Keywords:

intermetallic compounds, amorphous materials, nanocrystalline alloys, magnetism, magnetocaloric effect, thermoelectric power, Kondo lattices

The Laboratory is engaged in the complex studies of new magnetic materials such as:

• rare earth intermetallic compounds
• strongly correlated electron systems
• nanocrystalline magnetic alloys
• amorphous magnetic ribbons
• thin films of rare earth and transition metals
• metallic multilayers
• rare earth manganite
• magnetic nanostructures

Research aims

Experimental studies supported by the theoretical interpretation in the area of the strongly correlated electron systems with main emphasis on the Kondo lattices, systems with the impurity Kondo effect, fluctuating valence systems, spin glasses. Characterization of the glass forming ability of the amorphous alloys and the studies of the crystallization processes in the structurally metastable alloys. Search for new magnetocaloric and thermoelectric materials with parameters expected in applications.

Research profile

Preparation of the rare earth-based intermetallic compounds and alloys in a crystalline, nanocrystalline and amorphous form. Structural characterization (X-ray diffraction) and determination of the magnetic (magnetometry, dc and ac magnetic susceptibility), electrical (electrical resistivity, magnetoresistance, Hall effect), and thermal (specific heat, thermal conductivity, thermoelectric power) properties in a wide temperature range.

Scientific achievements

• A jump of material density was observed when changing the stoichiometry for Hf₁Cr₁Co₁₁B and Hf_0.5Cr_1.5Co₁₁B, which was correlated with a change of structure from amorphous to crystalline. Measurements have been carried out with a novel method, employing a confocal microscope, enabling measurements for samples with small volume [Śniadecki et al. Materials Characterization 132, 46 (2017)]
• Based on the measurements of the DC and AC magnetic susceptibility the magnetic phase diagram was determined for the series Ce(Cu_1-xNi_x)₄Mn. It shows a complex character, e.g. it indicates presence of regions with coexisting ferromagnetic and spin glass phases [K. Synoradzki, T. Toliński, Materials Chemistry and Physics, 177, 242-249 (2016)]
• Coexistence of two phases of Hf₂Co₁₁ was confirmed based on the XRD and thermomagnetic measurements of the alloy Hf₂Co₁₁B [A. Musiał et al. J. Alloys Compd. 665, 93 (2016)]
• The influence of the chemical and topological disorder on the magnetic properties of compounds based on the Pauli paramagnet YCo₂ has been observed and described [Z. Śniadecki et al., J. Appl. Phys. 115, 17E129 (2014), Z. Śniadecki et al., Appl. Phys. A 118, 1273 (2015), A. Wiśniewski et al., J. Alloys Compd. 618, 258 (2015)]
• Using semi-empirical models the glass forming ability of the transition metal based ternary systems has been determined. The ranges of stoichiometry promoting the alloys amorphization have been calculated [Z. Śniadecki, J. Alloys Compd. 615, S40 (2014)]
• Magnetic properties and parameters characterizing the magnetocaloric effect have been determined for ferrimagnets composed of two sublattices based on cobalt and rare earth element [Z. Śniadecki et al., J. Alloys Compd. 584, 477 (2014)]
• The mechanism of the amorphization of the alloys Y(Ce)-Cu-Al has been explained and the influence of the 4f electrons on the magnetic, transport, and thermal properties of these alloys has been described [B. Idzikowski et al., J. Non-Cryst. Solids 357, 3717 (2011), B. Idzikowski et al., J. Non-Cryst. Solids 383, 2 (2014)]
• For many cerium based compounds the influence of the crystal electric field on their physical properties has been determined. The research includes mainly the magnetic susceptibility, specific heat, and inelastic neutron scattering measurements [ Toliński et al., J. Magn. Magn. Mater. 345, 243 (2013)]
• For the first time the adiabatic temperature change and the influence of the grains size on the efficiency of the magnetocaloric effect in the Mn₅Ge₃ compound have been determined. For selected compounds of the series RNi₄M (R- rare earth, M - metalloid) the parameters characterizing the magnetocaloric effect have been extracted. [T. Toliński et al., Intermetallics 47, 1 (2014), Toliński et al., J. Alloys Compd. 523, 43 (2012)]
• Complementary studies of the isostructural series of compounds Ce(Cu_1-xNi_x)₄Mn_yAl_1-y enabled a construction of magnetic phase diagrams for four transformations between different ground states (ferromagnetic state, spin glass, fluctuating valence, heavy fermions) [K. Synoradzki et al., Phys.: Condens. Matter 24, 136003 (2012)]
• Magnetic susceptibility measurements in a wide temperature range (2-1000 K) supported by the interconfiguration fluctuation model (ICF) have shown a presence of the valence fluctuations between Yb³⁺ and Yb²⁺ for the compound YbNiAl This compound is not a heavy fermion system, which results from the determined small value of the electronic specific heat coefficient. [A. Kowalczyk et al., J. Appl. Phys. 107, 123917 (2010)]
• The temperature dependences of the thermopower have been determined and explained for the Kondo lattices CeCu₄M and for compounds exhibiting fluctuating valence CeNi₄M (M = In, Ga) [T. Toliński et al., J. Alloys Compd. 490, 15 (2010)]
• Apart from the experimental methods employed directly in the Magnetic Alloys Department, the carried out researches involve many complementary methods accessible in frames of the international cooperation (neutron diffraction, inelastic neutron scattering, synchrotron radiation)

