Press Releases July 1, 2026 08:40 AM

QTREX Engineers Conductivity Itself to Address Quantum Computing’s Cryogenic Heat-Load Barrier

QTREX Develops Innovative Conductivity-Controlled Cryogenic Interconnects to Enhance Quantum Computing Performance

By Ajmal Hussain
Share
Twitter Reddit Facebook LinkedIn
QTEX

QTREX Quantum Ltd. announced the development of a novel controlled-conductivity cryogenic microwave interconnect architecture designed to reduce heat conduction while maintaining microwave signal integrity in quantum computing systems. This technology leverages the Wiedemann–Franz Law to engineer materials that optimize electrical and thermal conductivities at cryogenic temperatures, addressing key heat-load challenges in scaling quantum infrastructure. The company filed a provisional patent and is engaging industry collaborators for near-term evaluation.

QTREX Engineers Conductivity Itself to Address Quantum Computing’s Cryogenic Heat-Load Barrier
QTEX
Summarize with
ChatGPT Perplexity Claude Grok Gemini

Key Points

  • QTREX uses additive manufacturing and materials engineering to control electrical and thermal conductivity, improving quantum computing interconnects at millikelvin temperatures.
  • The technology addresses heat-load constraints in dilution refrigerators, critical for scaling superconducting quantum processors.
  • QTREX’s vertical integration from materials chemistry to final component production offers a unique competitive advantage in quantum infrastructure solutions.

Nes Ziona, Israel, July 01, 2026 (GLOBE NEWSWIRE) -- QTREX Quantum Ltd. (Nasdaq: QTEX) ("QTREX" or the "Company"), a company focused on advancing Additively Manufactured Electronics (“AME”) for quantum computing infrastructure today announced the development of a controlled-conductivity cryogenic microwave interconnect architecture designed to reduce heat conduction while preserving microwave signal performance in quantum computing systems. The Company filed a U.S. Provisional Patent Application with the United States Patent and Trademark Office (“USPTO”) and the underlying technology is patent pending.

The Company’s architecture is based on the intentional use of the Wiedemann–Franz Law, a fundamental law of physics linking electrical conductivity and electronic thermal conductivity in metallic conductors, with particular relevance at cryogenic temperatures. By applying this law at the materials-design level, The Company is turning conductivity into an engineering parameter for cryogenic quantum infrastructure, enabling conductive materials to be designed not only for signal transmission, but also for thermal behavior in ultra-low-temperature environments.

This capability is enabled by QTREX’s control over the full materials-to-component process, from the chemistry and engineering of its manufacturing materials, through the additive manufacturing process, and into the final quantum-infrastructure component. This vertical control allows the Company to design material behavior for the specific requirements of quantum environments.

In superconducting quantum computing systems, microwave control and readout signals must travel from room-temperature electronics to quantum processors operating at millikelvin temperatures inside dilution refrigerators. Each interconnect line can also become a thermal pathway, conducting unwanted heat into the coldest stages of the system. This is already a significant constraint in today’s cryogenic quantum systems and becomes increasingly critical as systems scale.

"Our ability to dictate material properties from the chemical formulation through to the final component gives us a unique competitive advantage in the quantum sector", said Dagi Ben-Noon, CEO of QTREX. "This architecture is a direct result of our vertically integrated approach, demonstrating how our advanced manufacturing capabilities has the potential of solving complex infrastructure challenges that traditional methods simply cannot address."

QTREX has seen strong interest from industry participants exposed to this development, reflecting the fact that this approach introduces a new way of thinking about cryogenic quantum infrastructure. This interest is already moving into near-term technical evaluation, with one of the Company’s current industry collaborators expected to begin reviewing the architecture as early as next week.

About QTREX Quantum
QTREX Quantum Ltd. (Nasdaq: QTEX) is a technology company focused on advanced connectivity and electronics manufacturing solutions for next-generation hardware markets. Following its acquisition of the AME platform, the Company is developing high-density, thermally optimized quantum connectivity solutions for dilution cryostats and advancing AME applications for defense, aerospace, missile, space, and other mission-critical environments. The Company also continues to advance its medical technology portfolio, including respiratory support and blood monitoring platforms, while actively working to monetize certain parts of the medical business.

For more information, please visit: www.q-trex.com

Forward-Looking Statement Disclaimer
This press release contains express or implied forward-looking statements pursuant to U.S. Federal securities laws. These forward-looking statements are based on the current expectations of the management of the Company only and are subject to factors and uncertainties that could cause actual results to differ materially from those described in the forward-looking statements. For example, the Company is using forward-looking statements when it discusses Conductivity’s ability to address quantum computing’s cryogenic heat-load barrier; the Company’s ability to enable conductive materials to be designed also for thermal behavior in ultra-low-temperature environments; the capabilities of the Company’s controlled-conductivity cryogenic microwave interconnect architecture; approval of the Company’s pending patents; the Company’s ability to design material behavior for the specific requirements of quantum environments; the belief that constraints in today’s cryogenic quantum systems become increasingly critical as systems scale; the belief that the Company has a unique competitive advantage in the quantum sector and how its advanced manufacturing capabilities has the potential of solving complex infrastructure challenges; any interest from industry participants; and the belief that the Company’s approach may introduces a new way of thinking about cryogenic quantum infrastructure. Except as otherwise required by law, the Company undertakes no obligation to publicly release any revisions to these forward-looking statements. More detailed information about the risks and uncertainties affecting the Company is contained under “Risk Factors” in the Company’s annual report on Form 20-F for the fiscal year ended December 31, 2025, filed with the U.S. Securities and Exchange Commission.

Company Contact
QTREX Quantum
Email: [email protected]
Phone: +972-9-9664485


Risks

  • The technology is patent pending and may face uncertainties in patent approval and protection which could affect competitive advantage.
  • Success depends on acceptance and integration by industry collaborators; technical or commercial evaluation might not lead to adoption.
  • Quantum computing infrastructure remains a complex, evolving field with potential regulatory, technical, and market uncertainties impacting commercialization.

More from Press Releases

Tenable Named as the Current Company to Beat for AI-Powered Exposure Assessment in a June 2026 Gartner® Report Jul 1, 2026 NewcelX Announces Successful FDA Pre-IND Meeting with Clear Path Forward for NCEL-101 Toward Starting Clinical Trials for Type 1 Diabetes Jul 1, 2026 Gray Media Completes Offering of $70 Million of Additional 7.250% Senior Secured First Lien Notes due 2033 and Repurchases $50 million of Series A Preferred Stock Jul 1, 2026 Rekor Systems Launches Rekor Scout Axis Agent With Go-Secure.Video: Bringing Trusted and Tamper-Evident Video to Standard Axis Cameras Jul 1, 2026 Virtuix Expands Defense Business with First Air National Guard Deployment Jul 1, 2026