Electronic properties of reduced molybdenum oxides.
暂无分享,去创建一个
M. Nematollahi | T. Grande | M. Nematollahi | F. Vullum-Bruer | T. Reenaas | M. Nematollahi | S. Selbach | T. Grande | K. Inzani | F. Vullum-Bruer | T. W. Reenaas | S. M. Selbach | K. Inzani | Katherine Inzani
[1] Po-Tsung Hsieh,et al. Post-annealing effect upon optical properties of electron beam evaporated molybdenum oxide thin films , 2009 .
[2] L. Brewer,et al. The Mo-O system (Molybdenum-Oxygen) , 1980 .
[3] E. Broclawik,et al. SCF-SW-Xα calculations of the removal of oxygen from oxide surfaces by vacancy formation and crystallographic shear mechanisms , 1981 .
[4] A. Gavrilyuk,et al. The nature of the photochromism arising in the nanosized MoO3 films , 2011 .
[5] C. Battaglia,et al. Hole selective MoOx contact for silicon solar cells. , 2014, Nano letters.
[6] Chih-Chieh Chan,et al. Electrochromic properties of nanocrystalline MoO3 thin films , 2008 .
[7] Zhenghong Lu,et al. Metal/Metal‐Oxide Interfaces: How Metal Contacts Affect the Work Function and Band Structure of MoO3 , 2013 .
[8] S. Åsbrink,et al. A Study of the Crystal Symmetry and Structure of Orthorhombic Mo4O11 by Least-squares Techniques. , 1964 .
[9] Lingyu Kong,et al. Detrimental Effects of Oxygen Vacancies in Electrochromic Molybdenum Oxide , 2015 .
[10] T. Grande,et al. A van der Waals Density Functional Study of MoO3 and Its Oxygen Vacancies , 2016 .
[11] G. Rohrer,et al. Scanning Probe Microscopy of Cleaved Molybdates: α-MoO3(010), Mo18O52(100), Mo8O23(010), and η-Mo4O11(100) , 1996 .
[12] Jian Zhen Ou,et al. Tunable Plasmon Resonances in Two‐Dimensional Molybdenum Oxide Nanoflakes , 2014, Advanced materials.
[13] I. Navas,et al. Self-assembly and photoluminescence of molybdenum oxide nanoparticles , 2011 .
[14] Y. Foo,et al. Photochromism of amorphous molybdenum oxide films with different initial Mo5+ relative concentrations , 2013 .
[15] R. Grigorovici,et al. Optical Properties and Electronic Structure of Amorphous Germanium , 1966, 1966.
[16] A. Magnéli,et al. Studies on Molybdenum Oxides. , 1959 .
[17] L. Sygellou,et al. The influence of hydrogenation and oxygen vacancies on molybdenum oxides work function and gap states for application in organic optoelectronics. , 2012, Journal of the American Chemical Society.
[18] Kresse,et al. Efficient iterative schemes for ab initio total-energy calculations using a plane-wave basis set. , 1996, Physical review. B, Condensed matter.
[19] N. Floquet,et al. Reactivity of the Mo18O52(100) surface: A study by RHEED of the Mo18O52-MoO3 structural transformation , 1989 .
[20] L. Bursill. Electron microscope study of an homologous series of shear structures based on molybdenum trioxide , 1972 .
[21] X. Haitao,et al. Investigation of hole injection enhancement by MoO3 buffer layer in organic light emitting diodes , 2013 .
[22] G. Kresse,et al. Ab initio molecular dynamics for liquid metals. , 1993 .
[23] L. Liao,et al. Improved cation valence state in molybdenum oxides by ultraviolet-ozone treatments and its applications in organic light-emitting diodes , 2013 .
[24] G. B. Reddy,et al. Optical, structural and photoelectron spectroscopic studies on amorphous and crystalline molybdenum oxide thin films , 2004 .
