Further evidence against the alleged failure of the classical nucleation theory below the glass transition range

Acosta, María Helena Ramírez; Rodrigues, L. R.; Cassar, Daniel R.; Montazerian, Maziar; Filho, Oscar Peitl; Zanotto, Edgar Dutra

doi:10.1111/jace.17852

Cited by 11 publications

(10 citation statements)

References 47 publications

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“…The temperature dependence (450°C–600°C) of r * and Δ G * in Li 2 O–2SiO 2 glass/SCL is shown in Figure 8, indicating that both parameters increase with increasing temperature. That is, for the formation of nanocrystals having radius as possible as small, the nucleation should be carried out at low temperatures close to the glass transition temperature, that is, T g = 455°C 16 …”

Section: Scientific Background Behind Nucleation and Nanocrystallizationmentioning

confidence: 99%

“…Numerous studies on the nucleation mechanism and kinetics in oxide SCLs have been reported so far. In particular, the homogeneous nucleation kinetics by thermodynamic approach based on the classical nucleation theory (CNT) for some stoichiometric SiO 2 ‐based glasses/SCLs such as lithium disilicate Li 2 O–2SiO 2 and Na 2 O–2CaO–3SiO 2 have been studied in detail 4,11–16 . In the CNT approach, one of the most crucial issues is to evaluate the interfacial energy ( γ ) at the SCL–nucleus interface, because the γ value itself in oxide glasses/SCLs has not been measured directly (independently) from experiments.…”

Section: Introductionmentioning

confidence: 99%

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A new perspective for nucleation and nanocrystallization from interfacial energy and nanoscale composition fluctuations in glasses

Komatsu,

Honma

2023

Int J of Appl Glass Sci

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Nucleation behaviors in glasses/supercooled liquids (SCLs) such as lithium disilicate Li2O–2SiO2, cordierite Mg2Al4Si5O18, fresnoite Ba2TiSi2O8, and K2O–Nb2O5–GeO2/TeO2 glasses were analyzed and discussed from the interfacial energy γ at SCL–nucleus interfaces and nanoscale composition fluctuations. Based on the fragility concept for SCLs and the intrinsic origin of γ, the magnitude order of γ(fragile SCL) < γ(strong SCL) was proposed to be a crucial guide for an understanding of high homogeneous nucleation rates and prominent nanocrystallization. The role of nucleating agent TiO2/ZrO2 in accelerating the nucleation rate in cordierite‐based and β‐spodumene‐type Li2O–Al2O3–SiO2‐based glasses was discussed from the new perspective of γ(homoepitaxial‐like nucleation) < γ(heteroepitaxial‐like nucleation). Ferroelectric nanocrystals such as SrxBa1–xNb2O6 in borate glasses and fluoride nanocrystals such as CaF2 are also well understood from the proposed guidelines. The present article provides a new perspective for nucleation in glasses/SCLs, contributing to the comprehensive composition design of new innovative glass‐ceramics.

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Section: Scientific Background Behind Nucleation and Nanocrystallizationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A new perspective for nucleation and nanocrystallization from interfacial energy and nanoscale composition fluctuations in glasses

Komatsu,

Honma

2023

Int J of Appl Glass Sci

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“…Lastly, recent works are proposing a new theory to study nucleation, relating the relaxation of the material with the time needed to reach steady‐state nucleation, where it is proposed that a glass will only reach its steady state corresponding to the fully relaxed supercool liquid state 14–19 . Crystal nucleation happens concomitantly with the relaxation process toward the SCL, strongly affecting the nucleation rate measured at temperatures below T max , taking a very long time to reach steady‐state nucleation 15 .…”

Section: Introductionmentioning

confidence: 99%

“…12 Lastly, recent works are proposing a new theory to study nucleation, relating the relaxation of the material with the time needed to reach steady-state nucleation, where it is proposed that a glass will only reach its steady state corresponding to the fully relaxed supercool liquid state. [14][15][16][17][18][19] Crystal nucleation happens concomitantly with the relaxation process toward the SCL, strongly affecting the nucleation rate measured at temperatures below T max , taking a very long time to reach steady-state nucleation. 15 Finally, on a similar note, Abyzov et al showed that stresses present in the material reduce the thermodynamic driving force for crystallization and thus increase the nucleation barrier, causing a decrease in the nucleation rate.…”

Section: Introductionmentioning

confidence: 99%

Crystallization in a soda–lime‐silicate glass after high pressure

et al. 2023

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This work explored the permanent changes a high pressure (HP) processing could cause on nucleation, Raman vibrational modes, thermal, and mechanical properties of the Na 2 O • 2CaO • 3SiO 2 (N 1 C 2 S 3 ) glass. It was shown that, with higher pressure values, the number of nuclei per unit of volume, N V , has decreased. Raman spectra showed no significant changes in the vibrational modes; however, the differential thermal analysis performed indicated that the glass transition temperatures, T g , were higher than the pristine glass sample and that HP caused the glass to be less stable. The Vickers indentation radial cracks remained constant; however, the lateral cracks increased in size, indicating that the glass is more stressed after HP, and therefore, the relaxation time for nucleation will be higher, lowering N V further, as observed.

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“…However, the complicated structure of the textile usually hinders the distribution of the fillers into/onto the fabric. Neither the classical melting mixing method , nor the in situ process − for producing conductive composites is applicable for strain sensors based on textile matrices. Therefore, dip-coating processes with chemical solvents are often used. ,− …”

Section: Introductionmentioning

confidence: 99%

Carbon Black Nanoparticle/Polydopamine-Coated Core-Spun Yarns for Flexible Strain Sensors

Qin

et al. 2022

ACS Appl. Nano Mater.

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A smart and flexible textile strain sensor was developed based on a commercial core-spun yarn coated with carbon black (CB) nanoparticles and polydopamine (PDA). The morphology of the textile was studied using scanning electron microscopy (SEM), and the distribution of CB and self-polymerized PDA was observed. Thermogravimetric analysis (TGA) revealed the applicable temperature range of the strain sensor. The smart textile showed an outstanding strain sensor response range up to 450%, and its mechanical properties were only slightly reduced as compared to the original textile. The cyclic strain sensor behavior of the smart textile was investigated by stretching the textile 100% for 100 cycles, yielding a stable and durable output electrical signal. Application tests for various human motions were also performed. Finally, two mathematical equations based on tunneling theory were proposed to accurately predict the electrical signal during stretching and to reveal the fundamental properties of the textile. Our findings clearly expand the current knowledge of strain sensors.

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Further evidence against the alleged failure of the classical nucleation theory below the glass transition range

Cited by 11 publications

References 47 publications

A new perspective for nucleation and nanocrystallization from interfacial energy and nanoscale composition fluctuations in glasses

A new perspective for nucleation and nanocrystallization from interfacial energy and nanoscale composition fluctuations in glasses

Crystallization in a soda–lime‐silicate glass after high pressure

Carbon Black Nanoparticle/Polydopamine-Coated Core-Spun Yarns for Flexible Strain Sensors

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