Available for Licensing:High-Quality Superconducting ZrN Thin Films via Molecular Beam Epitaxy for Quantum Computing and Advanced Superconducting Technologies

High-Quality Superconducting ZrN Thin Films via Molecular Beam Epitaxy for Quantum Computing and Advanced Superconducting Technologies

Description

INL researchers have successfully established the parameters necessary for the deposition of high-quality superconducting zirconium nitride (ZrN) using molecular beam epitaxy (MBE). Key parameters include growth rate, temperature, flux ratios of zirconium (Zr) and nitrogen (N), and the choice of substrate. These parameters significantly impact the crystalline quality of the ZrN, which in turn affects its physical properties. Additionally, novel methods have been developed to induce unconventional superconductivity in conventional superconductors like ZrN.

Key Benefits

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  Superior Quality: MBE allows for fine-tuned growth parameters, resulting in top-quality, single-crystal ZrN superconducting films.

  
  

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  Unconventional Superconductivity: Methods for inducing unconventional superconductivity in ZrN have been conceptualized, potentially enabling more fault-tolerant computing.

  
  

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  Novel Application: ZrN has not previously been deposited using MBE, offering a unique advantage over existing superconducting thin films, which are often polycrystalline.

  
  

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  Tunable Impurities, Defects, and stoichiometry: The precise control during deposition minimizes impurities and defects, enabling better performance and higher critical temperatures. Direct control of stoichiometry allows for tunable performance metrics such as critical field and temperature.

  
  

Market Applications

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  Quantum Computing: Superconducting ZrN thin films can be used as platforms for superconducting qubits, a key component in the development of quantum computers.

  
  

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  Epitaxial Superconducting Heterostructures: The high-quality, high-uniformity films can be used to create advanced structures needed for unconventional superconducting technologies with atomic layer precision at wafer scale.

  
  

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  Research and Development: The technology can be utilized by researchers and companies focused on advancing superconducting materials and their applications.

  
  

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  Fault-Tolerant Computing: Unconventional superconducting schemes based on this technology could lead to more robust and fault-tolerant computing systems.

  
  

This technology represents a significant advancement in the field of superconducting materials, with broad implications for quantum computing and other high-tech applications.