May 22, 2025
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Quantum Magnetometry Equipment: 2025’s Breakout Tech Revolution & Multibillion Dollar Forecast

Joanna Rivers038 mins
Quantum Magnetometry Equipment: 2025’s Breakout Tech Revolution & Multibillion Dollar Forecast

Table of Contents

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Executive Summary: Key Findings for 2025–2030

The quantum magnetometry equipment manufacturing sector is poised for significant evolution between 2025 and 2030, driven by rapid advances in quantum technologies and growing demand for ultra-sensitive magnetic field detection across diverse industries. Quantum magnetometers—based on nitrogen-vacancy (NV) centers in diamond, optically pumped magnetometers (OPMs), and superconducting quantum interference devices (SQUIDs)—are transitioning from research laboratories to commercial and industrial applications.

Major manufacturers are scaling up production capacities and refining device architectures to deliver improved sensitivity, portability, and integration. Companies such as Qnami, which specializes in diamond-based quantum sensors, and Magneteca are expanding their portfolio of quantum magnetometry solutions, targeting sectors including biomedical imaging, materials characterization, and navigation. In parallel, established players like QuSpin are focusing on miniaturized OPMs for neuroimaging and defense.

The period from 2025 through 2030 is expected to be marked by:

  • Growing Commercialization: Quantum magnetometers are expected to achieve broader market penetration, with successful pilot deployments in healthcare (e.g., magnetoencephalography), non-destructive testing, and mineral exploration. Partnerships between equipment manufacturers and end users are anticipated to accelerate product validation and regulatory acceptance.
  • Technological Convergence: Integration of quantum magnetometry with advanced data analytics, photonic integration, and compact cryogenics is anticipated. Investments in R&D by firms like Qnami and QuSpin are projected to yield more robust, user-friendly instruments.
  • Expansion of Manufacturing Ecosystem: New entrants and partnerships are expected, as component suppliers and OEMs seek to tap into the growing demand for quantum-enabled sensors. Efforts to standardize device interfaces and calibration protocols are underway in collaboration with academic and government research bodies.
  • Regional Growth Dynamics: Europe and North America are set to remain leading hubs for innovation and manufacturing, with Asia-Pacific firms increasingly investing in quantum sensing. Collaborative initiatives and funding programs are likely to shape supply chain resilience and talent development.

Overall, the outlook for 2025–2030 reflects a sector transitioning from scientific curiosity to industrial utility, with equipment manufacturers playing a central role in enabling new applications and shaping the broader quantum sensing landscape.

Market Size & Growth Forecasts: Volumes and Revenue Projections

The quantum magnetometry equipment manufacturing sector is poised for significant expansion through 2025 and the succeeding years, driven by increased demand from sectors such as medical diagnostics, navigation, mineral exploration, and fundamental physics research. Quantum magnetometers, leveraging nitrogen-vacancy (NV) diamond, optically pumped magnetometers (OPMs), and superconducting quantum interference devices (SQUIDs), are enabling detection of minute magnetic fields with unprecedented sensitivity. This capability is rapidly pushing the adoption of such technologies across both established and emerging applications.

Although precise publicly available figures for the global quantum magnetometry equipment market size remain limited due to the nascent nature of the sector, leading manufacturers and research bodies indicate robust growth trajectories. For instance, QuSpin, a prominent supplier of commercial OPM-based magnetometers, reports increasing orders from neuroscience and biomagnetic research institutions, reflecting surging adoption in magnetoencephalography (MEG) and cardiography. Similarly, Lockheed Martin and Muquans are expanding their production capabilities to address growing orders for quantum-enabled navigation and mineral detection solutions.

