Crystal Growth in Amorphous Selenium Thin Films─Reviewed and Revisited: Direct Comparison of Microscopic and Calorimetric Measurements

Svoboda, Roman; Přikryl, Jan; Čičmancová, Veronika; Prokop, Vit; Kolobov, Alexander V.; Krbal, Miloš

doi:10.1021/acs.cgd.1c00984

Cited by 9 publications

(12 citation statements)

References 51 publications

(138 reference statements)

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“…However, a certain u kin -η decoupling was still identified in the fragile glasses at high viscosities (low temperatures nearing T g ). An alternative revision of the u kin -η decoupling was provided by Schmeltzer et al [ 76 ], who introduced a decoupling temperature T d , below which the decoupling between the diffusion and viscosity occurs, with the decoupling exponent being temperature dependent (a qualitatively similar finding was recently obtained for amorphous selenium [ 77 ]). An interesting alternative to the above-mentioned standard models for crystal growth is the approach of Martin et al [ 78 ], who introduced the “transition zone theory” based on the cooperating ensemble of structural entities driving the mechanistic formation of the crystalline phase.…”

Section: Discussionmentioning

confidence: 98%

Indomethacin: The Interplay between Structural Relaxation, Viscous Flow and Crystal Growth

et al. 2022

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Non-isothermal differential scanning calorimetry (DSC) was used to study the influences of particle size (daver) and heating rate (q+) on the structural relaxation, crystal growth and decomposition kinetics of amorphous indomethacin. The structural relaxation and decomposition processes exhibited daver-independent kinetics, with the q+ dependences based on the apparent activation energies of 342 and 106 kJ·mol−1, respectively. The DSC-measured crystal growth kinetics played a dominant role in the nucleation throughout the total macroscopic amorphous-to-crystalline transformation: the change from the zero-order to the autocatalytic mechanism with increasing q+, the significant alteration of kinetics, with the storage below the glass transition temperature, and the accelerated crystallization due to mechanically induced defects. Whereas slow q+ led to the formation of the thermodynamically stable γ polymorph, fast q+ produced a significant amount of the metastable α polymorph. Mutual correlations between the macroscopic and microscopic crystal growth processes, and between the viscous flow and structural relaxation motions, were discussed based on the values of the corresponding activation energies. Notably, this approach helped us to distinguish between particular crystal growth modes in the case of the powdered indomethacin materials. Ediger’s decoupling parameter was used to quantify the relationship between the viscosity and crystal growth. The link between the cooperativity of structural domains, parameters of the Tool-Narayanaswamy-Moynihan relaxation model and microscopic crystal growth was proposed.

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Section: Discussionmentioning

confidence: 98%

Indomethacin: The Interplay between Structural Relaxation, Viscous Flow and Crystal Growth

et al. 2022

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“…In addition to the macroscopic crystal growth explored by DSC, optical transmission microscopy was used to investigate the microscopic aspect of the crystal growth (utilizing the newly developed methodology of paired microscopy-DSC experiments introduced in ref ). The example of the typical micrographs is shown in Figure A–C; all observed Se–Te crystals exhibited similar morphology (round cylindritessee Supplemental online material for schematic representation of the cylindrites formation) and were randomly distributed throughout the films.…”

Section: Discussionmentioning

confidence: 99%

“…Similarly inconsistent behavior (although quantitatively different) is exhibited by the E values corresponding to the DSC crystallization in Se−Te powders, where the deviations are caused by the not always standardized influence of the mechanically induced defects. This might theoretically suggest that much closer attention needs to be paid to the quality of the microscopic observations of crystal growth in bulk chalcogenide materials, where no exact methodology (such as 32 for chalcogenide thin films) was developed. In particular, the improvements should be considered with regard to the following: pre-experiment annealing at T g to standardize the level of thermally induced stress, careful, and unified approach to the processing of the bulk glass (grinding and polishing can induce defects�that can both catalyze and hinder crystal growth�deep within the bulk sample 69 ), detailed recognition of different types of crystal growth (especially the non-homogeneous modes) in order to avoid mismatch, pairing the microscopic growth studies in bulk sample with identification of the ideal nucleation conditions (or negating this need by implementing parallel measurements if different-sized crystallites).…”

