Samuel Froeschke scite author profile

Tungsten telluride WTe 2 is the sole candidate of a group of two-dimensional layered transition metal dichalcogenides (TMDCs) MX 2 with a thermodynamically stable 1T′-structure at room temperature. The binary system W/Te was audited with respect to a rational approach of planning and realization of a bottom-up synthesis of WTe 2 nanostructures. Thus, the parameters of the synthesis via chemical vapor transports (CVT) were derived by thermodynamic simulations of the reaction pathway according to the Calphad method. Reflecting on the peritectic melting behavior at 1020 °C, the values ofAccording to modeling, crystal growth by short time vapor transport is reasonable under the addition of bromine or TeBr 4 in the temperature range between 650 and 750 °C. Experimental implementation of crystal growth of WTe 2 nanosheets succeeded in a temperature gradient from 725 to 675 °C on yttria-stabilized zirconia (YSZ) (111) substrates, observing the deposition of single crystal sheets of high crystallinity with thicknesses of 15−20 nm (∼20−30 layers). The high crystallinity, pristine morphology, and overall quality of the deposited nanosheets is shown by means of atomic resolution transmission electron microscopy, selected area electron diffraction (SAED), and atomic force microscopy as well as profound double-polarized Raman spectroscopy.

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Understanding the chemistry of 2D rhodium trihalide solid solutions: tuning of optical properties and nanocrystal deposition

Froeschke

Schroth

Steiner

et al. 2023

2D Mater.

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In the search for novel 2D materials with potentially valuable properties, such as a tuneable band gap for optoelectronic or catalytic applications, solid solutions hold the potential to significantly expand the inventory of available 2D nanomaterials. In this study, we present for the first-time the synthesis of such 2D rhodium trihalide solid solutions: RhBr x Cl3−x and RhBr x I3−x . We use thermodynamic simulations and simultaneous thermal analysis to predict conditions for their rational synthesis and to investigate suitable chemical vapor transport (CVT) parameters for these solid solutions. The evolution of the lattice parameters is investigated by powder X-ray diffraction, showing an isostructural relationship of the synthesized compounds and only minor deviation from Vegard’s law. The optical band gap of these materials can be tuned in an energy range from 1.5 eV (RhCl3) to 1.2 eV (RhI3) by choosing the composition of the solid solution, while the samples also exhibit photoluminescence in similar energy ranges. Ultimately, the successful deposition of bulk as well as ultrathin 2D nanocrystals of RhBr x Cl3−x by CVT from 925 °C to 850 °C is shown, where the composition of the deposited crystals is precisely controlled by the choice of the starting composition and the initial amount of material. The high quality of the obtained nanocrystals is confirmed by atomic force microscopy, high resolution transmission electron microscopy and selected area electron diffraction. For RhBr x I3−x , the CVT from 900 °C to 825 °C is more difficult and has only been practically demonstrated for an exemplary case. According to the observed properties, these novel solid solutions and nanocrystals show a great potential for an application in optoelectronic devices.

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Crystal growth of the 2D Janus rhodium chalcohalide RhSeCl

Nowak

Valldor

Rubrecht

et al. 2023

Inorg. Chem. Front.

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Direct Deposition of (Bi_xSb_1–x)₂Te₃ Nanosheets on Si/SiO₂ Substrates by Chemical Vapor Transport

Hansen

Fucke

Charvin

et al. 2022

Crystal Growth & Design

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The tellurides of bismuth and antimony (Bi 2 Te 3 and Sb 2 Te 3 ) are prominent members of the V 2 VI 3 material family that exhibit promising topological properties. We provide a method for the rational synthesis of mixed crystals of these materials ((Bi x Sb 1−x ) 2 Te 3 with x = 0.1, ..., 0.9) by means of a bottom-up chemical vapor transport (CVT) approach. Thermodynamic calculations showed the synthesis to be possible in the temperature range of 390−560 °C without significant enrichment of either component and without adding a transport agent. The starting materials were synthesized and verified by X-ray diffraction (XRD). Optimization experiments showed the ideal conditions for nanosheet synthesis to be T 2 = 560 °C, T 1 = 390 °C with a reaction time of t = 36 h. Crystals with heights of down to 12 nm (12 quintuple layers) were synthesized and analyzed by means of scanning electron microscopy, energy-dispersive X-ray spectrometry, and atomic force microscopy. High-resolution transmission electron microscopy confirmed the R3̅ m crystal structure, high crystallinity, and overall quality of the synthesized (Bi x Sb 1−x ) 2 Te 3 nanosheets. Magnetotransport measurements revealed that such ternary compounds can have a significantly reduced carrier density compared to the binary parent compounds.

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