CH-4: Imperfections in Solids So far we have seen perfect crystals: X-ray diffraction and Bragg’s law Imperfections or defects are covered in ch-4. Defects.

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CH-4: Imperfections in Solids
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Presentation transcript:

CH-4: Imperfections in Solids So far we have seen perfect crystals: X-ray diffraction and Bragg’s law Imperfections or defects are covered in ch-4. Defects in crystals make them interesting 2 major types of defects: Chemical – Impurities or Alloying elements Atomic arrangement- Structure Real materials are not perfect Good Chemical Imperfections: dopants & alloying element Atomic arrangements: missing atom, extra atom, differently oriented unit cells, etc…

Why STUDY Imperfections in Solids? Many of the important properties of materials are due to the presence of imperfections. Pure metals experience significant alterations when alloyed: Sterling silver: 92.5% Ag & 7.5% Cu. Cartridge brass: 70% Cu & 30% Zn. Impurities play important roles in semiconductors.semiconductors Steel (composition ) and (making)compositionmaking Atomic defects are responsible for reducing gas pollutant emissions in automobiles: Molecules of pollutant gases become attached to surface defects of crystalline metallic materials ((Ce 0.5 Zr 0.5 )O 2 ) in the catalytic converter. While attached to these sites, chemical reactions convert them into other non- or less-polluting substances.

Catalyst: (Ce 0.5 Zr 0.5 )O 2 High-resolution transmission electron micrograph of single crystal (Ce 0.5 Zr 0.5 )O 2, which is used in Catalytic Converters. Catalytic Converters Catalyst is a substance that speeds up the rate of a chemical reaction without participating in the reaction itself. Catalyst adsorbs on its surface gas pollutants (CO and NO X ) and molecules of unburned hydrocarbons, which are converted to CO 2 and H 2 O.adsorbs Schematic representation of surface defects that are potential adsorption sites for catalysts.

talytic-converter2.htm In the catalytic converter, there are two different types of catalyst at work, a reduction catalyst and an oxidation catalyst. Both types consist of a ceramic structure coated with a metal catalyst, usually platinum, rhodium and/or palladium. The idea is to create a structure that exposes the maximum surface area of catalyst to the exhaust stream, while also minimizing the amount of catalyst required, as the materials are extremely expensive. The catalyst used in a catalytic converter is a combination of platinum (Pt), palladium (Pd), and rhodium (Rh). These metals coat a ceramic honeycomb (or ceramic beads) contained within a metal casing that is attached to the exhaust pipe. The catalytic converter’s honeycomb structure provides the maximum surface area on which reactions can take place while using the least amount of catalyst. - See more at: FB.dpuf

5 Catalysts and Surface Defects A catalyst increases the rate of a chemical reaction without being consumed Active sites on catalysts are normally surface defects Fig. 4.10, Callister & Rethwisch 8e. Fig. 4.11, Callister & Rethwisch 8e. Single crystals of (Ce 0.5 Zr 0.5 )O 2 used in an automotive catalytic converter

6 Vacancy atoms Interstitial atoms Substitutional atoms Point defects Types of Imperfections Dislocations Line defects Grain Boundaries Area defects

7 Vacancies: -vacant atomic sites in a structure. Self-Interstitials: -"extra" atoms positioned between atomic sites. Point Defects in Metals Vacancy distortion of planes self- interstitial distortion of planes

 8 Boltzmann's constant (1.38 x J/atom-K) (8.62 x eV/atom-K) N v N  exp  Q v kT      No. of defects No. of potential defect sites Activation energy Temperature Each lattice site is a potential vacancy site Equilibrium concentration varies with temperature! Equilibrium Concentration: Point Defects

9 We can get Q v from an experiment.   N v N = exp  Q v kT      Measuring Activation Energy Measure this... N v N T exponential dependence! defect concentration Replot it... 1/T N N v ln - Q v /k/k slope

10 Find the equil. # of vacancies in 1 m 3 of Cu at 1000  C. Given: A Cu = 63.5 g/mol  = 8.4 g/cm 3 Q v = 0.9 eV/atom N A = 6.02 x atoms/mol Estimating Vacancy Concentration For 1 m 3, N = N A A Cu  x x1 m 3 = 8.0 x sites = 2.7 x x eV/atom-K 0.9 eV/atom 1273 K  N v N  exp  Q v kT       Answer: N v =(2.7 x )(8.0 x ) sites = 2.2 x vacancies

Impurities in Solids A pure metal consisting of only one type of atom just isn’t possible. Even with sophisticated techniques, it is difficult to refine metals to a purity in excess of %. Very few metals are used in the pure or nearly pure state: 1. Electronic wires % purity Cu; Very high electrical conductivity % purity Al (super-pure Al) is used for decorative purposes-- Very bright metallic surface finish. Most engineering metals are combined with other metals or nonmetals to provide increased strength, higher corrosion resistance, etc. 1.Cartridge brass: 70% Cu & 30% Zn. 2.Sterling silver: 92.5% Ag & 7.5% Cu. 3.Inconel 718, Ni-base super-alloy, used for jet engine parts, has 10 elements.

Solid Solutions Simplest type of alloy is that of solid solution. Two types: 1. Substitution Solid Solution 2. Interstitial Solid Solution.

13 Conditions for Solid Solubility Conditions for substitutional solid solution (S.S.) W. Hume – Rothery rule – 1.  r (atomic radius) < 15% – 2. Proximity in periodic table i.e., similar electronegativities – 3. Same crystal structure for pure metals – 4. Valency All else being equal, a metal will have a greater tendency to dissolve a metal of higher valency than one of lower valency

14 Application of Hume–Rothery rules – Solid Solutions Table on p. 118, Callister & Rethwisch 8e. ElementAtomicCrystalElectro-Valence Radius Structure nega- (nm) tivity Cu0.1278FCC1.9+2 C0.071 H0.046 O0.060 Ag0.1445FCC1.9+1 Al0.1431FCC1.5+3 Co0.1253HCP1.8+2 Cr0.1249BCC1.6+3 Fe0.1241BCC1.8+2 Ni0.1246FCC1.8+2 Pd0.1376FCC2.2+2 Zn0.1332HCP : Which of these elements would you expect to form the following with copper: (a) A substitutional solid solution having complete solubility (b) A substitutional solid solution of incomplete solubility (c) An interstitial solid solution