Effects of Glass Transition and Structural Relaxation on Crystal Nucleation: Theoretical Description and Model Analysis

In the application of classical nucleation theory (CNT) and all other theoretical models of crystallization of liquids and glasses it is always assumed that nucleation proceeds only after the supercooled liquid or the glass have completed structural relaxation processes towards the metastable equilibrium state. Only employing such an assumption, the thermodynamic driving force of crystallization and the surface tension can be determined in the way it is commonly performed. The present paper is devoted to the theoretical treatment of a different situation, when nucleation proceeds concomitantly with structural relaxation. To treat the nucleation kinetics theoretically for such cases, we need adequate expressions for the thermodynamic driving force and the surface tension accounting for the contributions caused by the deviation of the supercooled liquid from metastable equilibrium. In the present paper, such relations are derived. They are expressed via deviations of structural order parameters from their equilibrium values. Relaxation processes result in changes of the structural order parameters with time. As a consequence, the thermodynamic driving force and surface tension, and basic characteristics of crystal nucleation, such as the work of critical cluster formation and the steady-state nucleation rate, also become time-dependent. We show that this scenario may be realized in the vicinity and below the glass transition temperature, and it may occur only if diffusion (controlling nucleation) and viscosity (controlling the alpha-relaxation process) in the liquid decouple. Analytical estimates are illustrated and confirmed by numerical computations for a model system. The theory is successfully applied to the interpretation of experimental data. Several further consequences of this newly developed theoretical treatment are discussed in detail. In line with our previous investigations, we reconfirm that only when the characteristic times of structural relaxation are of similar order of magnitude or longer than the characteristic times of crystal nucleation, elastic stresses evolving in nucleation may significantly affect this process. Advancing the methods of theoretical analysis of elastic stress effects on nucleation, for the first time expressions are derived for the dependence of the surface tension of critical crystallites on elastic stresses. As the result, a comprehensive theoretical description of crystal nucleation accounting appropriately for the effects of deviations of the liquid from the metastable states and of relaxation on crystal nucleation of glass-forming liquids, including the effect of simultaneous stress evolution and stress relaxation on nucleation, is now available. As one of its applications, this theoretical treatment provides a new tool for the explanation of the low-temperature anomaly in nucleation in silicate and polymer glasses (the so-called “breakdown” of CNT at temperatures below the temperature of the maximum steady-state nucleation rate). We show that this anomaly results from much more complex features of crystal nucleation in glasses caused by deviations from metastable equilibrium (resulting in changes of the thermodynamic driving force, the surface tension, and the work of critical cluster formation, in the necessity to account of structural relaxation and stress effects) than assumed so far. If these effects are properly accounted for, then CNT appropriately describes both the initial, the intermediate, and the final states of crystal nucleation.

[1]  Kenneth F. Kelton,et al.  Nucleation in condensed matter : applications in materials and biology , 2010 .

[2]  Edgar Dutra Zanotto,et al.  Stress development and relaxation during crystal growth in glass-forming liquids , 2006 .

[3]  John C. Mauro,et al.  Comment on “Glass Transition, Crystallization of Glass-Forming Melts, and Entropy” Entropy 2018, 20, 103 , 2018, Entropy.

[4]  C. Angell,et al.  The Kauzmann Paradox, Metastable Liquids, and Ideal Glasses: A Summary , 1986 .

[5]  Modern aspects of the kinetic theory of glass transition , 2016 .

[6]  G. P. Johari Calorimetric features of release of plastic deformation induced internal stresses, and approach to equilibrium state on annealing of crystals and glasses , 2014 .

[7]  J. Schmelzer,et al.  Curvature dependence of the surface tension and crystal nucleation in liquids , 2018, International Journal of Applied Glass Science.

[8]  V. Filipovich,et al.  Nucleation in silicate glasses and effect of preliminary heat treatment on it , 1981 .

[9]  Jürn W. P. Schmelzer,et al.  On the dependence of the properties of glasses on cooling and heating rates: I. Entropy, entropy production, and glass transition temperature , 2011 .

