H. Abele scite author profile

The discrete quantum properties of matter are manifest in a variety of phenomena. Any particle that is trapped in a sufficiently deep and wide potential well is settled in quantum bound states. For example, the existence of quantum states of electrons in an electromagnetic field is responsible for the structure of atoms, and quantum states of nucleons in a strong nuclear field give rise to the structure of atomic nuclei. In an analogous way, the gravitational field should lead to the formation of quantum states. But the gravitational force is extremely weak compared to the electromagnetic and nuclear force, so the observation of quantum states of matter in a gravitational field is extremely challenging. Because of their charge neutrality and long lifetime, neutrons are promising candidates with which to observe such an effect. Here we report experimental evidence for gravitational quantum bound states of neutrons. The particles are allowed to fall towards a horizontal mirror which, together with the Earth's gravitational field, provides the necessary confining potential well. Under such conditions, the falling neutrons do not move continuously along the vertical direction, but rather jump from one height to another, as predicted by quantum theory.

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The neutron. Its properties and basic interactions

Abele

2008

Progress in Particle and Nuclear Physics

269

361

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Measurement of quantum states of neutrons in the Earth’s gravitational field

Nesvizhevsky¹,

Börner²,

Gagarski³

et al. 2003

Phys. Rev. D

244

283

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Study of the neutron quantum states in the gravity field

et al. 2005

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We have studied neutron quantum states in the potential well formed by the earth's gravitational field and a horizontal mirror. The estimated characteristic sizes of the neutron wave functions in the two lowest quantum states correspond to expectations with an experimental accuracy. A position-sensitive neutron detector with an extra-high spatial resolution of ~2 µm was developed and tested for this particular experiment, to be used to measure the spatial density distribution in a standing neutron wave above a mirror for a set of some of the lowest quantum states. The present experiment can be used to set an upper limit for an additional short-range fundamental force. We studied methodological uncertainties as well as the feasibility of improving further the accuracy of this experiment.PACs Codes: 03.65, 28.20

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Realization of a gravity-resonance-spectroscopy technique

et al. 2011

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H. Abele

Quantum states of neutrons in the Earth's gravitational field

The neutron. Its properties and basic interactions

Measurement of quantum states of neutrons in the Earth’s gravitational field

Study of the neutron quantum states in the gravity field

Realization of a gravity-resonance-spectroscopy technique

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