P-type Al-doped Cr-deficient CrN thin films for thermoelectrics
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[1] Jun Lu,et al. Phonon thermal conductivity of scandium nitride for thermoelectrics from first-principles calculations and thin-film growth , 2017 .
[2] D. Fournier,et al. Reduction of the thermal conductivity of the thermoelectric material ScN by Nb alloying , 2017 .
[3] T. Sands,et al. Compensation of native donor doping in ScN: Carrier concentration control and p-type ScN , 2017 .
[4] E. Aydil,et al. Potential resolution to the doping puzzle in iron pyrite: Carrier type determination by Hall effect and thermopower , 2017 .
[5] P. Eklund,et al. Wet-cleaning of MgO(001): Modification of surface chemistry and effects on thin film growth investigated by x-ray photoelectron spectroscopy and time-of-flight secondary ion mass spectroscopy , 2017 .
[6] W. Pickett,et al. All-3 d Electron-Hole Bilayers in CrN /MgO (111 ) Multilayers for Thermoelectric Applications , 2017 .
[7] F. Eriksson,et al. Experimental and theoretical investigation of Cr 1-x Sc x N solid solutions for thermoelectrics , 2016 .
[8] W. Tremel,et al. A chemists view: Metal oxides with adaptive structures for thermoelectric applications , 2016 .
[9] P. Eklund,et al. Transition-metal-nitride-based thin films as novel energy harvesting materials , 2016, Journal of materials chemistry. C.
[10] G. Abadias,et al. A load-lock compatible system for in situ electrical resistivity measurements during thin film growth. , 2016, The Review of scientific instruments.
[11] Li-dong Zhao,et al. Thermoelectric materials: Energy conversion between heat and electricity , 2015 .
[12] Daniel A. Hillsberry,et al. Epitaxial CrN Thin Films with High Thermoelectric Figure of Merit , 2015, Advanced materials.
[13] B. Alling,et al. Role of N defects in paramagnetic CrN at finite temperatures from first principles , 2014, 1410.5346.
[14] K. Esfarjani,et al. Resonant bonding leads to low lattice thermal conductivity , 2014, Nature Communications.
[15] B. Rodríguez-González,et al. Thermoelectric properties of heavy-element doped CrN , 2014 .
[16] Mildred S Dresselhaus,et al. When thermoelectrics reached the nanoscale. , 2013, Nature nanotechnology.
[17] Taylor D. Sparks,et al. Data-Driven Review of Thermoelectric Materials: Performance and Resource Considerations , 2013 .
[18] Mark S. Lundstrom,et al. Thermoelectric properties of epitaxial ScN films deposited by reactive magnetron sputtering onto MgO(001) substrates , 2013 .
[19] C. Mitterer,et al. Insights into the atomic and electronic structure triggered by ordered nitrogen vacancies in CrN , 2013 .
[20] P. Eklund,et al. Effect of point defects on the electronic density of states of ScN studied by first-principles calculations and implications for thermoelectric properties , 2012 .
[21] L. Hultman,et al. The electronic-structure origin of the anisotropic thermopower of nanolaminated Ti3SiC2 determined by polarized x-ray spectroscopy and Seebeck measurements , 2012, 1205.4993.
[22] G. Wingqvist,et al. Anomalously high thermoelectric power factor in epitaxial ScN thin films , 2011 .
[23] Ryoji Funahashi,et al. Oxide thermoelectrics: The challenges, progress, and outlook , 2011 .
[24] P. Villechaise,et al. Reactive magnetron cosputtering of hard and conductive ternary nitride thin films: Ti–Zr–N and Ti–Ta–N , 2010 .
[25] J. Rivas,et al. Thermoelectric properties of stoichiometric and hole-doped CrN , 2009 .
[26] W. Lambrecht,et al. Electronic structure of CrN: A borderline Mott insulator , 2009 .
[27] M. Zebarjadi,et al. Thermoelectric Transport in a ZrN/ScN Superlattice , 2009 .
[28] Kunihito Koumoto,et al. Recent progress in oxide thermoelectric materials: p-type Ca3Co4O9 and n-type SrTiO3(-). , 2008, Inorganic chemistry.
[29] G. J. Snyder,et al. Complex thermoelectric materials. , 2008, Nature materials.
[30] S. Pantelides,et al. Structure and interaction of point defects in transition-metal nitrides , 2007 .
[31] Hubert Scherrer,et al. Transport in doped skutterudites: Ab initio electronic structure calculations , 2005 .
[32] A. Smith,et al. Incorporation of manganese into semiconducting ScN using radio frequency molecular beam epitaxy , 2004 .
[33] W. Tucker,et al. Growth of MgO thin films on M-, A-, C- and R-plane sapphire by laser ablation , 1999 .
[34] F. Disalvo,et al. Thermoelectric cooling and power generation , 1999, Science.
[35] M. S. Hegde,et al. Synthesis of TiN, VN, and CrN from Ammonolysis of TiS2, VS2, and Cr2S3☆☆☆ , 1997 .
[36] G. Lucovsky,et al. Effects of Resonance Bonding on the Properties of Crystalline and Amorphous Semiconductors , 1973 .
[37] H. Goldsmid,et al. Introduction to Thermoelectricity , 2010 .