FEMTOGAPENGINE

Femtosecond Laser Superconducting Circuit Gap Engineering
Project type: ERC Proof of Concept Grant
Call ID: ERC-2026-PoC
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Participating organization: Jožef Stefan Institute, CENN Nanocenter in cooperation with Midalix d.o.o.
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Abstract

The Quantum Noise Challenge

Quantum processors, the backbone of next-generation computing, face a critical obstacle: noise. Superconducting quantum circuits, widely used by industry leaders like Google, IBM, D-Wave, Rigetti, and IQM, suffer from noise-induced errors that limit their performance. The primary culprit is quasiparticle poisoning—a phenomenon where stray electrons from cosmic rays and other sources disrupt quantum coherence, hindering the development of practical, large-scale quantum computers.Current solutions, such as gap engineering, require complex redesigns and additional fabrication steps. These approaches lack the flexibility to post-process existing chips, leaving a critical gap in the market.

The FEMTOGAPENGINE project introduces a revolutionary, maskless, post-fabrication process using femtosecond laser pulses to locally tune the superconducting gap (Δ) in Al-on-Si circuits. This innovation enables designer superconducting gap landscapes: Create engineered energy barriers and quasiparticle sinks with micron-scale precision, compatible with industry-standard layouts, in-situ & in-operando tuning. It allows the adjustment of superconducting properties after fabrication, without adding new materials or complex lithography. Its use effectively blocks quasiparticles from reaching sensitive Josephson junctions, dramatically improving quantum coherence.

Laserska pulzna obdelava kvantnih vezij

FEMTOGAPENGINE aims to develop a prototype machine for in-situ, in-operando superconducting circuit tuning and testing. This project will explore laser-processing parameters and their long-term stability, demonstrate post-fabrication tuning of superconducting test circuits and establish the first laser-defined platform for local superconducting gap engineering.

A successful outcome could transform the quantum computing industry, providing a scalable solution for quasiparticle management in quantum processors, detectors, resonators, and hybrid devices. This technology has the potential to actively reduce noise, marking a major milestone for quantum computing.

The global quantum computing market is projected to reach $100 billion by 2035 (McKinsey). Noise mitigation is the single biggest bottleneck in scaling superconducting quantum processors. FEMTOGAPENGINE addresses this challenge head-on, offering: a tool for the Quantum Age: Laser-processing workstations with IP-protected know-how for modifying and controlling noise in superconducting processors. Positioning us as a tool provider for the quantum industry, enabling chip manufacturers to post-process and optimize their devices.

 

*For inquiries, collaboration opportunities, or media requests, please contact the project team.

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Prof. Dr. Dragan Mihailović
Prof. Dr. Dragan Mihailović is one of the world’s leading researchers in time-resolved spectroscopy of complex materials. His work on high-temperature superconductors, low-dimensional quantum materials, and molecular magnetism has set new benchmarks in understanding dynamic phenomena in quantum systems. At the Jožef Stefan Institute, he established the Department of Complex Matter and the Centre of Excellence in Nanoscience and Nanotechnology. Prof. Dr. Mihailović has authored over 500 scientific papers, which have received more than 11,000 citations. His groundbreaking discoveries include ultrafast switching in hidden quantum states, the development of novel methods for studying real-time dynamic transitions, and contributions to high-impact journals like Science and Nature. Among his numerous achievements, Prof. Dr. Mihailović has pioneered studies on phase transitions in superconductors, charge density waves, Jahn-Teller phase transitions, and fullerenes using laser spectroscopy . His team discovered a hidden topological quantum state in an electronic crystal and developed record-breaking ultrafast memory elements, which opened new avenues for quantum material research. Together with Viktor Kabanov, he developed a fundamental theory of high-temperature superconductivity, recognized as crucial by Nobel laureate K. A. Müller. His groundbreaking discoveries also include a femtosecond quantum simulator, the implementation of Grover's algorithm, and research on fullerene compounds, where he unveiled the mechanism of ferromagnetism. In the field of nanotechnology, he participated in the discovery of molybdenum nanowires and studied their properties. In Slovenia, he introduced new experimental approaches, such as fullerene physics, molecular electronics, and the physics of high-temperature superconductors. As the first Slovenian recipient of an ERC Advanced Grant for established researchers in 2013, Prof. Dr. Mihailović delved into the study of ultrafast phase transitions and the creation of new exotic quantum states in matter. In 2017, through the ERC Proof of Concept grant, he developed an energy-efficient and ultrafast memory element based on TaS₂. His work in this field paves the way for new technological applications of quantum materials. In 2024, he once again secured ERC funding for the HIMMS project for established researchers. Prof. Dr. Mihailović has now secured a fourth ERC project through the Proof of Concept Grant 2026 with FEMTOGAPENGINE, making him the Slovenian researcher with the highest number of ERC-funded projects to date.