Annual shipment volumes for advanced quantum magnetometers are projected to grow at a compound annual growth rate (CAGR) exceeding 25% from 2025 through 2028, as per statements from industry-leading manufacturers. The revenue outlook is equally optimistic, with the market forecast to approach the high tens of millions of dollars by the late 2020s—driven by both increased unit sales and the premium pricing of high-performance systems. For example, QuSpin has reported multi-year contracts with leading research laboratories and medical device integrators, suggesting sustained demand and recurring revenues. Meanwhile, Lockheed Martin’s investment in quantum navigation hints at anticipated large-scale government and defense procurements within the next few years.

Geographically, North America and Europe currently dominate the quantum magnetometry equipment market, owing to heavy R&D investments and early adoption in scientific and medical sectors. However, Asia-Pacific is expected to see the fastest growth, with companies like Muquans collaborating with regional partners for broader distribution and localized manufacturing.

Looking ahead, as quantum sensor miniaturization and mass-manufacturing processes continue to mature, the sector is expected to see further volume growth and gradual price moderation, broadening accessibility for a wider range of industrial and research applications. The interplay between ongoing innovation and scaling production capacity among established players such as QuSpin, Lockheed Martin, and Muquans is likely to define market size and revenue dynamics through the remainder of the decade.

Technological Innovations Shaping Quantum Magnetometry

The manufacturing landscape for quantum magnetometry equipment in 2025 is characterized by rapid innovation, driven by advancements in quantum sensing technologies and the increasing demand for ultra-sensitive magnetic field detection across scientific, medical, and industrial domains. Quantum magnetometers, leveraging quantum phenomena such as spin states in nitrogen-vacancy (NV) centers in diamond or alkali vapor cells, are pushing the boundaries of sensitivity and spatial resolution.

A notable trend in 2025 is the miniaturization and integration of quantum magnetometers, enabling portable and even wearable devices that maintain high precision. Manufacturers are adopting advanced nanofabrication techniques to produce NV-diamond chips with high defect control, a process refined by companies like Element Six, which specializes in synthetic diamond materials essential for NV-based quantum sensors. These materials underpin the next generation of quantum magnetometry devices, allowing for robust and scalable manufacturing.

Another key innovation is the transition from laboratory prototypes to commercially viable products. This is evident in the product lines of firms such as QuSpin and Qnami, which design and manufacture optically pumped magnetometers (OPMs) and scanning quantum magnetometers, respectively. Their efforts focus on reducing noise, enhancing temperature stability, and enabling multi-channel arrays, which are crucial for applications like biomagnetic imaging and materials characterization. For instance, QuSpin‘s zero-field OPMs are already seeing adoption in brain imaging research, while Qnami’s quantum scanning probes are expanding in the semiconductor inspection market.

The ecosystem is also witnessing increased collaboration between equipment manufacturers and quantum software specialists to improve device control and data interpretation. This vertical integration is exemplified by partnerships between hardware firms and quantum algorithm developers, streamlining the deployment of magnetometry solutions in real-world environments.

Looking ahead to 2026 and beyond, the manufacturing sector is anticipated to benefit from ongoing investments in quantum technology infrastructure, supported by national initiatives in Europe, North America, and Asia. The drive for higher throughput and lower cost per unit is catalyzing the development of automated assembly lines and quality control protocols tailored for quantum devices. Furthermore, the anticipated arrival of chip-scale quantum magnetometers, leveraging integrated photonics, will mark a significant leap in manufacturability and deployment scale.

In sum, the quantum magnetometry equipment manufacturing sector in 2025 is defined by material innovations, process automation, and the commercialization of robust, high-performance sensors. As industry standards mature and supply chains stabilize, the sector is poised for accelerated growth and broader application reach in the coming years.

Competitive Landscape: Leading Manufacturers and New Entrants

The competitive landscape of quantum magnetometry equipment manufacturing in 2025 is characterized by a blend of established instrumentation leaders and agile new entrants driving innovation. The sector is responding to surging demand from quantum sensing applications, medical diagnostics, and geophysical exploration, spurring both technological advancements and strategic partnerships.

