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QTREX Quantum (Nasdaq: QTEX) files patent for cryogenic interconnect architecture

Filing Impact
(Neutral)
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(Neutral)
Form Type
6-K

Rhea-AI Filing Summary

QTREX Quantum Ltd. reported a new controlled-conductivity cryogenic microwave interconnect architecture aimed at reducing heat conduction while maintaining signal performance in superconducting quantum computing systems. The design treats electrical conductivity as an engineering parameter for both signal transmission and thermal behavior in ultra-low-temperature environments.

The Company has filed a U.S. provisional patent application for this technology, which leverages the Wiedemann–Franz Law and QTREX’s vertically integrated AME-based manufacturing process to tailor material properties from chemistry through final component. QTREX notes strong industry interest, with an existing collaborator expected to begin technical evaluation of the architecture as early as next week, and reminds readers that these statements are forward-looking and subject to risks.

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Insights

QTREX unveils patent-pending cryogenic interconnect concept with early industry interest but no quantified impact yet.

QTREX describes a cryogenic microwave interconnect architecture that uses the Wiedemann–Franz Law to tune both electrical and thermal conductivity. By controlling materials from chemistry through additive manufacturing, it aims to reduce heat load while preserving signal integrity inside dilution refrigerators.

The Company has filed a U.S. provisional patent and calls the approach "potentially dominant" for critical cryogenic signal pathways. That language, plus early interest from an existing collaborator moving into technical evaluation, suggests strategic ambition but not yet commercial adoption or revenue visibility.

For now, this is a technology and IP milestone rather than a financial one. The eventual importance will depend on validation from collaborators, successful patent prosecution, and whether quantum system builders integrate this architecture into real systems, points that would be clarified only in future disclosures.

Additively Manufactured Electronics technical
"a company focused on advancing Additively Manufactured Electronics (“AME”) for quantum computing infrastructure"
Additively manufactured electronics are electronic components and circuits created by layer-by-layer printing techniques instead of traditional machining or assembly. Think of building a cake where each layer can contain wiring, sensors or conductive traces so a finished part can combine structure and electronics in one piece. For investors, this can cut production time and part counts, enable custom or lightweight designs, and open new product opportunities or cost savings across manufacturing and supply chains.
Wiedemann–Franz Law technical
"based on the intentional use of the Wiedemann–Franz Law, a fundamental law of physics linking electrical conductivity"
A physical rule that links how well a material conducts heat to how well it conducts electricity: in many metals, the better it carries an electrical current, the better it also carries heat, with the ratio scaling with temperature. For investors, this matters because it helps predict thermal management, efficiency and reliability of electronic and energy technologies—factors that affect product performance, manufacturing costs and competitive advantage in hardware-related industries.
cryogenic microwave interconnect architecture technical
"announced the development of a controlled-conductivity cryogenic microwave interconnect architecture designed to reduce heat conduction"
dilution refrigerators technical
"quantum processors operating at millikelvin temperatures inside dilution refrigerators"
A dilution refrigerator is a specialized cryogenic machine that reaches temperatures just a fraction of a degree above absolute zero by separating and mixing two helium isotopes, creating an ultra‑cold environment needed for devices that only work at those extreme temps. Investors should care because these refrigerators are essential infrastructure for commercializing technologies like quantum computers and ultra‑sensitive sensors—think of them as the precision refrigerators that keep a fragile, high‑value product usable; their availability, cost, and performance affect how quickly and cheaply such products can scale.
forward-looking statements regulatory
"This press release contains express or implied forward-looking statements pursuant to U.S. Federal securities laws."
Forward-looking statements are predictions or plans that companies share about what they expect to happen in the future, like estimating sales or profits. They matter because they help investors understand a company's outlook, but since they are based on guesses and assumptions, they can sometimes be wrong.
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FAQ

What did QTREX Quantum (QTEX) announce in its latest 6-K filing?

QTREX Quantum announced a new cryogenic microwave interconnect architecture for quantum computing systems. The design aims to reduce heat conduction while maintaining microwave signal performance and is supported by a U.S. provisional patent application, positioning the company within advanced quantum infrastructure development.

How does QTREX Quantum’s new architecture address cryogenic heat-load in quantum computers?

The architecture uses controlled conductivity to manage both signal and thermal behavior in cryogenic environments. By applying the Wiedemann–Franz Law at the materials-design level, QTREX seeks to limit unwanted heat conduction along interconnect lines into millikelvin-temperature quantum processors.