[10]  S. Vyazovkin,et al.  Effect of physical aging on nucleation of amorphous indomethacin. , 2007, The journal of physical chemistry. B.

[11]  J. Schmelzer,et al.  The effect of elastic stress and relaxation on crystal nucleation in lithium disilicate glass , 2004 .

[12]  H. S. Green,et al.  A Kinetic Theory of Liquids , 1947, Nature.

[13]  Alexander S. Abyzov,et al.  Entropy and the Tolman Parameter in Nucleation Theory , 2019, Entropy.

[14]  Edgar Dutra Zanotto,et al.  The race within supercooled liquids-Relaxation versus crystallization. , 2018, The Journal of chemical physics.

[15]  G. A. Sycheva Determination of the size of the critical nucleus of crystals in lithium and sodium silicate glass , 2015, Glass Physics and Chemistry.

[16]  J. Schmelzer,et al.  Crystallization of glass-forming melts: New answers to old questions , 2017, Journal of Non-Crystalline Solids.

[17]  C. Schick,et al.  General Concepts of Crystallization: Some Recent Results and Possible Future Developments , 2020 .

[18]  V. Slezov Kinetics of First Order Phase Transitions , 2009 .

[19]  K. Ngai Relaxation and Diffusion in Complex Systems , 2011 .

[20]  R. Youngman,et al.  The Low-Temperature Nucleation Rate Anomaly in Silicate Glasses is an Artifact. , 2020, 2005.04845.

[21]  Edgar Dutra Zanotto,et al.  Crystal nucleation in glass-forming liquids: Variation of the size of the “structural units” with temperature , 2016 .

[22]  G. A. Sycheva Surface energy at the crystal nucleus-glass interface in alkali silicate glasses , 1998 .

[23]  S. Nemilov The results of application of Maxwell’s equations in glass science , 2014, Glass Physics and Chemistry.

[24]  R. Davies,et al.  Thermodynamic and kinetic properties of glasses , 1953 .

[25]  J. Schmelzer,et al.  Kinetic criteria of glass-formation, pressure dependence of the glass-transition temperature, and the Prigogine–Defay ratio , 2015 .

[26]  Sergey Vyazovkin,et al.  Physical stability and relaxation of amorphous indomethacin. , 2005, The journal of physical chemistry. B.

[27]  I. Avramov,et al.  Generic phenomenology of vitrification and relaxation and the Kohlrausch and Maxwell equations , 2002 .

[28]  N. S. Yuritsyn Crystal Nucleation in Soda–Lime–Silica Glass at Temperatures below the Glass Transition Temperature , 2020, Glass Physics and Chemistry.

[29]  C. Schick,et al.  Relaxation and crystal nucleation in polymer glasses , 2018 .

[30]  Martin Goldstein,et al.  Viscous Liquids and the Glass Transition: A Potential Energy Barrier Picture , 1969 .

[31]  Edgar Dutra Zanotto,et al.  Crystallization in glass-forming liquids: Effects of fragility and glass transition temperature , 2015 .

[32]  Günter Reiter,et al.  The memorizing capacity of polymers. , 2020, The Journal of chemical physics.

[33]  Edgar Dutra Zanotto,et al.  Crystallization in glass-forming liquids: Effects of decoupling of diffusion and viscosity on crystal growth , 2015 .

[34]  Edgar Dutra Zanotto,et al.  How Do Crystals Form and Grow in Glass‐Forming Liquids: Ostwald's Rule of Stages and Beyond , 2010 .

[35]  M. Oguni,et al.  Anomalous generation and extinction of crystal nuclei in nonequilibrium supercooled liquid o -benzylphenol , 2002 .

[36]  Jürn W. P. Schmelzer,et al.  Homogeneous crystal nucleation in silicate glasses: A 40 years perspective , 2006 .

[37]  Rössler,et al.  Indications for a change of diffusion mechanism in supercooled liquids. , 1990, Physical review letters.