Among established manufacturers, Lockheed Martin and Magnicon remain prominent in producing superconducting quantum interference device (SQUID)-based magnetometers. These companies maintain significant market share by leveraging integrated manufacturing capabilities and building on decades of experience in ultra-sensitive measurement technologies. European-based Qnami has consolidated its position in quantum diamond magnetometry, offering turnkey scanning probe solutions for both research and industrial customers. Their commercial quantum sensors, based on nitrogen-vacancy (NV) centers in diamond, have attracted interest from semiconductor and life sciences sectors.

Industry giants such as Lockheed Martin are investing in quantum-enabled navigation and detection systems, often via collaborations with national laboratories and research institutes. Meanwhile, Magnicon has expanded its distribution partnerships in Asia and North America to meet rising demand.

New entrants are shaping the landscape with disruptive approaches. Startups like Qnami and QuSpin are commercializing compact, portable quantum magnetometers based on optically pumped magnetometer (OPM) technology and NV centers, respectively. These innovations target untapped markets in non-invasive brain imaging (magnetoencephalography), nondestructive testing, and field-based mineral exploration. QuSpin’s OPM devices, for example, are already deployed in research hospitals and are being evaluated for integration into wearable medical diagnostics.

The coming years are expected to see further entries, especially as universities and government-backed quantum technology hubs spin out new firms. Global supply chain developments, such as the increasing availability of high-purity diamond substrates and miniaturized laser systems, are lowering barriers for new manufacturers. Additionally, strategic public-private partnerships—particularly in the EU and US—are fostering commercialization and standardization efforts.

Overall, the competitive landscape in 2025 reflects a dynamic interplay between established manufacturers scaling production for large contracts and innovative startups targeting niche and emerging applications. As quantum magnetometry’s technical capabilities advance, it is anticipated that further consolidation and cross-industry collaborations will shape the sector’s evolution over the next few years.

Major End-User Segments: Healthcare, Defense, Research, and Beyond

Quantum magnetometry equipment manufacturing is poised for significant growth in 2025 and the following years, underpinned by increasing demand from major end-user sectors such as healthcare, defense, scientific research, and emerging industrial applications. The current landscape is shaped by rapid advances in quantum sensing technologies, miniaturization efforts, and the pursuit of higher sensitivity and reliability in magnetic field detection.

In healthcare, quantum magnetometers—particularly optically pumped magnetometers and superconducting quantum interference devices (SQUIDs)—are being increasingly adopted for noninvasive medical diagnostics. Applications like magnetoencephalography (MEG) and magnetocardiography (MCG) are benefiting from improved spatial resolution and portability, enabling new clinical workflows and ambulatory monitoring. Key manufacturers such as Tristan Technologies and ZIAGNOSTICS are advancing the integration of quantum sensors into next-generation medical imaging systems, with several ongoing collaborations between equipment providers and hospital research centers to expand use cases.

The defense sector remains a critical driver for quantum magnetometry equipment manufacturing. Military agencies are investing in ultra-sensitive magnetometers for surveillance, submarine detection, and navigation in GPS-denied environments. Companies such as MSquared and QuSpin are working with government agencies to deliver robust, field-deployable quantum sensors that offer strategic advantages in detection and situational awareness. These efforts are expected to accelerate in 2025, with new product launches and pilot deployments planned in both North America and Europe.

  • Scientific Research: Academic and government laboratories remain a foundational segment, utilizing quantum magnetometers for exploring condensed matter physics, biomagnetic phenomena, and fundamental quantum mechanics. Equipment suppliers such as Qnami are delivering instruments tailored for high-resolution imaging of magnetic domains and single-molecule detection, supporting breakthroughs in material science and quantum information processing.
  • Industrial and Emerging Markets: Beyond the core sectors, quantum magnetometry is gaining traction in non-destructive testing, mineral exploration, and environmental monitoring. Manufacturers are working to adapt laboratory-grade systems for rugged, field-ready deployment. Magnetic Sensors Corporation and similar firms are expanding their portfolios to cater to these evolving requirements.

