Jian Fan/Alamy
There is always a 鈥渓ook of indignation鈥 on students鈥 faces when they first learn about quantum superposition, says physicist . He has taught quantum mechanics, the theory governing the microcosmic world of atoms and particles, for decades, and his students’ consternation inevitably emerges right on cue: when he reaches the part about quantum objects apparently being in several places at once.
This story is part of our Concepts Special, in which we reveal how experts think about some of the most mind-blowing ideas in science. Read more here
The trouble is that words like 鈥渁pparently鈥 crop up an awful lot around this topic. Indeed, in the century or so since the idea of superposition emerged, its true meaning has remained contested. The only thing physicists agree on is that it takes us to the heart of what it means for something to be 鈥渞eal鈥.
A good place to start is with the Schr枚dinger equation. Developed by Erwin Schr枚dinger in the 1920s, it is a foundation stone of quantum theory that tells us the probability of finding a particle in a given state when we measure it. The point is that quantum mechanics is concerned with predicting the outcome of a situation 鈥 it says nothing concrete about what a particle was doing before it was measured.
However, the Schr枚dinger equation works by describing all the possible places a particle could be before it is measured using a piece of maths known as the wave function. This gives us one mathematical definition of a superposition: it is a sum of different possible quantum states.
We certainly know particles can exist in a superposition. In the double-slit experiment, for example, a single photon, a particle of light, is fired towards a grating with two narrow gaps in front of a screen. If a detector is watching, the photon will 鈥減ick鈥 one slit and hit a specific spot on the screen. But if there is no detector, an 鈥渋nterference pattern鈥 will appear on the screen, suggesting the particle behaved like a wave and went through both slits at once, interacting with itself.
Subscriber-only newsletter
Sign up to Lost in Space-Time
Untangle mind-bending physics, maths and the weirdness of reality with our monthly, special-guest-written newsletter.
What we don鈥檛 know for sure is what 鈥渂eing in superposition鈥 means. Broadly, there are two views. One says the wave function is a useful mathematical tool and no more. That is certainly where Gleiser, who is based at Dartmouth College, New Hampshire, comes down. 鈥淣othing in the formalism of quantum mechanics tells us that the wave function needs to be part of physical reality,鈥 he says. 鈥淭he belief in mathematics as truth is becoming a bit like a cult.鈥
Gleiser supports an interpretation of quantum mechanics called quantum Bayesianism (or QBism), which says the theory doesn鈥檛 describe reality per se, but rather what we know about it. Ultimately, what changes when we measure a quantum state is our information about it, not reality itself.
But there is a camp that flatly refutes this view. , a philosopher at the University of Oxford, believes the wave function is real. For him, a particle in a superposition is physically in more than one place simultaneously. 鈥淚t is an extended object,鈥 he says. 鈥淚t is delocalised.鈥 According to this perspective, we must accept that the world of particles doesn鈥檛 bear any resemblance to reality as we experience it. The electrons orbiting an atom, for instance, exist as a cloud of probability before we measure them.
Critics of this position often ask what happens to those other possibilities when a measurement snaps a particle into one place. Saunders is happy to embrace the radical answer that they all manifest themselves in their own branch of an infinite multiverse.
A resolution to this question isn鈥檛 going to come any time soon. In the meantime, researchers have gone far beyond placing single particles into superposition 鈥 it has been achieved for large molecules and even a 16-microgram crystal. If this tells us anything, it is that reality is far stranger than it seems.
Read the other stories in this series using the links below:
Topics:
