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Main Authors: Mishra, Harsh, Kozuka, Yusuke, Bonam, Sathish, Uzuhashi, Jun, Suggisetti, Praveenkumar, Ohkubo, Tadakatsu, Singh, Shiv Govind
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.04712
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author Mishra, Harsh
Kozuka, Yusuke
Bonam, Sathish
Uzuhashi, Jun
Suggisetti, Praveenkumar
Ohkubo, Tadakatsu
Singh, Shiv Govind
author_facet Mishra, Harsh
Kozuka, Yusuke
Bonam, Sathish
Uzuhashi, Jun
Suggisetti, Praveenkumar
Ohkubo, Tadakatsu
Singh, Shiv Govind
contents Scalable quantum computing currently requires a large array of qubit integration, but present two-dimensional interconnects face challenges such as wiring congestion, electromagnetic interference, and limited cryogenic space. To overcome this challenge, implementing three-dimensional (3D) vertical architectures becomes crucial. Niobium (Nb), due to its excellent superconducting characteristics and strong fabrication process compatibility, stands out as a prime material choice. The main challenge in Nb-Nb bonding is the presence of an oxide layer at the interface, even after post-bonding annealing across various bonding methods. The native Nb oxide forms rapidly in air, creating a resistive barrier to supercurrent flow and introducing two-level system losses that degrade qubit coherence while increasing the overall thermal budget. These issues show the need for effective surface engineering to suppress oxidation during bonding. This study introduces an ultrathin gold (Au) capping layer as a passivation strategy to prevent oxygen incorporation at the Nb surface. This approach enables low-temperature Nb-Nb thermocompression bonding at 350 °C under a reduced bonding pressure of 0.495 MPa. Detailed microstructural and interfacial analyses confirm that Au passivation effectively suppresses oxide formation and hence enhances bonding uniformity and strength with keeping the superconductivity, establishing a robust route toward low-temperature, low-pressure Nb-Nb bonding for scalable 3D superconducting quantum computing architectures.
format Preprint
id arxiv_https___arxiv_org_abs_2512_04712
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Demonstration of surface-engineered oxidation-resistant Nb-Nb thermocompression bonding toward scalable superconducting quantum computing architectures
Mishra, Harsh
Kozuka, Yusuke
Bonam, Sathish
Uzuhashi, Jun
Suggisetti, Praveenkumar
Ohkubo, Tadakatsu
Singh, Shiv Govind
Superconductivity
Materials Science
Scalable quantum computing currently requires a large array of qubit integration, but present two-dimensional interconnects face challenges such as wiring congestion, electromagnetic interference, and limited cryogenic space. To overcome this challenge, implementing three-dimensional (3D) vertical architectures becomes crucial. Niobium (Nb), due to its excellent superconducting characteristics and strong fabrication process compatibility, stands out as a prime material choice. The main challenge in Nb-Nb bonding is the presence of an oxide layer at the interface, even after post-bonding annealing across various bonding methods. The native Nb oxide forms rapidly in air, creating a resistive barrier to supercurrent flow and introducing two-level system losses that degrade qubit coherence while increasing the overall thermal budget. These issues show the need for effective surface engineering to suppress oxidation during bonding. This study introduces an ultrathin gold (Au) capping layer as a passivation strategy to prevent oxygen incorporation at the Nb surface. This approach enables low-temperature Nb-Nb thermocompression bonding at 350 °C under a reduced bonding pressure of 0.495 MPa. Detailed microstructural and interfacial analyses confirm that Au passivation effectively suppresses oxide formation and hence enhances bonding uniformity and strength with keeping the superconductivity, establishing a robust route toward low-temperature, low-pressure Nb-Nb bonding for scalable 3D superconducting quantum computing architectures.
title Demonstration of surface-engineered oxidation-resistant Nb-Nb thermocompression bonding toward scalable superconducting quantum computing architectures
topic Superconductivity
Materials Science
url https://arxiv.org/abs/2512.04712