Looking ahead, the sector anticipates continued collaboration between manufacturers and end-users to refine device performance, reduce costs, and diversify applications. Investments in R&D and supply chain optimization will likely enable broader adoption of quantum magnetometry equipment across diverse industries by the late 2020s.

Supply Chain Challenges and Solutions in 2025

The supply chain for quantum magnetometry equipment manufacturing in 2025 is facing a complex set of challenges, driven by the delicate nature of quantum components, globalized sourcing, and increased demand from research and industrial sectors. Quantum magnetometers, which often rely on ultra-pure materials, precision-engineered optics, and sophisticated cryogenic systems, require a supply base with specialized capabilities and robust quality controls. In 2025, the expansion of quantum sensing applications in fields like medical imaging, mineral exploration, and navigation is further pressuring manufacturers to secure reliable supply channels.

A key challenge is the availability of high-purity alkali metals and rare-earth elements, critical for devices such as optically pumped magnetometers (OPMs) and superconducting quantum interference devices (SQUIDs). Fluctuations in global mining outputs and geopolitical constraints have introduced uncertainties in sourcing these materials. Manufacturers such as QuSpin and SQUID Systems have reported increased lead times and volatility in raw material costs, prompting a shift toward multi-sourcing and the development of recycling initiatives to recover rare elements from end-of-life devices.

Another constraint in 2025 is the limited number of suppliers capable of precision manufacturing for quantum-grade optics and cryogenic components. For example, attocube systems AG and QZabre AG continue to invest in in-house manufacturing and collaborative R&D to mitigate disruptions associated with outsourced components, particularly those affected by global shipping delays and semiconductor shortages. These companies are also adopting digital supply chain management platforms to improve real-time tracking and predictive analytics, allowing for faster response to bottlenecks.

The semiconductor shortage, though less acute than in previous years, remains a concern due to the specific needs of quantum control electronics. Manufacturers are increasingly working directly with foundries and seeking long-term agreements to secure supply. Additionally, initiatives are underway in the EU and North America to onshore production of critical quantum components, supported by public-private partnerships aimed at boosting domestic capabilities.

Looking ahead, the sector is focused on building resilient, transparent, and flexible supply chains. This includes strengthening relationships with suppliers, investing in redundancy for critical parts, and leveraging automation to reduce manual error. As demand for quantum magnetometers grows, particularly for compact and deployable devices, manufacturers will continue to prioritize innovation in supply chain logistics, digitalization, and sustainable sourcing practices to maintain competitiveness and reliability.

Regional Analysis: North America, Europe, Asia-Pacific, and Emerging Markets

Quantum magnetometry equipment manufacturing is undergoing rapid evolution, driven by advancements in quantum sensing technologies and increased demand across scientific, medical, and industrial sectors. The regional dynamics in 2025 reflect varying stages of ecosystem maturity, investment levels, and strategic focus across North America, Europe, Asia-Pacific, and emerging markets.

