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![Page 1: “Physics of Glasses, Amorphous Solids and Disordered Crystals” Prof. Miguel Angel Ramos PROGRAMME 1. INTRODUCTION TO NON-CRYSTALLINE SOLIDS Introduction.](https://reader034.fdocuments.in/reader034/viewer/2022051211/551c148a550346a34f8b558b/html5/thumbnails/1.jpg)
“Physics of Glasses, Amorphous Solids and Disordered Crystals”
Prof. Miguel Angel Ramos
PROGRAMME 1. INTRODUCTION TO NON-CRYSTALLINE SOLIDS Introduction. Definitions. Types of disorder. Amorphous solids and glasses. 2. PREPARATION METHODS AND APPLICATIONS OF AMORPHOUS MATERIALS Melt quenching. Melt spinning. Splat cooling. Thermal evaporation. Chemical vapour deposition. Sol-gel processes. Irradiation. Pressure-induced amorphization. Applications of amorphous materials.
3. THE GLASS STATE AND THE GLASS TRANSITION a) The glass transition phenomenon: Thermodynamic and kinetic aspects. Is the glass transition a true thermodynamic phase transition? The Kauzmann paradox. The Angell’s classification: Strong and fragile glass-forming liquids. Relaxation processes in glasses and supercooled liquids.b) Old and current theories for the glass transition. The energy landscape. 4. STRUCTURE OF AMORPHOUS SOLIDS The Zachariasen model of Continuous Random Network. Experimental techniques: X-ray and neutron diffraction. The radial distribution function. Short-range and intermediate-range order. The First Sharp Diffraction Peak.
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“Physics of Glasses, Amorphous Solids and Disordered Crystals”
Prof. Miguel Angel Ramos
PROGRAMME 5. ATOMIC DYNAMICS IN AMORPHOUS SOLIDS Consequences of the lack of long-range order. Experimental techniques: Raman, Infrared and Brillouin spectroscopies. Inelastic neutron and X-ray scattering. The “boson peak”. Computational methods and molecular dynamics simulations. 6. LOW-TEMPERATURE PROPERTIES OF NON-CRYSTALLINE SOLIDS Universal “glassy anomalies” at low temperatures. Specific heat. Thermal conductivity. Acoustic and dielectric properties. The Tunnelling Model. The Soft Potential Model. 7. OTHER FAMILIES OF GLASSES AND DISORDERED CRYSTALS Quasicrystals. Plastic crystals and orientational glasses. Biomolecules and “Soft Matter”.
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BIBLIOGRAPHY
Fundamental textbooks: S. R. Elliott, Physics of Amorphous Materials, 2nd ed. (Longman, 1990). R. Zallen, The Physics of Amorphous Solids, (Wiley, 1983). I. Gutzow, J. Schmelzer, The Vitreous State (Springer, 1995). S. A. Brawer, Relaxation in viscous liquids and glasses (Am. Ceram. Soc., 1983). W. A. Phillips (ed.), Amorphous Solids: Low Temperature Properties (Topics in Current Physics, Vol. 24, Springer, 1981). Specialized review articles and books: Science 267 (1995), pp. 1924-1953. P. G. Debenedetti and F. H. Stillinger, Nature 410, 259 (2001). P. Esquinazi (ed.), Tunneling Systems in Amorphous and Crystalline Solids (Springer, 1998). A. Cavagna, Physics Reports 476, 51-124 (2009).
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1. INTRODUCTION TO NON-CRYSTALLINE SOLIDS
* What is a solid ?
A substance that does not flow, that is, its viscosity is:
1013 - 1014 poise
Maxwell equation for shear relaxation time:
= G
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Types of disorder:
Topological disorder Spin disorder
Vibrational disorderSubstitutional disorder
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CRYSTAL AMORPHOUS
solidity crystallinity !
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= G
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Differential Scanning Calorimetry
Differential Thermal Analysis
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nucleation rate
rate of crystal growth
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v = L (Tm-T) / 3a2Tm
velocity of crystallization:
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DEFINITIONS:
AMORPHOUS SOLIDS NON-CRYSTALLINE SOLIDS
are solid materials that do NOT possess the long-range
order (periodicity) characteristic of crystals.
GLASSES are amorphous solids obtained by cooling a melt.
Or, more generally, amorphous solids that exhibit a
glass transition when heated.
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DEFINITIONS and CLASSIFICATIONS
Perfect crystal: solid for which the atoms (or groups of atoms) exhibit a perfect periodicity towards the infinity. –i.e. long-range translational order
Disordered solids
NON-CRYSTALLINE SOLIDS = AMORPHOUS SOLIDSSolids which do not possess long-range translational order
GLASSES: amorphous solids exhibiting
a “glass transition”
Cuasicrystals = aperiodic crystals (“ordered in 6-D”)
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Preparation methods of amorphous materials
Melt quenching Splat cooling Melt spinning Thermal evaporation Sputtering Glow-discharge decomposition Chemical vapor deposition Sol-gel processes Electrolytic deposition Reaction amorphization Irradiation Pressure-induced amorphization Solid-state diffusional amorphization
2. PREPARATION METHODS AND APPLICATIONS OF AMORPHOUS MATERIALS
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melt quenching splat cooling thermal evaporation
melt spinning
~ 10-3 K/s ~ 102 K/s ~ 105 K/s ~ 1010 K/s
~ 107 K/s
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thermal evaporation
sputtering
glow-discharge decomposition
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sol-gelprocesses
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Preparation methods of amorphous materials
Melt quenching Splat cooling Melt spinning Thermal evaporation Sputtering Glow-discharge decomposition Chemical vapor deposition Sol-gel processes Electrolytic deposition Reaction amorphization Irradiation Pressure-induced amorphization Solid-state diffusional amorphization
2. PREPARATION METHODS AND APPLICATIONS OF AMORPHOUS MATERIALS
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APPLICATIONS OF AMORPHOUS SOLIDS
Type of amorphous solid
Representative material
Application Special properties used
Oxide glass (SiO2)1-x(Na2O)x
+ Other oxidesWindow glassArtistic, commercial, chemical glassware…
Transparency, solidity, formability as large sheets
Oxide glass (SiO2)1-x(Ge2O)x Fiber optic waveguides for communication networks
Ultratransparency, purity, formation as uniform fibers
Organic polymer Polystyrene, PVC, PMMA..
