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Lecture 6.0 Properties of Dielectrics
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Dielectric use in Silicon Chips Capacitors –On chip –On Circuit Board Insulators –Transistor gate –Interconnects Materials –Oxides –SiO 2 –Boro-Silicate Glass –Nitrides –BN –polymers
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Importance of Dielectrics to Silicon Chips Size of devices –Electron Tunneling dimension Chip Cooling- Device Density –Heat Capacity –Thermal Conductivity Chip Speed –Capacitance in RC interconnects
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Band theory of Dielectrics Forbidden Zone–Energy Gap-LARGE Valence Band Conduction Band
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Difference between Semiconductors and Dielectrics MaterialE g (eV) Ge0.67 Si1.12 GaAs1.43 SiO 2 8 UO 2 5.2 Ga 2 O 3 4.6 Fe 2 O 3 3.1 ZnO3.2 NiO4.2 Al 2 O 3 8 k B T =0.0257 eV at 298˚K
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Fermi-Dirac Probability Distribution for electron energy, E Probability, F(E)= (e {[E-E f ]/k B T} +1) -1 –E f is the Fermi Energy
![Fermi-Dirac Probability Distribution for electron energy, E Probability, F(E)= (e {[E-E f ]/k B T} +1) -1 –E f is the Fermi Energy](http://images.slideplayer.com/15/4661529/slides/slide_6.jpg "Fermi-Dirac Probability Distribution for electron energy, E Probability, F(E)= (e {[E-E f ]/k B T} +1) -1 –E f is the Fermi Energy")
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Number of Occupied States Fermi-Dirac Density of States T>1000K only
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Probability of electrons in Conduction Band Lowest Energy in CB E-E f E g /2 Probability in CB F(E)= (exp{[E-E f ]/k B T} +1) -1 ) = (exp{E g /2k B T} +1) -1 exp{-E g /2k B T} for E g >1 eV @ 298K exp{-(4eV)/2k B T}= exp{-100} @ 298K k B T =0.0257 eV at 298˚K
![Probability of electrons in Conduction Band Lowest Energy in CB E-E f E g /2 Probability in CB F(E)= (exp{[E-E f ]/k B T} +1) -1 ) = (exp{E g /2k B T} +1) -1 exp{-E g /2k B T} for E g >1 298K exp{-(4eV)/2k B T}= 298K k B T = eV at 298˚K](http://images.slideplayer.com/15/4661529/slides/slide_8.jpg "Probability of electrons in Conduction Band Lowest Energy in CB E-E f E g /2 Probability in CB F(E)= (exp{[E-E f ]/k B T} +1) -1 ) = (exp{E g /2k B T} +1) -1 exp{-E g /2k B T} for E g >1 298K exp{-(4eV)/2k B T}= 298K k B T = eV at 298˚K")
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Intrinsic Conductivity of Dielectric Charge Carriers –Electrons –Holes –Ions, M +i, O -2 = n e e e + n h e h # electrons = # holes – n e e ( e + h ) –n e C exp{-E g /2k B T}
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Non-Stoichiometric Dielectrics Metal Excess M 1+x O Metal with Multiple valence Metal Deficiency M 1-x O Metal with Multiple valence Reaction Equilibrium K eq (P O2 ) ±x/2 +4 +2 +3
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Density Changes with Po 2 SrTi 1-x O 3
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Non-Stoichiometric Dielectrics Excess M 1+x O Deficient M 1-x O
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Non-Stoichiometric Dielectrics K i =[h+][e-] K” F =[O” i ][V” O ] Conductivity =f(Po 2 ) Density =f(Po 2 )
![Non-Stoichiometric Dielectrics K i =[h+][e-] K F =[O i ][V O ] Conductivity =f(Po 2 ) Density =f(Po 2 )](http://images.slideplayer.com/15/4661529/slides/slide_13.jpg "Non-Stoichiometric Dielectrics K i =[h+][e-] K F =[O i ][V O ] Conductivity =f(Po 2 ) Density =f(Po 2 )")
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Dielectric Conduction due to Non-stoichiometry N-type P-type
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Dielectric Intrinsic Conduction due to Non-stoichiometry N-type P-type Excess Zn 1+x O Deficient Cu 2-x O + h
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Extrinsic Conductivity Donor Doping Acceptor Doping n-type p-type E d = -m* e e 4 /(8 ( o ) 2 h 2 ) E f =E g -E d /2 E f =E g +E a /2
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Extrinsic Conductivity of Non-stoichiometry oxides Acceptor Doping p-type p= 2(2 m* h k B T/h 2 ) 3/2 exp(-E f /k B T) Law of Mass Action, N i p i =n d p d or =n n d n @ 10 atom % Li in NiO conductivity increases by 8 orders of magnitude @ 10 atom % Cr in NiO no change in conductivity
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Capacitance C= o A/d =C/C o =1+ e e = electric susceptibility
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Polarization P = e E e = atomic polarizability Induced polarization P=(N/V)q
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Polar regions align with E field P=(N/V) E loc i (N i /V) i =3 o ( -1)/( +2)
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Local E Field Local Electric Field E loc =E’ + E E’ = due to surrounding dipoles E loc =(1/3)( +2)E
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Ionic Polarization P=P e +P i P e = electronic P i = ionic P i =(N/V)eA
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Thermal vibrations prevent alignment with E field
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Polar region follows E field opt = (Vel/c) 2 opt = n 2 n=Refractive index
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Dielectric Constant Material ( = 0) opt =n 2 Diamond5.685.66 NaCl5.902.34 LiCl11.952.78 TiO 2 946.8 Quartz(SiO 2 )3.852.13
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Resonant Absorption/dipole relaxation Dielectric Constant imaginary number ’ real part dielectric storage ” imaginary part dielectric loss o natural frequency
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Dipole Relaxation Resonant frequency, o Relaxation time,
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Relaxation Time,
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Dielectric Constant vs. Frequency
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Avalanche Breakdown
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Like nuclear fission
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