Temperature dependent spectroscopic ellipsometry of Ag<sub>2</sub>Se and Ag<sub>2</sub>S with phase transitions from ionic to superionic conductivity state

Alekperov, O. Z.; Gasimov, Nagi; Khalilova, Kh. S.; Shim, YongGu; Paucar, Raul; Abdulzade, N.N.; Самедов, О. А.; Jahangirli, Z. A.; Nakhmedov, É. P.; Wakita, Kazuki; Mamedov, Nazim

doi:10.1002/pssc.201400367

Cited by 10 publications

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“…Owing to the large anion defect formation energy within the ionic β phase, the IC is predominantly due to the motion of Ag + cation. Temperature‐dependent infrared (IR) and optical spectroscopic ellipsometry methods have been used to investigate the peculiarities of the transitions from the IC to the superionic conductivity states in Ag 2 S and Ag 2 Se compounds . The structural β → α phase transitions have also been investigated with spectroscopic ellipsometry methods.…”

Section: Introductionmentioning

confidence: 99%

First‐principles lattice dynamics and Raman scattering in ionic conductor β‐Ag₂S

Alekperov

Jahangirli

Paucar

2016

Physica Status Solidi (b)

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The phonon structure of the silver sulfide Ag 2 S was investigated, experimentally using Raman spectroscopy, and theoretically using the density-functional perturbation theory for the first time. Seven Raman-active modes were observed and identified at 23,39,42,44, 62, 65, and 243 cm À1 . Symmetry assignments of all the vibrational modes were derived from considerations of point group symmetry. The phonon band structure and the relative Raman intensities were also investigated by ab initio calculations and compared with the experimental data. The temperature, laser power, and illumination time dependencies of frequency, linewidth, and intensity of the Raman-active modes are discussed. In the Raman spectra at higher frequencies 1300-1700 cm À1 , additional broad Raman modes observed in all samples at higher laser powers 8-10 mW were ascribed to luminescence from b-Ag 2 S. The phonon and Raman spectra of the b-Ag 2 S provide a useful insight into the b-Ag 2 S ! a-Ag 2 S phase transition. Finally, calculated infrared vibrational mode frequencies were compared with measured infrared mode frequencies.

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Section: Introductionmentioning

confidence: 99%

First‐principles lattice dynamics and Raman scattering in ionic conductor β‐Ag₂S

Alekperov

Jahangirli

Paucar

2016

Physica Status Solidi (b)

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“…Meanwhile, all PbSe-Ag nanocomposites are characterized with higher σ than pure PbSe, with a maximum σ appeared around 400 K, but decrease with further increase in temperature. We attributed this maximum σ to the increase of free carriers during the typical Ag 2 Se phase transition ∼ 407 K (Figure S7), from orthorhombic to cubic phase. − Also, the higher σ found in all PbSe-Ag nanocomposites is attributed to the charge carrier donating effect of Ag, which was also later confirmed using Hall measurement. In contrast to pristine PbSe, PbSe-Ag nanocomposites showed a positive Seebeck coefficient ( p -type behavior) for the entire measurement temperature.…”

Section: Resultsmentioning

confidence: 54%

Thermoelectric Properties of PbSe Nanocomposites from Solution-Processed Building Blocks

Zhou

Nasser

et al. 2021

ACS Appl. Energy Mater.

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High thermoelectric performance and low material cost are essential to the commercialization of thermoelectric modules. Microstructural design, size effects, and rational band engineering are among the keys to high thermoelectric performance, especially for nanocomposites. Here, we demonstrate a facile and versatile bottom-up approach to produce nanocomposites by heat consolidating solution-processed PbSe nanoparticles with a proper amount of Ag. In this PbSe-Ag system, a certain amount of Ag diffuses into the PbSe matrix and partially substituted Pb while other forms Ag2Se at the interphases. This increased the electrical conductivity and inversed the n-type behavior of PbSe to p-type, which is observed from the positive Seebeck coefficient for PbSe-Ag nanocomposites over the temperature range. Nonetheless, the decrease of total lattice thermal conductivity at high temperature is ascribed to the effective phonon at grain boundaries, Ag2Se nanodomain, and point defect. Overall, we obtained an optimized figure of merit, ZT = 0.97 at 723 K for 5 wt % Ag, a significant improvement of 8.8 times than the pure PbSe. Thus, this partially substituting host atom and the presence of a secondary phase provide another potential strategy to enhance the thermoelectric performance of PbSe, promoting its commercialization.

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“…That makes the material of great interest from both fundamental science and technological applications perspectives. In the past, experimental studies have addressed the optical properties of bulk Ag 2 S materials [ 16,17 ] and colloidal quantum dots. [ 18,19 ] A theoretical study of the optical properties of different bulk Ag 2 S phases will be an important step forward in revealing relationships between the structure and optical properties of this material.…”

Section: Introductionmentioning

confidence: 99%

Ab initio Study of Atomic Structure and Electronic Properties of Different Phases of Polymorphic Ag₂S

Makeev

Sahu

Rajput

2022

Physica Status Solidi (b)

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Silver sulfide is a polymorphic material that exists in different crystalline forms including 3D structures with different symmetries, quasi‐2D layers, and 0D quantum dots. The crystal structures of identified and characterized to date forms of Ag2S differ, and so do their electronic properties. In the past, two different bulk crystalline phases of Ag2S with the same symmetry have been characterized experimentally. Herein, an empirical relation is proposed, which allows for the identification of these experimentally observed structures of Ag2S as thermodynamically stable and predicts a new, potentially stable, crystalline phase of this material. The band structures of these three phases are investigated using computational quantum methods. The calculations are performed using the hybrid density functional approximation and quasiparticle partially self‐consistent GW method. The effects of crystal structure on the semiconductor properties are discussed based on the results obtained for the three crystalline structures. The findings, reported in this work, can be of significance for technological applications that exploit the electronic properties of crystalline Ag2S.

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Temperature dependent spectroscopic ellipsometry of Ag₂Se and Ag₂S with phase transitions from ionic to superionic conductivity state

Cited by 10 publications

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First‐principles lattice dynamics and Raman scattering in ionic conductor β‐Ag₂S

First‐principles lattice dynamics and Raman scattering in ionic conductor β‐Ag₂S

Thermoelectric Properties of PbSe Nanocomposites from Solution-Processed Building Blocks

Ab initio Study of Atomic Structure and Electronic Properties of Different Phases of Polymorphic Ag₂S

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Temperature dependent spectroscopic ellipsometry of Ag2Se and Ag2S with phase transitions from ionic to superionic conductivity state

Cited by 10 publications

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First‐principles lattice dynamics and Raman scattering in ionic conductor β‐Ag2S

First‐principles lattice dynamics and Raman scattering in ionic conductor β‐Ag2S

Thermoelectric Properties of PbSe Nanocomposites from Solution-Processed Building Blocks

Ab initio Study of Atomic Structure and Electronic Properties of Different Phases of Polymorphic Ag2S

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Temperature dependent spectroscopic ellipsometry of Ag₂Se and Ag₂S with phase transitions from ionic to superionic conductivity state

First‐principles lattice dynamics and Raman scattering in ionic conductor β‐Ag₂S

First‐principles lattice dynamics and Raman scattering in ionic conductor β‐Ag₂S

Ab initio Study of Atomic Structure and Electronic Properties of Different Phases of Polymorphic Ag₂S