| Nome |
# |
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Recent developments in the experimental investigations of relaxations in pharmaceuticals by Dielectric Spectroscopy and High Pressure techniques, file e0d6c928-c5e6-fcf8-e053-d805fe0aa794
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233
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Complex Dynamics of a Fluorinated Vinylidene Cyanide Copolymer Highlighted by Dielectric Relaxation Spectroscopy, file e0d6c927-8e32-fcf8-e053-d805fe0aa794
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195
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The JG β-relaxation in water and impact on the dynamics of aqueous mixtures and hydrated biomolecules, file e0d6c92e-5c01-fcf8-e053-d805fe0aa794
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191
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Relation between the activation energy of the Johari-Goldstein beta relaxation and T(g) of glass formers, file e0d6c925-f046-fcf8-e053-d805fe0aa794
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177
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Thermodynamic scaling of vibrational dynamics and relaxation, file e0d6c928-78ff-fcf8-e053-d805fe0aa794
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150
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Coupling of Caged Molecule Dynamics to JG β-Relaxation: I, file e0d6c926-c570-fcf8-e053-d805fe0aa794
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138
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|
A perspective on experimental findings and theoretical explanations of novel dynamics at free surface and in freestanding thin films of polystyrene, file e0d6c926-d792-fcf8-e053-d805fe0aa794
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103
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Thermodynamic Scaling of the Dynamics of a Strongly Hydrogen-Bonded Glass-Former, file e0d6c929-2e12-fcf8-e053-d805fe0aa794
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60
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|
null, file e0d6c92e-8f0b-fcf8-e053-d805fe0aa794
|
58
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Segmental α-Relaxation for the First Step and Sub-Rouse Modes for the Second Step in Enthalpy Recovery in the Glassy State of Polystyrene, file e0d6c92e-3138-fcf8-e053-d805fe0aa794
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54
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Coupling of Caged Molecule Dynamics to JG β-Relaxation II: Polymers, file e0d6c926-cbc8-fcf8-e053-d805fe0aa794
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49
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A microscopic look at the Johari-Goldstein relaxation in a hydrogen-bonded glass-former, file e0d6c92e-6aa6-fcf8-e053-d805fe0aa794
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45
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Coupling of Caged Molecule Dynamics to JG β-Relaxation III: Van der Waals Glasses, file e0d6c926-c5af-fcf8-e053-d805fe0aa794
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42
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Dynamics of hydrated proteins and bio-protectants: Caged dynamics, β-relaxation, and α-relaxation, file e0d6c928-c76c-fcf8-e053-d805fe0aa794
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41
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Thermodynamic scaling of vibrational dynamics and relaxation, file e0d6c928-d8c8-fcf8-e053-d805fe0aa794
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41
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Evidence of negative thermal expansion in supercooled tantala, file e0d6c931-40c0-fcf8-e053-d805fe0aa794
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29
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Study of the cold crystallization of poly(ethylene terephthalate) at the air interface by ATR spectroscopy, file e0d6c926-c66d-fcf8-e053-d805fe0aa794
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25
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Direct Evidence of Relaxation Anisotropy Resolved by High Pressure in a Rigid and Planar Glass Former, file e0d6c929-e92c-fcf8-e053-d805fe0aa794
|
24
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Critical structural fluctuations of proteins upon thermal unfolding challenge the Lindemann criterion, file e0d6c931-1e6d-fcf8-e053-d805fe0aa794
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21
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How to align a nematic glassy phase – Different conditions – Different results, file e0d6c92e-4d25-fcf8-e053-d805fe0aa794
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15
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A microscopic look at the Johari-Goldstein relaxation in a hydrogen-bonded glass-former, file e0d6c92e-5a41-fcf8-e053-d805fe0aa794
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13
