Abstract
A new experimental setup and methodology that allows the automatic tracking of a Mössbauer absorption line as its energy position varies during the experiment is introduced. As a test the sixth spectral line of FeSn2 was tracked while temperature was varied between room temperature and a value slightly above its Néel temperature.
Article PDF
Similar content being viewed by others
Avoid common mistakes on your manuscript.
References
Paulsen, H., Schünemann, V., Trautwein, A.X., Winkle, H.: Mössbauer studies of coordination compounds using synchrotron radiation. Coord. Chem. Rev. 249, 255–272 (2005)
Mørup, S.: Mössbauer studies of relaxation effects by use of a polarized source. Hyperfine Interact. 1, 533–543 (1975)
Hesse, J., Graf, T., Kopcewicz, M., Afanas’ev, A., Chuev, M.: Mössbauer experiments in radio frequency magnetic fields: a method for investigations of nanostructured soft magnetic materials. Hyperfine Interact. 113, 499–506 (1998)
Mendoza Zélis, P., Pasquevich, G.A., Sánchez, F.H., Veiga, A., Martínez, N.: A new application of Mössbauer effect thermal scans: determination of the magnetic hyperfine field temperature dependence. Phys. Lett. A 298, 55–59 (2002)
Pasquevich, G.A., Mendoza Zélis, P., Fernández van Raap, M.B., Sánchez, F.H.: Hyperfine field temperature dependence of Fe3Si from Mössbauer thermal scans. Physica B 354, 369–372 (2004)
Pasquevich, G.A., Mendoza Zélis, P., Sánchez, F.H., Fernández van Raap, M.B., Veiga, A., Martínez, N.: Magnetic and thermal Mössbauer effect scans: a new approach. Hyperfine Interact. 167, 839–844 (2006)
Mendoza Zélis, P., Rodriguez Torres, C., Cabrera, A.F., Fernández van Raap, M., Pasquevich, G.A., Sánchez, F.H., González, A., Sunyol, J.J.: Thermal evolution of Fe65Ni20Nb6B9 nanocrystalline metastable alloy. J. Metastable Nanocryst. Mater. 20, 571–575 (2004)
Sánchez, F.H., Pasquevich, G.A., Mendoza Zélis, P., Cabrera, A.F., Ying-feng, L., Vázquez, M.: Study of magnetic materials by Mössbauer thermal scans. Application to nanocrystalline systems. J. Metastable Nanocryst. Mater. 22, 39–44 (2004)
Saccone, F.D., Rodríguez Torres, C.E., Pasquevich, G.A., Fernández van Raap, M.B., Sánchez, F.H.: Crystallisation kinetics of B-rich mischmetal-Fe-B nanocomposite ribbons. Physica B 354, 237–240 (2004)
Pasquevich, G.A., Mendoza Zélis, P., Sánchez, F.H., Fernández van Raap, M.B., Veiga, A., Martínez, N.: Determination of the iron atomic magnetic moments dynamics in the nanocrystalline ribbons Fe90Zr7B3 by Mössbauer magnetic scans. Physica B 384, 348–350 (2006)
Veiga, A., Martínez, N., Mayosky, M., Spinelli, E., Mendoza Zélis, P., Pasquevich, G.A., Sánchez, F.H.: A constant-velocity Mössbauer spectrometer with controlled temperature sweep. Rev. Sci. Instrum. 73, 3579–3583 (2002)
Veiga, A., Martínez, N., Mendoza Zélis, P., Pasquevich, G.A., Sánchez, F.H.: Advances in constant-velocity Mössbauer instrumentation. Hyperfine Interact. 167, 905–909 (2006)
Nam, H.D., Kim, E.C., Han, J.S.: Mössbauer study of iron sulfides doped with 3d-transition metals. Solid State Commun. 135, 327–329 (2005)
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Veiga, A., Pasquevich, G.A., Zélis, P.M. et al. Experimental design and methodology for a new Mössbauer scan experiment: absorption line tracking. Hyperfine Interact 188, 137–142 (2009). https://doi.org/10.1007/s10751-008-9899-y
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10751-008-9899-y