  • North America: North America continues to be a frontrunner in quantum magnetometry manufacturing, anchored by the United States’ extensive R&D infrastructure and robust collaborations between academia, national laboratories, and private industry. Companies such as Lockheed Martin and National Institute of Standards and Technology (NIST) are instrumental in both the development and commercialization of quantum magnetometers, particularly for defense, navigation, and medical diagnostics. In 2025, increased federal funding for quantum sensing and the integration of magnetometers into quantum computing and communications systems are expected to fuel further growth.
  • Europe: Europe has cultivated a vibrant quantum technology sector, supported by the European Union’s Quantum Flagship initiative and strong national programs in countries like Germany and the United Kingdom. Notably, firms such as Qnami (Switzerland) and MAGNETEC (Germany) are advancing manufacturing capabilities for high-sensitivity quantum magnetometers used in both scientific instrumentation and industrial process monitoring. The region’s emphasis on standardization, cross-border collaboration, and investment in quantum startups positions Europe for continued leadership and export growth through 2025 and beyond.
  • Asia-Pacific: The Asia-Pacific region is rapidly scaling up quantum magnetometry manufacturing, propelled by strong government funding and expanding domestic applications. China, in particular, has prioritized the development of quantum sensors for healthcare and navigation, with companies such as China Aerospace Science and Industry Corporation (CASIC) investing in production lines and new product development. Japan and South Korea are also emerging as key players, leveraging their advanced electronics industries to refine miniaturized and robust quantum magnetometers for commercial and academic use.
  • Emerging Markets: While still nascent, emerging markets in Latin America, the Middle East, and Africa are beginning to engage with quantum magnetometry equipment, primarily through technology transfer, academic partnerships, and pilot deployments. Initiatives supported by organizations like The Abdus Salam International Centre for Theoretical Physics (ICTP) are fostering local capabilities in quantum sensing, laying the groundwork for future manufacturing activities as regional demand and expertise grow through the latter half of the decade.

Outlook for the next few years indicates continued regional diversification, with North America and Europe maintaining leadership in innovation and high-end equipment, while Asia-Pacific closes the gap through state-driven scale-up and integration into broader quantum technology supply chains. Emerging markets are expected to participate more actively as technology diffusion accelerates, regulatory frameworks mature, and local manufacturing capabilities expand.

Key Regulatory and Standards Updates Impacting the Industry

The quantum magnetometry equipment manufacturing sector is experiencing significant regulatory and standards-related developments as the industry matures and quantum sensing technologies move toward broader commercialization. In 2025, key regulatory updates focus on safety, electromagnetic compatibility (EMC), export controls, and the establishment of technical standards—particularly as quantum magnetometers increasingly intersect with fields such as healthcare, aerospace, and defense.

One of the most notable developments is the ongoing work by international standards bodies to define measurement protocols and performance benchmarks for quantum magnetometers. Organizations such as the International Organization for Standardization (ISO) and the International Electrotechnical Commission (IEC) are collaborating with industry leaders to establish guidelines for measurement accuracy, calibration, and interoperability. These efforts are crucial for manufacturers, as adherence to standardized procedures will be increasingly required for product certification and market entry, particularly in regulated sectors like medical diagnostics or aerospace.

Meanwhile, regulatory agencies in the United States and Europe have intensified their focus on electromagnetic compatibility and radiofrequency emissions as quantum magnetometry equipment becomes more sensitive and is deployed in environments with strict EMC requirements. The U.S. Food and Drug Administration (FDA) and the European Commission are revising technical guidance for equipment that may interact with human health or critical infrastructure, reflecting the rapid progress of quantum sensing in biomagnetic imaging and geophysical surveying.

Export controls remain a dynamic area, especially for quantum-enabled devices with potential dual-use applications. The U.S. Bureau of Industry and Security (BIS) has updated its Commerce Control List to include certain quantum sensing components, requiring manufacturers to secure appropriate licenses before exporting to specific countries. Similarly, the Wassenaar Arrangement is reviewing its controls on sensitive quantum technologies to balance technological advancement and national security concerns.

Industry participants, including leading manufacturers such as QNAMI and MSquared Lasers, are actively engaging with standards bodies and regulatory agencies to shape practical, innovation-friendly frameworks. Looking ahead, 2025 and the following years are expected to bring more harmonized international standards, clearer pathways for medical and industrial certification, and more stringent export compliance requirements—trends that will shape product development and global market strategies through the latter half of the decade.

The quantum magnetometry equipment manufacturing sector is experiencing accelerated activity in strategic partnerships, mergers and acquisitions (M&A), and investment rounds as the field matures and its commercial promise becomes evident. In 2025, the competitive landscape is being shaped by collaborations between quantum technology startups, established scientific instrumentation firms, and major industrial conglomerates seeking to integrate quantum sensors into their broader product offerings.