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Fast differential scanning calorimetry: new solutions in data treatment and applications to molecular glass-formers, file abd124cc-a807-4541-ac40-c968075223ed
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12
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Extended model for the interaction of dielectric thin films with an electrostatic force microscope probe, file e0d6c926-cac9-fcf8-e053-d805fe0aa794
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11
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Molecular dynamics in amorphous ergocalciferol, file e0d6c926-cbc7-fcf8-e053-d805fe0aa794
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10
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In silico broadband mechanical spectroscopy of amorphous tantala, file e0d6c92f-f77c-fcf8-e053-d805fe0aa794
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9
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Does the Johari-Goldstein β-Relaxation Exist in Polypropylene Glycols?, file e0d6c926-c587-fcf8-e053-d805fe0aa794
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8
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Glass formability in medium-sized molecular systems/pharmaceuticals. I. Thermodynamics vs. kinetics, file e0d6c928-c442-fcf8-e053-d805fe0aa794
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8
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Coupling of caged molecule dynamics to Johari-Goldstein β-relaxation in metallic glasses, file e0d6c928-c5f1-fcf8-e053-d805fe0aa794
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8
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Contrasting two different interpretations of the dynamics in binary glass forming mixtures, file e0d6c92a-db5e-fcf8-e053-d805fe0aa794
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8
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Uncovering a novel transition in the dynamics of proteins in the dry state, file e0d6c92e-27fc-fcf8-e053-d805fe0aa794
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8
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Special issue: "7th IDMRCS: Relaxations in complex systems", file e0d6c926-c5ad-fcf8-e053-d805fe0aa794
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7
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Secondary relaxation dynamics in rigid glass-forming molecular liquids with related structures, file e0d6c926-c8c3-fcf8-e053-d805fe0aa794
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7
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Revealing the rich dynamics of glass-forming systems by modification of composition and change of thermodynamic conditions, file e0d6c926-ca3b-fcf8-e053-d805fe0aa794
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7
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Quantitative explanation of the enhancement of surface mobility of the metallic glass Pd40Cu30Ni10P20 by the Coupling Model, file e0d6c929-25d2-fcf8-e053-d805fe0aa794
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7
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|
Resolving the controversy on the glass transition temperature of water?, file e0d6c92c-02f4-fcf8-e053-d805fe0aa794
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7
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The JG β-relaxation in water and impact on the dynamics of aqueous mixtures and hydrated biomolecules, file e0d6c92e-5c02-fcf8-e053-d805fe0aa794
|
7
|
|
Direct Experimental Characterization of Contributions from Self-Motion of Hydrogen and from Interatomic Motion of Heavy Atoms to Protein Anharmonicity, file e0d6c92e-722b-fcf8-e053-d805fe0aa794
|
7
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|
Including Plastic Strain Into the Discrete Preisach-Mayergoyz Space: Application to Granular Media, file e0d6c92e-80f6-fcf8-e053-d805fe0aa794
|
7
|
|
Vibrational dynamics changes of protein hydration water across the dynamic transition, file e0d6c926-c65b-fcf8-e053-d805fe0aa794
|
6
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|
Broadband local dielectric spectroscopy, file e0d6c928-bd99-fcf8-e053-d805fe0aa794
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6
|
|
Sub-Rouse modes in polymer thin films: Coupling to density and responding to physical aging, file e0d6c928-bda7-fcf8-e053-d805fe0aa794
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6
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Molecular relaxations in amorphous phenylbutazone, file e0d6c928-bdac-fcf8-e053-d805fe0aa794
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6
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Relaxation dynamics of amorphous dibucaine using dielectric studies, file e0d6c929-2f62-fcf8-e053-d805fe0aa794
|
6
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Dielectric behaviour versus temperature of a monoepoxide, file e0d6c926-3c97-fcf8-e053-d805fe0aa794
|
5
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The Dynamics of Hydrated Proteins Are the Same as Those of Highly Asymmetric Mixtures of Two Glass-Formers, file e0d6c930-0808-fcf8-e053-d805fe0aa794
