The specific features of phononic and magnetic subsystems of type-VII clathrate EuNi2P4.

A type-VII clathrate with a Eu2+ guest embedded into a Ni-P covalent framework, EuNi2P4, was synthesized by a standard two-stage ampoule synthesis and confirmed to crystallize in the orthorhombic space group Fddd with unit cell parameters a = 5.1829(1) Å, b = 9.4765(1) Å, and c = 18.9900(1) Å. A general technique for studying the lattice and magnetic properties of REE containing compounds is proposed. The temperature and field dependences of electrical resistivity ρ(T,H), magnetization M(T,H), magnetic susceptibility χ(T,H), heat capacity Cp(T), and unit cell parameters a(T), b(T), c(T), and volume V(T) were experimentally studied and analyzed at different pressures in the temperature range of 2-300 K. A cascade of anomalies in the studied dependences was identified and attributed to the magnetic phase transformation and peculiar lattice contributions at temperatures below 20 K. As a result of comparison with an isostructural clathrate SrNi2P4, the parameters of the magnetic and lattice contributions were determined. It is characteristic that the phase transition from the paramagnetic to the magnetically ordered state is not reflected in the temperature changes of the lattice parameters due to weak bonds between guest europium atoms and the Ni-P host matrix. We have constructed a tentative H-T phase diagram based on the M(T) and M(H) data, which includes 6 different phases. It is established that the anomalous lattice contribution to the clathrate heat capacity CTLS(T) appears due to the effect of two-level systems (TLS) in the Eu2+ subsystem on the thermodynamic properties of EuNi2P4. The values of TLS parameters as well as the parameters of the magnetic subsystem of the clathrate were determined.

[1]  E. Zvereva,et al.  Low-temperature thermodynamic and magnetic properties of clathrate-like arsenide Eu7Cu44As23 , 2020 .

[2]  A. Tsirlin,et al.  EuNi2P4, the first magnetic unconventional clathrate prepared via a mechanochemically assisted route , 2020, Inorganic Chemistry Frontiers.

[3]  D. Johnston,et al.  Helical antiferromagnetic ordering in EuNi1.95As2 single crystals , 2019, Physical Review B.

[4]  V. Novikov,et al.  Structure‐Related Thermal Properties of Type‐VII Clathrates SrNi2P4 and BaNi2P4 at Low Temperature , 2018 .

[5]  S. Kuznetsov,et al.  Specific features of the heat capacity and thermal expansion of icosahedral holmium boride HoB50 at temperatures of 2–300 K , 2017 .

[6]  P. Rogl,et al.  Skutterudites, a most promising group of thermoelectric materials , 2017 .

[7]  A. Shevelkov Thermoelectric Power Generation by Clathrates , 2016 .

[8]  A. Huq,et al.  Thermal expansion modeling of framework-type Na[AsW2O9] and K[AsW2O9] , 2016 .

[9]  A. Shevelkov,et al.  Negative thermal expansion and low-temperature heat capacity anomalies of Ge31P15Se8 semiclathrate , 2016 .

[10]  D. Morelli,et al.  Better thermoelectrics through glass-like crystals. , 2015, Nature materials.

[11]  V. Novikov,et al.  Peculiarities of electronic, phonon and magnon subsystems of lanthanum and samarium tetraborides , 2015 .

[12]  K. Kovnir,et al.  Twisted Kelvin Cells and Truncated Octahedral Cages in the Crystal Structures of Unconventional Clathrates, AM2P4 (A = Sr, Ba; M = Cu, Ni) , 2015 .

[13]  A. Morozov,et al.  Peculiarities of the lattice thermal properties of rare-earth tetraborides , 2015, Journal of Thermal Analysis and Calorimetry.

[14]  D. Johnston,et al.  Physical properties of EuPd2As2 single crystals , 2014, Journal of physics. Condensed matter : an Institute of Physics journal.

[15]  R. Prozorov,et al.  Spin glass and glass-like lattice behaviour in HoB66 at low temperatures , 2013 .

[16]  D. Johnston,et al.  Structural, thermal, magnetic, and electronic transport properties of the LaNi₂(Ge1-xPx)₂ system , 2011, 1112.1864.

[17]  A. Morozov,et al.  Low-temperature heat capacity of rare-earth tetraborides , 2011 .

[18]  B. Iversen,et al.  Thermoelectric clathrates of type I. , 2010, Dalton transactions.

[19]  V. Novikov Mean-square displacements of metal and boron atoms in crystal lattices of rare-earth hexaborides , 2003 .

[20]  A. Tari,et al.  The Specific heat of matter at low temperatures , 2003 .

[21]  V. Novikov Components of the low-temperature heat capacity of rare-earth hexaborides , 2001 .

[22]  G. Nolas,et al.  The Phonon—Glass Electron-Crystal Approach to Thermoelectric Materials Research , 2001 .

[23]  A. Novikov,et al.  Identity period and thermal expansion coefficient for rare-earth hexaborides at temperatures of 5–320 K , 2000 .

[24]  A. A. Sidorov,et al.  Heat capacity, root-mean-square displacements of atoms and thermal expansion coefficient of europium hexaboride , 2000 .

[25]  Z. Fisk,et al.  Structure and magnetic order of EuB{sub 6} , 1998 .

[26]  E. Johnston-Halperin,et al.  Angular dependence of metamagnetic transitions in HoNi2 B2 C , 1997 .

[27]  Mukherjee,et al.  Thermal expansion study of ordered and disordered Fe3Al: An effective approach for the determination of vibrational entropy. , 1996, Physical review letters.

[28]  Blanco,et al.  Specific heat in some gadolinium compounds. II. Theoretical model. , 1991, Physical review. B, Condensed matter.

[29]  Liu,et al.  Expansion in 1/z for the transition temperature and specific heat of ferromagnets. , 1989, Physical review. B, Condensed matter.

[30]  J. Schilling,et al.  Pressure and temperature dependence of electrical resistivity of Pb and Sn from 1-300K and 0-10 GPa-use as continuous resistive pressure monitor accurate over wide temperature range; superconductivity under pressure in Pb, Sn and In , 1981 .

[31]  J. Schilling Pressure as a parameter in the study of dilute magnetic alloys , 1979 .

[32]  B. Lüthi,et al.  Crystal field effect in the thermal expansion of cubic rare earth compounds , 1977 .

[33]  B. Lüthi,et al.  Crystal-Electric-Field Effects on the Thermal Expansion of TmSb , 1976 .

[34]  J. W. Stout,et al.  HEAT CAPACITY OF ZINC FLUORIDE FROM 11 TO 300 K. THERMODYNAMIC FUNCTIONS OF ZINC FLUORIDE. ENTROPY AND HEAT CAPACITY ASSOCIATED WITH THE ANTIFERROMAGNETIC ORDERING OF MANGANOUS FLUORIDE, FERROUS FLUORIDE, COBALTOUS FLUORIDE, AND NICKELOUS FLUORIDE , 1955 .