Title :
Fabrication process of planarized multi-layer Nb integrated circuits
Author :
Satoh, Tetsuro ; Hinode, Kenji ; Akaike, Hiroyuki ; Nagasawa, Shuichi ; Kitagawa, Yoshihiro ; Hidaka, Mutsuo
Author_Institution :
Supercond. Res. Lab., ISTEC, Ibaraki, Japan
fDate :
6/1/2005 12:00:00 AM
Abstract :
To improve the operating speed and density of Nb single-flux-quantum integrated circuits, we developed an advanced fabrication process based on NEC´s standard process. We fabricated planarized six-Nb-layer circuit structures using this advanced process. This new structure has four Nb wiring layers for greater design flexibility. To shield the magnetic field produced by the DC bias current, the DC bias power supply layer was placed under the groundplane. The critical current density of the Josephson junction was 10 kA/cm2. We fabricated and tested more than 10 wafers and demonstrated that the six-layer circuits were successfully planarized. We also confirmed insulation between each Nb layer and the reliability of superconducting contacts. This planarization did not significantly degrade the junction characteristics. We measured small spreads in the critical current of less than 2%. These results demonstrated the effectiveness of this advanced process based on mechanical-polishing planarization.
Keywords :
chemical mechanical polishing; critical current density (superconductivity); integrated circuit technology; magnetic shielding; niobium; planarisation; superconducting integrated circuits; Josephson junction; Nb; critical current density; integrated circuit fabrication; magnetic field shielding; mechanical polishing planarization; operating speed; planarized multilayer Nb integrated circuits; single flux quantum integrated circuits; six-layer circuits; superconducting integrated circuits; wiring layers; Circuit testing; Fabrication; Josephson junctions; Magnetic shielding; National electric code; Niobium; Planarization; Power supplies; Standards development; Wiring; Integrated circuit fabrication; Niobium; planarization; superconducting integrated circuits;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2005.849698
