Materials Science (cond-mat.mtrl-sci)

Abstract: We present an experimental study on the etching of detonation nanodiamond (DND) seeds during typical microwave chemical vapor deposition (MWCVD) conditions leading to ultra-thin diamond film formation, which is fundamental for many technological applications. The temporal evolution of the surface density of seeds on Si(100) substrate has been assessed by scanning electron microscopy (SEM). The resulting kinetics have been explained in the framework of a model based on the effect of particle size, according to the Young-Laplace equation, on both chemical potential of carbon atoms in DND and activation energy of reaction. We found that seeds with size smaller than a critical radius, r*, are etched away while those greater than r* can grow. Finally, the model allows to estimate the rate coefficients for growth and etching from the experimental kinetics.

Abstract: Metallic/intermetalic materials with BCC structures hold an intrinsic instability due to phonon softening along [110] dirrection, causing BCC to lower-symmetry phases transformation when the BCC structures are thermally or mechanically stressed. Fe50Rh50 binary system is one of the exceptional BCC structures (ordered-B2) that has not been yet showing such transformation upon application of thermal stress, although mechanical deformation results in B2 to disordered FCC (gamma) and L10 phases transformation. Here, a comprehensive transmission electron microscopy (TEM) study is conducted on thermally-stressed samples of Fe50Rh50 aged at water and liquid nitrogen from 1150 degree C and 1250 degree C. The results show that, samples quenched from 1150 degree C into water and liquid nitrogen show presence of 1/4{110} and 1/2{110} satellite reflections, the latter of which is expected from phonon dispersion curves obtained by density functional theory calculation. Therefore, it is believed that Fe50Rh50 maintains the B2 structure that is in premartensite state. Once Fe50Rh50 is quenched from 1250 degree C into liquid nitrogen, formation of two short-range ordered tetragonal phases with various c/a ratios (~1.15 and 1.4) is observed in line with phases formed from mechanically deformed (30%) sample. According to our observations, an accurate atomistic shear model ({110}<1-10>) is presented that describes the martensitic transformation of B2 to these tetragonal phases. These findings offer implications useful for understanding of magnetic and physical characteristics of metallic/intermetallic materials.

Abstract: This paper reports a combination of experimental and theoretical approaches to find a significant correlation between Urbach energy (Eu) and asymmetry parameter (q) of Raman mode in GO-hBN nanocomposite. The experiment involves liquid phase exfoliation synthesis of hexagonal boron nitride (hBN) and GO-hBN nanocomposite with varying hBN and graphene oxide (GO) ratios. We study the electron-phonon interaction (EPI) strength in the nanocomposites via UV-Vis absorption and Raman spectroscopic analysis. The induced disorders in the nanocomposites due to varying compositions of hBN and GO have been quantified by Eu. Simultaneously, the EPI contribution to the induced disorders is measured via UV-Vis absorption spectra and represented as Ee-p. The EPI impact is also observed in Raman phonon modes and quantified as an asymmetry parameter (q). The inverse of the asymmetry parameter provides electron-phonon interaction strength (Ee-p), i.e. Ee-p ~ 1/|q|. A lower value of q indicates more substantial interference between electronic and phononic scattering in the nanocomposites, thus justifying the presence of more disorders, which has also been quantified by Eu. A linear relationship has been observed between Eu and the proportional parameter (k), where k involves both asymmetry parameter q and intensity of specific Raman mode (I).

Abstract: Machine-learning potentials provide computationally efficient and accurate approximations of the Born-Oppenheimer potential energy surface. This potential determines many materials properties and simulation techniques usually require its gradients, in particular forces and stress for molecular dynamics, and heat flux for thermal transport properties. Recently developed potentials feature high body order and can include equivariant semi-local interactions through message-passing mechanisms. Due to their complex functional forms, they rely on automatic differentiation (AD), overcoming the need for manual implementations or finite-difference schemes to evaluate gradients. This study demonstrates a unified AD approach to obtain forces, stress, and heat flux for such potentials, and provides a model-independent implementation. The method is tested on the Lennard-Jones potential, and then applied to predict cohesive properties and thermal conductivity of tin selenide using an equivariant message-passing neural network potential.

Abstract: Recently, topologically nontrivial polarization textures have been predicted and observed in nanoscale systems. While these polarization textures are interesting and promising in terms of applications, their topology in general is yet to be fully understood. For example, the relation between topological polarization structures and band topology has not been explored, and polar domain structures are typically considered in topologically trivial systems. In particular, the local polarization in a crystal supercell is not well-defined, and typically calculated using approximations which do not satisfy gauge invariance. Furthermore, local polarization in supercells is typically approximated using calculations involving smaller unit cells, meaning the connection to the electronic structure of the supercell is lost. In this work, we propose a definition of local polarization which is gauge invariant and can be calculated directly from a supercell without approximations. We show using first-principles calculations for commensurate bilayer hexagonal boron nitride that our expressions for local polarization give the correct result at the unit cell level, which is a first approximation to the local polarization in a moir\'e superlattice. We also illustrate using an effective model that the local polarization can be directly calculated in real space. Finally, we discuss the relation between polarization and band topology, for which it is essential to have a correct definition of polarization textures.

Abstract: We demonstrate the emergence of a pronounced thermal transport in the recently discovered class of magnetic materials-altermagents. From symmetry arguments and first principles calculations performed for the showcase altermagnet, RuO2, we uncover that crystal Nernst and crystal thermal Hall effects in this material are very large and strongly anisotropic with respect to the Neel vector. We find the large crystal thermal transport to originate from three sources of Berry's curvature in momentum space: the pseudo-nodal surfaces, the Weyl fermions due to crossings between well-separated bands, and the spin-flip ladder transitions, defined by transitions among very weakly spin-split states of similar dispersion crossing the Fermi surface. Moreover, we reveal that the anomalous thermal and electrical transport coefficients in RuO2 are linked by an extended Wiedemann-Franz law in a temperature range much wider than expected for conventional magnets. Our results suggest that altermagnets may assume a leading role in realizing concepts in spincaloritronics not achievable with ferromagnets or antiferromagnets.

Abstract: Carbon nitrides have recently come into focus for photo- and thermal catalysis, both as support materials for metal nanoparticles as well as photocatalysts themselves. While many approaches for the synthesis of three-dimensional carbon nitride materials are available, only top-down approaches by exfoliation of powders lead to thin film flakes of this inherently two-dimensional material. Here, we describe an in situ on-surface synthesis of monolayer 2D carbon nitride films, as a first step towards precise combination with other 2D materials. Starting with a single monomer precursor, we show that 2,5,8-triazido-s-heptazine (TAH) can be evaporated intact, deposited on a single crystalline Au(111) or graphite support, and activated via azide decomposition and subsequent coupling to form a covalent polyheptazine network. We demonstrate that the activation can occur in three pathways, via electrons (X-ray illumination), photons (UV illumination) and thermally. Our work paves the way to coat materials with extended carbon nitride networks which are, as we show, stable under ambient conditions.

Abstract: Superionic conductivity, or conductivity that rivals or exceeds those of the liquid phase (0.01 S/cm), is predicted to be possible through couplings between the mobile ion and the phonon vibrations of the crystal lattice. However, few experimental techniques have directly probed the many-body phonon modes that enable superionic conductivity. In this work, we develop a laser-driven impedance technique to measure the relative contribution of specific phonon modes to ion migration in a solid-state electrolyte Li0.5La0.5TiO3 (LLTO). Through ab initio calculations, we find that a few collective phonon-ion modes, mostly TiO6 rocking modes in the <6 Terahertz (THz) range, provide more than 40% of the energy required for the ion hop in the LLTO lattice. Next, we experimentally measure the change in impedance of LLTO using electrochemical impedance spectroscopy (EIS) while driving the TiO6 octahedral rocking modes with THz radiation. In agreement with our ab initio theoretical calculations and molecular dynamics simulations, experimentally exciting these rocking modes decreases the measured impedance ten-fold compared to exciting the acoustic and optical phonon bath at similar populations or heating LLTO. The decreased impedance also persists longer than the driving light. Our newly developed experiments can quantify phonon-ion coupling in multiple classes of ion conductors and suggest the potential for metastable states for opto-ionic materials.