MARC Record from Library of Congress

LEADER: 03718cam a22004217a 4500
001 2013427174
003 DLC
005 20130806083723.0
008 130730s2013 si a b 001 0 eng d
010 $a 2013427174
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016 7 $a016211282$2Uk
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020 $a9814355801 (pbk.)
035 $a(OCoLC)ocn818463679
040 $aUKMGB$beng$cUKMGB$dOCLCO$dBTCTA$dYDXCP$dCDX$dEYM$dBWX$dUOH$dUPM$dDEBBG$dDLC
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050 00 $aQC176.8.E4$bL86 2013
080 $a50.94
080 $a621.3815
082 04 $a621.3815$223
084 $aUG 2300$2rvk
100 1 $aLundstrom, Mark.
245 10 $aNear-equilibrium transport :$bfundamentals and applications /$cMark Lundstrom, Changwook Jeong.
260 $aSingapore ;$aHackensack, NJ :$bWorld Scientific,$cc2013.
300 $axxi, 227 p. :$bill. ;$c24 cm.
490 1 $aLessons from nanoscience ;$vv. 2
504 $aIncludes bibliographical references and index.
505 0 $aMachine generated contents note: 1.Overview -- 1.1.Introduction -- 1.2.Diffusive electron transport -- 1.3.Types of electron transport -- 1.4.Why study near-equilibrium transport? -- 1.5.About these lectures -- 1.6.Summary -- 1.7.References -- 2.General Model for Transport -- 2.1.Introduction -- 2.2.Mathematical model -- 2.3.Modes -- 2.4.Transmission -- 2.5.Near-equilibrium (linear) transport -- 2.6.Transport in the bulk -- 2.7.Summary -- 2.8.References -- 3.Resistance: Ballistic to Diffusive -- 3.1.Introduction -- 3.2.2D resistors: ballistic -- 3.3.2D resistors: diffusive to ballistic -- 3.4.Discussion -- 3.5.Summary -- 3.6.References -- 4.Thermoelectric Effects: Physical Approach -- 4.1.Introduction -- 4.2.Electric current flow: Seebeck effect -- 4.3.Heat current flow: Peltier effect -- 4.4.Coupled flows -- 4.5.Thermoelectric devices -- 4.6.Discussion -- 4.7.Summary -- 4.8.References -- 5.Thermoelectric Effects: Mathematics -- 5.1.Introduction -- 5.2.Driving forces for current flow -- 5.3.Charge current -- 5.4.Heat current -- 5.5.Discussion -- 5.6.Summary -- 5.7.References -- 6.An Introduction to Scattering -- 6.1.Introduction -- 6.2.Physics of carrier scattering -- 6.3.Transmission and mean-free-path -- 6.4.Mean-free-path and scattering -- 6.5.Discussion -- 6.6.Summary -- 6.7.References -- 7.Boltzmann Transport Equation -- 7.1.Introduction -- 7.2.The Boltzmann Transport Equation -- 7.3.Solving the steady-state BTE -- 7.4.Transport coefficients -- 7.5.Magnetic fields -- 7.6.Discussion -- 7.7.Summary -- 7.8.References -- 8.Near-equilibrium Transport: Measurements -- 8.1.Introduction -- 8.2.Resistivity/conductivity measurements -- 8.3.Hall effect measurements -- 8.4.The van der Pauw method -- 8.5.Temperature-dependent measurements -- 8.6.Discussion -- 8.7.Summary -- 8.8.References -- 9.Phonon Transport -- 9.1.Introduction -- 9.2.Electrons and phonons -- 9.3.General model for heat conduction -- 9.4.Thermal conductivity -- 9.5.Debye model for Mph(hw) -- 9.6.Phonon scattering -- 9.7.Discussion -- 9.8.Summary -- 9.9.References -- 10.Graphene: A Case Study -- 10.1.Introduction -- 10.2.Graphene -- 10.3.Density-of-states and carrier density -- 10.4.Number of modes and conductance -- 10.5.Scattering -- 10.6.Conductance vs. carrier density -- 10.7.Discussion -- 10.8.Summary -- 10.9.References.
650 0 $aElectron transport.
650 0 $aNanoelectronics.
650 07 $aElektronentransfer.$2gnd
650 07 $aNanoelektronik.$2gnd
700 1 $aJeong, Changwook.
830 0 $aLessons from nanoscience ;$vv. 2.
856 4 $uhttp://www.gbv.de/dms/tib-ub-hannover/647228483.pdf$yInhaltsverzeichnis$304