Hyperfine fields for119Sn in laves phases Rt2 (R=rare earth: T=Fe,Co, Ni)

The hyperfine fields acting on¹¹⁹Sn nuclei in the RT₂ (R=Sm?Lu; T=Fe, Co, Ni) have been measured by Mössbauer spectroscopy. It has been found that the hyperfine fields acting on¹¹⁹Sn nuclei in the RT₂ compounds are changed at some electronic occupation of the 4f shell of the R-component. The occupation of 4f shell is varied with the T-component. The sharp change of the hyperfine fields are connected with the change of the electronic band structure.     

Spin-canting and transverse relaxation in maghemite nanoparticles and in tin-doped maghemite

The magnetic properties of maghemite nanoparticles and tin-doped maghemite have been studied by ⁵⁷Fe and ¹¹⁹Sn Mössbauer spectroscopy at temperatures from 6 to 300 K with and without applied magnetic fields. The low-temperature ⁵⁷Fe spectra of both samples, obtained in a field of 4 T, can be described in terms of A-site and B-site components with perfect ferrimagnetic order and a strongly canted component, which seems to have its main contribution from B-site ions. At higher temperatures, the components with strong canting are influenced by transverse relaxation, which results in significant line broadening, a reduction of the magnetic hyperfine splitting and a reduction in the relative areas of lines 2 and 5. The ¹¹⁹Sn spectra show a very broad distribution of magnetic hyperfine fields at low temperatures. When the sample was exposed to applied magnetic fields the distribution became narrower. The spectra show that the direction of the hyperfine field of a large fraction of the tin ions in maghemite is antiparallel to the applied field, but a minor fraction of the tin ions have canted hyperfine fields.     

Mössbauer and XRD study of novel quaternary Sn-Fe-Co-Ni electroplated alloy

Constant current electrochemical deposition technique was used to obtain quaternary alloys of Sn-Fe-Co-Ni from a gluconate electrolyte, which to date have not been reported in the literature. For the characterization of electroplated alloys, ⁵⁷Fe and ¹¹⁹Sn Conversion Electron Mössbauer Spectroscopy (CEMS), XRD and SEM/EDAX were used. XRD revealed the amorphous character of the novel Sn-Fe-Co-Ni electrodeposited alloys. ⁵⁷Fe Mössbauer spectrum of quaternary deposit with composition of 37.0 at% Sn, 38.8 at% Fe, 16.8 at% Co and 7.4 at% Ni displayed a magnetically split sextet (B = 28.9T) with broad lines typical of iron bearing ferromagnetic amorphous alloys. Magnetically split ¹¹⁹Sn spectra reflecting a transferred hyperfine field (B = 2.3T) were also observed. New quaternary Sn-Fe-Co-Ni alloys were successfully prepared.     

Defect annealing in Sb/Sn implanted diamond investigated with Sn Mössbauer spectroscopy

The annealing of defects in Sb/Sn implanted diamond has been studied in ¹¹⁹Sn Mössbauer spectroscopy following the implantation of radioactive parent isotopes ¹¹⁹Xe and ^119mSn. Our results show that after annealing above 1300 K, 40% of the implanted ions are located at or near regular sites in the lattice. Significant implantation induced defects however remain.     

Magnetic hyperfine fields acting on diamagnetic119Sn impurity in rare-earth-3d transition metal laves phases,crystallized under high pressure

A summary of the magnetic and the electronic properties of Laves Phases compounds RT₂ (R=Sm-Lu; T=Fe, Co, Ni) synthesized under high pressure is presented. The hyperfine fields acting on tin impurity nuclei in RT₂ have been obtained by Mössbauer spectroscopy. It has been found that hyperfine fields at¹¹⁹Sn and their temperature dependences for the RFe₂ (R=Sm-Ho), the RCo₂ (R=Sm-Tb) and GdNi₂ prepared at high and atmospheric pressures, are substantially different, respectively.     

The radial dependence of the magnetic hyperfine field for Sn atoms in the ferromagnetic Heusler alloys

The magnetic hyperfine fields,B _hf, for impurity¹¹⁹Sn atoms in Z sites of ferromagnetic Heusler alloys Co₂MnZ (Z=Si, Ge) are measured by the Mössbauer effect. At 77 KB _hf=–1.43±0.04 T in Co₂MnSi andB _hf=+1.05±0.05 T in Co₂MnGe. From the comparison between the values ofB _hf for Sn atoms in Co₂MnZ (Z=Si, Ge, Sn), it follows that the negative contribution toB _hf drops as the interatomic distance begins to increase. This radial dependence also manifests itself in the anomalies of the temperature dependences of the hyperfine fields. The temperature anomaly is positive for Sn in Co₂MnGe and negative for Sn in Co₂MnSi.     

