Rich Polymorphism of Layered NbS<sub>3</sub>

Conejeros, Sergio; Guster, Bogdan; Alemany, Pere; Pouget, Jean‐Paul; Canadell, Enric

doi:10.1021/acs.chemmater.1c01417

Cited by 30 publications

(47 citation statements)

References 70 publications

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“…Carbon, sulfur, phosphorus, , iron, , and so forth are well known to have different allotropes, and the physical properties of one crystal structure could be quite contrasting to those of another. Apart from the case of such above-mentioned elements, one may find quite a few examples of binary or ternary compounds that can exhibit different crystal structures under ambient conditions. − For example, LaIr 2 Si 2 and PrIr 2 Si 2 have been reported to form two different tetragonal crystal structures (viz., CaBe 2 Ge 2 -type and ThCr 2 Si 2 -type), and the properties of these two phases have much contrast. , For LaIr 2 Si 2 , the phase formed in the CaBe 2 Ge 2 -type crystal structure undergoes a superconducting transition below 1.6 K, whereas the other polymorphic phase that forms in the ThCr 2 Si 2 -type crystal structure lacks that pristine property . Even in the case of PrIr 2 Si 2 , the magnetic properties of two polymorphic phases have also been reported to be quite different .…”

Section: Introductionmentioning

confidence: 99%

Similar and Dissimilar Properties of Polymorphic Phases of NdIr₃

et al. 2022

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We report the formation and physical properties of a new polymorphic phase of NdIr3 (AuBe5-type cubic), along with those of one earlier reported phase (AuCu3-type cubic), formed together during the synthesis process. Our experimental data shows that the magnetic properties of these two phases are of contrasting characters: the former becomes ferromagnetic at low temperatures, while the latter remains paramagnetic down to the lowest measured temperature, 2.5 K. Interestingly, the magnetic properties of the cubic AuBe5-type phase have an uncanny similarity to that recently reported in another polymorphic phase (rhombohedral PuNi3-type) of the same compound. We have investigated the origin of such similarities and dissimilarities in magnetic properties of these three polymorphic phases of NdIr3 through a few diverse directions: structural, theoretically calculated spin-polarized density of states, and magnetic ground state and RKKY framework. We have shown that the similarity of the Curie temperature of the cubic AuBe5-type and rhombohedral PuNi3-type phases is the result of aperiodicity in the first nearest neighbors and similarity in the Fermi momentum space.

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Section: Introductionmentioning

confidence: 99%

Similar and Dissimilar Properties of Polymorphic Phases of NdIr₃

et al. 2022

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“…The crystal structure of NbS 3 can be rationalized as Nb(S 2 )S, containing alternating short and long Nb−Nb distances in the structure, and possesses an intricate series of structural and electronic states arising from charge-density waves. 7 NbS 3 has both semiconducting and metallic polymorphs, whereas all other niobium sulfides are metallic, or low T c superconductors. 7,8,14,15 Niobium disulfide (NbS 2 ) is a 2D metallic transition-metal dichalcogenide with interesting anisotropic magnetic, optical, and superconducting (T c = 6.3 K) properties.…”

Section: ■ Introductionmentioning

confidence: 99%

“…7 NbS 3 has both semiconducting and metallic polymorphs, whereas all other niobium sulfides are metallic, or low T c superconductors. 7,8,14,15 Niobium disulfide (NbS 2 ) is a 2D metallic transition-metal dichalcogenide with interesting anisotropic magnetic, optical, and superconducting (T c = 6.3 K) properties. 2,17 It appears with three stacking polytypes1T (trigonal), 2H (hexagonal), and 3R (rhombohedral)and has been investigated as a cathode material in lithium batteries.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Binary metal sulfides have been the subject of considerable research efforts because of their diverse electronic, electrical, and optical properties. − It can be assumed that the vast majority of binary metal sulfides have already been discovered. Some missing compounds may still be expected, but new phases are hard to predict in metal-rich systems, especially those with nonrational compositions.…”

Section: Introductionmentioning

confidence: 99%

“…The presence of excess electrons in these systems allows for interesting physical effects related to electronic correlations. The crystal structure of NbS 3 can be rationalized as Nb(S 2 )S, containing alternating short and long Nb–Nb distances in the structure, and possesses an intricate series of structural and electronic states arising from charge-density waves . NbS 3 has both semiconducting and metallic polymorphs, whereas all other niobium sulfides are metallic, or low T c superconductors. ,,, …”

Section: Introductionmentioning

confidence: 99%

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Formation of a Polar Structure in the Metallic Niobium Sulfide Nb₄S₃

et al. 2021

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The synthesis of Nb 4 S 3 , a previously undiscovered binary sulfide, was achieved using Nb 3 Br 7 S as a precursor. Its structure is composed of Nb 6 S triangular prisms arranged in a polar (Imm2) configuration, with sulfur atoms lying in channels along the a axis. Electrical resistivity measurements and density functional theory calculations were used to determine that Nb 4 S 3 is metallic and therefore a polar metal, with metallic bands occupied by electrons with primarily niobium character. The electrons near the Fermi level are so closely associated with the niobium sublattice that the sulfur atoms have positive Born effective charges, indicating that the electrostatic interactions between sulfur atoms are unscreened. Calculations of the dependence of the electron density on the sulfur atomic positions confirm that the metallic electrons do not screen the dipole−dipole interactions between sulfur atoms, which allows polarity and metallicity to coexist in Nb 4 S 3 . These findings suggest that applied electric fields might be able to reverse the polarity of thin films of Nb 4 S 3 .

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Quantum Composites with Charge‐Density‐Wave Fillers

et al. 2023

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A unique class of advanced materials—quantum composites based on polymers with fillers composed of a van der Waals quantum material that reveals multiple charge‐density‐wave quantum condensate phases—is demonstrated. Materials that exhibit quantum phenomena are typically crystalline, pure, and have few defects because disorder destroys the coherence of the electrons and phonons, leading to collapse of the quantum states. The macroscopic charge‐density‐wave phases of filler particles after multiple composite processing steps are successfully preserved in this work. The prepared composites display strong charge‐density‐wave phenomena even above room temperature. The dielectric constant experiences more than two orders of magnitude enhancement while the material maintains its electrically insulating properties, opening a venue for advanced applications in energy storage and electronics. The results present a conceptually different approach for engineering the properties of materials, extending the application domain for van der Waals materials.

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Rich Polymorphism of Layered NbS₃

Cited by 30 publications

References 70 publications

Similar and Dissimilar Properties of Polymorphic Phases of NdIr₃

Similar and Dissimilar Properties of Polymorphic Phases of NdIr₃

Formation of a Polar Structure in the Metallic Niobium Sulfide Nb₄S₃

Quantum Composites with Charge‐Density‐Wave Fillers

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Rich Polymorphism of Layered NbS3

Cited by 30 publications

References 70 publications

Similar and Dissimilar Properties of Polymorphic Phases of NdIr3

Similar and Dissimilar Properties of Polymorphic Phases of NdIr3

Formation of a Polar Structure in the Metallic Niobium Sulfide Nb4S3

Quantum Composites with Charge‐Density‐Wave Fillers

Contact Info

Product

Resources

About

Rich Polymorphism of Layered NbS₃

Similar and Dissimilar Properties of Polymorphic Phases of NdIr₃

Similar and Dissimilar Properties of Polymorphic Phases of NdIr₃

Formation of a Polar Structure in the Metallic Niobium Sulfide Nb₄S₃