Te-As-Se glass destabilization using high energy milling

Calvez, Laurent; Lavanant, Enora; Anna, Novikova; Goncalves, Claudia; Bureau, Bruno; Nazabal, Virginie; Jouan, Thierry; Zhang, Xianghua

doi:10.1016/j.jnoncrysol.2017.08.017

Cited by 7 publications

(3 citation statements)

References 20 publications

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“…It can be noticed that this shifted peak is located at the same angle as a diffraction line of the crystallized phase. It could be due (a) to a structural transformation of the initial glass into another polyamorph as already observed in other chalcogenide glasses, 16,17 or (b) to the emergence of nanometric crystalline domains, considering the low stability (T c -T g ) of the glass (~30 K 6 ) where T c and T g are the crystallization and glass transition temperatures, respectively. Other evidences for this glass transformation will be further discussed below.…”

Section: Resultsmentioning

confidence: 75%

Improved ZT in ball‐milled and spark plasma sintered Cu₁₅As₃₀Te₅₅ glass‐ceramics

et al. 2018

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The influence of ball milling followed by Spark Plasma Sintering (SPS) on the thermoelectric properties of the Cu 15 As 30 Te 55 glass composition has been investigated by means of X-ray diffraction, scanning electron microscopy, and differential scanning calorimetry. The microstructure, composition, and thermal stability of the ball-milled samples before and after SPS have been correlated with the electrical and thermal transport properties. Upon ball milling, a glass-to-glass transformation is evidenced for short ball-milling times, followed by crystallization of the metastable β-As 2 Te 3 phase within the glassy matrix. This glass-to-glass transformation favors the occurrence of the β-As 2 Te 3 phase during the SPS process. A maximum figure of merit ZT of 0.29 at 400 K is obtained in the sample exhibiting the largest β-As 2 Te 3 crystalline fraction. This ZT value is twice as high as the value obtained for the glass-ceramic sintered from non-ball-milled powder. K E Y W O R D Sball milling, chalcogenide glass-ceramics, thermoelectric materials

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Section: Resultsmentioning

confidence: 75%

Improved ZT in ball‐milled and spark plasma sintered Cu₁₅As₃₀Te₅₅ glass‐ceramics

et al. 2018

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“…The results obtained suggest that further research into developing methods of mechanical milling of chalcogenide glasses doped with RE elements and their subsequent sintering using, for example, Spark Plasma Sintering (SPS) technology [9], will make it possible to obtain glasses with significantly increased luminescence efficiency. Based on these glasses, optically active fibers for the IR range can be fabricated.…”

Section: Structure and Optical Propertiesmentioning

confidence: 99%

“…Consequently, the challenge arises from enhancing the homogeneity of RE element distribution within the chalcogenide glass matrix. It was previously shown that chalcogenide glasses can be successfully obtained by the mechanical alloying method from elementary substances [8,9]. This technique has been employed to obtain glassy compositions that are challenging to achieve through conventional melt quenching techniques [10,11].…”

Section: Introductionmentioning

confidence: 99%

Mechanical Alloying and Concentration Quenching of the Luminescence of Pr3+ Ions in Chalcogenide Glass

Tverjanovich,

Mikhaylova,

Bychkov

2024

Solids

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The disadvantage of chalcogenide glasses containing rare earth ions as luminescent materials for the IR optical range is the strong concentration quenching of luminescence due to the non-uniform distribution of rare earth ions in the glass matrix. This study investigates the effect of grinding chalcogenide glass containing Pr3+ ions in a planetary ball mill on its luminescent properties in the near-IR range, as well as its optical properties and structure. The results indicate that milling, under certain conditions, leads to a decrease in the concentration quenching of the luminescence of Pr3+ ions. This finding suggests that milling can be used in the development of glassy materials with the increased efficiency of luminescence of rare earth ions. However, it is essential to consider that high-energy milling may result in the formation of areas with increased pressure in the obtained material, leading to structural changes in the glass.

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Obtaining ultra-high hardness in spark plasma sintered Ge40As40Se20 bulk glass

Xie,

Gu,

Jia

et al. 2024

Infrared Physics & Technology

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Te-As-Se glass destabilization using high energy milling

Cited by 7 publications

References 20 publications

Improved ZT in ball‐milled and spark plasma sintered Cu₁₅As₃₀Te₅₅ glass‐ceramics

Improved ZT in ball‐milled and spark plasma sintered Cu₁₅As₃₀Te₅₅ glass‐ceramics

Mechanical Alloying and Concentration Quenching of the Luminescence of Pr3+ Ions in Chalcogenide Glass

Obtaining ultra-high hardness in spark plasma sintered Ge40As40Se20 bulk glass

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Te-As-Se glass destabilization using high energy milling

Cited by 7 publications

References 20 publications

Improved ZT in ball‐milled and spark plasma sintered Cu15As30Te55 glass‐ceramics

Improved ZT in ball‐milled and spark plasma sintered Cu15As30Te55 glass‐ceramics

Mechanical Alloying and Concentration Quenching of the Luminescence of Pr3+ Ions in Chalcogenide Glass

Obtaining ultra-high hardness in spark plasma sintered Ge40As40Se20 bulk glass

Contact Info

Product

Resources

About

Improved ZT in ball‐milled and spark plasma sintered Cu₁₅As₃₀Te₅₅ glass‐ceramics

Improved ZT in ball‐milled and spark plasma sintered Cu₁₅As₃₀Te₅₅ glass‐ceramics