Structural materials, plastics
Strength, light weight, ease of processing
Amorphous semiconductor
Te0.8Ge0.2 Computer-memory elements
Electric-field induced amcryst transformations
Amorphous semiconductor
Si0.9H0.1 Solar cells Photovoltaic optical propt. Large-area thin films
Metallic glass Fe0.8B0.2 Transformer cores Ferromagnetism, low losses formation as long ribbons
Chalcogenide (S, Se, Te) glasses
Se, As2Se3 Xerography Photoconductivity, formability as large-area films
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APPLICATIONS OF AMORPHOUS SOLIDS
Type of amorphous solid
Representative material
Application Special properties used
Oxide glass (SiO2)1-x(Na2O)x
+ Other oxidesWindow glassArtistic, commercial, chemical glassware…
Transparency, solidity, formability as large sheets
(the most familiar format of glasses)
It exemplifies 2 general aspects common to many applications of a-solids:
1) These materials harden continuously with decreasing T approaching Tg
ability to control the viscosity and thereby the flow properties
2) Glasses much better than crystals when an application demands large-area sheets or films
In addition, for window-glass like applications:
1)The glass is optically ISOTROPIC while the crystal is anisotropic
2) The glass is a far better thermal insulator, and a window should keep heat and cold out as well as let light in!
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APPLICATIONS OF AMORPHOUS SOLIDS
Type of amorphous solid
Representative material
Application Special properties used
Oxide glass (SiO2)1-x(Ge2O)x Fiber optic waveguides for communication networks
Ultratransparency, purity, formation as uniform fibers
They are glass-wires transmitting an optical signal (EM wave, 21014 Hz) with extremely low losses
CLAD
CLAD
CORE
nCLAD < nCORE
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APPLICATIONS OF AMORPHOUS SOLIDS
Type of amorphous solid
Representative material
Application Special properties used
Organic polymer Polystyrene, PVC, PMMA..
Structural materials, plastics
Strength, light weight, ease of processing
The most ubiquitous amorphous solids in present-day society are organic glasses: polymeric (amorphous) solids composed of entangled long-chain organic molecules
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APPLICATIONS OF AMORPHOUS SOLIDS
Type of amorphous solid
Representative material
Application Special properties used
Amorphous semiconductor
Te0.8Ge0.2 Computer-memory elements
Electric-field induced amcryst transformations
It exploits the phenomenon of electric-field induced crystallization of the glass.
Both crystalline and amorphous forms of Te-Ge are semiconductors, but with different energy gaps. A current pulse converts the low-conductivity glass to a high-conductivity crystal
( it pulses the material from OFF to ON state!).
The crystal-glass transition is reversible.
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APPLICATIONS OF AMORPHOUS SOLIDS
Type of amorphous solid
Representative material
Application Special properties used
Amorphous semiconductor
Si0.9H0.1 Solar cells Photovoltaic optical propt. Large-area thin films
a-Si can be prepared in large-area films much cheaper than c-Si. Because of disorder, a-Si has a much higher optical absorption than c-Si.
In fact, it is not pure a-Si the material of interest for solar-cell technology applications but rather the hydogenated [a-Si:H]. The role of H is to eliminate electronic defects.
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APPLICATIONS OF AMORPHOUS SOLIDS
Type of amorphous solid
Representative material
Application Special properties used
Metallic glass Fe0.8B0.2 Transformer cores Ferromagnetism, low losses formation as long ribbons
They combine high saturation magnetization with the useful property of being “magnetically soft” (i.e. low coercivity, easily magnetized by small magnetic fields), at the same time they remain mechanically quite hard!
Magnetic glasses are isotropic, without a crystalline axis of easy magnetization allows to rotate the magnetization direction at a much smaller energy cost than in crystals.
Other potential applications: magnetic disks memories, read/write recorder heads…
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APPLICATIONS OF AMORPHOUS SOLIDS
Type of amorphous solid
Representative material
Application Special properties used
Chalcogenide (S, Se, Te) glasses
Se, As2Se3 Xerography Photoconductivity, formability as large-area films
![Page 29: “Physics of Glasses, Amorphous Solids and Disordered Crystals” Prof. Miguel Angel Ramos PROGRAMME 1. INTRODUCTION TO NON-CRYSTALLINE SOLIDS Introduction.](https://reader034.fdocuments.in/reader034/viewer/2022051211/551c148a550346a34f8b558b/html5/thumbnails/29.jpg)
xerography