What intellectual property steps has QTREX Quantum (QTEX) taken for this technology?

QTREX has filed a U.S. provisional patent application covering the new cryogenic interconnect architecture. The underlying technology is described as patent pending, and the company characterizes the approach as potentially dominant for critical cryogenic signal pathways in quantum infrastructure.

What role does QTREX’s Additively Manufactured Electronics (AME) platform play in this development?

QTREX’s AME platform enables vertical control from materials chemistry through final quantum components. This manufacturing approach lets the company engineer specific electrical and thermal properties into interconnects, tailoring behavior to the demanding conditions inside dilution refrigerators used in superconducting quantum computers.

Is there industry interest in QTREX Quantum’s cryogenic interconnect technology?

QTREX reports strong interest from industry participants exposed to the development. According to the company, one existing industry collaborator is expected to begin near-term technical evaluation of the architecture as early as next week, although no commercial agreements are described in the disclosure.

What markets beyond quantum computing does QTREX Quantum target?

QTREX targets advanced connectivity and electronics for defense, aerospace, missile, space, and medical applications. It is developing high-density, thermally optimized quantum connectivity and advancing AME-based solutions for mission-critical environments, while also progressing respiratory support and blood monitoring medical platforms.

 

 

UNITED STATES

SECURITIES AND EXCHANGE COMMISSION

Washington, D.C. 20549

 

 

 

FORM 6-K

 

 

 

REPORT OF FOREIGN PRIVATE ISSUER

PURSUANT TO RULE 13a-16 OR 15d-16

UNDER THE SECURITIES EXCHANGE ACT OF 1934

 

For the Month of July 2026

 

Commission File Number: 001-40303

 

Qtrex Quantum Ltd.

(Translation of registrant’s name into English)

 

2 Ha-Tidhar St.

Ra’anana 4366504, Israel

(Address of principal executive office)

 

Indicate by check mark whether the registrant files or will file annual reports under cover of Form 20-F or Form 40-F:

 

Form 20-F Form 40-F

 

 

 

 

 

 

CONTENTS

 

On July 1, 2026, Qtrex Quantum Ltd. (the “Company”) issued a press release titled “QTREX Engineers Conductivity Itself to Address Quantum Computing’s Cryogenic Heat-Load Barrier,” a copy of which is furnished as Exhibit 99.1 with this Report of Foreign Private Issuer on Form 6-K (this “Report”).

 

The first four paragraphs, the sixth paragraph, as well as the section titled “Forward-Looking Statement Disclaimer,” of the press release are incorporated by reference into the Company’s Registration Statements on Form F-3 (Registration Nos. 333-284308, 333-289324 and 333-296482) and Form S-8 (Registration Nos. 333-259057, 333-277980, 333-285565, 333-290162 and 333-292592), filed with the Securities and Exchange Commission, to be a part thereof from the date on which this Report is submitted, to the extent not superseded by documents or reports subsequently filed or furnished.

 

Exhibit No.    
99.1   Press release issued by Qtrex Quantum Ltd. on July 1, 2026, titled “QTREX Engineers Conductivity Itself to Address Quantum Computing’s Cryogenic Heat-Load Barrier.”

 

1

 

 

SIGNATURES

 

Pursuant to the requirements of the Securities Exchange Act of 1934, the registrant has duly caused this report to be signed on its behalf by the undersigned, thereunto duly authorized.

 

  Qtrex Quantum Ltd.
     
Date: July 1, 2026 By: /s/ Dagi Ben-Noon
    Name:  Dagi Ben-Noon
    Title: Chief Executive Officer

 

 

2

 

 

Exhibit 99.1

 

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

 

The Company Filed a U.S. Provisional Patent Application Covering a Potentially Dominant Approach to the Critical Cryogenic Signal Pathway, Designed to Overcome Limitations of Traditional Manufacturing

 

Ness Ziona, Israel, July 1, 2026 – 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 and that the patent application covers a potentially dominant approach to the critical cryogenic signal pathway; 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; that constraints in today’s cryogenic quantum systems become increasingly critical as systems scale; 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; that the Company’s approach may introduces a new way of thinking about cryogenic quantum infrastructure; and that the interest from the industry participants 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. 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: info@q-trex.com
Phone: +972-9-9664485

 

 

Filing Exhibits & Attachments

1 document