Energy gap formation mechanism through the interference phenomena of electrons in face-centered cubic elements and compounds with the emphasis on half-Heusler and Heusler compounds

Abstract Many face-centred cubic elements and compounds with the number of atoms per unit cell N equal to 8, 12 and 16 are known to be stabilised by forming either a band gap or a pseudogap at the Fermi level. They are conveniently expressed as cF8, cF12 and cF16, respectively, in the Pearson symbol. From the cF8 family, we worked on three tetravalent elements C (diamond), Si and Ge, SZn-type AsGa compound and NaCl-type compounds like BiLu, AsSc, etc. From the cF12 family, more than 80 compounds were selected, with a particular emphasis on ABC- and half-Heusler-type ternary equiatomic compounds. Among cF16 compounds, both the Heusler compounds ABC2 and Zintl compounds were studied. We revealed that, regardless of whether or not the transition metal (TM) and/or rare-earth (RE) elements are involved as constituent elements, the energy gap formation mechanism for cF8, cF12 and cF16 compounds can be universally discussed in terms of interference phenomenon of itinerant electrons with set of reciprocal lattice planes with = 8, 11 and 12, where refers to square of the critical reciprocal of lattice vector of an fcc lattice. The number of itinerant electrons per unit cell, e/uc, for all these band gap/pseudogap-bearing compounds is found to fall on a universal line called “3/2-power law” when plotted against on a logarithmic scale. This proves the validity of the fulfilment of the interference condition in conformity with other pseudogap compounds with different crystal symmetries and different sizes of the unit cell reported in literature.

[1]  Jessica Schulze,et al.  The Nature Of The Chemical Bond , 2016 .

[2]  Ruoff,et al.  Experimental study of the crystal stability and equation of state of Si to 248 GPa. , 1990, Physical review. B, Condensed matter.

[3]  Hirokazu Sato,et al.  The Physics of the Hume-Rothery Electron Concentration Rule , 2017 .

[4]  Linus Pauling,et al.  THE NATURE OF THE CHEMICAL BOND. APPLICATION OF RESULTS OBTAINED FROM THE QUANTUM MECHANICS AND FROM A THEORY OF PARAMAGNETIC SUSCEPTIBILITY TO THE STRUCTURE OF MOLECULES , 1931 .

[5]  Y. Nishino,et al.  Doping effects on thermoelectric properties of the off-stoichiometric Heusler compounds Fe2−xV1+xAl , 2014 .

[6]  Hirokazu Sato,et al.  Determination of electrons per atom ratio for transition metal compounds studied by FLAPW-Fourier calculations , 2016 .

[7]  Hirokazu Sato,et al.  Electrons per atom ratio determination and Hume-Rothery electron concentration rule for P-based polar compounds studied by FLAPW-fourier calculations. , 2015, Inorganic chemistry.

[8]  R. P.,et al.  The Theory of the Properties of Metals and Alloys , 1937, Nature.

[9]  A R Plummer,et al.  Introduction to Solid State Physics , 1967 .

[10]  U. Mizutani,et al.  Electron Theory of Complex Metallic Alloys , 2014 .

[11]  P. Strange,et al.  Understanding the valency of rare earths from first-principles theory , 1999, Nature.

[12]  Patrice E.A. Turchi. Thaddeus B. Massalski The science of complex alloy phases: proceedings of a symposium , 2005 .

[13]  Uichiro Mizutani,et al.  Introduction to the Electron Theory of Metals: Superconductivity , 2001 .

[14]  水谷 宇一郎 Introduction to the electron theory of metals , 2001 .