2024年量子科技领域涌现诸多突破。量子传感方面，科学家研发出可探测单原子电磁场的量子传感器和全方位磁场量子传感器；量子通信领域，提出真空管道量子网络方案，可实现超高速量子信息传输；量子基础研究方面，利用量子设备和原理研究引力，包括探索引力子的探测、量子引力实验和微观粒子引力测量等。此外，量子计算验证、量子真伪判定以及利用量子比特探测暗物质等研究也引人关注。这些成果标志着量子科技在各方向取得显著进展，为未来发展奠定基础。

⚛️量子传感：德国和韩国科学家合作研发的量子传感器可探测单原子的电场和磁场，该传感器基于扫描隧道显微镜尖端的分子自旋技术，能精确测量铁原子和银二聚体的偶极场。澳大利亚的研究团队则开发出基于氮化硼的新型全方位磁场量子传感器，该传感器还能感知温度变化。

📡量子通信：芝加哥大学、加州理工学院和斯坦福大学的研究团队提出构建真空管道量子网络的创新方案，该网络能以每秒10^13量子比特的速率传输量子信息，比现有卫星或光纤量子通道快至少四个数量级，为远距离、高速量子通信提供了新思路。

🌌量子基础：科学家们正利用量子设备和原理探索引力。一种方案是通过共振杆吸收引力子，从而改变量子状态进行探测；另一种方案是利用量子版的卡文迪什扭秤，研究两个扭摆之间的关联，以验证引力是否为经典理论。此外，研究人员还成功测量了微米级粒子受到的引力，为研究量子效应与引力之间的关系提供了新的实验基础。

🤔其他亮点：中国研究人员减少了验证在线购物交易所需的量子比特数量；奥地利科学家研究了经典计算机能否识别量子计算机是否在说真话；美国SLAC国家实验室的物理学家提出，量子比特出现异常可能是因为受到暗物质轰击。

With so much fascinating research going on in quantum science and technology, it’s hard to pick just a handful of highlights. Fun, but hard.  Research on entanglement-based imaging and quantum error correction both appear in Physics World’s list of 2024’s top 10 breakthroughs, but beyond that, here are a few other achievements worth remembering as we head into 2025 – the International Year of Quantum Science and Technology.

Quantum sensing

In July, physicists at Germany’s Forschungszentrum Jülich and Korea’s IBS Center for Quantum Nanoscience (QNS) reported that they had fabricated a quantum sensor that can detect the electric and magnetic fields of individual atoms. The sensor consists of a molecule containing an unpaired electron (a molecular spin) that the physicists attached to the tip of a scanning-tunnelling microscope. They then used it to measure the magnetic and electric dipole fields emanating from a single iron atom and a silver dimer on a gold substrate.

Not to be outdone, an international team led by researchers at the University of Melbourne, Australia, announced in August that they had created a quantum sensor that detects magnetic fields in any direction. The new omnidirectional sensor is based on a recently-discovered carbon-based defect in a two-dimensional material, hexagonal boron nitride (hBN). This same material also contains a boron vacancy defect that enables the sensor to detect temperature changes, too.

Quantum communications

One of the challenges with transmitting quantum information is that pretty much any medium you send it through – including high-spec fibre optic cables and even the Earth’s atmosphere  – is at least somewhat good at absorbing photons and preventing them from reaching their intended destination.

In July, a team at the University of Chicago, the California Institute of Technology and Stanford University proposed a novel solution. A continent-scale network of vacuum-sealed tubes, they suggested, could transmit quantum information at rates as high as 10¹³ qubits per second. This would exceed currently-available quantum channels based on satellites or optical fibres by at least four orders of magnitude. Whether anyone will actually build such a network is, of course, yet to be determined – but you have to admire the ambition behind it.

Quantum fundamentals

Speaking of ambition, this year saw a remarkable flurry of ideas for using quantum devices and quantum principles to study gravity. One innovative proposal involves looking for the gravitational equivalent of the photoelectric effect in a system of resonant bars that have been cooled and tuned to vibrate when they absorb a graviton from an incoming gravitational wave. The idea is that absorbing a graviton would change the quantum state of the column, and this change of state would, in principle, be detectable.

Another quantum gravity proposal takes its inspiration from an even older experiment: the Cavendish torsion balance. The quantum version of this 18^th-century classic would involve studying the correlations between two torsion pendula placed close together as they rotate back and forth like massive harmonic oscillators. If correlations appear that can’t be accounted for within a classical theory of gravity, this could imply that gravity is not, in fact, classical.

Perhaps the most exciting development in this space, though, is a new experimental technique for measuring the pull of gravity on a micron-scale particle. Objects of this size are just above the limit where quantum effects start to become apparent, and the Leiden and Southampton University researchers who performed the experiment have ideas for how to push their system further towards this exciting regime. Definitely one to keep an eye on.

The best of the rest

It wouldn’t be quantum if it wasn’t at least little bit weird, so here’s a few head-scratchers for you to puzzle over.

This year, researchers in China substantially reduced the number of qubits required to verify an online shopping transaction. Physicists in Austria asked whether a classical computer can tell when a quantum computer is telling the truth. And in a development that’s sure to warm the hearts of quantum experimentalists the world over, physicists at the SLAC National Laboratory in the US suggested that if your qubits are going haywire and you don’t know why, maybe, just maybe, it’s because they’re being constantly bombarded with dark matter.

Using noisy qubits to detect dark matter? Now that really would be a breakthrough.

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