The work done mostly concerns problems which were brought to our attention by other research groups, who needed the Mössbauer techniques and expertise available in our laboratory. Worth mentioning here are the following achievements:
- 197Au Mössbauer effect in ternary alloys /35/ and Au(I) and Au(III) compounds /68/
- On-line Mössbauer measurements at low temperatures of 83mKr implanted into Al /44/
- 237Np Mössbauer measurements on heptavalent neptunium /26, 27/, where we observed the largest isomer shift values ever observed
- 119Sn Mössbauer measurements on organo-tin compounds /31/
- 61Ni Mössbauer spectroscopy of nickel compounds /12/, of local magnetic fields in spinels with nickel in tetrahedral and octahedral lattice positions /52, 89, 118/, of the hydrogen battery material with and without hydrogen loading /67/, of the magnetic properties of fine Ni particles /97/, on surfaces of amorphous alloys and metglasses /113, 131, 133/, of the valence state of nickel in BaNiO3 /274/, Ni3Sn2S2 /289/, and biomolecules /239/, of magnetic properties of the ternary phosphide CrNiP /441/ and the ternary arsenide CrNiAs /442/. 61Ni Mössbauer spectroscopy is difficult to perform, because the halflife of the source is very short (99 min) and must be activated in an electron accelerator near to the Mössbauer laboratory right before the actual measurement
- 193Ir Mössbauer measurement on an iridium fullerene compound in order to study the covalence state of Ir /200/
- 151Eu Mössbauer measurements to study the Verwey-type transition in EuNiP /410/