Tailoring thermal conduction in anatase TiO2

Thermal conductivity (κ) plays an essential role in functional devices. It is advantageous to design materials where one can tune κ in a wide range according to its function: single-crystals and nanowires of anatase polymorph of titanium dioxide, broadly used in applications ranging from photovoltaics, reflective coatings to memristors, have been synthesized in large quantities. Here we identify a new, strong diffusion mechanism of heat by polaronic structures due to oxygen vacancies, which considerably influences both the absolute value and the temperature dependence of κ. The additional decrease of κ is achieved in anatase nanowires organized into foam, where porosity and the quasi-one-dimensional size-effect dramatically hinder the propagation of heat, resulting in an extremely low κ = 0.014 W/Km at room-temperature. Doping this anatase foam could herald promising applications, in particular in thermoelectricity.

Tailoring thermal properties of functional materials

Xavier François Mettan

Thermal conductivity (k) plays an essential role in functional devices. In some cases, high value is required to transfer heat efficiently. In others, low k assists in maintaining a temperature gradient necessary for device operation. It is profitable to design materials where one can tune k in a broad range according to its function. Beyond functionality, k is a fundamental property of matter, and a fantastic probe to assess vibrational dynamics and electronic structure in condensed matter. In conjunction with other transport properties such as electrical resistivity and thermoelectric power, k promotes a deeper understanding of the electronic and vibrational structure of materials. In the present Thesis, careful experimental determination of the transport coefficients of a variety of systems over a broad temperature range (4-300 K) let me unveil subtle interactions between phonons and/or electrons. The insights gained from an accurate interpretation of these properties empowers us to engineer and fine-tune the functionality of materials for applications. I first investigate the thermoelectric properties of nickel-based high-entropy alloys (HEAs), believed to host unconventional effects arising from the high level of site-disorder in their crystalline structure. Anomalous resistivity with a low temperature coefficient validates the disordered nature of HEAs. The Seebeck coefficient, reported for the first time for HEAs, is surprisingly low. In the quest to understand transport in HEA, I have discovered that iron-nickel alloys exhibit a promising thermoelectric figure of merit (ZT) of 0.1 at room temperature. One way to further increase ZT is to decrease k (in FeNi alloys or other materials) by texturing the material. Aluminium foams are systems of choice to observe the effect of a modified structure on the thermoelectric properties. Tailoring of the bubbles' size is demonstrated by applying an external acoustic force in the foaming process. Moreover, the influence of the macro- and micro- structure of the foams on thermoelectric properties is discussed. The best example for tuning k by texturing it is anatase titanium dioxide (TiO2). k was varied over three orders of magnitude by adjusting its oxygen contents and by texturing it into a foam, aerogel-like structure. We identified a new, strong diffusion mechanism of heat by polarons, created as a consequence of oxygen vacancies. Furthermore, anatase nanowires organized into foams result in an unprecedented low k = 0.014 W/Km at room-temperature. Doping this anatase foam heralds promising applications, in particular in thermoelectricity. An oxide which has an intrinsically nanoporous structure reminding that of a foam, is Mayenite (Ca12Al14O33). The thermal conductivity of such system is verified to be intrinsically low. The peculiar cage structure could host atomic of molecular species to tune its electrical conductivity, with bright prospects for thermoelectric applications. Finally, the thermoelectric properties of hybrid halide perovskites, cheap and easy-to-synthesise compounds, were studied. Three materials of this family have ultra-low k, due to the vibrational degrees of freedom of their organic cations. Notably, a tin-based organic-inorganic compound delivers ZT = 0.13 at room temperature. The thermoelectric conversion efficiency of this material was measured directly and is believed to yield promising thermoelectric applications.

