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市场调查报告书
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1813469
2032 年量子磁体市场预测:按产品类型、应用、最终用户和地区进行的全球分析Quantum Magnets Market Forecasts to 2032 - Global Analysis By Product Type, Application, End User and By Geography |
根据 Stratistics MRC 的数据,全球量子磁铁市场预计在 2025 年将达到 8.192 亿美元,到 2032 年将达到 23.013 亿美元,预测期内的复合年增长率为 15.9%。量子磁体是一种磁性受自旋挫败和纠缠等动态力学效应控制的材料。与传统磁铁不同,它们的行为源自于量子涨落,从而产生自旋液体和拓扑序等奇异相。人们正在探索这些材料在量子计算、自旋电子学和先进磁感测器中的潜在应用。它们独特的磁态能够以最小的能量损失实现原子级资讯操控。
根据2021年3月发表在《物理评论B》上的一项研究,量子磁体BaCuTe2O6表现出独特的结构和磁性:反铁磁相互作用发生在居里-外斯温度-78K,而远距磁序则出现在更低的1.8K温度下。
对量子计算和感测的兴趣日益浓厚
人们对量子运算和感测日益增长的兴趣是量子磁体市场的主要驱动力。这些尖端技术从根本上依赖精确的磁场控制和测量,而量子磁体能够实现这一点。公共和私营部门对量子资讯科学的大量投资正在加速研发活动。这种关注度的提升与对超导性量子干涉元件(SQUID)等高效能元件的需求成长直接相关。此外,对量子霸权的追求正在突破材料科学的界限,需要开发和整合先进的量子磁感测器和系统,从而刺激市场扩张。
极端的冷却和隔离要求
量子磁体广泛商业化的一大障碍是其严格依赖低温操作,并且需要与周围环境杂讯进行高度隔离。维持这些条件需要复杂且昂贵的基础设施,包括液态氦冷却系统和先进的屏蔽系统。这显着增加了整体拥有成本和操作复杂性,使该技术难以普及。此外,这些要求限制了现场部署应用的实用性,并可能阻碍成本敏感产业的潜在终端用户采用量子磁解决方案,从而抑制整体市场渗透率和成长潜力。
用于医学成像和地质学的量子感测器
在医疗保健领域,量子磁力仪可协助实现超低场磁振造影 (MRI) 和脑磁图 (MEG) 等突破性诊断工具,从而增强成像能力,而无需传统系统庞大的基础设施。在地质应用中,这些感测器可为矿产探勘和油气储存测绘提供前所未有的磁异常检测解析度。在这些高价值领域提供卓越性能的能力,不仅创造了新的收益来源,刺激了特定应用领域的创新,也显着拓展了量子磁铁供应商的潜在市场。
与超导性和拓朴材料的竞争
量子磁体市场面临着替代量子位元技术快速发展的强大威胁,尤其是基于超导性电路和拓朴材料的技术。超导性位元目前是量子运算的主导方法,正在争夺研发资金和商业性应用。此外,拓朴量子位元的理论前景(可能提供固有的容错能力)构成了长期的竞争挑战。如果此类替代平台迅速实现技术成熟和可扩展性,它们可能会取代对特定量子磁系统的需求,从而侵蚀市场份额并影响专用量子磁体解决方案的成长轨迹。
新冠疫情最初扰乱了量子磁体市场,导致供应链延迟,全球封锁和保持社交距离的规定也暂时停止了实验室研发活动。这导致计划被推迟,从而导致需求短期萎缩。然而,这场危机也凸显了先进技术研究的重要性,并带来了强劲的復苏。政府的奖励策略以及对量子计算等战略技术的重新关注,帮助市场迅速復苏。疫情最终加速了数位转型,间接促进了对量子技术及相关组件的长期投资。
预计 SQUID 磁力仪市场在预测期内将占据最大份额
预计SQUID磁强计细分市场将在预测期内占据最大市场份额,这得益于其无与伦比的灵敏度和成熟的应用基础。 SQUID是量子磁体领域最成熟的技术,在研究和商业应用方面都拥有良好的业绩记录。其探测极小磁场的能力使其成为生物医学影像应用(例如脑磁图 (MEG) 系统、基础物理研究和无损检测)中不可或缺的一部分。持续的技术改进及其作为超低场磁性感测黄金标准的地位,确保了其持续的主导地位,并为整个市场带来显着的收益贡献。
预计医疗保健产业在预测期内将实现最高复合年增长率
预计医疗保健产业将在预测期内实现最高成长率,因为基于量子的生物医学感测技术正越来越多地应用于先进的诊断程序。脑磁图 (MEG) 和超低场磁振造影 (MRI) 等应用因其提供患者友善高解析度成像而日益普及。此外,针对早期疾病检测和神经系统疾病图谱绘製的医学研究的大量投资也推动了需求。量子感测器也正变得越来越小型化,使其与临床环境的整合更加可行且更具成本效益,从而进一步推动了该领域的扩张。
预计北美将在预测期内占据最大的市场份额。这种主导地位归功于其强大的量子技术生态系统,包括领先的研究机构、主要的产业参与者,以及由美国国家量子计画和加拿大类似计画等组织资助的大量政府计画。终端用户产业(尤其是医疗保健和国防)的集中,加上量子运算和量子感测技术的早期积极应用,正在推动对量子磁体的需求。
预计亚太地区在预测期内的复合年增长率最高。这项加速成长得益于中国、日本和澳洲在量子技术研发方面投入的大量公共和私人资金。该地区拥有强大的电子和半导体製造基础,为量子磁体元件的製造提供了协同优势。此外,工业自动化、医疗保健现代化和自然资源探勘等领域日益增长的应用也推动了量子技术的采用。快速发展的科技业和政府的支持性政策为市场扩张创造了有利环境,从而带来了更高的成长率。
According to Stratistics MRC, the Global Quantum Magnets Market is accounted for $819.2 million in 2025 and is expected to reach $2301.3 million by 2032 growing at a CAGR of 15.9% during the forecast period. Quantum magnets refer to materials exhibiting magnetic properties governed by quantum mechanical effects, such as spin frustration and entanglement. Unlike classical magnets, their behavior arises from quantum fluctuations, leading to exotic phases like spin liquids and topological orders. These materials are investigated for potential applications in quantum computing, spintronics, and advanced magnetic sensors. Their unique magnetic states enable manipulation of information at the atomic level with minimal energy loss.
