering of Zinc Oxide by Intracrystalline Incorporation of Amino Acids , 2019, Advanced materials.
[42] Shaoming Fang,et al. Tunable electronic and magnetic properties of graphene-like ZnO monolayer upon doping and CO adsorption: a first-principles study , 2014 .
[43] Derek R. Miller,et al. Nanoscale metal oxide-based heterojunctions for gas sensing: A review , 2014 .
[44] R. Ahuja,et al. Sensing propensity of a defected graphane sheet towards CO, H2O and NO2 , 2014, Nanotechnology.
[45] R. Ahuja,et al. Complementing the adsorption energies of CO2, H2S and NO2 to h-BN sheets by doping with carbon , 2015 .
[46] M. Hu,et al. Synthesis and room temperature CH4 gas sensing properties of vanadium dioxide nanorods , 2016 .
[47] M. Hu,et al. Room temperature CH4 sensing properties of Au decorated VO2 nanosheets , 2016 .
[48] R. Ahuja,et al. Augmenting the sensing aptitude of hydrogenated graphene by crafting with defects and dopants , 2016 .
[49] E. Massera,et al. Effects of graphene defects on gas sensing properties towards NO2 detection. , 2017, Nanoscale.
[50] Changsheng Xie,et al. Metal-oxide-semiconductor based gas sensors: screening, preparation, and integration. , 2017, Physical chemistry chemical physics : PCCP.
[51] N. Tit,et al. Ab-initio investigation of adsorption of CO and CO 2 molecules on graphene: Role of intrinsic defects on gas sensing , 2017 .
[52] C. Majumder. Adsorption and decomposition of dimethyl methylphosphonate on pristine and mono-vacancy defected graphene: A first principles study , 2017 .
[53] X. Chu,et al. Preparation and gas sensing properties of graphene-Zn2SnO4 composite materials , 2017 .
[54] Na Yeon Kim,et al. Atomic Scale Study on Growth and Heteroepitaxy of ZnO Monolayer on Graphene , 2016, Nano letters.
[55] Ning Yang,et al. First-principles approach to design and evaluation of graphene as methane sensors , 2017 .
[56] Bing Wang,et al. Low-temperature and highly sensitive C2H2 sensor based on Au decorated ZnO/In2O3 belt-tooth shape nano-heterostructures , 2017 .
[57] Ghenadii Korotcenkov,et al. Metal oxide composites in conductometric gas sensors: Achievements and challenges , 2017 .
[58] B. P. Dhonge,et al. Fabrication of ultra-high sensitive and selective CH4 room temperature gas sensing of TiO2 nanorods: Detailed study on the annealing temperature , 2017 .