Ab initio calculation of the neutron-proton mass difference

Sz Borsanyi; S. Durr; Z. Fodor; C. Hoelbling; S. D. Katz; S. Krieg; L. Lellouch; T. Lippert; A. Portelli; K. K. Szabo; B. C. Toth

doi:10.1126/science.1257050

Ab initio calculation of the neutron-proton mass difference

Sz Borsanyi, S. Durr, Z. Fodor, C. Hoelbling, S. D. Katz, S. Krieg, L. Lellouch, T. Lippert, A. Portelli, K. K. Szabo, B. C. Toth

Physics

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329 Scopus citations

Abstract

The existence and stability of atoms rely on the fact that neutrons are more massive than protons. The measured mass difference is only 0.14% of the average of the two masses. A slightly smaller or larger value would have led to a dramatically different universe. Here, we show that this difference results from the competition between electromagnetic and mass isospin breaking effects. We performed lattice quantum-chromodynamics and quantum-electrodynamics computations with four nondegenerate Wilson fermion flavors and computed the neutron-proton mass-splitting with an accuracy of 300 kilo-electron volts, which is greater than 0 by 5 standard deviations.We also determine the splittings in the ∑, Ξ, D, and Ξ_cc isospin multiplets, exceeding in some cases the precision of experimental measurements.

Original language	English (US)
Pages (from-to)	1452-1455
Number of pages	4
Journal	Science
Volume	347
Issue number	6229
DOIs	https://doi.org/10.1126/science.1257050
State	Published - Mar 27 2015

All Science Journal Classification (ASJC) codes

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10.1126/science.1257050

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title = "Ab initio calculation of the neutron-proton mass difference",

abstract = "The existence and stability of atoms rely on the fact that neutrons are more massive than protons. The measured mass difference is only 0.14% of the average of the two masses. A slightly smaller or larger value would have led to a dramatically different universe. Here, we show that this difference results from the competition between electromagnetic and mass isospin breaking effects. We performed lattice quantum-chromodynamics and quantum-electrodynamics computations with four nondegenerate Wilson fermion flavors and computed the neutron-proton mass-splitting with an accuracy of 300 kilo-electron volts, which is greater than 0 by 5 standard deviations.We also determine the splittings in the ∑, Ξ, D, and Ξcc isospin multiplets, exceeding in some cases the precision of experimental measurements.",

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T1 - Ab initio calculation of the neutron-proton mass difference

AU - Borsanyi, Sz

AU - Durr, S.

AU - Fodor, Z.

AU - Hoelbling, C.

AU - Katz, S. D.

AU - Krieg, S.

AU - Lellouch, L.

AU - Lippert, T.

AU - Portelli, A.

AU - Szabo, K. K.

AU - Toth, B. C.

PY - 2015/3/27

Y1 - 2015/3/27

N2 - The existence and stability of atoms rely on the fact that neutrons are more massive than protons. The measured mass difference is only 0.14% of the average of the two masses. A slightly smaller or larger value would have led to a dramatically different universe. Here, we show that this difference results from the competition between electromagnetic and mass isospin breaking effects. We performed lattice quantum-chromodynamics and quantum-electrodynamics computations with four nondegenerate Wilson fermion flavors and computed the neutron-proton mass-splitting with an accuracy of 300 kilo-electron volts, which is greater than 0 by 5 standard deviations.We also determine the splittings in the ∑, Ξ, D, and Ξcc isospin multiplets, exceeding in some cases the precision of experimental measurements.

AB - The existence and stability of atoms rely on the fact that neutrons are more massive than protons. The measured mass difference is only 0.14% of the average of the two masses. A slightly smaller or larger value would have led to a dramatically different universe. Here, we show that this difference results from the competition between electromagnetic and mass isospin breaking effects. We performed lattice quantum-chromodynamics and quantum-electrodynamics computations with four nondegenerate Wilson fermion flavors and computed the neutron-proton mass-splitting with an accuracy of 300 kilo-electron volts, which is greater than 0 by 5 standard deviations.We also determine the splittings in the ∑, Ξ, D, and Ξcc isospin multiplets, exceeding in some cases the precision of experimental measurements.

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Ab initio calculation of the neutron-proton mass difference

Abstract

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