According to the Physical Review B journal study published in March 2021, the quantum magnet BaCuTe2O6 exhibits specific structural and magnetic properties where antiferromagnetic interactions occur with a Curie-Weiss temperature of -78 K, while long-range magnetic order manifests at the much lower temperature of 1.8 K.
Rising interest in quantum computing and sensing
The burgeoning interest in quantum computing and sensing is a primary driver for the quantum magnets market. These advanced technologies fundamentally rely on precise magnetic field control and measurement, which quantum magnets provide. The significant investments from both public and private sectors into quantum information science are accelerating R&D activities. This heightened focus is directly translating into increased demand for high-performance components like superconducting quantum interference devices (SQUIDs). Moreover, the pursuit of quantum supremacy is pushing the boundaries of material science, necessitating the development and integration of sophisticated quantum magnetic sensors and systems, thereby fueling market expansion.
Extreme cooling and isolation requirements
A significant impediment to the widespread commercialization of quantum magnets is their stringent operational dependency on cryogenic temperatures and exceptional isolation from ambient environmental noise. Maintaining these conditions necessitates complex and expensive infrastructure, such as liquid helium cooling systems and advanced shielding. This substantially increases the total cost of ownership and introduces operational complexities, making the technology less accessible. Additionally, these requirements limit the practicality for field-deployable applications and can deter potential end-users in cost-sensitive industries from adopting quantum magnetic solutions, thereby restraining overall market penetration and growth potential.
Quantum sensors for medical imaging and geology
In healthcare, quantum magnetometers enable revolutionary diagnostic tools like ultra-low-field MRI and magnetoencephalography (MEG), offering enhanced imaging capabilities without the bulky infrastructure of traditional systems. For geological applications, these sensors provide unprecedented resolution in magnetic anomaly detection for mineral exploration and oil & gas reservoir mapping. The ability to deliver superior performance in these high-value sectors creates new revenue streams and drives application-specific innovation, significantly expanding the addressable market for quantum magnet providers.
