ZadeNor AI
ZadeNor AI
Back to Blog
Quantum Computing

Leiden University and QuantaMap Introduce Multi-Modal Quantum Microscope

February 15, 2026
5 min
1,811 views
By ZadeNor AI Team
Leiden University and QuantaMap Introduce Multi-Modal Quantum Microscope

Leiden University and QuantaMap Introduce Multi-Modal Quantum Microscope

Revolutionizing Quantum Research: Leiden University and QuantaMap Unveil Breakthrough Multi-Modal Quantum Microscope

In a groundbreaking achievement, physicists at Leiden University, in collaboration with the startup QuantaMap, have introduced a revolutionary microscope designed specifically for the "quantum age." The Tapping-Mode SQUID-on-Tip (TM-SOT) microscope, affectionately nicknamed "Tortilla," is the first industrial-grade tool capable of simultaneously imaging four critical material properties—temperature, magnetism, structure, and electrical behavior—with nanoscale precision in a single scan.

The Technical Core: nanoSQUID Sensor and Atomic Force Microscope

The technical core of the instrument is a nanoSQUID (Superconducting Quantum Interference Device) sensor integrated into the very tip of an atomic force microscope (AFM) probe. This innovative design allows researchers to resolve nanoscale currents as small as 100 nA without the need for lasers or external radiation, which could otherwise disturb delicate quantum states. The nanoSQUID sensor is a crucial component, as it enables the microscope to detect even the slightest changes in the material's properties.

Tapping-Mode Feedback: Stability and Precision

By utilizing tapping-mode feedback, the microscope maintains extreme stability even when scanning highly corrugated or "bumpy" surfaces, such as fully fabricated quantum chips. This non-invasive technique allows researchers to study the material's properties without causing any damage or disruption. The tapping-mode feedback is a key feature of the microscope, as it enables researchers to achieve high precision and accuracy in their measurements.

Commercialization and Industry Impact

The commercialization of this technology is being led by QuantaMap, a Leiden-based startup co-founded by Kaveh Lahabi. The company aims to solve a primary bottleneck in quantum manufacturing: the lack of localized diagnostic tools. While traditional testing can take weeks to determine if a finished chip works, QuantaMap's system enables root-cause analysis at any fabrication stage. This allows developers to pinpoint why specific qubits underperform—whether due to thermal dissipation, magnetic impurities, or structural defects—thereby accelerating the design-fabrication-test cycle for scalable quantum processors.

Practical Implications and Real-World Applications

The introduction of the TM-SOT microscope has significant implications for the development of quantum computing and other quantum technologies. By enabling researchers to study the material's properties at the nanoscale, the microscope will help to accelerate the development of more efficient and reliable quantum processors. This, in turn, will enable the creation of more powerful and secure quantum computers, which will have a profound impact on various fields, including cryptography, optimization, and simulation.

Future Directions and Challenges

While the introduction of the TM-SOT microscope is a significant achievement, there are still many challenges to be addressed. One of the main challenges is the development of more advanced materials and technologies that can take advantage of the microscope's capabilities. Additionally, the microscope's high precision and accuracy require sophisticated data analysis and interpretation techniques, which will need to be developed and refined.

Conclusion

The introduction of the TM-SOT microscope is a groundbreaking achievement that will have a significant impact on the development of quantum computing and other quantum technologies. By enabling researchers to study the material's properties at the nanoscale, the microscope will help to accelerate the development of more efficient and reliable quantum processors. As the field continues to evolve, we can expect to see even more innovative technologies and applications emerge, and the TM-SOT microscope will play a key role in driving this progress.

References


Source: https://quantumcomputingreport.com/leiden-university-and-quantamap-introduce-multi-modal-quantum-microscope/

About the Author

ZadeNor AI Team is a leading expert in QUANTUM COMPUTING, contributing to cutting-edge research and development in the field.

Related Posts

Pasqal and MegazoneCloud Sign MoU for Neutral-Atom Hardware Deployment in South Korea

Pasqal and MegazoneCloud Sign MoU for Neutral-Atom Hardware Deployment in South Korea

Neutral-atom quantum hardware developer Pasqal and South Korean cloud managed service provider MegazoneCloud have executed a Memorandum of Understanding (MoU) to integrate quantum workloads into commercial enterprise infrastructures across South Korea. The non-binding framework outlines the domestic distribution of Pasqal’s hardware layers via MegazoneCloud's managed cloud service infrastructure, alongside collaborative application testing inside primary industrial [...] The post Pasqal and MegazoneCloud Sign MoU for Neutral-Atom Hardware Deployment in South Korea appeared first on Quantum Computing Report. ]]>

404
5 min
University of Michigan-Led QuPID Project Advances to Phase 2 of NSF National Quantum Virtual Laboratory Competition

University of Michigan-Led QuPID Project Advances to Phase 2 of NSF National Quantum Virtual Laboratory Competition

A research consortium led by University of Michigan Engineering has secured a $4 million USD Phase 2 award in the National Science Foundation’s (NSF) National Virtual Quantum Laboratory design competition. The two-year project, titled Quantum Photonic Integration and Deployment (QuPID), is one of nine initiatives selected to design plug-and-play photonic circuits that transition quantum measurements [...] The post University of Michigan-Led QuPID Project Advances to Phase 2 of NSF National Quantum Virtual Laboratory Competition appeared first on Quantum Computing Report. ]]>

404
5 min
Crédit Agricole CIB and Pasqal Execute Strategic Production Roadmap for Neutral Atom Quantum Finance Deploys

Crédit Agricole CIB and Pasqal Execute Strategic Production Roadmap for Neutral Atom Quantum Finance Deploys

Crédit Agricole CIB, the corporate and investment banking arm of Crédit Agricole Group, has finalized a strategic production partnership with neutral atom hardware developer Pasqal to transition capital markets workflows from exploratory research into operational industrialization. Building upon an initial exploratory collaboration established in 2019, the joint multi-year roadmap is structured to integrate quantum processing [...] The post Crédit Agricole CIB and Pasqal Execute Strategic Production Roadmap for Neutral Atom Quantum Finance Deploys appeared first on Quantum Computing Report. ]]>

234
5 min