Direct Bonding of NbN for 3-D Chip Integration of quantum processors

Abstract

3-D chip integration is considered to be the best way for further increasing the number of qubits on chip, and also for integration of qubits and readout electronics. Works have been done to stack two wafers with superconductive interconnections as a demonstration for feasibility of 3-D qubit integration.But all of them use an extra layer of adhesives, indium in particular, to join two neighboring planes.Indium is a good choice of adhesive for wafer bonding at cryogenic temperature. However, there are potential issues to employ this extra layer of adhesive. First, the critical temperature (Tc) of indium being 3.4K means it is suitable preferably for superconducting qubits, but not good enough for qubit implementations or other cryogenic that have above-4K expectations. Second, one general problem in wafer bonding is that alignment is not accurate. Adding an extra layer of anything increases the degree of misalignment. In this work, the extra adhesive layer is abandoned and two wafers are bonded by direct-bonding technique. First, niobium nitride (NbN) is chosen to be the skeleton for this 3-D structure due to its high Tc (18K) as well as its simple composition hence easy fabrication. Sputtering is the method used to fabricate such metal nitride. Sample with Tc=15.6K has been measured so far. Second, both wafer-scale and miniaturized pattern are designed to measure contact resistance of direct bonding of NbN films in room and cryogenic temperature. This work shows the potential of direct-wafer bonding in 3-D chip integration at cryogenic environment, and could further lead to scaling up of quantum processors.