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Vibrating crystal made of 10 billion atoms smashes quantum record

Testing increasingly large objects proves that quantum mechanics works at larger scales - a finding that could help build quantum computers
Even "big" objects can be quantum
Even 鈥渂ig鈥 objects can be quantum
TEK IMAGE/SCIENCE PHOTO LIBRARY

The quantum world keeps getting bigger. An experiment on crystals made from 10 billion atoms proves that even relatively large objects follow the weird rules of quantum mechanics.

One such rule is entanglement: the properties of two particles can聽be linked together so that measuring the state of one determines the measured state of the other in聽what Einstein called 鈥渟pooky action at a distance鈥.

A standard test for entanglement is Bell鈥檚 inequality, which sets a limit on how often two particles can end up in the same state by chance, with no quantum weirdness involved. If a聽pair of particles violates Bell鈥檚 inequality, it shows that quantum mechanics really is at work.

Most of the time, we test this using single particles, often photons of light. Now, Simon Gr枚blacher at the Delft University of Technology in the Netherlands and his colleagues have raised the聽stakes with a Bell test on crystals made of about 10聽billion atoms, bringing quantum weirdness one step closer to the聽human scale.

Cold crystals

The experiment starts with two聽silicon crystals, each far聽smaller than a grain of sand, cooled to near absolute zero to dampen extra vibrations. A laser pulse is split in two and directed towards the crystals. Most photons from the laser pass through them, but about one in every 100 bounces off.

This causes those photons to lose some of their energy and the crystals to vibrate, entangling quantum states of the photons and crystals.

The researchers repeated this experiment about 1 billion times, taking different combinations of measurements of the vibrations and photons.

The photon energies and crystal vibrations matched far聽more often than would be expected if their behaviour wasn鈥檛 ruled by quantum mechanics, violating Bell鈥檚 inequality and showing that the system was truly quantum.

鈥淚t鈥檚 astounding that they鈥檝e been able to do this with an object with 10 billion atoms instead of a single atom,鈥 says David Kaiser at the Massachusetts Institute of Technology. 鈥淚t鈥檚 a breathtaking result.鈥

Quantum writ large

That leap in size is important because we aren鈥檛 sure how big an object can get before quantum mechanics no longer applies. We聽know that anything large enough for us to interact with in聽everyday life doesn鈥檛 need quantum mechanics and that individual particles do 鈥 but in between is a grey area.

鈥淭he ultimate goal is to really test how we go from quantum to classical physics, whether there is some fundamental reason why big things don鈥檛 behave quantum mechanically,鈥 says Gr枚blacher.

Building larger objects that behave according to quantum mechanics may also have practical uses. It could help with technologies such as quantum computers, sensors and communication.

鈥淎s we get closer and closer to a world where many of us depend on devices that exploit quantum entanglement, they鈥檝e shown that entanglement can be robust even in devices that can actually be manufactured,鈥 says Kaiser.

Physical Review Letters

This article appeared in print under the headline 鈥淐rystal test beats quantum record鈥

Article amended on 17 December 2018

We clarified entanglement

Topics: Quantum mechanics