Bünzli / Pecharsky Handbook on the Physics and Chemistry of Rare Earths

Chapter 252 Thermal and Electronic Properties of Rare Earth Compounds at High Pressure Y. Uwatoko*, I. Umehara†, M. Ohashi‡, T. Nakano§, G. Oomi¶|| * The Institute for Solid State Physics, The University of Tokyo, Kashiwa, Japan † Department of Physics, Faculty of Engineering, Yokohama National University, Yokohama, Japan ‡ Faculty of Environmental Design, Kanazawa University, Kakuma-machi, Kanazawa, Ishikawa, Japan § Department of Materials Science and Technology, Faculty of Engineering, Niigata University, Ikarashi, Niigata, Japan ¶ Department of Physics, Kyushu University, Hakozaki, Fukuoka, Japan || Department of Education and Creation Engineering, Kurume Institute of technology, Kamitsu-machi, Kurume, Fukuoka, Japan Abstract Electronic properties of rare earth metals, alloys and intermetallic compounds have attracted a lot of attention not only from the viewpoint of fundamental aspects but also from the application. These materials show a wide variety of electronic and magnetic properties, such as magnetic order, superconductivity, intermediate valence, Kondo effect and so forth. In this chapter we introduce a lot of experimental studies about the effect of pressure on the thermal, structural and electronic properties of rare earth compounds, in which the electronic states are marginal due to unstable 4f electrons. We describe the present status in this research area. In section 2, the relations between crystal structure and electronic and magnetic state by using X-ray and neutron diffraction under pressure are reported. Effect of pressure on the thermal properties mainly for heavy fermions are reported in section 3. Novel pressure-induced electronic phase transitions such as the crossover in the electronic states and superconductivity are introduced for several heavy fermion materials in section 4. In the last section 5, we show miscellaneous examples which are found recently for amorphous state rare earth compounds and rare earth magnetic multilayers. Abbreviations a thermal expansion coefficient amag the magnetic contribution to a ? electronic specific heat coefficient eF Fermi energy ? the compressibility ?i linear compressibilities along i-axis (i = a, b, or c) ? resistivity t wave vector ?s angular frequency ?(0) superconducting gap at T = 0 G' Grüneisen parameter ?l/l linear thermal expansion ?mag energy gap of antiferromagnetic magnon TD Debye temperature A coefficient of T2 term in resistivity AFM antiferromagnetism B0 bulk modulus B0' pressure derivative of bulk modulus BCS Bardeen–Cooper–Schrieffer BT the isothermal bulk modulus C heat capacity Cac alternating current specific heat CEF crystalline electric field CK concentrated Kondo Cs heat capacity of superconductivity CV the specific heat at constant volume D(E) density of state at energy E E energy FRP fiber-reinforced plastic FWHM full width at half maximum g0 the degeneracy factor of ground state g1 the degeneracy factor of exited sate H magnetic field reduced Planck constant or Dirac constant HF heavy fermion hpp high-pressure phase HRC Rockwell hardness in C-scale IC incommensurate kB Boltzmann constant lpp low-pressure phase MPMS magnetic property measurement system n electronic density ND neutron diffraction NMR nuclear magnetic resonance P pressure Pc critical pressure Q wave vector q1 propagation vector R gas constant SC superconductivity T temperature T0 a characteristic temperature TC Curie temperature Tc superconducting transition temperature TF the temperature where electron becomes in Fermi liquid state TK Kondo temperature Tmax temperature showing resistance maximum TN Néel temperature TPT topological phase transition Tsf spin fluctuation temperature U internal energy V volume of unit cell V0 volume at ambient pressure 1. INTRODUCTION
The physical properties of condensed matter are dominated by interactions between particles or quasiparticles. Among them, the electron correlations are the most important interactions in determining the electronic and magnetic properties of condensed matter. In other words, the understanding of the mechanisms of electron correlations in condensed matter is one of the most basic problems in solid-state physics. High-Tc superconductivity (SC) and novel physical properties of rare earth compounds are thought to originate from strong electron correlations in f- and d-electron systems. In alloys and intermetallic compounds, including rare earth elements, many anomalous physical properties such as Kondo effect, magnetic ordering, SC, and other have been observed. These phenomena are closely connected to the electron correlations between localized 4f electrons and conduction electrons. It has been well known that physical properties of materials on the border of magnetic instability are strongly dependent on external parameters such as external pressure, magnetic fields, and chemical composition. Novel electronic properties of rare earth compounds are due to the existence of localized 4f electrons, which generally speaking, have strong electron correlations and unstable electronic states. These properties are also expected from the anomalous pressure–temperature phase diagram of rare earth elements, in which numerous phase transitions are observed at low temperature and at high pressure. The heavy fermion (HF) compounds, which are a group of Kondo compounds that have extremely large specific heat coefficients, are typical examples having unstable electronic states, and it is well known that their physical properties are affected strongly by a change of magnetic field and external pressure. In this chapter, we present the structural and thermal properties of rare earth compounds under high pressure in connection with their electronic and magnetic properties. Pressure is an excellent tool facilitating many types of phase transitions, including quantum phase transitions (QPTs) in condensed matter. There is a large body of research describing physical properties of condensed matter under high pressure in relationship not only to magnetic and electronic properties but also to structural properties. Because of size constrains, we confine our discussion to the present status of research in thermal and electronic aspects of physical properties of rare earth compounds, in which almost all examples are or may potentially be highly correlated compounds including rare...