[38]  R. Müller,et al.  Theory of nucleation in viscoelastic media: application to phase formation in glassforming melts , 2003 .

[39]  J. Schawe,et al.  Isothermal crystallization of cis-1.4-polybutadiene at low temperatures , 2020 .

[40]  J. Schmelzer,et al.  Time of Formation of the First Supercritical Nucleus, Time‐lag, and the Steady‐State Nucleation Rate , 2017 .

[41]  Edgar Dutra Zanotto,et al.  Crystallization of glass-forming liquids: Maxima of nucleation, growth, and overall crystallization rates , 2015 .

[42]  J. Schmelzer,et al.  Crystallization of Glass: What We Know, What We Need to Know , 2016 .

[43]  J. Schmelzer,et al.  Crystallization of glass-forming liquids: Specific surface energy , 2016 .

[44]  A. Michaelides,et al.  Crystal Nucleation in Liquids: Open Questions and Future Challenges in Molecular Dynamics Simulations , 2016, Chemical reviews.

[45]  Y. Zeldovich,et al.  10. On the Theory of New Phase Formation. Cavitation , 1992 .

[46]  J. Schmelzer,et al.  Comments on the thermodynamic analysis of nucleation in confined space , 2014 .

[47]  V. Yamakov,et al.  Generic Phenomenological Theory of Vitrification , 2001 .

[48]  G. P. Johari,et al.  A mechanism for spontaneous relaxation of glass at room temperature , 2003 .

[49]  J. Schmelzer Kinetic criteria of glass formation and the pressure dependence of the glass transition temperature. , 2012, The Journal of chemical physics.

[50]  I. Avramov,et al.  Kinetics of segregation and crystallization with stress development and stress relaxation , 1996 .

[51]  J. Schmelzer,et al.  How Do Crystals Nucleate and Grow: Ostwald’s Rule of Stages and Beyond , 2017 .

[52]  Edgar Dutra Zanotto,et al.  Recent studies of internal and surface nucleation in silicate glasses , 2003, Philosophical Transactions of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences.

[53]  W. Kauzmann The Nature of the Glassy State and the Behavior of Liquids at Low Temperatures. , 1948 .

[54]  H. Sardón,et al.  Chemical Structure Drives Memory Effects in the Crystallization of Homopolymers , 2020, Macromolecules.

[55]  A. M. Rodrigues,et al.  The effect of heterogeneous structure of glass-forming liquids on crystal nucleation , 2017 .

[56]  M. Oguni,et al.  Discovery of crystal nucleation proceeding much below the glass transition temperature in a supercooled liquid , 1996 .

[57]  Edgar Dutra Zanotto,et al.  New insights on the thermodynamic barrier for nucleation in glasses: The case of lithium disilicate , 2005 .

[58]  Edgar Dutra Zanotto,et al.  Homogeneous nucleation versus glass transition temperature of silicate glasses , 2003 .

[59]  C. Schick,et al.  Homogeneous crystal nucleation in polymers , 2017, Journal of physics. Condensed matter : an Institute of Physics journal.

[60]  W. Pannhorst,et al.  Surface energy and structure effects on surface crystallization , 1995 .

[61]  G. P. Johari Decrease in heat capacity and enthalpy of an aging glass – A conflict with standard procedure for determining enthalpy loss and fictive temperature , 2020 .

[62]  J. Schmelzer,et al.  Surface-induced devitrification of glasses: the influence of elastic strains , 1993 .

[63]  J. Schmelzer,et al.  Freezing-in and production of entropy in vitrification. , 2006, The Journal of chemical physics.

[64]  A. Müller,et al.  Self-Nucleation Effects on Polymer Crystallization , 2020, Macromolecules.

[65]  Jürn W. P. Schmelzer,et al.  The Vitreous State: Thermodynamics, Structure, Rheology, and Crystallization , 2013 .

[66]  C. Schick,et al.  On the dependence of the properties of glasses on cooling and heating rates II: Prigogine–Defay ratio, fictive temperature and fictive pressure , 2011 .

