Title :
A high density 4 kA/cm2 Nb integrated circuit process
Author :
Kerber, George L. ; Abelson, Lynn A. ; Leung, Michael L. ; Herr, Quentin P. ; Johnson, Mark W.
Author_Institution :
Electron. & Technol. Div., TRW Inc., Redondo Beach, CA, USA
fDate :
3/1/2001 12:00:00 AM
Abstract :
We have developed an improved 4 kA/cm2 process technology that allows a significant increase in circuit speed and density. Improved photoresist and dry etch processes have reduced critical dimension (CD) variation and improved CD linearity to below 1 μm. These improvements have enabled a substantial reduction in feature size and full utilization of existing photolithography and etch tools. We have demonstrated mire pitch of 2.0 μm with less than 0.1 μm CD loss. Minimum junction diameter and contact are 1.75 μm and 1.0 μm, respectively. Junctions, fabricated using a new barrier oxidation method with improved pressure control, have excellent I-V characteristics and array Ic nonuniformity less than 1.6% (1σ). We have demonstrated a 200 GHz, 12-stage divider circuit that is the fastest complex digital superconductor integrated circuit fabricated to date. With the present process tools, defects are the limiting factor to further increases in circuit density and yield. In this paper, we discuss process improvements, electrical performance, defect reduction, and circuit performance
Keywords :
integrated circuit technology; niobium; oxidation; photolithography; sputter etching; superconducting integrated circuits; 200 GHz; I-V characteristics; Josephson junction array; Nb; Nb process technology; SFQ logic; barrier oxidation; critical current; critical dimension; digital superconductor integrated circuit; divider circuit; dry etching; photolithography; photoresist; Digital integrated circuits; Dry etching; Integrated circuit yield; Josephson junctions; Linearity; Lithography; Oxidation; Pressure control; Resists; Superconducting integrated circuits;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