Section: Crystalmentioning

confidence: 99%

“…Similar state of affairs exists also for the Se–Te chalcogenide glasses, where the high-quality microscopic studies are very scarce − but inconsistent, and do not provide a complex perspective of the interconnection between the macro- and microscopic data. Acquirement of such overall view was enabled only recently, through a break-through advancement in direct combined observation of the calorimetric signal and microscopic insight under exactly similar conditions. The effectivity of the combined procedure also allows for processing large enough data sets to explore the influences of composition, synthesis, and measurement conditions on the crystal growth kinetics.…”

Section: Introductionmentioning

confidence: 99%

“…The general outcomes of the studies, − with regard to the crystal growth in thin Se–Te films, were the sometimes significantly faster growth in the films (compared to the bulk material), and disunity of the explanations thereof. It was shown in ref that in case of the Se thin film it is the physico-chemical quality of the substrate that is absolutely crucial for the rates of the nucleation and growth phenomena. In compliance with this new approach, the goal of the present paper is to provide an overview of the crystal growth behavior in the Se–Te chalcogenide thin films and bulk glasses.…”

Section: Introductionmentioning

confidence: 99%

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Crystal Growth in Se–Te Chalcogenides: Overview of the Growth/Relaxation/Viscosity Interplay for Bulk Glasses and Thin Films

Svoboda

Přikryl

Provotorov

et al. 2022

Crystal Growth & Design

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Crystal growth in 1 μm Se(1–y)Te y thin films (for y = 0, 7, 10, and 17) deposited on the Kapton, SiO2 glass, and white glass substrates was researched and quantified by means of a unique combination of direct joint microscopic and calorimetric measurements. As a general feature, the crystal growth in the Se–Te thin films deposited on a Kapton tape was very close to the native/bulk crystal growth. Deposition on the inorganic glassy substrates largely accelerated the crystal growth in the Se–Te thin films due to the build-up of internal tension originating from the large difference in thermal expansion coefficients between the film and the substrate. An additional increase in the crystal growth rate was also caused by the diffusion of Na+ ions from the white glass substrate into the Se–Te films. Almost perfect correspondence was found for the activation energies of crystal growth determined by various measurement techniques (calorimetry and microscopy) and for various Se–Te sample forms (thin films, bulk glass, powdered bulk glass). A very good agreement was found also between the activation energies of viscous flow and structural relaxation at the glass transition temperature T g. At higher temperatures, the Se–Te thin films exhibit a minor-to-moderate breach of the Stokes–Einstein law, as expressed by the value of Ediger’s decoupling parameter ξ ≈ 0.80 ± 0.05. At lower temperatures near the glass transition, the violation of the Stokes–Einstein relation deepens for the thin films with higher Te content. An explanation was proposed based on the potential interconnection between the below-T g relaxation kinetics and above-T g connectivity of the undercooled liquid domains (resulting either in changes of the effective hydrodynamic radius during the self-diffusion or in the tendency to create structural inhomogeneities via thermal fluctuations).

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Preparation of Sb2Se3-based ceramics and glass-ceramics from native thin films deposited on Kapton foil

Svoboda

Přikryl

Kolobov

et al. 2022

Ceramics International

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Crystal Growth in Amorphous Selenium Thin Films─Reviewed and Revisited: Direct Comparison of Microscopic and Calorimetric Measurements

Cited by 9 publications

References 51 publications

Indomethacin: The Interplay between Structural Relaxation, Viscous Flow and Crystal Growth

Indomethacin: The Interplay between Structural Relaxation, Viscous Flow and Crystal Growth

Crystal Growth in Se–Te Chalcogenides: Overview of the Growth/Relaxation/Viscosity Interplay for Bulk Glasses and Thin Films

Preparation of Sb2Se3-based ceramics and glass-ceramics from native thin films deposited on Kapton foil

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