Title :
Focused-Ion-Beam Direct-Writing of Ultra-Thin Superconducting Tungsten Composite Films
Author :
Li, Wuxia ; Fenton, Jon C. ; Warburton, Paul A.
Author_Institution :
London Centre for Nanotechnol., Univ. Coll. London, London, UK
fDate :
6/1/2009 12:00:00 AM
Abstract :
Tungsten composite films of thickness as low as 19 nm have been deposited using a 30 keV Ga+ focused-ion-beam with tungsten carboxyl (W(CO)6) as the gas precursor. Films of thickness 25 nm or more are superconducting with a transition temperature exceeding 5 K. Films in the thickness range 25 nm to 50 nm show an increasing Tc for a decreasing film thickness. This correlates well with the measured dependence of the normal state resistivity upon film thickness. We attribute this behavior to an increase in the BCS electron-phonon interaction potential resulting from a reduction in the electron mean-free-path as the film thickness is reduced. In the light of these data we discuss the applicability of FIB-deposited tungsten for devices requiring ultra-thin superconducting films, including photon detectors and phase-slip qubits.
Keywords :
BCS theory; composite materials; electron-phonon interactions; focused ion beam technology; superconducting thin films; superconducting transition temperature; BCS electron-phonon interaction potential; W; focused ion beam direct writing; phase-slip qubits; photon detectors; superconducting films; superconducting transition temperature; tungsten carboxyl; tungsten composite films; ultra thin films; Direct-writing; focused-ion-beam; superconductivity; thin film; tungsten composite;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2009.2019251
