Building and Breaking Bonds by Homogenous Nucleation in Glass-Forming Melts Leading to Transitions in Three Liquid States

Tournier, R.; Ojovan, Michael I.

doi:10.3390/ma14092287

Cited by 14 publications

(36 citation statements)

References 61 publications

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“…The complete annihilation of configurons occurs by heating above the temperature T n+ > T m toward the homogeneous liquid state. Each configuron has the energy of an antibond, which is equal in size but with an opposite sign to that of a bond that would appear by annealing the homogeneous liquid between T m and T n+ and would disappear by heating above T n+ [ 80 ].…”

Section: Discussionmentioning

confidence: 99%

“…Kinetically controlled shifts of T g within a relatively narrow temperature interval by the decrease of cooling rate q are thus explained, revealing the logarithmic dependence of T g on q within CPT. The nucleation of bonds also occurs between T m and T n+ and not only below T m [ 36 , 80 ]. Consequently, clusters of bound colloids are built below T n+ , and when the number of new bonds attains the percolation threshold, the crystallization occurs at T m if the liquid is slowly cooled instead of being quenched.…”

Section: Discussionmentioning

confidence: 99%

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On Structural Rearrangements Near the Glass Transition Temperature in Amorphous Silica

Ojovan

Tournier

2021

Materials

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The formation of clusters was analyzed in a topologically disordered network of bonds of amorphous silica (SiO2) based on the Angell model of broken bonds termed configurons. It was shown that a fractal-dimensional configuron phase was formed in the amorphous silica above the glass transition temperature Tg. The glass transition was described in terms of the concepts of configuron percolation theory (CPT) using the Kantor-Webman theorem, which states that the rigidity threshold of an elastic percolating network is identical to the percolation threshold. The account of configuron phase formation above Tg showed that (i) the glass transition was similar in nature to the second-order phase transformations within the Ehrenfest classification and that (ii) although being reversible, it occurred differently when heating through the glass–liquid transition to that when cooling down in the liquid phase via vitrification. In contrast to typical second-order transformations, such as the formation of ferromagnetic or superconducting phases when the more ordered phase is located below the transition threshold, the configuron phase was located above it.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

On Structural Rearrangements Near the Glass Transition Temperature in Amorphous Silica

Ojovan

Tournier

2021

Materials

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“…At this time, it was already known that crystals covered by a solid thin film or imbedded into a matrix could melt at higher temperatures than T m by homogeneous nucleation in crystal hearts instead of surface melting [ 47 , 48 , 49 , 50 ]. This idea was relaunched in glass-forming melts accompanied by predictions of their melting temperatures T n+ > T m using the non-classical model of homogeneous nucleation [ 1 , 33 , 34 , 51 ] confirmed by experimental observations [ 52 , 53 , 54 , 55 , 56 , 57 , 58 , 59 , 60 , 61 , 62 , 63 , 64 , 65 , 66 , 67 , 68 ]. These predictions had established that the medium-range order persists in liquids from T g up to T n+ due to residual bonds producing endothermic enthalpy or due to antibonds producing exothermic enthalpy at T n+ where the homogeneous state of liquids appears.…”

Section: Introductionmentioning

confidence: 89%

“…Glass transition temperatures are observed at a temperature T = T g during heating of quenched melts. Below T g , atomic bonds system produces enthalpy relaxation between the two homogeneous nucleation temperatures T n− of the glassy phase with the highest being T g [ 1 , 2 ]. The glass formation at the lowest T n- occurs in hyperquenched glass-forming melts at the departure of the enthalpy relaxation [ 3 , 4 , 5 , 6 ].…”

Section: Introductionmentioning

confidence: 99%

“…The reduced temperatures θ 0m and θ 0g are the Vogel–Fulcher–Tammann temperatures of these two liquids and are defined by the coefficients ε ls0 and ε gs0 , depending on the nucleation temperatures in the two liquids equal to [ε ls (θ) − 2]/3 for ∆ε = 0 [ 1 , 36 ]. The reduced glass transition temperature θ g is used to define them [ 37 , 38 , 39 ].…”

Section: Introductionmentioning

confidence: 99%

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Prediction of Second Melting Temperatures Already Observed in Pure Elements by Molecular Dynamics Simulations

Tournier

Ojovan

2021

Materials

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A second melting temperature occurs at a temperature Tn+ higher than Tm in glass-forming melts after heating them from their glassy state. The melting entropy is reduced or increased depending on the thermal history and on the presence of antibonds or bonds up to Tn+. Recent MD simulations show full melting at Tn+ = 1.119Tm for Zr, 1.126Tm for Ag, 1.219Tm for Fe and 1.354Tm for Cu. The non-classical homogeneous nucleation model applied to liquid elements is based on the increase of the Lindemann coefficient with the heating rate. The glass transition at Tg and the nucleation temperatures TnG of glacial phases are successfully predicted below and above Tm. The glass transition temperature Tg increases with the heating rate up to Tn+. Melting and crystallization of glacial phases occur with entropy and enthalpy reductions. A universal law relating Tn+ and TnG around Tm shows that TnG cannot be higher than 1.293Tm for Tn+= 1.47Tm. The enthalpies and entropies of glacial phases have singular values, corresponding to the increase of percolation thresholds with Tg and TnG above the Scher and Zallen invariant at various heating and cooling rates. The G-phases are metastable up to Tn+ because the antibonds are broken by homogeneous nucleation of bonds.

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Room Temperature Viscous Flow of Amorphous Silica Induced by Electron Beam Irradiation

et al. 2023

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The increasing use of oxide glasses in high‐tech applications illustrates the demand of novel engineering techniques on nano‐ and microscale. Due to the high viscosity of oxide glasses at room temperature, shaping operations are usually performed at temperatures close or beyond the point of glass transition Tg. Those treatments, however, are global and affect the whole component. It is known from the literature that electron irradiation facilitates the viscous flow of amorphous silica near room temperature for nanoscale components. At the micrometer scale, however, a comprehensive study on this topic is still pending. In the present study, electron irradiation inducing viscous flow at room temperature is observed using a micropillar compression approach and amorphous silica as a model system. A comparison to high temperature yielding up to a temperature of 1100 °C demonstrates that even moderate electron irradiation resembles the mechanical response of 600 °C and beyond. As an extreme case, a yield strength as low as 300 MPa is observed with a viscosity indicating that Tg has been passed. Those results show that electron irradiation‐facilitated viscous flow is not limited to the nanoscale which offers great potential for local microengineering.

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Building and Breaking Bonds by Homogenous Nucleation in Glass-Forming Melts Leading to Transitions in Three Liquid States

Cited by 14 publications

References 61 publications

On Structural Rearrangements Near the Glass Transition Temperature in Amorphous Silica

On Structural Rearrangements Near the Glass Transition Temperature in Amorphous Silica

Prediction of Second Melting Temperatures Already Observed in Pure Elements by Molecular Dynamics Simulations

Room Temperature Viscous Flow of Amorphous Silica Induced by Electron Beam Irradiation

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