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Materials Properties Electrical properties Magnetic properties Optical properties.

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Presentation on theme: "Materials Properties Electrical properties Magnetic properties Optical properties."— Presentation transcript:

1 Materials Properties Electrical properties Magnetic properties Optical properties

2 Electrical properties Ohm’s law Resistance, resistivity, conductivity Matthiessen’s rule

3 Electrical resistivity

4 Energy bands K LM discrete energy levels (Pauli exclusion principle) splitting into energy bands (N=12)

5 Electron Band Structures metal (e.g. Cu) energy valence band gap conduction band metal (e.g. Mg) EFEF EFEF isolators (E gap >2eV) semiconductors E gap

6 Conductors EFEF

7 Semiconductors (intrinsic) band gap

8 n-type Extrinsic Semiconductor

9 p-type Extrinsic Semiconductor

10 The p-n Diode reverse bias forward bias

11 Magnetic properties Magnetic field strength, magnetic flux density, magnetization, permeability, and magnetic susceptibility

12 The Magnetic Field vacuum atmosphere/material

13 The Magnetic Moment orbital contribution => m l µ B spin contribution => +/-µ B Bohr magneton: µ B =9.27 x 10 -24 Am²

14 Diamagnetic Materials

15 Paramagnetic Materials

16 Ferromagnetic Materials

17 The B-H Hysteresis remanent flux density coercive force

18 Hard and Soft Magnetic Materials soft: alternating magnetic fields hard: permanent magnets energy product coercivity

19 Magnetic Storage coil: magnetic field in gap magnetic field: induces electric current

20 Optical properties Transmission Refraction Absorption

21 Electro magnetic waves electric field E magnetic field H (perpendicular to E) light = electromagnetic wave wave: c= ln (const. light velocity in vacuum= 300,000 km/s) photons: E=h n (Planck constant, 6.63 x 10 -34 J/s)

22 Light Interaction with Solid I 0 =I transmitted +I absorbed +I reflected transparent translucent opaque heat reflection (metals): absorption (electrons excitation by D E) => re-emission of photons color (e.g. Au, Cu => only partial re-emission) refraction: transmission into transparent material => decrease in v (n=c/v), bending at interface

23 Absorption I reflected IoIo x (transparent medium) I transmitted I absorbed I transmitted =I 0 (1-R) 2 exp(- b x) absorption coefficient reflectivity

24 Photon Absorption in a (Semiconducting) Solid 1. hole/electron pair generation E gap,max =hc/ l min (>3.1eV no visible light absorption=transparent) E gap,min ( l max,visible =700nm) (<1.8eV all visible light absorbed=opaque) 2. hole/electron pair generation in between colored!! e.g. red ruby Al 2 O 3 with Cr 2 O 3 impurity level in the band gap

25 Light Transmission in Al 2 O 3 single crystal: transparent poly-crystal: translucent with 5% pores: opaque internal reflection/refraction at grain/phase boundaries – pores polymers: scattering at boundaries betw. crystalline/amorphous regions

26 Effects/Applications luminescence absorbing energy => re-emitting visible light (1.8eV<hv<3.1eV) fluorescence (<1s) phosphorescence (>1s) e.g. TV (fluoresc. coating) LED (forward bias diode – recombination=> light) photoconductivity illumination => generation of charge carriers e.g. light meters, solar cells optical fibres 1/0 impulses – high information density 24000 telephone calls by two wires e.g. 30000kg Cu corresp. to 0.1kg high-purified SiO 2 glass

27 Laser Concepts 1.Xe flash lamp excite electrons from Cr 3+ ions 2.large number of electrons falls back to intermediate state 3.after approx. 3ms: spontaneous emission – triggers avalanche of emissions 4.photons parallel to the rod are transmitted to the semi-silvered end (light amplification by stimulated emission of radiation) monochromatic, high-intensity coherent red beam

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