Hyperfine Interaction of 111Cd in Fe3Sn Compound

The hyperfine interaction of ¹¹¹Cd in ferromagnetic Fe₃Sn compound was investigated by TDPAC in the paramagnetic region and below the Curie temperature. The results are compared with hyperfine magnetic fields and EFGs on ¹¹¹Cd and ¹¹⁹Sn in other stoichiometric Fe–Sn phases. This revised version was published online in September 2006 with corrections to the Cover Date.     

Magnetism of ErAgSn studied by 119Sn Mössbauer spectroscopy

Antiferromagnetic ErAgSn compound was investigated in detail by ¹¹⁹Sn Mössbauer spectroscopy in a temperature range between 2.2 and 300 K. The ¹¹⁹Sn spectra recorded below 4.2 K can be well fitted with a single main magnetic component in agreement with recent neutron diffraction studies [1]. A broad distribution of magnetic hyperfine fields observed above 4.2 K and enhanced spin correlations among Er³⁺ ions at T > T _N = 5.6 K are the remarkable features of the investigated system.     

Magnetic hyperfine structure of 119Sn in ferromagnetic Pd2MnSb

A magnetic hyperfine field of H = + 210 ± 5 kOe has been observed at Sn in Pd₂MnSb_0.99Sn_0.01 by Mössbauer spectroscopy on ¹¹⁹Sn. The significance of this measurement with respect to other hyperfine fields and theoretical calculations is discussed.     

Effet Mössbauer sur les noyaux d'impuretes 119Sn4+ dans la matrice de VO2

The phase transition in VO₂ doped with 0.16 at.% Sn⁴⁺ was investigated by Mössbauer spectroscopy of ¹¹⁹Sn. Hyperfine magnetic fields were observed on ¹¹⁹Sn nuclei below the transition temperature. At 77 K the maximum hyperfine magnetic field was found to be H(0)_{77 K} = 120 ± 10 kOe The results obtained are discussed in terms of fine antiferromagnetic particles.     

Magnetic hyperfine interactions and compositional short range order in the Heusler alloys Cu2MnIn1-xSnx

A comprehensive study of the magnetic hyperfine interactions and the processes of crystallographic ordering in the Heusler alloy system Cu₂MnIn_1-xSn_x has been made. We report the results of Mössbauer effect experiments, X-ray diffraction studies, electrical transport, and Curie temperature measurements. By a rapid quenching, low temperature annealing technique we have been able to extend the ordered L2₁ structure to high Sn concentration. Observations of inequivalent Sn sites and nonunique ¹¹⁹Sn hyperfine field values in these alloys are shown to be due to difficulties in ordering the L2₁ structure and a basic instability of this phase for high Sn concentrations. The compositional variation of ¹¹⁹Sn hyperfine fields in the ordered L2₁ phase of the Cu₂MnIn_1-xSn_x system reveals a systematic increase with Sn composition. Calculations of these fields based on a homogeneously spin polarized electron gas model reproduce the observed field systematics quite well. The implications of these results on the nature of magnetic interactions in Heusler alloys are discussed.     

Mössbauer study of119Sn defects in silicon from ion implantations of radioactive119In

Radioactive¹¹⁹In⁺ ions (T _1/2=2.1 min) obtained from the ISOLDE facility at CERN have been implanted into silicon single crystals at room temperature. Mössbauer emission spectra from the 24 keV -radiation of the daughter¹¹⁹Sn have been measured by fast resonance-counting technique. Five independent lines, characterized by their hyperfine parameters and Debye temperatures, have been found in the spectra. From the bonding configurations, deduced for the Sn impurity atoms, these are concluded to be located in four different defects in the silicon lattice. Simple models are proposed for the defects.     

Mössbauer study of the formation of impurity-vacancy complexes in copper

The formation of impurity-vacancy complexes has been studied with ion-implanted radioactive¹¹⁹Xe and its decay products, which populate the¹¹⁹Sn Mössbauer state via the decay chain¹¹⁹Xe→¹¹⁹I→¹¹⁹Te→¹¹⁹Sb→¹¹⁹Sn. The results of these implantations arecompared to those from earlier¹¹⁹In or Sbimplantations.     

119Sn Mössbauer spectroscopy of U x Th1−x CoSn and UCoAl1−x Sn x

Magnetization and¹¹⁹Sn Mössbauer spectroscopy studies were performed on two pseudoternary systems, namely U _x Th_1?x CoSn and UCoAl_1?x Sn _x . Magnetic hyperfine fields on¹¹⁹Sn nuclei were found to be due to local surrounding of U atoms which carry magnetic moments. In pure UCoSn the valuesB _hf=8.66 T and μ_∪ satisfy the relationB _hf=6.75 μ_B found for a number of UTX compounds studied. Local surrounding effects are indicated by multicomponent spectra obtained for the two pseudoternary series.     

