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The Oxford Solid State Basics, Solution Manual PDF

199 Pages·2015·2.436 MB·English
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The Oxford Solid State Basics Solutions to Exercises Steven H. Simon Oxford University . CLARENDON PRESS OXFORD 2015 iii These are the solutions to exercises from the Book The Oxford Solid StateBasics byStevenH.Simon,publishedbyOxfordUniversityPress, 2013 edition. Please do everyone a favor and do not circulate these solutions. Donotpostthesesolutionsonyourwebsite. Donotputthem onRussianwebsites. Donotcopythemandhandthemouttostudents. Whilethereisnowayformetoenforcethesereasonablerules,beassured thatI,beingaprofessoratHogwarts,aminpossessionofpowerfulhexes which I have used to protect the secrecy of these solutions. Those who attemptto circulatethesesolutionsunlawfully willactivatethe hex and will suffer thirty years of bad luck, including spiders crawling into your underwear. Some of these solutions have been tested through use in severalyears of courses. Other solutions have not been completely tested. Errors or ambiguities that are discovered in the exercises will be listed on my web page. If you think you have found errors in the problems or the solutions please do let me know,and I will make sure to fix them in the next version. Doing so will undoubtedly improve your Karma. , Steven H Simon Oxford, United Kingdom January 2014 Contents 1 About Condensed Matter Physics 1 2 SpecificHeatofSolids: Boltzmann, Einstein,and Debye 3 3 Electrons in Metals: Drude Theory 15 4 More Electrons in Metals: Sommerfeld (Free Electron) Theory 21 5 The Periodic Table 35 6 What Holds Solids Together: Chemical Bonding 39 7 Types of Matter 47 8 One-Dimensional Model of Compressibility, Sound, and Thermal Expansion 49 9 Vibrations of a One-Dimensional Monatomic Chain 55 10 Vibrations of a One-Dimensional Diatomic Chain 71 11 Tight Binding Chain (Interlude and Preview) 81 12 Crystal Structure 95 13 Reciprocal Lattice, Brillouin Zone, Waves in Crystals 99 14 Wave Scattering by Crystals 111 15 Electrons in a Periodic Potential 125 16 Insulator, Semiconductor, or Metal 135 17 Semiconductor Physics 139 18 Semiconductor Devices 149 19 Magnetic Properties of Atoms: Para- and Dia-Magnetism 159 vi Contents 20 Spontaneous Magnetic Order: Ferro-, Antiferro-, and Ferri-Magnetism 167 21 Domains and Hysteresis 175 22 Mean Field Theory 179 23 Magnetism from Interactions: The Hubbard Model 191 About Condensed Matter 1 Physics There are no exercises for chapter 1. Specific Heat of Solids: Boltzmann, Einstein, and 2 Debye (2.1) Einstein Solid ity should be 3Nk = 3R, in agreement with the law of B (a) Classical Einstein (or “Boltzmann”) Solid: Dulong and Petit. Consider a three dimensional simple harmonic oscilla- (b) Quantum Einstein Solid: tor with mass m and spring constant k (i.e., the mass NowconsiderthesameHamiltonianquantummechan- is attracted to the origin with the same spring constant ically. in all three directions). The Hamiltonian is given in the (cid:3) Calculate thequantum partition function usual way by p2 k H = + x2 Z = e−βEj 2m 2 (cid:3) Calculate theclassical partition function Xj dp Z = dxe−βH(p,x) where thesum overj is a sum over all eigenstates. (2π~)3 (cid:3) Explain therelationship with Bose statistics. Z Z Note: inthisproblempandxarethreedimensionalvec- (cid:3) Find an expression for the heat capacity. tors. (cid:3) Show that the high temperature limit agrees with (cid:3) Usingthepartitionfunction,calculatetheheatca- thelaw of Dulong of Petit. pacity 3k . (cid:3) Sketchtheheat capacity as a function of tempera- B (cid:3) Concludethatifyoucanconsiderasolidtoconsist ture. of N atoms all in harmonic wells, then the heat capac- (Seealso exercise 2.7 for more on thesame topic) (a) p2 k H = + x2 2m 2 dp Z = dxe−βH(p,x) (2π~)3 Z Z Since, ∞ dye−ay2 = π/a Z−∞ p in three dimensions, we get 3 Z = 1/(2π~) π/(β/2m) π/(βk/2)) =(~ωβ)−3 h p p i with ω = k/m. From the partition function p U = (1/Z)∂Z/∂β =3/β =3k T B − 4 Specific Heat of Solids: Boltzmann, Einstein, and Debye Thus the heat capacity ∂U/∂T is 3k . B (b) Quantum mechanically, for a 1d harmonic oscillator, we have eigenenergies E =~ω(n+1/2) n with ω = k/m. The partition function is then p Z = e−β~ω(n+1/2) 1d n≥0 X = e−β~ω/21/(1 e−β~ω) − = 1/[2sinh(β~ω/2)] The expectation of energy is then E = (1/Z)∂Z/∂β =(~ω/2)coth(β~ω/2) 1 h i − 1 = ~ω(n (β~ω)+ ) B 2 0.75 where n is the boson occupation factor B 0.5 n (x)=1/(ex 1) B − (hence again the relationship with free bosons). The high temperature 0.25 limitgivesn (x) 1/(x+x2/2)=1/x 1/2sothat E k T. More B B → − h i→ generally, we obtain 0 0 1 2 eβ~ω C =k (β~ω)2 Fig. 2.1Heatcapacity intheEinstein B (eβ~ω 1)2 − model (per atom) in one dimension. UnitsarekbonverticalaxisandkbT/ω In 3D, onhorizontal. Inthreedimensions,the heat capacity per atom is three times E =~ω[(n +1/2)+(n +1/2)+(n +1/2)] aslarge. n1,n2,n3 1 2 3 and Z3d = e−βEn1,n2,n3 =[Z1d]3 n1,n2,n3≥0 X and correspondingly 1 E =3~ω(n (β~ω)+ ) B h i 2 So the high temperature limit is E 3k T and the heat capacity B h i → C =∂ E /∂T =3k . More generally we obtain B h i eβ~ω C =3k (β~ω)2 B (eβ~ω 1)2 − Plotted this looks like Fig. 2.1.

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