[67]  E. Ruckenstein,et al.  Effect of chemical aging of aqueous organic aerosols on the rate of their steady-state nucleation. , 2020, Physical chemistry chemical physics : PCCP.

[68]  G. Wilde,et al.  Melt undercooling and nucleation kinetics , 2016 .

[69]  Alexander S. Abyzov,et al.  Crystallization of Supercooled Liquids: Self-Consistency Correction of the Steady-State Nucleation Rate , 2020, Entropy.

[70]  J. Perepezko,et al.  Separating β relaxation from α relaxation in fragile metallic glasses based on ultrafast flash differential scanning calorimetry , 2020 .

[71]  G. P. Johari,et al.  Non-exponential nature of calorimetric and other relaxations: effects of 2 nm-size solutes, loss of translational diffusion, isomer specificity, and sample size. , 2013, The Journal of chemical physics.

[72]  B. Wunderlich,et al.  Kinetics of nucleation and crystallization in poly(ɛ-caprolactone) (PCL) , 2011 .

[73]  N. S. Yuritsyn Influence of preformed nuclei on crystal nucleation kinetics in soda–lime–silica glass , 2015 .

[74]  Jürn W. P. Schmelzer,et al.  Glass Transition, Crystallization of Glass-Forming Melts, and Entropy , 2018, Entropy.

[75]  C. Schick,et al.  Steady-State Crystal Nucleation Rate of Polyamide 66 by Combining Atomic Force Microscopy and Fast-Scanning Chip Calorimetry , 2020, Macromolecules.

[76]  C. Schick,et al.  Kauzmann paradox and the crystallization of glass-forming melts , 2017, Journal of Non-Crystalline Solids.

[77]  Jürn W. P. Schmelzer,et al.  Reply to “Comment on ‘Glass Transition, Crystallization of Glass-Forming Melts, and Entropy”’ by Zanotto and Mauro , 2018, Entropy.

[78]  R. Tolman The Effect of Droplet Size on Surface Tension , 1949 .

[79]  J. Schmelzer,et al.  Structural order parameters, the Prigogine–Defay ratio and the behavior of the entropy in vitrification , 2009 .

[80]  C. Schick,et al.  Sequence of enthalpy relaxation, homogeneous crystal nucleation and crystal growth in glassy polyamide 6 , 2014 .

[81]  Jürn W. P. Schmelzer Application of the Nucleation Theorem to Crystallization of Liquids: Some General Theoretical Results , 2019, Entropy.

[82]  J. Schmelzer,et al.  Kinetics of transient nucleation in glass-forming liquids: a retrospective and recent results , 1997 .

[83]  J. Schawe,et al.  Competition between Structural Relaxation and Crystallization in the Glass Transition Range of Random Copolymers † , 2020, Polymers.

[84]  Edgar Dutra Zanotto,et al.  The effect of elastic stresses on the thermodynamic barrier for crystal nucleation , 2016 .

[85]  G. Reiter,et al.  Polymer crystallization : observations, concepts and interpretations , 2003 .

[86]  G. A. Sycheva Evaluation of the surface energy at the crystal-glass interface in sodium silicate glass 46Na2O.54SiO2 , 1998 .

[87]  J. Schmelzer,et al.  Crystallization of glass-forming liquids: Thermodynamic driving force , 2016 .

[88]  Edgar Dutra Zanotto,et al.  Critical assessment of the alleged failure of the Classical Nucleation Theory at low temperatures , 2020 .

[89]  C. Brooks Computer simulation of liquids , 1989 .

[90]  G. P. Johari Configurational and residual entropies of nonergodic crystals and the entropy's behavior on glass formation. , 2010, The Journal of chemical physics.

[91]  M. Oguni,et al.  Generation and extinction of crystal nuclei in an extremely non-equilibrium glassy state of salol , 2003 .

[92]  J. Schmelzer,et al.  Glasses and the Glass Transition , 2011 .