EPFL2019

Ultra-Low Thermal Conductivity in Organic-Inorganic Hybrid Perovskite CH3NH3PbI3

László Forró, Richard Gaal, Endre Horvath, Jacim Jacimovic, Andrea Pisoni, Massimo Spina

We report on the temperature dependence of thermal conductivity of single crystalline and polycrystalline organometallic perovskite CH3NH3PbI3. The comparable absolute values and temperature dependence of the two samples' morphologies indicate the minor role of the grain boundaries on the heat transport. Theoretical modeling demonstrates the importance of the resonant scattering in both specimens. The interaction between phonon waves and rotational degrees of freedom of CH3NH3+ sublattice emerges as the dominant mechanism for attenuation of heat transport and for ultralow thermal conductivity of 0.5 W/(Km) at room temperature.

Amer Chemical Soc2014

Pressure-tuned Transport Properties of Novel Iron-based Superconductors and Topological Insulators

Andrea Pisoni

The majority of interactions in solids strongly depend on the interatomic distances. The application of pressure changes the lattice parameters and modifies the electronic and the phononic energy spectra of a material avoiding some of the undesirable effects induced by chemical doping, like lattice disorder, impurity phases and phase separations. Layered materials are particularly affected by the application of pressure because their anisotropic structure eases the contraction of the lattice along specific crystallographic directions. In this thesis I study the effect of pressure on the transport properties of two new layered materials: L4Fe2As2Te(1-x)O4 (L = Pr, Sm, Gd) superconductors and beta-Bi4I4 topological insulator. The discovery of Fe-based superconductors (Fe-SCs) provided a new material base for studying the mechanism of high temperature superconductivity. These materials present unexpectedly high critical temperatures (Tc ) despite the presence of magnetic atoms. The parent compounds of Fe-SCs are semimetals with an antiferromagnetic ground state in which the itinerant electrons form a periodic modulation of spin density called spin density wave (SDW). By changing the structural properties or by adding/removing carriers the SDW order can be suppressed and superconductivity emerges. Our group recently succeeded in synthesizing a new family of Fe-SCs that presents Tc up to 45 K upon optimum chemical doping and substitution. I performed a systematic study of the upper critical field and the pressure-dependent electrical resistivity of single crystals of Pr4Fe2As2Te(1-x)O4 and Sm4Fe2As2Te(1-x)O(4-y)Fy . Hall coefficient and magnetoresistance of Pr4Fe2As2Te(1-x)O4 revealed electrons as the dominant type of charge carriers. The results can be successfully fitted by a two-band model that allows the estimation of the temperature dependent electron and hole densities and mobilities. In view of the exceptionally high structural anisotropy of this new class of Fe-SCs I investigated the electronic anisotropy of Sm4Fe2As2Te(1-x)O(4-y)Fy by means of microfabrication techniques. The results show a ratio between the out-of-plane and in-plane electrical resistivities that is the highest reported so far in Fe-SCs. Topological insulators (TIs) form another class of materials that is currently attracting a lot of attention both for fundamental physics and potential applications. In TIs metallic surface states coexist with an insulating bulk. Most of the TIs known so far are either three-dimensional strongly bonded bulk materials or layered van der Waals crystals. Beta-Bi4I4 is a material composed of quasi-one-dimensional molecular chains that was theoretically predicted, and only recently experimentally verified, to be a novel strong topological insulator. Due to its particular structure, beta-Bi4I4 offers the possibility to study the interplay between different ground states like topological insulating phase, charge-density-wave and superconductivity. Here I present, for the first time, a study of the thermoelectric properties of beta-Bi4I4 single crystals. Electrical resistivity, Seebeck coefficient, thermal conductivity and Hall coefficient measurements reveal a possible charge density-wave-order (CDW) at low temperature. According to resistivity and thermoelectric power measurements, pressure suppresses the CDW order. Resistivity measurements performed in a diamond anvil cell up to 20 GPa demonstrate that superconductivity is induced in beta-Bi4I4 for pressure above 10 GPa. Preliminary X-ray diffraction measurements by synchrotron radiation, performed on the sample recovered at ambient pressure after the experiment, reveal that a new Bi-I phase is formed at high pressure. The possibility that the topological insulator state could coexist with superconductivity in beta-Bi4I4 is certainly a fascinating option but it remains for now an open question.