Thermodynamic, crystallographic, and dielectric study of the nature of glass transitions in cyclo-octanol

Puertas, R.; Rute, M.A.; Salud, J.; López, David; Díez, Sergio Cañas; Miltenburg, J. Kees van; Pardo, Luis Carlos; Tamarit, J. Ll.; Barrio, Marı́a; Pérez‐Jubindo, M. A.; Fuente, M. R. de la

doi:10.1103/physrevb.69.224202

Cited by 53 publications

(69 citation statements)

References 43 publications

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“…Temperature was controlled by means of a System Quatro from Novocontro with stabilization at different temperatures with a precision of the order of 20 mK. Additional details of the experimental technique can be found elsewhere [39,40].…”

Section: Bds Measurementsmentioning

confidence: 99%

Influence of internal flexibility on the double glass transition in a series of odd non-symmetric liquid crystal dimers characterised by dielectric measurements

et al. 2017

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Section: Bds Measurementsmentioning

confidence: 99%

Influence of internal flexibility on the double glass transition in a series of odd non-symmetric liquid crystal dimers characterised by dielectric measurements

et al. 2017

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mentioning

confidence: 99%

“…Such plastic phases are formed from the liquid and can be supercooled, giving rise to the so-called orientational glasses (OG) or "glassy crystals" [6][7][8][9]. They show typically low fragility, as cyclooctanol (m ¼ 33) [10,11], cycloheptanol (m ¼ 22) [12], ortho-carborane (m ¼ 20) [13], cyano-adamantane (m ¼ 17) [9,14], adamantanone (m ≈ 16) [9,15], ethanol (m ¼ 48) [9], or mixed molecular crystals NPA 0.7 NPG 0.3 fðCH 2 OHÞCðCH 3 Þ 3 g 0.7 fðCH 2 OHÞ 2 CðCH 3 Þ 2 g 0.3 (m¼30) [16][17][18]. The most fragile OG known to date are the Freon 112 (CCl 2 F-CCl 2 F) with m ¼ 68 [19] and a co-crystal of succinonitrile (60%) and glutaronitrile (40%) with m ¼ 62 [20].…”

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Thermodynamic and Kinetic Fragility of Freon 113: The Most Fragile Plastic Crystal

Vispa¹,

Romanini²,

Ramos

et al. 2017

Phys. Rev. Lett.

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We present a dynamic and thermodynamic study of the orientational glass former Freon 113 (1,1,2-trichloro-1,2,2-trifluoroethane, CCl 2 F-CClF 2 ) in order to analyze its kinetic and thermodynamic fragilities. Freon 113 displays internal molecular degrees of freedom that promote a complex energy landscape. Experimental specific heat and its microscopic origin, the vibrational density of states from inelastic neutron scattering, together with the orientational dynamics obtained by means of dielectric spectroscopy have revealed the highest fragility value, both thermodynamic and kinetic, found for this orientational glass former. The excess in both Debye-reduced specific heat and density of states (boson peak) evidences the existence of glassy low-energy excitations. We demonstrate that early proposed correlations between the boson peak and the Debye specific heat value are elusive as revealed by the clear counterexample of the studied case. DOI: 10.1103/PhysRevLett.118.105701 When a structurally disordered system is rapidly cooled to avoid crystallization, some properties, such as viscosity, show a dramatic increase down to the glass transition where the material reaches viscosity values comparable to those of a solid (10 12 Pa s), i.e., relaxation times of ≈100 s. Such behavior contrasts with that typical for most liquids at high temperatures, which usually exhibit a simple Arrhenius behavior of the relaxation time, τ ¼ τ 0 expðE a =k B TÞ, where the activation energy is temperature independent.Decreasing temperature relaxation time shows a stronger increase, faster than that of the Arrhenius law and accompanied with an increase of some characteristic cooperativity relaxation length. The viscosity (or τ) increase is generally characterized by recourse to the concept of the kinetic fragility [1,2], m ¼ fð∂ log τÞ=½∂ðT g =TÞg T¼T g , which accounts for the deviation of the Arrhenius temperature dependence.In terms of fragility index m, materials for which τ follow an Arrhenius law are known as "strong" glass formers, whereas "fragile" glass formers are those exhibiting super-Arrhenius behavior. For such cases, the temperature dependence of τ is given through the Vogel-FulcherTammann (VFT) expression,where the temperature T 0 is associated with an ideal glass transition and even with the so-called Kauzmann temperature [3], and the fragility strength parameter D is linked to the fragility parameter by. Typical strong glass formers (m ≈ 16, or D ≥ 100) are tetrahedral network liquids as SiO 2 or GeO 2 . The highest values of fragility for organic materials (exception made of polymers) have been found in cis-or trans-decahydronaphthalene (m ¼ 147 [4]). Another group of materials exhibiting glasslike properties is that of crystals with positional order and orientational disorder [5]. Such plastic phases are formed from the liquid and can be supercooled, giving rise to the so-called orientational glasses (OG) or "glassy crystals" [6][7][8][9]. They show typically low fragility, as cyclooctanol (m ¼ 33) [10,11]