Magnetic properties and 119Sn hyperfine interaction parameters of LiMn6Sn6

We have synthesized LiMn₆Sn₆, the first RMn₆Sn₆ compound involving an alkali metal as R element. It crystallizes in the hexagonal (P6/mmm) HfFe₆Ge₆-type structure. From magnetic measurements and powder neutron diffraction experiments it is found that LiMn₆Sn₆ magnetically orders at T_C = 380 K in a simple easy-plane ferromagnetic structure (m_Mn = 2.58 μ_B at 2 K). The ¹¹⁹Sn M?ssbauer spectrum recorded at 5 K indicates that the tin nuclei experience huge hyperfine fields (as large as 35 T). Electronic structure calculations are used to gain information about the microscopic origin of both the hyperfine field and electric field gradient at the Sn nuclei. The former arises due to spin-dependent hybridization between the 5s states of Sn and the 3d states of Mn. The latter comes from the 5p charge density close to the nucleus, whose anisotropy is mainly produced through directional interactions with the 3d states of the first Mn neighbors. Comparison between experimental quadrupole splittings and theoretical electric field gradients allows us to propose a value of for the quadrupole moment of the first excited state (I= 3/2) of the ¹¹⁹Sn nucleus.     

Influence of chromium on119Sn site hyperfine fields in Fe−Cr alloys

By diffusing¹¹⁹Sn probe atoms into a range of Fe–Cr alloys and carrying out Mössbauer effect measurements it has been shown that Sn site hyperfine fields exhibit the same dependence on chromium concentration as Fe site fields do. It has also been shown that the change in the Sn site field produced by Cr atoms situated in the first or in the second coordination sphere is the same as the corresponding change in the Fe site field. This shows that all the change in the hyperfine field caused by substitution of chromium into an iron matrix is due to conduction electron polarization contributions.     

Sn-vacancy defects in GaP

Complex¹¹⁹Sn-vacancy defects in GaP have been studied by Mössbauer-emission spectroscopy on the 24-keV γ radiation of¹¹⁹Sn. The defects were created by ion implantations of radioactive¹¹⁹In⁺ and¹¹⁹Sb⁺, which in their decays both populate the Mössbauer state of¹¹⁹Sn. The radiogenic¹¹⁹Sn-vacancy defects are proposed to consist of substitutional¹¹⁹Sn on Ga or P sites, respectively, associated with (P or Ga) vacancies.     

Mössbauer study of defects created by low-fluence In+ implantations in InP

The temperature and fluence dependence of defect interactions in damage cascades in n-type InP has been investigated with ion-implanted radioactive¹¹⁹In (T _1.2=2.1 min) probe atoms. The hyperfine interactions for the¹¹⁹Sn Mössbauer daughter atoms in the resulting defect structures have been determined. An annealing model based on the temperature dependent mobility of lattice defects and their interactions in three observed annealing stages is proposed.     

Magnetic hyperfine fields at Fe,Cd and Sn sites in an FeCo alloy

The magnetic hyperfine field at an Fe site in the ferromagnetic alloy Fe_0.475Co_0.525 was measured using the Mössbauer effect. The value obtained at room temperature was 343 kOe. The hyperfine field at a substituted Cd impurity was measured by the method of time differential perturbed angular correlations. A single frequency was observed at room temperature, corresponding to a field of -177 kOe. Using the Mössbauer effect, the Sn site hyperfine field was measured in a sample in which 0.3 atomic percent of ¹¹⁹Sn had been substituted. The room temperature spectrum consisted of the superposition of a single line, together with a six-line hyperfine spectrum, corresponding to a field of 231 kOe. A phenomenological interpretation is proposed for Fe, Cd and Sn fields in the binary alloys of iron.     

99Ru,61Ni,57Fe,and119Sn Mössbauer studies of Heusler alloys containing ruthenium

⁹⁹Ru,⁶¹Ni,⁵⁷Fe and¹¹⁹Sn Mössbauer spectroscopic studies were made on ternary intermetallic compounds containing ruthenium, Ru_xY_3?xZ (Y=Fe, Ni; Z=Si, Sn). In the system of Ru_xFe_3?xSi, two different hyperfine magnetic fields were observed at the⁹⁹Ru nuclei (H _hf[Ru]) in the range ofx≤1.0 and the magnitude of eachH _hf[Ru] was found to decrease with an increase in the ruthenium concentrationx. Both the⁹⁹Ru and¹¹⁹Sn Mössbauer spectra of Ru₂FeSn could be analyzed with two sets of magnetically split lines. The⁶¹Ni Mössbauer spectra of Ru₂NiSn were obtained at 5 and 77 K.