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5
|
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Applications of the rheo-dielectric technique, file e0d6c925-f359-fcf8-e053-d805fe0aa794
|
4
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High-pressure cell for simultaneous dielectric and neutron spectroscopy, file e0d6c92a-b8a3-fcf8-e053-d805fe0aa794
|
4
|
|
A semi-empirical approach to model pressure dependence of elastic moduli in granular media accounting for variations of coordination-number and Poisson-ratio, file e0d6c92e-80f4-fcf8-e053-d805fe0aa794
|
4
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Comment on "A molecular dynamics simulation study of relaxation processes in the dynamical fast component of miscible polymer blends", file e0d6c925-f569-fcf8-e053-d805fe0aa794
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3
|
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Polarization fluctuations in an epoxy system above and below the glass transition, file e0d6c925-f89a-fcf8-e053-d805fe0aa794
|
3
|
|
Surface diffusion of polymer glasses redux, file e0d6c928-bc5a-fcf8-e053-d805fe0aa794
|
3
|
|
Direct Evidence of Relaxation Anisotropy Resolved by High Pressure in a Rigid and Planar Glass Former, file e0d6c929-ac4c-fcf8-e053-d805fe0aa794
|
3
|
|
Direct Evidence of Relaxation Anisotropy Resolved by High Pressure in a Rigid and Planar Glass Former, file e0d6c929-e92b-fcf8-e053-d805fe0aa794
|
3
|
|
Predicting the Pressure Dependence of Elastic Velocities of Dry Granular Assemblies Using a Modified GCT Model, file e0d6c929-f97b-fcf8-e053-d805fe0aa794
|
3
|
|
Relations of pressure and temperature dependences of the Johari-Goldstein β -relaxation to the α-relaxation: Amorphous polymers, file e0d6c92b-f89d-fcf8-e053-d805fe0aa794
|
3
|
|
Isochronal superposition and density scaling of the α -relaxation from pico- to millisecond, file e0d6c92c-065e-fcf8-e053-d805fe0aa794
|
3
|
|
Non-local cooperative atomic motions that govern dissipation in amorphous tantala unveiled by dynamical mechanical spectroscopy, file e0d6c92f-9493-fcf8-e053-d805fe0aa794
|
3
|
|
Experimental evidence of mosaic structure in strongly supercooled molecular liquids, file e0d6c931-d2d5-fcf8-e053-d805fe0aa794
|
3
|
|
What can we learn by squeezing a liquid?, file e0d6c925-f9cb-fcf8-e053-d805fe0aa794
|
2
|
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Relationship between structural and secondary relaxation in glass formers: Ratio between glass transition temperature and activation energy, file e0d6c926-2dca-fcf8-e053-d805fe0aa794
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2
|
|
null, file e0d6c926-d2a3-fcf8-e053-d805fe0aa794
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2
|
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Critical structural fluctuations of proteins upon thermal unfolding challenge the Lindemann criterion, file e0d6c92a-08db-fcf8-e053-d805fe0aa794
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2
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|
Strain Accumulation Mechanisms in Unconsolidated Sediments during Compression, file e0d6c92c-f941-fcf8-e053-d805fe0aa794
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2
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|
Mixtures of m-fluoroaniline with apolar aromatic molecules: Phase behaviour, suppression of H-bonded clusters, and local H-bond relaxation dynamics, file e0d6c92e-4d28-fcf8-e053-d805fe0aa794
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2
|
|
Coincident correlation between vibrational dynamics and primary relaxation of polymers with strong or weak johari-goldstein relaxation, file e0d6c92f-e7db-fcf8-e053-d805fe0aa794
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2
|
|
Lateral resolution of electrostatic force microscopy for mapping of dielectric interfaces in ambient conditions, file e0d6c930-04f3-fcf8-e053-d805fe0aa794
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2
|
|
Molecular dynamic in binary mixtures and polymer blends with large difference in glass transition temperatures of the two components: A critical review, file e0d6c931-c844-fcf8-e053-d805fe0aa794
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2
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A new solution for UHDP and UHDR (Flash) measurements: Theory and conceptual design of ALLS chamber, file 158eb19e-6f63-4d80-aef7-d79bb9d1bb64
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1
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A new calculation method for the free electron fraction of an ionization chamber in the ultra-high-dose-per-pulse regimen, file 17b79f25-7123-4043-a66d-5dab5b938c43
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1
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Arriving at the most plausible interpretation of the dielectric spectra of glycerol with help from quasielastic gamma-ray scattering time-domain interferometry, file 285e7708-db36-428f-8c95-768012b0df90
