Radioactive 57Mn+(T 1/2 = 1.5 min) ions have been implanted at the ISOLDE facility at CERN with 60 keV energy to fluences <1012/cm2 into p-type Si1 - x Ge x (x < 0.1) single crystals held at 300-600 K. The implantation and annealing processes result in the majority of the implanted Mn ions occupying substitutional lattice sites. In the subsequent 57Mn nuclear ? - -decay to the 14.4 keV Mössbauer state of 57Fe (T 1/2 = 100 ns), an average recoil energy of 40 eV is imparted to the 57Fe daughter atoms which results in a large fraction being expelled into tetrahedral interstitial sites and the creation of a vacancy. The remainder occupies substitutional sites. This technique of recoil production of 57m FeI thus allows for the study of the diffusion characteristics of interstitial Fe. From the temperature dependent line broadening, the activation energies have been determined and decrease with increasing Ge concentration which contributes significantly to the increase of the jump frequency. A similar result has been obtained in n-type SiGe but there the values for the activation energies were much higher.
57 Fe Mössbauer investigations in p-type Silicon Germanium single crystals
R Mantovan;M Fanciulli
2009
Abstract
Radioactive 57Mn+(T 1/2 = 1.5 min) ions have been implanted at the ISOLDE facility at CERN with 60 keV energy to fluences <1012/cm2 into p-type Si1 - x Ge x (x < 0.1) single crystals held at 300-600 K. The implantation and annealing processes result in the majority of the implanted Mn ions occupying substitutional lattice sites. In the subsequent 57Mn nuclear ? - -decay to the 14.4 keV Mössbauer state of 57Fe (T 1/2 = 100 ns), an average recoil energy of 40 eV is imparted to the 57Fe daughter atoms which results in a large fraction being expelled into tetrahedral interstitial sites and the creation of a vacancy. The remainder occupies substitutional sites. This technique of recoil production of 57m FeI thus allows for the study of the diffusion characteristics of interstitial Fe. From the temperature dependent line broadening, the activation energies have been determined and decrease with increasing Ge concentration which contributes significantly to the increase of the jump frequency. A similar result has been obtained in n-type SiGe but there the values for the activation energies were much higher.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.