欧洲核子研究组织（CERN）的 BASE 合作组发明了一种新型粒子阱，这将使物理学家能够比以往更精确地测量反质子的磁矩。该实验表明，反粒子的磁矩与物质对应物的磁矩相差最大 10–9。宇宙为何几乎完全由物质构成，而反物质含量极少？这是当今物理学领域最大的谜团之一。标准模型认为，宇宙在近 140 亿年前形成时，应该产生了等量的反物质和物质。当这些反物质和物质粒子对碰撞时，它们会湮灭并产生能量爆发。这种能量会产生新的反物质和物质粒子，这些粒子会再次相互湮灭，如此循环往复。物理学家一直在试图通过寻找粒子（如质子）与其反粒子之间的微小差异来解开这个谜团。如果成功，这种差异（即使非常小）也会揭示更多关于反物质-物质不对称性的信息，甚至可能揭示标准模型之外的物理学。

😁 BASE 合作组旨在以极高的精度测量反质子的磁矩，并将其与质子的磁矩进行比较。为此，研究人员使用彭宁阱，该阱利用磁场和电场来束缚带负电的反质子，并且可以储存反质子长达数年。

😊 为使反质子的自旋量子态能够被测量，需要将其冷却到极低的温度（200 mK）。以前的技术需要 15 小时才能实现这一点，但 BASE 现在已将冷却时间缩短至 8 分钟。

🤩 BASE 团队通过将两个彭宁阱连接起来，制造了一个所谓的“麦克斯韦妖冷却双阱”，实现了这一壮举。第一个阱冷却反质子。第二个阱（在本研究中被称为分析阱）具有同类设备中最高的磁场梯度，以及改进的噪声保护电子设备、低温回旋运动探测器和两个阱之间的超快传输。

🥳 新型仪器使研究人员能够仅将最冷的反质子用于测量，同时排除非冷反质子。这意味着他们不必浪费时间冷却这些更热的粒子。

😇 新型冷却装置可能对整个彭宁阱界都有益，因为更冷的粒子通常会导致更精确的测量。例如，它可用于相敏检测方法或自旋态分析。

A novel particle trap invented at CERN could allow physicists to measure the magnetic moments of antiprotons with higher precision than ever before. The experiment, carried out by the international BASE collaboration, revealed that the magnetic moments of the antiparticles differ by a maximum of 10^–9 from those of their matter counterparts.

One of the biggest mysteries in physics today is why the universe appears to be made up almost entirely of matter and contains only tiny amounts of antimatter. According to the Standard Model, our universe should be largely matter-less. This is because when the universe formed nearly 14 billion years ago, equal amounts of antimatter and matter were generated. When pairs of these antimatter and matter particles collided, they annihilated and produced a burst of energy. This energy created new antimatter and matter particles, which annihilated each other again, and so on.

Physicists have been trying to solve this enigma by looking for tiny differences between a particle (such as a proton) and its antiparticle. If successful, such differences (even if extremely small) would shed more light on antimatter–matter asymmetry and perhaps even reveal physics beyond the Standard Model.

The aim of the BASE (Baryon Antibaryon Symmetry Experiment) collaboration is to measure the magnetic moment of the antiproton to extremely high precision and compare it with the magnetic moment of the proton. To do this, the researchers are using Penning traps, which employ magnetic and electric fields to hold a negatively charged antiproton, and can store antiprotons for years.

Quicker cooling

Preparing individual antiprotons so that their spin quantum states can be measured, however, involves cooling them down to extremely cold temperatures of 200 mK. Previous techniques took 15 h to achieve this, but BASE has now shortened this cooling time to just eight minutes.

The BASE team achieved this feat by joining two Penning traps to make a so-called “Maxwell’s demon cooling double trap”. The first trap cools the antiprotons. The second (referred to as the analysis trap in this study) has the highest magnetic field gradient for a device of its kind, as well as improved noise-protection electronics, a cryogenic cyclotron motion detector and ultrafast transport between the two traps.

The new instrument allowed the researchers to prepare only the coldest antiprotons for measurement, while at the same time rejecting any that had a higher temperature. This means that they did not have to waste time cooling down these warmer particles.

“With our new trap we need a measurement time of around one month, compared with almost 10 years using the old technique, which would be impossible to realize experimentally,” explains BASE spokesperson Stefan Ulmer, an experimental physicist at Heinrich Heine University Düsseldorf and a researcher at CERN and RIKEN.

Ulmer says that he and his colleagues have already been able to measure that the magnetic moments of protons and antiprotons differ by a maximum of one billionth (10^–9). They have also improved the error rate in identifying the antiproton’s spin by more than a factor of 1000. Reducing this error rate was one of the team’s main motivations for this project.

The new cooling device could be of benefit to the Penning trap community at large, since colder particles generally result in more precise measurements. For example, it could be used for phase sensitive detection methods or spin state analysis, says Barbara Maria Latacz, CERN team member and lead author of this study. “Our trap is particularly interesting because it is relatively simple and robust compared to laser cooling systems,” she tells Physics World. “Specifically, it allows us to cool a single proton or antiproton to temperatures below 200 mK in less than eight minutes, which is not achievable with other cooling methods.”

The new device will now be a key element of the BASE experimental set-up, she says.

Looking forward, the researchers hope to improve the detection accuracy of the antiproton magnetic moment to 10^–10 in their next measurement campaign. They report their current work in Physical Review Letters.

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