SUMMARYWe describe the recent progress on a Nb nine-layer fabrication process for large-scale single flux quantum (SFQ) circuits. A device fabricated in this process is composed of an active layer including Josephson junctions (JJ) at the top, passive transmission line (PTL) layers in the middle, and a DC power layer at the bottom. We describe the process conditions and the fabrication equipment. We use both diagnostic chips and shift register (SR) chips to improve the fabrication process. The diagnostic chip was designed to evaluate the characteristics of basic elements such as junctions, contacts, resisters, and wiring, in addition to their defect evaluations. The SR chip was designed to evaluate defects depending on the size of the SFQ circuits. The results of a long-term evaluation of the diagnostic and SR chips showed that there was fairly good correlation between the defects of the diagnostic chips and yields of the SRs. We could obtain a yield of 100% for SRs including 70,000 JJs. These results show that considerable progress has been made in reducing the number of defects and improving reliability.
The use of highly packed multilevel interconnections with low resistance and low parasitic capacitance has attracted much attention as a method for increasing operating speed of ultralarge scale integrated circuits (ULSIs). 1 Copper (Cu) metallization has been intensively studied for increasing current density as well as reducing the resistance of interconnections and is going to be put to practical use. 2,3 The damascene process is expected to be very promising for producing fine Cu lines, 4 and the key to establishing this process is chemical mechanical polishing (CMP) of Cu and barrier metals. Slurries for Cu CMP usually contain an oxidizer, abrasive powder, etching chemicals of Cu or Cu oxide, and an inhibitor when necessary. 5,6 Kaufman et al. proposed a mechanism of tungsten CMP, a mechanism thought to be common to many kinds of metals, i.e., oxidation of the metal surface, removal of the oxide on protruding areas by abrasive particles in the slurry, and reoxidation of the exposed metal surface. 7 In order to provide damascene metal lines of high accuracy and at a high yield, the optimization of chemical characteristics of slurries and the CMP conditions have been investigated for achieving a large removal rate while suppressing dishing and erosion. 8 The Cu films, however, are very quick to corrode or be etched, especially in a wet-chemical environment. Two types of corrosion are known to occur during Cu CMP. One is chemical corrosion due to the chemical reaction of Cu with chemicals in the slurry, and the other is galvanic corrosion that occurs when two electrochemically different metals are electrically connected and exposed to the same electrolyte. Since these types of corrosion would result in pattern defects and loss of metal thickness (resistance increase), the chemicals of the Cu CMP slurry must be chosen carefully.This paper reports on the investigation of corrosion induced by Cu CMP slurries and describes a new mode of corrosion called pattern-specific corrosion. This paper also clarifies that this corrosion is due to photoillumination during interconnection fabrication; 9 thus, it may also be called photocorrosion. 10 Experimental CMP conditions and slurries.-A dead-weight-type CMP apparatus with an 18 in. diam platen was used with a grid-grooved, foamed polyurethane polishing pad (IC1000, Rodel Co.). The linear velocity of the wafer center to the polishing pad was varied from 25 to 50 m/min, and the down forces were varied from 140 to 210 g/cm 2 (13.7-21.6 kPa). Two kinds of alumina-based slurries were prepared. Slurry A is a mixture of hydrogen peroxide solution (H 2 O 2 , 30 wt % in water) and a commercially available, alumina abrasive suspension (QCTT1010, Rodel). The hydrogen exponent pH of the suspension is about 4.5. Though the suspension is an old one, it was chosen because it has been widely used as the standard suspension commercially available. The recommended mixing ratio of QCTT1010 to H 2 O 2 is 7:3 (volume ratio). Slurry B is a mixture of H 2 O 2 and an experimental alumina abrasiv...
The Superconductivity Research Laboratory has successfully fabricated large quantities of single flux quantum (SFQ) large scale integrated circuits, including several thousands of Josephson junctions (JJs). Using a J c = 2.5 kA cm −2 process in which the number of Nb layers was four and the minimum JJ size was 2 µm square. We developed a new advanced fabrication process that produced a J c = 10 kA cm −2 , nine Nb layers and a minimum JJ size of 1 µm square. The increase in the number of Nb layers was achieved by using a planarization technique. The target of our next generation process is a J c = 40 kA cm −2 with a 0.5 µm square for the minimum junction size. This specification will be achieved by using advanced semiconductor technologies. This process will enable SFQ circuits to be produced with one million JJs on a chip and achieve a clock frequency greater than 100 GHz.
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