Solidification and melting of mercury in a porous glass as studied by NMR and acoustic techniques

Borisov, B. F.; Charnaya, E. V.; Plotnikov, P. G.; Hoffmann, Wolf-Dieter; Michel, D.; Kumzerov, Yu. A.; Tien, Cheng; Wur, Ching-Shuei

doi:10.1103/physrevb.58.5329

Cited by 52 publications

(30 citation statements)

References 52 publications

(82 reference statements)

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“…On a laboratory time scale liquids can be further supercooled below the thermodynamic freezing transition because of the presence of a kinetic barrier to crystallization ͑genuine and dynamical supercooling͒. [15][16][17][18] In homogeneous nucleation, this barrier can be reduced only through deep supercooling. It is well known, however, that bulk liquids cannot be supercooled below the particular temperatures where the thermal energy becomes comparable to the reduced kinetic barrier.…”

Section: B Pore-size Dependence Of Phase-transition Temperaturesmentioning

confidence: 99%

Freezing and melting of methanol in a single cylindrical pore: Dynamical supercooling and vitrification of methanol

Morishige

Kawano

2000

The Journal of Chemical Physics

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Articles you may be interested inOn the state of water in 2.4 nm cylindrical pores of MCM from dynamic and normal specific heat studies J. Chem. Phys. 139, 064507 (2013); 10.1063/1.4817333 Heat capacity of tetrahydrofuran clathrate hydrate and of its components, and the clathrate formation from supercooled melt Universal scaling, dynamic fragility, segmental relaxation, and vitrification in polymer melts Melting/freezing behavior of a fluid confined in porous glasses and MCM-41: Dielectric spectroscopy and molecular simulation J. Chem. Phys. 114, 950 (2001); 10.1063/1.1329343Freezing and melting of water in a single cylindrical pore: The pore-size dependence of freezing and melting behaviorTo study the freezing/melting behavior of a confined CH 3 OH, we performed x-ray diffraction measurements of CH 3 OH confined inside the cylindrical pores of seven kinds of regular mesoporous adsorbents ͑MCM-41 and SBA-15͒ with different pore radii (rϭ1.2, 2.1, 2.5, 3.9, 4.5, 5.3, and 7.0 nm͒ as a function of temperature. The freezing/melting behavior depends markedly upon the pore size. Within the pores of rр3.9 nm, the confined CH 3 OH vitrifies on freezing. On the other hand, cooling of the CH 3 OH confined to the pores of rу4.5 nm results in crystallization of the liquid. Within the pores of rϭ5.3 nm, the crystallization proceeds in two steps: prefreezing first occurs and then it transforms into a crystalline solid with the same structure as that of the bulk ␣ phase. The prefreezing temperature seems to lower steeply with decreasing pore-size and to approach the freezing temperature for the pores of rϭ4.5 nm. Cooling of the CH 3 OH confined to the pores of rϭ7.0 nm results in formation of a crystalline solid with the same structure as that of the bulk ␤ phase and it does not transform into the low temperature ␣ phase on further cooling down to 30 K, leading to the appearance of a glassy crystal with the ␤ phase structure. A large hysteresis effect between freezing and melting is observed. A mechanism of the vitrification is discussed.

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Section: B Pore-size Dependence Of Phase-transition Temperaturesmentioning

confidence: 99%

Freezing and melting of methanol in a single cylindrical pore: Dynamical supercooling and vitrification of methanol

Morishige

Kawano

2000

The Journal of Chemical Physics

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“…Due to high wetting ability it is possible to produce nanocomposite sodium nitrite on the basis of different porous media with various topology and dimensionality: 3D random dendritetype (porous glasses) and regular (opals) interconnected nanocaverns, quasi-1D parallel nanochannels (chrysotile asbestos and mobile crystalline material (MCM)-41) etc. Such nanocomposites have been extensively studied by different experimental methods including calorimetry [1], nuclear magnetic resonance (NMR) [2][3][4], ultrasonic [5,6] and dielectric [3,[7][8][9][10] measurements, Raman [11], X-ray and neutron diffraction [12][13][14][15] etc, and very intriguing and surprising results were obtained. In particular it was shown that sodium nitrite (NaNO 2 ) within artificial opals demonstrates a giant growth of ε (up to 10 8 at 100 Hz) at approaching the bulk melting temperature [7].…”

Section: Introductionmentioning

confidence: 99%

Ferroelectric phase transitions in sodium nitrite nanocomposites

et al. 2008

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The structure and dielectric properties of sodium nitrite and its solid solutions confined in porous glasses have been studied. The temperature dependences of the order parameter and the unit cell volume for NaNO 2 embedded into porous glasses with different pore sizes were studied by neutron diffraction in the ferro-and paraelectric phases. The characteristic sizes of nanoparticles are determined. It is shown that at a size of nanoparticles smaller than~50 nm a crossover of the phase transition from first order to second order is observed. The effect of doping of sodium nitrite with potassium nitrite on the dielectric properties of the nanocomposite materials was studied and a strong lowering of the dielectric losses was observed.

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“…Significant melting point depression and large hysteresis between melting and freezing (solidification) have been observed for cryogenic fluids [1,5,6] and low melting point metals [7][8][9][10][11][12][13][14]. There are also reports [15,16] showing that nanoclusters consisting a few tens of atoms display much higher melting points than in the bulk form.…”

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confidence: 94%

Unusual Freezing and Melting of Gallium Encapsulated in Carbon Nanotubes

et al. 2004

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The freezing and melting behavior of gallium (Ga) encapsulated in carbon nanotubes was investigated through in situ observation in a transmission electron microscope. It is shown that Ga remains liquid up to -80 degrees C when encapsulated in carbon nanotubes. Results of detailed electron diffraction analysis show that the encapsulated Ga can crystallize in either beta phase or gamma phase rather than the common alpha phase upon freezing. Both beta-Ga and gamma-Ga melt at around -20 degrees C. While this is very close to the melting point of bulk beta-Ga (-16 degrees C), it is considerably higher than that of bulk gamma-Ga (-35.6 degrees C). It was observed that upon solidification, Ga has its unique crystallographic orientation relative to the host carbon nanotube.

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Solidification and melting of mercury in a porous glass as studied by NMR and acoustic techniques

Cited by 52 publications

References 52 publications

Freezing and melting of methanol in a single cylindrical pore: Dynamical supercooling and vitrification of methanol

Freezing and melting of methanol in a single cylindrical pore: Dynamical supercooling and vitrification of methanol

Ferroelectric phase transitions in sodium nitrite nanocomposites

Unusual Freezing and Melting of Gallium Encapsulated in Carbon Nanotubes

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