美国莱斯大学和荷兰莱顿大学的物理学家们正在探索一种新方法来搜寻暗物质。他们利用了磁悬浮技术，将一个微小的钕磁粒子悬浮在超导陷阱中。虽然尚未探测到暗物质信号，但该实验首次在暗物质搜寻领域测试了磁悬浮技术，这被视为一个重要的概念验证。研究人员认为，这种高灵敏度的探测平台有望为解决现代物理学中的重大谜团提供一条有前景的实验途径。该技术在超低温下运行，能有效减少热噪声，从而提高探测精度。

🔬 磁悬浮技术应用于暗物质搜寻：莱斯大学和莱顿大学的研究团队成功将一个微小的钕磁粒子通过磁悬浮技术悬浮在超导陷阱中，并将其作为探测暗物质的新平台。这是首次在暗物质搜寻实验中应用磁悬浮技术，证明了其可行性。

🌌 暗物质的未知性与探测挑战：暗物质被认为是构成宇宙物质的主要部分，但其性质极其神秘，只能通过引力效应间接观测，其与其他粒子或力的相互作用方式、质量和自旋等参数均未知。理论预测其质量范围跨越90个数量级，给探测带来巨大挑战。

💡 超导磁悬浮的优势：该实验选择超导磁悬浮是因为悬浮的磁体是极佳的力与加速度传感器，非常适合探测超轻暗物质（ULDM）产生的微弱信号。同时，在超低温下运行可极大减少热噪声干扰，使其比依赖光学或电磁悬浮的探测器更灵敏，能处理更重的物体。

🔬 POLONAISE实验的精确性：该实验名为POLONAISE，通过在接近绝对零度的超导陷阱中悬浮由三块钕-铁-硼磁体组成的微小磁体，实现了极高的灵敏度。研究人员解释说，如果超轻暗物质存在，它会像波动一样穿过地球，以可预测的波浪状模式轻微地拉动磁体，这种运动将是暗物质存在的直接证据。

🤝 跨学科合作催生新思路：该合作始于研究人员在一次气候抗议活动中的偶然交流，他们对跨学科思考的共同兴趣促成了这项实验。经过一年的努力，成功地将实验与理论相结合，实现了技术上的突破，尽管未直接探测到暗物质，但为未来的搜寻提供了宝贵经验和方向。

A tiny neodymium particle suspended inside a superconducting trap could become a powerful new platform in the search for dark matter, say physicists at Rice University in the US and Leiden University in the Netherlands. Although they have not detected any dark matter signals yet, they note that their experiment marks the first time that magnetic levitation technology has been tested in this context, making it an important proof of concept.

“By showing what current technology can already achieve, we open the door to a promising experimental path to solving one of the biggest mysteries in modern physics,” says postdoctoral researcher Dorian Amaral, who co-led the project with his Rice colleague Christopher Tunnell, as well as Dennis Uitenbroek and Tjerk Oosterkamp in Leiden.

Dark matter is thought to make up most of the matter in our universe. However, since it has only ever been observed through its gravitational effects, we know very little about it, including whether it interacts (either with itself or with other particles) via forces other than gravity. Other fundamental properties, such as its mass and spin, are equally mysterious. Indeed, various theories predict dark matter particle masses that range from around 10⁻¹⁹ eV/c² to a few times the mass of our own Sun – a staggering 90 orders of magnitude.

The B‒L model

The theory that predicts masses at the lower end of this range is known as the ultralight dark matter (ULDM) model. Some popular ULDM candidates include the QCD axion, axion-like particles and vector particles.

In their present work, Amaral and colleagues concentrated on vector particles. This type of dark-matter particle, they explain, can “communicate”, or interact, via charges that are different from those found in ordinary electromagnetism. Their goal, therefore, was to detect the forces arising from these so-called dark interactions.

To do this, the team focused on interactions that differ based on the baryon (B) and lepton (L) numbers of a particle. Several experiments, including fifth-force detectors such as MICROSCOPE and Eöt-Wash as well as gravitational wave interferometers such as LIGO/Virgo and KAGRA, likewise seek to explore interactions within this so-called B‒L model. Other platforms, such as torsion balances, optomechanical cavities and atomic interferometers, also show promise for making such measurements.

Incredibly sensitive setup

The Rice-Leiden team, however, chose to explore an alternative that involves levitating magnets with superconductors via the Meissner effect. “Levitated magnets are excellent force and acceleration sensors, making them ideal for detecting the minuscule signatures expected from ULDM,” Amaral says.

Such detectors also have a further advantage, he adds. Because they operate at ultralow temperatures, they are much less affected by thermal noise than is the case for detectors that rely on optical or electrical levitation. This allows them to levitate much larger and heavier objects, making them more sensitive to interactions such as those expected from B‒L model dark matter.

In their experiment, which is called POLONAISE (Probing Oscillations using Levitated Objects for Novel Accelerometry In Searches of Exotic physics), the Rice and Leiden physicists levitated a tiny magnet composed of three neodymium-iron-boron cubes inside a superconducting trap cooled to nearly absolute zero. “This setup was incredibly sensitive, enabling us to detect incredibly small motions caused by tiny external forces,” Amaral explains. “If ultralight dark matter exists, it would behave like a wave passing through the Earth, gently tugging on the magnet in a predictable, wave-like pattern. Detecting such a motion would be a direct signature of this elusive form of dark matter.”

An unconventional idea

The Rice-Leiden collaboration began after Oosterkamp and Tunnell met at a climate protest and got to chatting about their scientific work. After over a decade working on some of the world’s most sensitive dark matter experiments – with no clear detections to show for it – Tunnell was eager to return to the drawing board in terms of detector technologies. Oosterkamp, for his part, was exploring how quantum technologies could be applied to fundamental questions in physics. This shared interest in cross-disciplinary thinking, Amaral remembers, led them to the unconventional idea at the heart of their experiment. “From there, we spent a year bridging experimental and theoretical worlds. It was a leap outside our comfort zones – but one that paid off,” he says.

“Although we did not detect dark matter, our result is still valuable – it tells us what dark matter is not,” he adds. “It’s like searching a room and not finding the object you are looking for: now you know to look somewhere else.”

The team’s findings, which are detailed in Physical Review Letters, should help physicists refine theoretical models of dark matter, Amaral tells Physics World. “And on the experimental side, our work advises the key improvements needed to turn magnetic levitation into a world-leading tool for dark matter detection.”

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