Pierre Auger – Lise Meitner: Comparative contributions to the Auger effect
Abstract
It has been claimed by R. Sietmann that the attribution of the discovery of the so-called ‘Auger’ effect to Pierre Auger was a false attribution and that Lise Meitner should have got the credit for that discovery. However Sietmann himself recognised that Meitner's description of this effect was ‘buried in’ two larger papers whose primary concern was nuclear physics. Sietmann only mentioned Auger's 1925 article and did not mention his 1923 article, an omission now found in many places. We examine again L. Meitner's and P. Auger's contributions to the description of the ‘Auger’ effect. Meitner's concern was the exact nature of the (nuclear) beta radiations about which she opposed Ch. D. Ellis, and this had been the subject of an intense Berlin–Cambridge controversy where Ellis' description eventually prevailed. Auger's observations were the central theme of his PhD thesis at the J. Perrin's laboratory on the composed photoelectric effect. We thus believe that while L. Meitner should have shared the Nobel Prize with O. Hahn, the Auger effect has rightly been attributed to Auger.
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© 2009, Carl Hanser Verlag, München
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Articles in the same Issue
- Contents
- Contents
- History
- Surface and grain-boundary segregation studied by quantitative AES and XPS
- High temperature mechanical spectroscopy of fine-grained ceramics
- The effect of electro-thermal fatigue on the structure of power electronic devices. Micro-structural evolution of the metallization layer
- f-Element hydrides: structure and magnetism
- Basic
- Hydrogen as a probe into 5f-magnetism
- Magnetism in PrPdSn and NdPdSn studied on single crystals
- Magnetic properties of fcc Ni-based transition metal alloys
- X-ray characterization of magnetic digital alloys
- Are RENiAl hydrides metallic?
- HoZn5Al3: rare-earth magnetism in a new structure type
- The influence of substitutions on the magnetocaloric effect in RCo2 compounds
- Thickness shear modes and magnetoelastic waves in a bi-layered structure: magnetic film–non-magnetic substrate
- Electrochemical properties of fine-grained AZ31 magnesium alloy
- Severe plastic deformation in Gum Metal with composition at the structural stability limit
- Applied
- Structural, magnetic, and transport properties of quantum well GaAs/δ-Mn/GaAs/InxGa1–xAs/GaAs heterostructures
- Effect of co-doping by Pb and La on structural and magnetic properties of Bi2212 superconducting ceramics
- Magnetic properties of the hydrogenated unconventional superconductor UCoGe–H
- Electrophoresis deposition of metal nanoparticles with reverse micelles onto InP
- Electronic structure and electric field gradient calculations for the Zr2Ni intermetallic compound
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- Low-temperature specific heat of selected ceramics
- Novel behaviors in rare-earth-filled skutterudites studied by bulk-sensitive photoemission spectroscopy
- Charge transport in photosensitive nanocrystalline PbTe(In) films in an alternating electric field
- Enrichment and depletion of alloying elements in surface layers of iron base alloys annealed under different conditions
- Notifications
- Personal