• NIR - FT - Raman spectrometer (IFS 66 FRA 106, Bruker)
• Raman microscope with helium cryostat - financed by the Foundation for Polish Science, 1996.
• Equipment for dielectric spectroscopy in frequency range 10 - 10⁹ Hz and temperature range 10 - 500 K.
• Equipment for electric conductivity measurements from d.c. to 10⁹ Hz.
• Equipment for optical study in temperature range 70 - 870 K (Linkam).
• Differential scanning calorimeter - Netzsch DSC 200

  

  Phot.1 Equipment for dielectric spectroscopy in frequency range 10 - 10⁹ Hz and temperature range 10 - 500 K.

• Ball-mill Pulverisette 6, Fritsch
  

  

  

• University of Stuttgart,Stuttgart, Germany (Prof. Frank Giesselmann)
• Academy of Sciences of the Czech Republic, Prague, Czech Republic (Prof. M. Glogarova, Dr V. Hamplova,Dr A. Bubnov, Dr V. Novotna)
• University of Picardy, Amiens, France (Prof. Jiri Pavel)
• Chalmers University of Technology, Göteborg, Sweden (Prof. P. Rudquist)
• Landau Institute for Theoretical Physics, Moscow, Russia (Prof. V.A. Belyakov)
• Poznan University of Technology, Institute of Physics, Poznań, Poland (Prof. P. Pierański, Prof. T. Martyński, Dr E. Chrzumnicka, Dr A. Modlińska, Dr R. Hertmanowski, Dr hab. Arkadiusz Ptak oraz dr inż. Szymon Maćkowiak)
• Military University of Technology, Department of Physics and Technology Crystals, Warsaw, Poland (Prof. R. Dąbrowski, Prof. Z. Raszewski, Prof. J. Kędzierski, Prof. P. Perkowski, Prof. W. Piecek, Prof. M. Tykarska, Prof. P. Kula)
• University of London, Royal Holloway, Department of Physics, London, UK (Prof. D. M. Heyes)
• Imperial College of London, Department of Mechanical Engineering, London, UK (Dr. D. Dini)
• Wood Technology Institute, Department of Glues and Wood-Based Materials, Poznań, Poland (Dr. D. Janiszewska)
• Faculty of Chemistry UWr, Wrocław, Poland (Prof. Zbigniew Galewski)

Scientific Problems

The mission of the Department of Ferroelectrics is:

• study of electric and magnetic materials including ferroics nanomaterials, ferroelectrics, multiferroics, ionic and superprotonic conductors by means of high-frequency dielectrometry method and magnetometric methods (VSM magnetometer, AC susceptometer)
• characterization of morphology, structure and composition of these materials using electron microscopy (SEM, TEM, SAED, EDS), X-ray diffraction
• synthesis of materials and nanomaterials by means of mechanical alloying and microwave activated hydrothermal reaction method.

The general aim of researches is manufacturing of new ferroic and multiferroics materials, getting knowledge about theirs properties, and explaining mechanisms of electric transport in fast ion conductors and polymers.

Researches of ferroics including M-hexaferrites Sr(Ba)Fe₁₂O₁₉ and of BiFeO₃ multiferroics are aimed at synthesis of new materials (by means of mechanosynthesis or by hydrothermal synthesis) and explaining the influence of morphology and doping with Nd³⁺, Al³⁺, Sc³⁺, … ions on theirs magnetoelectric properties.

The researches concern also magnetic orderings in large systems of magnetic nanoparticles like, for example, Fe₃O₄@SiO₂ magnetite particles in silica shell and investigations of conducting properties of LiMn₂O₄ doped ceramics.

In the case of fast ion conductors the studies are aimed at getting basic knowledge about electric transport mechanisms, phase transitions and physical properties of new organic compounds like, for example, new ferroelectrics [C(NH₂)₃]₄X₂SO₄ (X=Cl, Br) or [C(NH₂)₃]₄Cl₂SO₄ and (NH₄)₄H₂(SeO₄)₂ crystals. Similar studies are performed for [(CH₃)₂CHCH₂]NHSO₄ compound with hyper polarized organic cathions.

Badanie własności elektrycznych i magnetycznych materiałów oraz nanomateriałów ferroicznych, M-heksaferrytów, multiferroików, ferroelektryków oraz przewodników jonowych i superprotonowych metodami wysokoczęstościowej dielektrometrii oraz magnetometrii (magnetometr z wibrującą próbką VSM, podatnościomierz AC), charakteryzowanie: morfologii, składu i struktury tych materiałów za pomocą mikroskopii elektronowej (SEM, TEM, SAED, EDS), dyfrakcji rentgenowskiej, oraz wytwarzanie materiałów i nanomateriałów metodą mechanosyntezy i mikrofalowo aktywowanej syntezy hydrotermalnej.

Figs 2-5 Various forms of bismuth ferrite BiFeO₃ micro- and nanocrystals (synthesis performed by dr. Katarzyna Chybczyńska).