Crystal Structures, Optical, and Magnetic Properties of Zn3-xMnxTeO6

Shufang LI; Shuang ZHAO; Xiao ZHOU; Manrong LI

doi:10.15541/jim20190606

[1] Y TOKURA, S SEKI, N NAGAOSA. Multiferroics of spin origin. Reports Progress in Physics, 77, 076501(2014).

[2] W EERENSTEIN, N D MATHUR, J F SCOTT. Multiferroic and magnetoelectric materials. Nature, 442, 759-765(2006).

[3] C N R RAO, A SUNDARESAN, R SAHA. Multiferroic and magnetoelectric oxides: the emerging scenario. The Journal of Physical Chemistry Letters, 3, 2237-2246(2012).

[4] N A SPALDIN, M FIEBIG. The renaissance of magnetoelectric multiferroics. Science, 309, 391-392(2005).

[5] T KIMURA, T GOTO, H SHINTANI et al. Magnetic control of ferroelectric polarization. Nature, 426, 55-58(2003).

[6] J WANG, J B NEATON, H ZHENG et al. Epitaxial BiFeO₃ multiferroic thin film heterostructures. Science, 299, 1719-1722(2003).

[7] Y KITAGAWA, Y HIRAOKA, T HONDA et al. Low-ﬁeld magnetoelectric effect at room temperature. Nature Materials, 9, 797-802(2010).

[8] M R LI, U ADEM, S R C MCMITCHELL et al. A polar corundum oxide displaying weak ferromagnetism at room temperature. Journal of the American Chemical Society, 134, 3737-3747(2012).

[9] L W FINGER, R M HAZEN. Crystal structure and compression of ruby to 46 kbar. Journal of Applied Physics (USA), 49, 5823-5826(1978).

[10] G H CAI, M GREEBLATT, M R LI. Polar magnets in double corundum oxides. Chemistry of Materials, 29, 5447-5457(2017).

[11] H SCHULZ, G BAYER. Structure determination of Mg₃TeO₆. Acta Crystallographica,Section B (Structural Crystallography and Crystal Chemistry), B27, 815-21(1971).

[12] M WEIL. Mn₃TeO₆. Acta Crystallographica Section E Structure Reports Online, 62, i244-i245(2006).

[13] R BECKER, H BERGER. Reinvestigation of Ni₃TeO₆. Acta Crystallographica Section E-Structure Reports Online, 62, I222-I223(2006).

[14] L FALCK, O LINDQVIST, J MORET. Tricopper(II) tellurate(VI). Acta Crystallographica Section B, 34, 896-897(1978).

[15] M HERAK. Cubic magnetic anisotropy of the antiferromagnetically ordered Cu₃TeO₆. Solid State Communications, 151, 1588-1592(2011).

[16] R MATHIEU, S A IVANOV, P NORDBLAD et al. Enhancement of antiferromagnetic interaction and transition temperature in M₃TeO₆ systems (M=Mn, Co, Ni, Cu). The European Physical Journal B, 86, 361(2013).

[17] G CAIMI, L DEGIORGI, H BERGER et al. Optical evidence for a magnetically driven structural transition in the spin web Cu₃TeO₆. Europhysics Letters, 75, 496(2006).

[18] A BHIM, J GOPALAKRISHNAN, S NATARAJAN. Exploring the corundum structure as a host for colored compounds-synthesis, structures, and optical studies of (MM’)₃TeO₆(M=Mg, Mn, Co, Ni, Zn; M’=Mg, Mn, Co, Ni, Cu). European Journal of Inorganic Chemistry, 2277-2284(2018).

[19] M WEIL. Zn₃TeO₆. Acta Crystallographica Section E Structure Reports Online, 62, i246-i247(2006).

[20] S A IVANOV, R TELLGREN, C RITTER et al. Temperature- dependent multi-k magnetic structure in multiferroic Co₃TeO₆. Materials Research Bulletin, 47, 63-72(2012).

[21] S A IVANOV, R MATHIEU, P NORDBLAD et al. Spin and dipole ordering in Ni₂InSbO₆ and Ni₂ScSbO₆ with corundum-related structure. Chemistry of Materials, 22, 935-945(2013).

[22] K Y CHOI, P LEMMENS, E S CHOI et al. Lattice anomalies and magnetic excitations of the spin web compound Cu₃TeO₆. Journal of Physics: Condensed Matter, 20, 505214(2008).

[23] H SINGH, H GHOSH, RAO T V CHANDRASEKHAR et al. Short range ferromagnetic, magneto-electric, and magneto- dielectric effect in ceramic Co₃TeO₆. Journal of Applied Physics, 119, 044104(2016).

[24] H SINGH, A K SINHA, H GHOSH et al. Structural investigations on Co_3-xMn_xTeO₆; (0<x≤2): high temperature ferromagnetism and enhanced low temperature anti-ferromagnetism. Journal of Applied Physics (USA), 116, 074904-1-9(2014).

[25] A B HARRIS. Symmetry analysis of multiferroic Co₃TeO₆. Physical Review B, 85, 100403(2012).

[26] J L HER, C C CHOU, Y H MATSUDA et al. Magnetic phase diagram of the antiferromagnetic cobalt tellurate Co₃TeO₆. Physical Review B, 84, 35123(2011).

[27] P TOLEDANO, V CAROLUS, M HUDL et al. First-order multi-k phase transitions and magnetoelectric effects in multiferroic Co₃TeO₆. Physical Review B, 85, 214439(2012).

[28] C W WANG, C H LEE, C Y LI et al. Complex magnetic couplings in Co₃TeO₆. Physical Review B, 88, 184427(2013).

[29] M HUDL, R MATHIEU, S A IVANOV et al. Complex magnetism and magnetic-field-driven electrical polarization of Co₃TeO₆. Physical Review B, 84, 180404(2011).

[30] A B HARRIS. Symmetry analysis of multiferroic Co₃TeO₆. Physical Review B, 85, 100403(2012).

[31] H SINGH, H GHOSH, T V C RAO et al. Observation of high-spin mixed oxidation state of cobalt in ceramic Co₃TeO₆. Journal of Applied Physics, 116, 214106-1-7(2014).

[32] S A IVANOV, P NORDBLAD, R MATHIEU et al. New type of incommensurate magnetic ordering in Mn₃TeO₆. Materials Research Bulletin, 46, 1870-1877(2011).

[33] S A IVANOV, R MATHIEU, P NORDBLAD et al. Chemical pressure effects on structural, dielectric and magnetic properties of solid solutions Mn_3-xCo_xTeO₆. Materials Research Bulletin, 50, 42-56(2014).

[34] A COELHO. Whole-profile structure solution from powder diffraction data using simulated annealing. Journal of Applied Crystallography, 33, 899-908(2000).

[35] J TAUC. Optical properties and electronic structure of amorphous Ge and Si. Materials Research Bulletin, 3, 37-46(1968).

[36] C LIU, M YE, A HAN et al. Structural analysis and characterization of doped spinel Co_2-xM_xTiO₄ (M=Mg ²⁺, Mn ²⁺, Ni ²⁺, Cu ²⁺ and Zn ²⁺) coated mica composite pigments. Ceramics International, 41, 5537-5546(2015).