Competition from superconducting and topological materials
The quantum magnets market faces a potent threat from the rapid advancement of alternative qubit technologies, particularly those based on superconducting circuits and topological materials. Superconducting qubits are currently a leading modality in quantum computing, vying for R&D funding and commercial adoption. Furthermore, the theoretical promise of topological qubits, which may offer inherent error resistance, poses a long-term competitive challenge. If these alternative platforms achieve technological maturity and scalability more rapidly, they could potentially supplant the need for certain quantum magnetic systems, thereby eroding market share and impacting the growth trajectory of dedicated quantum magnet solutions.
The COVID-19 pandemic initially disrupted the quantum magnets market, causing supply chain delays and temporarily halting laboratory-based R&D activities due to global lockdowns and social distancing mandates. This led to project postponements and a short-term contraction in demand. However, the crisis also underscored the critical importance of advanced technological research, leading to a resilient recovery. Government stimulus packages and a renewed focus on strategic technologies like quantum computing helped the market rebound swiftly. The pandemic ultimately accelerated digital transformation, indirectly benefiting long-term investment in quantum technologies and associated components.
The SQUID magnetometers segment is expected to be the largest during the forecast period
The SQUID magnetometers segment is expected to account for the largest market share during the forecast period owing to its unparalleled sensitivity and established application base. SQUIDs represent the most mature technology within the quantum magnet space, with a proven track record in both research and commercial settings. Their ability to detect infinitesimal magnetic fields makes them indispensable in sectors like biomedical imaging for MEG systems, fundamental physics research, and nondestructive testing. The continuous technological refinements and their status as the gold standard for ultra-low-field magnetic sensing ensure their sustained dominance and significant revenue contribution to the overall market.
The healthcare segment is expected to have the highest CAGR during the forecast period
Over the forecast period, the healthcare segment is predicted to witness the highest growth rate, driven by the accelerating adoption of quantum-based biomedical sensing technologies for advanced diagnostic procedures. Applications such as magnetoencephalography (MEG) and ultra-low-field MRI are gaining traction as they offer patient-friendly, high-resolution imaging alternatives. Furthermore, substantial investments in medical research aimed at early disease detection and neurological disorder mapping are propelling demand. The segment's expansion is also fueled by the ongoing miniaturization of quantum sensors, which makes their integration into clinical environments more feasible and cost-effective.
During the forecast period, the North America region is expected to hold the largest market share. This dominance is attributed to the presence of a robust quantum technology ecosystem, including leading research institutions, key industry players, and substantial government funding initiatives from entities like the National Quantum Initiative in the U.S. and similar strategies in Canada. The high concentration of end-user industries, particularly in healthcare and defense, coupled with early and aggressive adoption of quantum computing and sensing technologies, creates a concentrated demand for quantum magnets, cementing North America's position as the revenue leader in this market.
Over the forecast period, the Asia Pacific region is anticipated to exhibit the highest CAGR. This accelerated growth is fueled by massive public and private investments in quantum technology research and development from China, Japan, and Australia. The region's strong manufacturing base for electronics and semiconductors provides a synergistic advantage for producing quantum magnet components. Additionally, growing applications in industrial automation, healthcare modernization, and natural resource exploration are driving adoption. The rapidly expanding technology sector and supportive government policies are creating a highly conducive environment for market expansion, leading to superior growth rates.
Key players in the market
Some of the key players in Quantum Magnets Market include IBM, Google, Microsoft, Amazon Web Services, Rigetti Computing, D-Wave Quantum Inc., Quantinuum, Intel, IonQ, PsiQuantum, Oxford Instruments, and TDK.
In April 2025, Google Quantum AI introduced a novel hybrid approach to quantum simulation, enabling scientific discoveries in quantum magnetism. This platform combines digital and analog quantum computing techniques to simulate magnetic systems, opening new possibilities for beyond-classical applications.
In February 2025, Microsoft announced the development of Chip Majorana 1, a significant advancement in topological qubits. This achievement is part of the DARPA Underexplored Systems for Utility-Scale Quantum Computing (US2QC) program, aiming to create scalable and fault-tolerant quantum computers.
In April 2023, AWS, in collaboration with Element Six, explored the use of color centers in diamonds for quantum communication. This research focuses on utilizing diamond materials to enhance quantum networking nodes, contributing to advancements in quantum communication technologies.
Note: Tables for North America, Europe, APAC, South America, and Middle East & Africa Regions are also represented in the same manner as above.