Nobel Prize in Physics Awarded to John Clarke, Michel Devoret and John Martinis

Summary

Navigate to: Summary- John Clarke- Michel H. Devoret- John M. Martinis Press release Advanced information Popular information Popular science background: Quantum properties on a human scale (pdf)Populärvetenskaplig information: Kvantegenskaper på mänsklig skala (pdf) Quantum properties on a human scale The Nobel Prize laureates in physics for 2025, John Clarke, Michel H. Devoret and John M. Martinis, used a series of experiments to demonstrate that the bizarre properties of the quantum world can be made concrete in a system big enough to be held in the hand. Their superconducting electrical system could tunnel from one state to another, as if it were passing straight through a wall. They also showed that the system absorbed and emitted energy in doses of specific sizes, just as predicted by quantum mechanics. A series of groundbreaking experiments © Johan Jarnestad/The Royal Swedish Academy of Sciences Quantum mechanics describes properties that are significant on a scale that involves single particles. In quantum physics, these phenomena are called microscopic, even when they are much smaller than can be seen using an optical microscope. This contrasts with macroscopic phenom­ena, which consist of a large number of particles. For example, an everyday ball is built up of an astronomical amount of molecules and displays no quantum mechanical effects. We know that the ball will bounce back every time it is thrown at a wall. A single particle, however, will sometimes pass straight through an equivalent barrier in its microscopic world and appear on the other side. This quantum mechanical phenomenon is called tunnelling. This year’s Nobel Prize in Physics recognises experiments that demonstrated how quantum tunnelling can be observed on a macroscopic scale, involving many particles. In 1984 and 1985, John Clarke, Michel Devoret and John Martinis conducted a series of experiments at the University of California, Berkeley. They built an electrical circuit with two superco...