One of the most notable trends is the formation of joint ventures between quantum sensor innovators and established equipment manufacturers. For instance, Qnami, a Switzerland-based leader in quantum sensing solutions, has entered multiple strategic collaborations with European and Asian instrumentation companies since 2023 to scale the production of diamond-based quantum magnetometers for both research and industrial diagnostics. Such partnerships enable startups to leverage existing manufacturing capabilities and global distribution channels, accelerating time-to-market for advanced magnetometry solutions.

Investment activity remains robust, with venture capital and corporate funds focusing on companies developing scalable and robust quantum magnetometry platforms. MagiQ Technologies has attracted new investment in 2025 to expand its quantum sensing product line, emphasizing platforms that integrate with existing industrial automation systems. Funding is also directed toward startups such as SQUTEC, which are developing miniaturized quantum magnetometers suited for field deployment across medical imaging, navigation, and non-destructive testing markets.

M&A activity is expected to intensify through 2025 and beyond, as large instrumentation firms seek to acquire quantum technology startups to gain a foothold in the emerging quantum sensing market. Companies like Oxford Instruments are actively monitoring the sector, aiming to integrate quantum-enabled magnetometry solutions into their scientific and industrial portfolios. Strategic acquisitions enable the rapid assimilation of intellectual property and technical expertise, which is critical given the complexity of quantum device manufacturing and the sector’s stringent performance requirements.

Looking ahead, the sector is likely to see more cross-border alliances and consortia, especially as quantum magnetometry equipment becomes integral to next-generation healthcare diagnostics, aerospace, and defense applications. Collaborative efforts, such as those under pan-European quantum initiatives, are expected to further boost technology transfer and standardization, supporting the rapid industrialization of quantum magnetometry manufacturing through 2025 and into the later 2020s.

The quantum magnetometry equipment manufacturing sector is poised for significant transformation through 2030, driven by advances in quantum sensing, miniaturization, and industrial adoption. As of 2025, leading manufacturers are focused on developing quantum magnetometers with higher sensitivity, lower power consumption, and greater robustness, targeting both scientific and emerging commercial applications.

One of the most disruptive trends is the integration of nitrogen-vacancy (NV) centers in diamond and optically-pumped atomic magnetometers (OPAMs) into compact, deployable devices. Companies such as Qnami are already commercializing NV-center-based magnetometers for nanoscopic imaging and material science, while QuSpin Inc. is advancing the miniaturization of OPAMs for biomedical and geophysical uses. Through 2025 and beyond, further reduction in size and cost is anticipated, enabling field-deployable quantum sensors for applications ranging from brain imaging and non-destructive testing to navigation in GPS-denied environments.

The sector is also witnessing a shift toward scalable manufacturing processes. Efforts are underway to standardize diamond growth and fabrication for NV devices, as seen in collaborative efforts between instrument makers and synthetic diamond suppliers. At the same time, the improvement of vapor cell production and laser miniaturization is expected to further expand OPAM accessibility. Industry partnerships and public-private initiatives are accelerating these developments; for instance, Lockheed Martin has announced investments in quantum sensing for defense and aerospace, signaling mainstream industry adoption.

Looking to the second half of the decade, integration with quantum computing and communications infrastructure is a strong possibility. Quantum magnetometers are expected to play a vital role in quantum networks and secure communications, with companies like Qnami and QuSpin Inc. positioned to supply enabling technologies. Furthermore, the push for quantum-enabled medical diagnostics is intensifying, with equipment manufacturers collaborating with medical device firms to develop next-generation magnetoencephalography (MEG) and magnetic particle imaging systems.

By 2030, the sector is anticipated to experience broader commercialization, with quantum magnetometers transitioning from research laboratories to widespread deployment in healthcare, security, materials science, and navigation. Manufacturers will likely focus on further automation, supply chain optimization, and compliance with emerging international standards, solidifying quantum magnetometry equipment as a foundational technology across industries.

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