Structure of Amorphous Materials

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Presentation transcript:

Structure of Amorphous Materials Crystalline vs. amorphous materials Free volume and the glass transition Radial distribution function, short range order and structure factor Voronoi polyhehra Medium-range order and nanocrystalline materials 1

Crystalline vs. amorphous There is long-range order (LRO)in crystals - a unit repeats itself and fills the space There is no LRO in amorphous materials 1

Free volume and the glass transition Free volume = specific volume (volume per unit mass) - specific volume of the corresponding crystal At the glass transition temperature, Tg, the free volume increases leading to atomic mobility and liquid-like behavior. Below the glass transition temperature atoms (ions) are not mobile and the material behaves like solid 1

Glass transition Within the free volume theory it is understood that with large enough free volume mobility is high, viscosity is low. When the temperature is decreased free volume becomes “critically” small and the system “jams up” The glass transition is not first order transition (such as melting), meaning there is no discontinuity in the thermodynamic functions (energy, entropy, density). Typically Tg is ~ 50-60% of the melting point The effective glass transition temperature, is a function of cooling rate - higher rate  higher Tg. It is also called the fictive temperature Sometimes the glass transition it is a first order transition, most prominently in Si where the structure changes from 4 coordinated amorphous solid to to ~ six coordinated liquid. The same applies to water (amorphous ice) 1

Characterizing the structure - radial distribution function, also called pair distribution function Gas, amorphous/liquid and crystal structures have very different radial distribution function 1

Radial distribution function - definition dr r Carve a shell of size r and r + dr around a center of an atom. The volume of the shell is dv=4r2dr Count number of atoms with centers within the shell (dn) Average over all atoms in the system Divide by the average atomic density <>

Properties of the radial distribution function For gases, liquids and amorphous solids g(r) becomes unity for large enough r. The distance over which g(r) becomes unity is called the correlation distance which is a measure of the extent of so-called short range order (SRO) The first peak corresponds to an average nearest neighbor distance Features in g(r) for liquids and amorphous solids are due to packing (exclude volume) and possibly bonding characteristics 1

Radial Distribution Function - Crystal and Liquid Liquid/amorphous g(r), for large r exhibit oscillatory exponential decay Crystal g(r) does not exhibit an exponential decay (  ∞)

Radial distribution functions and the structure factor The structure factor, S(k), which can be measured experimentally (e.g. by X-rays) is given by the Fourier transform of the radial distribution function and vice versa Radial distribution functions can be obtained from experiment and compared with that from the structural model

More detailed structural characterization - Voronoi Polyhedra Draw lines between a center of an atom and nearby atoms. Construct planes bisecting the lines perpendicularly The sets of planes the closest to the central atom forms a convex polyhedron Perform the statistical analysis of such constructed polyhedrons, most notably evaluate an average number of faces For no-directional bonding promoting packing number of faces is large ~ 13-14 (metallic glasses) For directional bonding (covalent glasses) number of faces is small Ionic glasses - intermediate In all cases the number of faces is closely related to the number of nearest neighbors (the coordination number)

Medium range order and radial distribution function Radial distribution functions (and also X-ray) of amorphous silicon and model Si with ~ 2 nm crystalline grains are essentially the same - medium range order difficult to see by standard characterization tools. Such structure is called a paracrystal.

Radial Distribution Function Sensitive enough to see medium range order and crystal size Behavior of g(r), for large r clearly shows differences for CRN and paracrystal models, and also provide a measure of paracrystal size

Radial Distribution Function Nanocrystalline material Nanocrystalline materials shows clear crystalline peaks with some background coming from the grain boundary