[25] N. Xu,et al. Highly conductive vertically aligned molybdenum nanowalls and their field emission property , 2012, Nanoscale Research Letters.
[26] Bruce Dunn,et al. Oxygen vacancies enhance pseudocapacitive charge storage properties of MoO3-x. , 2017, Nature materials.
[27] Xuefeng Guo,et al. Partially nitrided molybdenum trioxide with promoted performance as an anode material for lithium-ion batteries , 2014 .
[28] Xing-hua Zhu,et al. Strong influence of substrate temperature on the growth of nanocrystalline MoO3 thin films , 2009 .
[29] Chih‐I Wu,et al. Enhancing the incorporation compatibility of molybdenum oxides in organic light emitting diodes with gap state formations , 2013 .
[30] T. He,et al. Photochromism of molybdenum oxide , 2003 .
[31] L. Kranz,et al. Development of MoOx thin films as back contact buffer for CdTe solar cells in substrate configuration , 2013 .
[32] G. Seifert,et al. A two-electron mechanism of lithium insertion into layered α-MoO3: a DFT and DFT+U study , 2013 .
[33] E. Mccarron. β-MoO3: a metastable analogue of WO3 , 1986 .
[34] M. Gao,et al. Thermodynamic modeling and first-principles calculations of the Mo–O system , 2014 .
[35] A. H. Klahn,et al. Growth and characterization of molybdenum oxide thin films prepared by photochemical metal–organic deposition (PMOD) , 2010 .
[36] Changsheng Shi,et al. Room-temperature sol-gel derived molybdenum oxide thin films for efficient and stable solution-processed organic light-emitting diodes. , 2013, ACS applied materials & interfaces.
[37] Juan Bisquert,et al. Combinatorial Investigation and Modelling of MoO3 Hole‐Selective Contact in TiO2|Co3O4|MoO3 All‐Oxide Solar Cells , 2016 .
[38] D. Willock,et al. The (010) surface of α-MoO3, a DFT + U study , 2005 .
[39] Geoffrey B. Smith,et al. The insulator to correlated metal phase transition in molybdenum oxides , 2013 .
[40] Thomas M. Higgins,et al. Production of Molybdenum Trioxide Nanosheets by Liquid Exfoliation and Their Application in High-Performance Supercapacitors , 2014 .
[41] Lei Ding,et al. Aqueous solution-processed MoO3 thick films as hole injection and short-circuit barrier layer in large-area organic light-emitting devices , 2014 .
[42] Y. Tezuka,et al. Soft X-ray absorption and emission study on anisotropic electronic structure of MoO3 , 2010 .
[43] Dae-gun Kim,et al. MoO3 thin film synthesis by chemical vapor transport of volatile MoO3(OH)2 , 2010 .
[44] Geoffroy Hautier,et al. Data mining approaches to high-throughput crystal structure and compound prediction. , 2014, Topics in current chemistry.
[45] Y. Sakurai,et al. Characterization of MoO3-x Thin Films , 2001 .
[46] K. Latham,et al. Electrodeposited alpha- and beta-phase MoO3 films and investigation of their gasochromic properties , 2012 .
[47] N. Motta,et al. Hydrogen gas sensors based on thermally evaporated nanostructured MoO3 Schottky diode: A comparative study , 2011, 2011 IEEE SENSORS Proceedings.
[48] G. Kresse,et al. Efficiency of ab-initio total energy calculations for metals and semiconductors using a plane-wave basis set , 1996 .
[49] R. Schlögl,et al. Properties of oxygen sites at the MoO_3(010) surface: density functional theory cluster studies and photoemission experiments , 2001 .
[50] Du Xiang,et al. Gap States Assisted MoO3 Nanobelt Photodetector with Wide Spectrum Response , 2014, Scientific Reports.
[51] S. Pradhan,et al. MoO3 anode buffer layer for efficient and stable small molecular organic solar cells , 2015 .
[52] Brian E. McCandless,et al. Characterization of reactively sputtered molybdenum oxide films for solar cell application , 2013 .
