QTREX Awarded Government Grant to Advance Native RF Dielectric Material for Quantum Computing

Insider Brief QTREX has received an approximately $1 million grant from the Israel Innovation Authority to develop a dielectric material for superconducting quantum computing connectivity. The project focuses on improving high-density, low-loss RF and microwave signal routing in cryogenic quantum computing environments. QTREX is developing the material as part of its additively manufactured electronics platform for scalable quantum computing infrastructure. PRESS RELEASE — QTREX Quantum Ltd. (Nasdaq: QTEX) (“QTREX” or the “Company”), a company focused on advancing Additively Manufactured Electronics (“AME”) for quantum computing infrastructure, today announced that the Israel Innovation Authority (“IIA”) has awarded the Company an approximately $1 million grant to support the development of a purpose-built dielectric material engineered for high-density, low-loss RF signal routing in scalable superconducting quantum computing systems. QTREX’s program targets one of the core scaling constraints in superconducting quantum computing: the growing need to move more RF and microwave signals through cryogenic environments with lower loss, higher density and fewer assembly points. QTREX is developing the material as a native layer within its quantum connectivity architecture, enabling the Company to engineer the dielectric, conductor and 3D geometry together rather than adapting off-the-shelf materials to quantum requirements. This matters because in superconducting quantum systems, signal loss, impedance control, density and thermal behavior are driven by how the dielectric, conductor and geometry work together as a single structure. As superconducting quantum processors scale, connectivity becomes a system-level bottleneck across the industry. More qubits require more RF lines, tighter packaging, cleaner signal paths and lower thermal impact. This creates a clear need for purpose-built materials and monolithic connectivity components designed specifically for the physical demands of scalable quantum computing. “Superconducting quantum computers cannot scale on conventional wiring architecture,” said Dagi Ben-Noon, Chief Executive Officer of QTREX. “QTREX’s existing materials and AME capabilities already go beyond conventional industry approaches by enabling the Company to engineer materials, conductive pathways and 3D geometry as one integrated platform. This grant strengthens a core materials layer inside our quantum connectivity architecture and expands a capability we believe the industry has been missing. As we enter upcoming technical and commercial discussions with quantum hardware companies, QTREX is bringing a clear message to the market: scalable quantum computing requires a new connectivity architecture, and we are building it from the materials level up.” Mohib Ur Rehman LinkedIn Mohib has been tech-savvy since his teens, always tearing things apart to see how they worked. His curiosity for cybersecurity and privacy evolved from tinkering with code and hardware to writing about the hidden layers of digital life. Now, he brings that same analytical curiosity to quantum technologies, exploring how they will shape the next frontier of computing. Share this article: