Chemistry and Physical Properties of the Phosphide Telluride Zr2PTe2

Two-Dimensional Transition Metal Phosphides As Cathode Additive in Robust Lithium-Sulfur Batteries

The development of advanced cathode materials able to promote the sluggish redox kinetics of polysulfides is crucial to bringing lithium-sulfur batteries to the market. Herein, two electrode materials: namely, Zr2PS2 and Zr2PTe2, are identified through screening several hundred thousand compositions in the Inorganic Crystal Structure Database. First-principles calculations are performed on these two materials. These structures are similar to that of the classical MXenes. Concurrently, calculations show that Zr2PS2 and Zr2PTe2 possess high electrical conductivity, promote Li ion diffusion, and have excellent electrocatalytic activity for the Li-S reaction and particularly for the Li2S decomposition. Besides, the mechanisms behind the excellent predicted performance of Zr2PS2 and Zr2PTe2 are elucidated through electron localization function, charge density difference, and localized orbital locator. This work not only identifies two candidate sulfur cathode additives but may also serve as a reference for the identification of additional electrode materials in new generations of batteries, particularly in sulfur cathodes.

Ti2PTe2 monolayer: a promising two-dimensional anode material for sodium-ion batteries

Developing efficient anode materials with a good electrochemical performance has been a key scientific issue in the development of sodium ion batteries (SIBs). In this work, by means of density functional theory (DFT) computations, we demonstrate that two-dimensional (2D) Ti2PTe2 monolayer is a promising candidate for this application. The exfoliation of Ti2PTe2 monolayer from its experimentally known layered bulk phase is feasible due to the moderate cohesive energy. Different from many binary 2D transitions metal chalcogenides (TMCs) that are semiconducting, Ti2PTe2 monolayer is metallic with considerable electronic states at the Fermi level. Remarkably, Ti2PTe2 monolayer has a considerably high theoretical capacity of 280.72 mA h g-1, a rather small Na diffusion barrier of 0.22 eV, and a low average open circuit voltage of 0.31 eV. These results suggest that Ti2PTe2 monolayer can be utilized as a promising anode material for SIBs with high power density and fast charge/discharge rates.

Uncovering the behavior of Hf2Te2P and the candidate Dirac metal Zr2Te2P

Results are reported for single crystal specimens of Hf2Te2P and compared to its structural analogue Zr2Te2P, which was recently proposed to be a potential reservoir for Dirac physics [1]. Both materials are produced using the iodine vapor phase transport method and the resulting crystals are exfoliable. The bulk electrical transport and thermodynamic properties indicate Fermi liquid behavior at low temperature for both compounds. Quantum oscillations are observed in magnetization measurements for fields applied parallel but not perpendicular to the c-axis, suggesting that the Fermi surfaces are quasi-two dimensional. Frequencies are determined from quantum oscillations for several parts of the Fermi surfaces. Lifshitz-Kosevich fits to the temperature dependent amplitudes of the oscillations reveal small effective masses, with a particularly small value [Formula: see text] for the α branch of Zr2Te2P. Electronic structure calculations are in good agreement with quantum oscillation results and illustrate the effect of a stronger spin-orbit interaction going from Zr to Hf. These results suggest that by using appropriate tuning parameters this class of materials may deepen the pool of novel Dirac phenomena.

Temperature initiated P-polymerization in solid [Cd3Cu]CuP10

[Cd3Cu]CuP10, a polyphosphide containing adamantine-analogue [P10] unit undergoes a solid-state polymerization to form [P6] rings and tubular [P26] polymer units at elevated temperatures. This reaction represents the rare case of a polyphosphide polymerization in the solid state. The formation of such a polymeric unit starting from a molecular precursor is the first evidence of the general possibility to perform a bottom-up route to the well-known tubular polyphosphide units of elemental phosphorus in a solid material. Temperature-dependent X-ray powder diffraction experiments substantiate the solid phase transformation of [Cd3Cu]CuP10 starting at 550 °C to the polymerized form via an additional intermediate step. A single crystal structure determination of the quenched product at room temperature was performed to evaluate the structural properties and the resulting polyphosphide units. The full polymerization and decomposition mechanism has been analyzed by thermogravimetric experiments and subsequent X-ray powder phase analyses. The present [P26] polymer unit represents a former unseen one-dimensional cut-out of the two-dimensional polyphosphide substructure of Ag3P11 and can be directly related to the tubular polyphosphide substructures of violet or fibrous phosphorus.