[53] A. Magnéli,et al. The Crystal Structures of Mo9O26 (beta'-Molybdenum Oxide) and Mo8O23 (beta-molybdenum Oxide). , 1948 .
[54] L. Bursill. Crystallographic shear in molybdenum trioxide , 1969, Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences.
[55] John Wang,et al. Ordered mesoporous alpha-MoO3 with iso-oriented nanocrystalline walls for thin-film pseudocapacitors. , 2010, Nature materials.
[56] A. Heeger,et al. A Solution‐Processed MoOx Anode Interlayer for Use within Organic Photovoltaic Devices , 2012 .
[57] G. Kresse,et al. Improved hybrid functional for solids: the HSEsol functional. , 2011, The Journal of chemical physics.
[58] S. Sreedhar,et al. Alteration of architecture of MoO₃ nanostructures on arbitrary substrates: growth kinetics, spectroscopic and gas sensing properties. , 2014, Nanoscale.
[59] G. Kresse,et al. From ultrasoft pseudopotentials to the projector augmented-wave method , 1999 .
[60] P. L. Gai-Boyes. Defects in Oxide Catalysts: Fundamental Studies of Catalysis in Action , 1992 .
[61] R. Landers,et al. Molybdenum oxide thin films obtained by the hot-filament metal oxide deposition technique , 2004 .
[62] S. Russo,et al. Substoichiometric two-dimensional molybdenum oxide flakes: a plasmonic gas sensing platform. , 2014, Nanoscale.
[63] R. G. Egdell,et al. Theoretical and experimental study of the electronic structures of MoO 3 and MoO 2 , 2010 .
[64] Kyu-Nam Jung,et al. Synthesis of nitrided MoO2 and its application as anode materials for lithium-ion batteries , 2012 .
[65] J. S. Lee,et al. Free-polymer controlling morphology of α-MoO3 nanobelts by a facile hydrothermal synthesis, their electrochemistry for hydrogen evolution reactions and optical properties , 2012 .
[66] M. Onoda,et al. Structural transitions in MonO3n-1 (n=9 and 10) , 1987 .
[67] J. Robertson,et al. Metal Oxide Induced Charge Transfer Doping and Band Alignment of Graphene Electrodes for Efficient Organic Light Emitting Diodes , 2014, Scientific Reports.
[68] L. Larsson,et al. The Crystal Structure of Mo17O47. , 1960 .
[69] D. B. Rogers,et al. Crystal chemistry of metal dioxides with rutile-related structures , 1969 .
[70] M. Strano,et al. Enhanced Charge Carrier Mobility in Two‐Dimensional High Dielectric Molybdenum Oxide , 2013, Advanced materials.
[71] C. Humphreys,et al. Electron-energy-loss spectra and the structural stability of nickel oxide: An LSDA+U study , 1998 .
[72] C. Liu,et al. Ultrasonic synthesis of MoO3 nanorods and their gas sensing properties , 2012 .
[73] P. Carcia,et al. Synthesis and properties of thin film polymorphs of molybdenum trioxide , 1987 .
[74] Wang Shimin,et al. Preparation and Characterization of Molybdenum Oxide Thin Films by Sol-Gel Process , 2003 .
[75] R. Adelung,et al. Investigation of optical properties and electronic transitions in bulk and nano-microribbons of molybdenum trioxide , 2014 .
[76] David O. Scanlon,et al. Theoretical and Experimental Study of the Electronic Structures of MoO3 and MoO2 , 2010 .
[77] W. H. Baur. The geometry of polyhedral distortions. Predictive relationships for the phosphate group , 1974 .
[78] Zhenghong Lu,et al. Impact of lattice distortion and electron doping on α-MoO3 electronic structure , 2014, Scientific Reports.
[79] V. R. Porter,et al. Optical spectra of the intermediate oxides of titanium, vanadium, molybdenum, and tungsten , 1972 .