V, I, R measurements: how to generate and measure quantities and then how to get data (resistivity, magnetoresistance, Hall). Makariy A.
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1 V, I, R measurements: how to generate and measure quantities and then how to get data (resistivity, magnetoresistance, Hall). 590B Makariy A. Tanatar November 12, 2008 Resistivity Typical resistivity temperature dependence: metals, semiconductors Magnetic scattering
2 Resistivities of Real Materials Material Silver Copper Aluminum Tungsten Platinum Manganin Constantan Nichrome Germanium Glass PET Teflon Resistivity 20 o C 1.59 µω cm 1.72 µω cm 2.82 µω cm 5.8 µω cm 11 µω cm 48 µω cm 49 µω cm 110 µω cm Ω cm Ω cm Ω cm Most semiconductors in their pure form are not good conductors, they need to be doped to become conducting. Not all so called ionic materials like oxides are insulators.
3 We can relate the conductivity, σ, of a material to microscopic parameters that describe the motion of the electrons (or other charge carrying particles such as holes or ions). σ = ne(eτ/m*) µ = e τ /m* σ = ne µ where n = the carrier concentration (cm -3 ) e = the charge of an electron = C τ = the relaxation time (s) {the time between collisions} m* = the effective mass of the electron (kg) µ = the electron mobility (cm 2 /V-s)
4 Metals, Semiconductors & Insulators Insulator Semiconductor Metal Big variation is due to big difference in free carrier density
5 Energy bands in semiconductors Direct-gap III-V II-VI Indirect band-gap Si, Ge
6 Compound Structure Bandgap (ev) e - mobility (cm 2 /V-s) h + mobility (cm 2 /V-s) Si Diamond 1.11 (I) 1, Ge Diamond 0.67 (I) 3,900 1,900 AlP Sphalerite 2.43 (I) GaAs Sphalerite 1.43 (D) 8, InSb Sphalerite 0.18 (D) 100,000 1,700 AlAs Sphalerite 2.16 (I) 1, GaN Wurtzite 3.4 (D)
7 Electron mobility and scattering What scatters carriers? Disruptions in periodicity defects lattice vibrations surfaces
8 Thermal energy some electrons are excited from the valence band into the conduction band conduction electrons This leaves an empty state in the valence band a hole n: density of CE p: density of holes n p = N C N V exp E g k B T Intrinsic semiconductor: electrons and holes form in pairs n i = p i = Conductivity: N C N V exp E g 2k B T σ = n i eµ e + p i eµ h = n i e(µ e + µ h )
9 Carrier density Low T: ionization of dopants n-type: donor atoms donate e to conduction band p-type: acceptor atoms accept e from valence band Intermediate T: all dopants ionized n-type: exhaustion of donors p-type: saturation of acceptors High T: intrinsic behavior
10 Can obtain bandgap for intrinsic region n = p = N C N V exp E g 2k B T Intrinsic If density of dopants N>>n,p Behaves like extrinsic conductor Extrinsic σ = neµ e + peµ h neµ e = N d eµ e
11 Metals ρ ρ = ρ α( T T ) Cu Temperature coefficient of resistivity α reflects electron-phonon interaction, property of material Thermal vibrations scatter carriers mobility conductivity resistivity
12 Effect of impurities on µ ρ = Ac 1 c ( ) i i i A: property of host and impurity c i : atomic fraction of impurity Increasing alloying with Ni
13 Effect of deformation on µ Dislocations (regions of deformed material) scatter carriers, increasing the electrical resistivity by ρ D ρ d ρ i
14 Resistivity temperature dependence of metals closer look High temperature ρ ρ = ρ α( T T ) Θ D T T>>Θ D density of phonons ~T T<Θ D spectrum of phonons changes Bloch-Gruneisen law For most of metals R=R 0 f(t/θ), Θ is close to Debye temperature in specific heat, not the same due to selectivity of scattering
15 xt Θ D After G. T. Meaden Electrical Resistance of Metals ρ ph ~f(q)s ph With some filtering due to q-dependence of Comparison of Θ R and Θ D scattering probability Metal Ag Au Al Cu Pd Pt Rh Θ R
16 q=0 at T=0 Direct electron scattering on phonons at low temperatures does not contribute much to resistivity, electrons can not scatter at large angle due to momentum conservation law The only efficient way: Umklapp processes, scattering with momentum transfer to reciprocal lattice
17 Umklapp processes g q k K k k q k g
18 Electron-electron scattering At low temperatures ρ=ρ 0 +αt n n=5 e-ph Not very efficient in scattering In e-e scattering total momentum is conserved Scattering does not contribute to resistivity Umklapp Electrons from different bands s-d scattering Bands a and b, densities α and β Relaxation times τ a and τ b Mott: τ a and τ b are of the same order of magnitude; αand β can be very different, High probability of scattering into large DOS band n=2 e-e n=3 s-d
19 Kondo effect Dilute magnetic impurities in metals Interaction of conduction electrons with magnetic impurities Characteristic temperature T K (varies a lot! From 0.1mK Mn in Au to 300K V in Au, usually ~10 K) b Specific heat per impurity C~T/TK Impurity spins completely screened at low temperatures
20 Anderson impurity model Peak in DOS Bound to E F additional scattering ρ/ρ 0 =f(t/t K ) universal function of one parameter T K ρ~lnt
21 Magnetic scattering Ce 1-x La x RhIn5 f-electrons are localized Same lattice localized f-electrons add to scattering LaRhIn5 CeRhIn5 ρ mag
22 CeRhIn5 ρ mag ~S mag S mag T N w mag ρ mag ρ mag q-filtering removed: Full scattering directly proportional to entropy
23 Ce 1-x La x CoIn5 Ce 1-x La x RhIn5 Ce 1-x La x IrIn5 Dense lattice: interactions start to build in Suggest two-fluid description Kondo liquid + Kondo gas Dilute impurity ρ~ lnt
24 Density waves Rudolph Peierls "Frisch-Peierls Memorandum" of March 1940, proposing a "super-bomb which utilizes the energy stored in atomic nuclei as a source of energy." 1957 on request of US government removed security clearance, suspected of spying Klaus Fuchs knighted in Distortion with 2K F periodicity Decreases electron energy BCS-like solution =1.75 Tc
25 The Fermi surface of a quasi-1d conductor wo distinct parts at +k F and -k F (here in a cut view). Q nest one part to another by translation.
26 Chain Density waves: increasing dimensionality Layer T2 T 1 T CDW NbSe2 NbSe3 T1=142K ICDW1 q1=(0.245±0.007) b* T2=58K ICDW2 q2(0.494±0.008) a*+(0.267±0.007) b*+0.50 c*
27 Density-wave-Like Anion ordering: big external periodic potential with periodicity close to 2K F
28 Almost all high-tc materials have unusual ρ(t) Electrons pair as they scatter! A15 Martensitic transformation Strong electron-phonon interaction Nb3Sn Unusual ρ(t) dependence: saturation at high T, Low T- extended range of T 2 behavior Correlating with T 2 (rather than T 3 ) lattice specific heat
29 La 2-x Sr x CuO 4 X= X= PG ρ~t at optimal doping ρ~t n at higher dopings
30 La 2-x Sr x CuO 4 C-axis transport O-T
31 Highest Tc heavy fermion CeCoIn5 Highest Tc organic superconductors
32 Need to understand what does this mean!
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