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1
|
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Fast differential scanning calorimetry: new solutions in data treatment and applications to molecular glass-formers, file 72ac2670-577b-49f2-a6fa-04c82ffc819a
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1
|
|
Comment on "A Generalized Rouse Incoherent Scattering Function for Chain Dynamics of Unentangled Polymers in Dynamically Asymmetric Blends", file e0d6c926-403c-fcf8-e053-d805fe0aa794
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1
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|
Nature of the water specific relaxation in hydrated proteins and aqueous mixtures, file e0d6c926-403e-fcf8-e053-d805fe0aa794
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1
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Temperature Dependence of the Structural Relaxation Time in Equilibrium below the NominalTg: Results from Freestanding Polymer Films, file e0d6c926-4040-fcf8-e053-d805fe0aa794
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1
|
|
Origins of the two simultaneous mechanisms causing glass transition temperature reductions in high molecular weight freestanding polymer films, file e0d6c926-4042-fcf8-e053-d805fe0aa794
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1
|
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Change of caged dynamics at T-g in hydrated proteins: Trend of mean squared displacements after correcting for the methyl-group rotation contribution, file e0d6c926-4ae8-fcf8-e053-d805fe0aa794
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1
|
|
Response to "Comment on 'Unified explanation of the anomalous dynamic properties of highly asymmetric polymer blends' " [J. Chem. Phys. 138, 197101 (2013)], file e0d6c926-4ae9-fcf8-e053-d805fe0aa794
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1
|
|
An explanation of the differences in diffusivity of the components of the metallic glass Pd43Cu27Ni10P20, file e0d6c926-4aea-fcf8-e053-d805fe0aa794
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1
|
|
Unified explanation of the anomalous dynamic properties of highly asymmetric polymer blends, file e0d6c926-4aeb-fcf8-e053-d805fe0aa794
|
1
|
|
Coupling of Caged Molecule Dynamics to JG β-Relaxation: I, file e0d6c926-c571-fcf8-e053-d805fe0aa794
|
1
|
|
Coupling of Caged Molecule Dynamics to JG β-Relaxation II: Polymers, file e0d6c926-c5ae-fcf8-e053-d805fe0aa794
|
1
|
|
Coupling of Caged Molecule Dynamics to JG β-Relaxation III: Van der Waals Glasses, file e0d6c926-c8bf-fcf8-e053-d805fe0aa794
|
1
|
|
Surface diffusion of polymer glasses redux, file e0d6c928-bc59-fcf8-e053-d805fe0aa794
|
1
|
|
Dynamics of hydrated proteins and bio-protectants: Caged dynamics, β-relaxation, and α-relaxation, file e0d6c928-bc6f-fcf8-e053-d805fe0aa794
|
1
|
|
Recent developments in the experimental investigations of relaxations in pharmaceuticals by Dielectric Spectroscopy and High Pressure techniques, file e0d6c928-c5e5-fcf8-e053-d805fe0aa794
|
1
|
|
Probing the Thermal Stability of Lysozyme in Crowded Environments: Tracking Lindemann Criterion, file e0d6c928-c668-fcf8-e053-d805fe0aa794
|
1
|
|
Critical structural fluctuations of proteins upon thermal unfolding challenge the Lindemann criterion, file e0d6c929-eaed-fcf8-e053-d805fe0aa794
|
1
|
|
Direct Experimental Characterization of Contributions from Self-Motion of Hydrogen and from Interatomic Motion of Heavy Atoms to Protein Anharmonicity, file e0d6c92c-4bfc-fcf8-e053-d805fe0aa794
|
1
|
|
Direct Experimental Characterization of Contributions from Self-Motion of Hydrogen and from Interatomic Motion of Heavy Atoms to Protein Anharmonicity, file e0d6c92c-56dc-fcf8-e053-d805fe0aa794
|
1
|
|
Including plastic behaviour in the Preisach-Mayergoyz space to find static and dynamic bulk moduli in granular media, file e0d6c92d-1ea5-fcf8-e053-d805fe0aa794
|
1
|
|
How to align a nematic glassy phase – Different conditions – Different results, file e0d6c92e-27ff-fcf8-e053-d805fe0aa794
|
1
|
|
Strain-accumulation mechanisms in sands under isotropic stress, file e0d6c92e-3147-fcf8-e053-d805fe0aa794
|
1
|
|
Segmental α-Relaxation for the First Step and Sub-Rouse Modes for the Second Step in Enthalpy Recovery in the Glassy State of Polystyrene, file e0d6c92e-4d21-fcf8-e053-d805fe0aa794
|
1
|
|
Complex Dynamics of a Fluorinated Vinylidene Cyanide Copolymer Highlighted by Dielectric Relaxation Spectroscopy, file e0d6c92e-7227-fcf8-e053-d805fe0aa794
|
1
|
|
A semi-empirical approach to model pressure dependence of elastic moduli in granular media accounting for variations of coordination-number and Poisson-ratio, file e0d6c92e-88d2-fcf8-e053-d805fe0aa794
|
1
|
|
Absolutely necessary to consider the caged dynamics and the JGX β-relaxation in solving the glass transition problem, file e0d6c92e-94a5-fcf8-e053-d805fe0aa794
|
1
|
|
Lateral resolution of electrostatic force microscopy for mapping of dielectric interfaces in ambient conditions, file e0d6c930-0f5e-fcf8-e053-d805fe0aa794
|
1
|
| Totale |
1.972 |