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“…Concerning the dynamics of OD phases, dielectric spectroscopy has been revealed to be a useful tool to understand the complex dynamics of these phases [7,8,9,10,11,12,13].…”

Section: Introductionmentioning

confidence: 99%

“…But a mesophase can exist between the completely ordered crystalline phase and the translationally and orientationally disordered liquid phase, the so called plastic phase or orientationally disordered (OD) phase [2,3]. In the plastic phase, the centers of mass of the molecules have spatial long range order, forming a lattice which generally has high symmetry (such as cubic, quasi-cubic or rhombohedral [2, 3, 4]), but there is only short-range order with respect to the orientational degrees of freedom [5].As for glass-forming liquids, the typical phenomenology of a glass transition also can be realized in various plastic crystals when the temperature is decreased, but in this case only the orientational degrees of freedom are frozen, yielding the formation of a "glassy crystal"[6], also called OD glass.Concerning the dynamics of OD phases, dielectric spectroscopy has been revealed to be a useful tool to understand the complex dynamics of these phases [7,8,9,10,11,12,13].Based on these works there seem to be some general dynamic features of OD phases and its glasses: They are rather strong (following the definition of Angell [14]) and they follow the Böhmer relation between non-exponentiality of the α relaxation and fragility [15,16].On the contrary, the so called Nagel scaling [17] does not seem to work for these phases [7,11,18]. In addition there is only a weak or no β-relaxation at all and the excess wing, showing up as a second power law at the high frequency flank of the α peak in many canonical glass formers [17,19,20,21], is either absent in plastic crystals [11] or can be ascribed to a weak secondary relaxation [7,9].…”

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α and β relaxation dynamics of a fragile plastic crystal

Pardo

Lunkenheimer

Loidl

2006

The Journal of Chemical Physics

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We present a thorough dielectric investigation of the relaxation dynamics of plastic crystalline Freon112, which exhibits freezing of the orientational degrees of freedom into a glassy crystal below 90 K. Among other plastic crystals, Freon112 stands out by being relatively fragile within Angell's classification scheme and by showing an unusually strong β-relaxation. Comparing the results to those on Freon112a, having only a single molecular conformation, points to the importance of the presence of two molecular conformations in Freon112 for the explanation of its unusual properties. 1 INTRODUCTIONGlass phenomena occur when a dynamically disordered system (e. g. aliquid, plastic crystal or paramagnet) freezes as a function of external temperature or pressure devoid of long range order. In this freezing process, one or more degrees of freedom of atoms or molecules continuously slow down, reaching the so called glass transition when their dynamics has a characteristic time, generally chosen to be 10 2 s (for recent reviews on glass transition see, e.g., [1]). Since in the liquid phase there is translational and orientational disorder, the glass transition of canonical glass formers is associated with the freezing of these two degrees of freedom. But a mesophase can exist between the completely ordered crystalline phase and the translationally and orientationally disordered liquid phase, the so called plastic phase or orientationally disordered (OD) phase [2,3]. In the plastic phase, the centers of mass of the molecules have spatial long range order, forming a lattice which generally has high symmetry (such as cubic, quasi-cubic or rhombohedral [2, 3, 4]), but there is only short-range order with respect to the orientational degrees of freedom [5].As for glass-forming liquids, the typical phenomenology of a glass transition also can be realized in various plastic crystals when the temperature is decreased, but in this case only the orientational degrees of freedom are frozen, yielding the formation of a "glassy crystal"[6], also called OD glass.Concerning the dynamics of OD phases, dielectric spectroscopy has been revealed to be a useful tool to understand the complex dynamics of these phases [7,8,9,10,11,12,13].Based on these works there seem to be some general dynamic features of OD phases and its glasses: They are rather strong (following the definition of Angell [14]) and they follow the Böhmer relation between non-exponentiality of the α relaxation and fragility [15,16].On the contrary, the so called Nagel scaling [17] does not seem to work for these phases [7,11,18]. In addition there is only a weak or no β-relaxation at all and the excess wing, showing up as a second power law at the high frequency flank of the α peak in many canonical glass formers [17,19,20,21], is either absent in plastic crystals [11] or can be ascribed to a weak secondary relaxation [7,9].

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Thermodynamic, crystallographic, and dielectric study of the nature of glass transitions in cyclo-octanol

Cited by 53 publications

References 43 publications

Influence of internal flexibility on the double glass transition in a series of odd non-symmetric liquid crystal dimers characterised by dielectric measurements

Influence of internal flexibility on the double glass transition in a series of odd non-symmetric liquid crystal dimers characterised by dielectric measurements

Thermodynamic and Kinetic Fragility of Freon 113: The Most Fragile Plastic Crystal

α and β relaxation dynamics of a fragile plastic crystal

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