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MicroAlign Secures €2.5M EIC Accelerator Grant and Equity Investment
•February 18, 2026
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Why It Matters
The grant removes a key supply‑chain constraint, speeding up commercial deployment of photonic quantum computers. It also positions MicroAlign to become a core supplier for high‑performance optical interconnects across telecom and imaging sectors.
Key Takeaways
- •€2.5M EIC grant accelerates high‑volume quantum fiber production
- •Nanometer‑scale alignment cuts photon loss at fiber‑chip interface
- •127 µm channel pitch meets dense integrated photonic circuit needs
- •Technology applicable to MEMS switches, wavelength‑selective switches
- •Goal: supply majority of photonic quantum market by 2029
Pulse Analysis
Photonic quantum computers rely on precise optical pathways to preserve qubit fidelity, and fiber‑to‑chip coupling has long been a performance choke point. Traditional passive assembly introduces alignment tolerances that translate into significant photon loss, limiting scalability. By injecting €2.5 million of EIC capital, MicroAlign can transition its patented micro‑actuator platform from laboratory prototypes to a high‑throughput line, directly tackling this bottleneck and enabling the thousands of fiber arrays required for next‑generation quantum processors.
The company’s micro‑manipulation approach offers nanometer‑scale active alignment, a stark contrast to the micrometer‑level tolerances of conventional telecom assemblies. This precision reduces insertion loss to well below 0.5 dB, a threshold critical for both quantum error rates and power budgets in dense photonic circuits. Moreover, the 127 µm channel pitch aligns with industry standards for integrated photonic chips, facilitating seamless integration with existing silicon‑photonic platforms. Beyond quantum computing, the same low‑loss, high‑density arrays are ideal for MEMS optical switches, wavelength‑selective devices, and high‑gain amplifiers, expanding the addressable market.
Strategically, the EIC Accelerator grant underscores Europe’s commitment to nurturing quantum‑hardware ecosystems. MicroAlign’s roadmap targets a dominant share of the global photonic quantum interconnect market by 2029, positioning the firm as a critical infrastructure provider. This scale‑up not only accelerates quantum hardware availability but also creates downstream opportunities for telecom operators, medical imaging firms, and materials‑science researchers who depend on ultra‑low‑loss optical networks. As the quantum sector matures, suppliers that can deliver mass‑produced, high‑precision components will dictate the pace of commercial adoption.
Deal Summary
MicroAlign announced it has received a €2.5 million accelerator grant and equity investment from the European Innovation Council (EIC) to industrialize high‑precision quantum fiber arrays, moving from pilot‑scale to high‑volume production. The funding will support the company’s roadmap to address bottlenecks in the photonic quantum computing supply chain.
Article
Source: Quantum Computing Report
MicroAlign secures €2.5 million ($3 million USD) EIC funding for industrialization of quantum fiber arrays
February 18, 2026
MicroAlign has secured a €2.5 million ($3 million USD) Accelerator Grant and equity investment from the European Innovation Council (EIC) to industrialize the production of high‑precision fiber arrays. These components are essential for photonic quantum architectures, which require thousands of arrays per system to maintain qubit preservation and control. The capital will transition the company’s manufacturing from pilot‑scale to high‑volume production, addressing a critical bottleneck in the photonic quantum computing supply chain.
The company utilizes patented micro‑manipulation technology to achieve nanometer‑scale active alignment of individual optical fibers. Unlike passive assembly methods used in standard telecommunications, this micro‑actuator‑based approach minimizes photon loss at the fiber‑to‑chip interface. For the 2026 product cycle, MicroAlign is miniaturizing this platform to deliver ultra‑high‑accuracy arrays with channel pitches reduced to 127 µm, meeting the density requirements of integrated photonic circuits.
Beyond quantum computing, the technology is being deployed for high‑end optical components such as MEMS switches, wavelength‑selective switches, and optical amplifiers. These applications increasingly require optical‑coupling loss targets below 0.5 dB across multi‑channel interfaces. By 2029, the firm intends to provide the optical interconnect infrastructure for a significant portion of the global photonic quantum market, facilitating advances in materials science and large‑scale diagnostic imaging.
For further technical details, view the official announcement on IO+ here, review the EIC Accelerator funding objectives here, or access the OFC 2026 exhibition schedule here.
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