Large crystal grain niobium thin films deposited by energetic condensation in vacuum arc

Journal of Vacuum Science and Technology A: Vacuum, Surfaces and Films

Volumn 27, Issue 4, 2009, Pages 620-625

  Zhao, Xin ^a   Valente Feliciano, A M ^a   Xu, C ^a   Geng, R L ^a   Phillips, L ^a   Reece, C E ^a   Seo, K ^b   Crooks, R ^c   Krishnan, M ^d   Gerhan, A ^d   Bures, B ^d   Elliott, K Wilson ^d   Wright, J ^d  

^a THOMAS JEFFERSON NATIONAL ACCELERATOR FACILITY   (United States)

^b NORFOLK STATE UNIVERSITY   (United States)

^c Black Laboratories   (United Kingdom)

^d ALAMEDA APPLIED SCIENCES CORPORATION   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

ATOMIC LAYER; BREAK-UP; COLUMNAR STRUCTURES; COPPER SUBSTRATES; CRYSTAL GRAIN SIZE; CRYSTAL PLANES; CU SUBSTRATE; DENSE FILMS; DEPOSITION TECHNIQUE; ELECTRICAL PROPERTY; ELECTRON BACK SCATTER DIFFRACTION; ENERGETIC CONDENSATION; FAST IONS; HIGH ENERGY; HIGH SUBSTRATE TEMPERATURE; IN-VACUUM; ION POPULATION; LARGE CRYSTAL; LOWER COST; NANO SCALE; NANOSCALE FEATURES; NB FILM; NIOBIUM THIN FILM; NON EQUILIBRIUM; ORDER OF MAGNITUDE; POLY-CRYSTALLINE BULK; RESIDUAL RESISTIVITY RATIOS; SAMPLE SURFACE; SAPPHIRE SUBSTRATES; SMALL CRYSTALS; SOURCE MATERIAL; STATE OF THE ART; SUBSTRATE TEMPERATURE; SUPERCONDUCTING RADIO FREQUENCY; VACUUM ARCS; X-RAY DIFFRACTION MEASUREMENTS;

ADATOMS; CAVITY RESONATORS; COPPER; CORUNDUM; CRYSTAL ATOMIC STRUCTURE; ELECTRIC PROPERTIES; ELECTRON DIFFRACTION; GRAIN BOUNDARIES; GRAIN SIZE AND SHAPE; LIGHT; NANOSTRUCTURED MATERIALS; NIOBIUM; PARTICLE ACCELERATORS; PHYSICAL VAPOR DEPOSITION; SAPPHIRE; SINGLE CRYSTALS; SUBSTRATES; SUPERCONDUCTING FILMS; SUPERCONDUCTING TRANSITION TEMPERATURE; SUPERCONDUCTIVITY; THIN FILMS; VACUUM; VACUUM DEPOSITION;

AMORPHOUS FILMS;

EID: 67650337582     PISSN: 07342101     EISSN: None     Source Type: Journal    
DOI: 10.1116/1.3131725     Document Type: Article

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