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2 ( ) 1.1( ) 1.1: 2

3 ( ) ,3, : 1,2,3,4 a 1 2a 6 2 2,3,4 1,2,3,4 1.2( ) 4 1.2( ) 3

4 1.2( ) : 4

5 : a a R = l a l 5

6 R = l a + const. a 1.5: a, b 1.2 6

7 R = l a+m b+n c l, m, n a, b, c α, β, γ : /4 7

8 1.7: /4 1.8: /4 8

9 1.9: / a, b, c α, β, γ 1.2 a n n = 1, 2,

10 2.1: 5 a

11 International Tables for Crystallography vol. A 2.2: 2.2 P 2 1 /c a, b, c [u, v, w] R = u a + v b + w c [uvw] [111] [222] [ ] 2 [111] a, b, c [111] [111] < 111 > 11

2.3: a, b, c a, b, c (hkl) h k l i 2.4 2.

12 2.3: a, b, c a, b, c (hkl) h k l i ABCABC ABAB < 111 > < 001 > 2.5 (hkl) (h k l ) [uvw] [uvw] 2.6 [uvw] 12

13 2.4: 2.5: 13

14 (hkl) [uvw] hu + kw + lv = 0 2.6:

15 2.7: (001) [011] (2.5 ) (hkl) (h k l ) (phqh pkqk plql ) p, q 15

16 2.8: 2.9:

17 3 Ewald (010) 010 (hkl) g hkl 3.1: 17

18 :

19 3.3: 3.4: (1/2) 19

20 3.5: (2/2) 3.6: 20

21 A, B k 0 k k 0 k λ k 0 = k = 1 λ R Ψ A Ψ B 3.7: Ψ A Ψ B 3.8 l λ l A B λ r r k k 0 k k 0 k 0 k r q = 3.9 e iθ = cosθ + isinθ n 21

22 3.8: 3.4 r n q 3.10 R pqr = p a + q b + r c r n = R pqr g hkl R pqr = q = g hkl q = g hkl 2sinθ = 1 λ d hkl λ = 2dsinθ 3.5 Ewald Ewald

23 3.9: 3.10: 23

24 λ 1 λ k 0 0 Ewald 0 k 0 = k = 1 λ k 0 k q k k 0 k 0 k g hkl q 3.11: Ewald Ewald 24

25 4 4.1 t T 0 x(t) x(t) = a {a n cos(nω 0 t) + b n sin(nω 0 t)} (4.1) n=1 ω 0 T 0 f 0 ω 0 = 2πf 0 = 2π T 0 (4.2) (4.1) ω 0 nω 0 a n b n a n b n a n = 2 T 0 T0 2 b n = 2 T 0 T0 2 T 0 2 x(t)cos(nω 0 t)dt (4.3) T 0 2 x(t)sin(nω 0 t)dt (4.4) 4.2 (e iθ = cosθ + jsinθ) x(t) = n= c n e jnω 0t where, c n = 1 T 0 T0 2 T 0 2 x(t)e jnω 0t dt (4.5) nω 0 ω 0, 2ω 0, 3ω 0 ω 0 0 ω X(ω) = c n T 0 X(ω) = 25 x(t)e jwt dt (4.6)

26 (4.6) x(t) t s ω s f(t)=sin(t) g(t)=sint(2t)+ 1sin( t 2 2 ) f(t) t(s) sin g(t) sin(t) ( ) 4.2 f sin(t) 2,000(s)(0.5 mhz) sin(t)( ) 0.5 mhz 2t t 0.25 mhz mhz sin(t) t / s : f(t) g(t) 4.3 x(t) x( ) 26

27 Power f / Hz x : f(t) g(t)

28 4.3: 2 4.4: 2 28

29 4.5: 2 4.6: 2 29

30 X 5.2 Mo : 30

31 5.2: l l = ±1 31

32 K α1, K α2 α1,α2 K α1 K α2 K α1 K α2 K α1 K α2 K α1 K α2 K α 5.3: K α X K β K α K α X K α K β

33 5.4: X ω θ θ 0 o ω θ θ θ 33

34 5.5: 5.6: 34

35 ( 1 + cos I = F 2 2 ) 2θ 1 2µt p (1 e 2sin 2 sinθ )e 2M θcosθ 2µ (5.1) F 2 p 1 2µt (1 e sinθ ) 2µ - e 2M (5.1) 1. hkl N F hkl = f j e 2πi(hu j+kv j +lw j ) j=1 f j j u j, v j, w j j N {100} (100), (010), (001), (100), (010), (001) θ 35

36 2θ 5.7: γ = β = θ 1 2µt (1 e sinθ ) 2µ t 1 2µ 6. - u 2 2 M = 8π 2 u 2 ( sinθ 2 λ ) = B( sinθ λ 2 ) (5.2) 36

37 5.8: (5.1) 4sin 2 θ λ 2 = 1 d 2 = h2 + k 2 + l 2 a 2 (5.3) θ 5.2 h 2 + k 2 + l 2 a (5.3) ,

38 5.9: JCPDS(Joint Committee on Powder Diffraction Standards) 38

39 :

40 6.2: a, b, c a = b c a (b c), b = c a b (c a), c = a b c (a b) (6.1) a, b, c bc ca ab a, b, c a, b, c a, b, c a = 1 a, b = 1 b, c = 1 c (6.2) 40

41 2. 1. (hkl) F (hkl) F (hkl) 2 F (hkl) = n f n e 2πi(hxn+kyn+lzn) (6.3) f n n (x n, y n, z n ) n (6.3) n : 41

42 R d Rd = Lλ (6.4) : 2. 42

43 100kV : [double reflection] 6.6 Nd 2 Fe 1 4B 6.6(b) h + l = 43

2n + 1(n ) h + l = 2n + 1 6.6(a),(c) h + l = 2n + 1 300, 003 6.

44 2n + 1(n ) h + l = 2n (a),(c) h + l = 2n , (b) (a),(c) (b) h + l = 2n + 1 (a),(c) 6.6: [systematic reflections] h00 h = 0, +1, h, k, l h + k + l 44

45 [110] [110] Cu 3 Au CsCl ZnS 6.7: 45

46 3. Incommensurate Structure [Incommensurate Structure] 6.8(a) Cu 3 Pd M (b) Tl- a 5.9 (a) (b) 6.8: 46

47 4. SiC 6.9(a) 6.9: 6.9(b) c 47

48 d λ n 7.1: d = 0.61λ (7.1) n sinα α n sinα 1.5 λ 0.5 µm 0.2 µm (7.1) 48

49 d e CS λ e d e = 0.65C 1 4 s λ 3 4 e (7.2) 300kV nm 0.60 mm (7.2) 0.17 nm kev A-B 7.3 θ 49

50 7.2: 0.1µmϕ nmϕ (a) 7.4(b) 50

51 7.3: 7.5(a) (b) 7.5(b) g 7.6(a) 7.6(b) (c) 7.6(b) g 3g g 51

52 7.4: 7.5: 52

53 7.6: 7.6(c) g 7.6(b) g g-3g 3g 7.7 g = 220 g 3g nm 7.4(c) (7.2)

54 7.7: 54

55 7.8: 55

Xray.dvi

Xray.dvi 1 X 1 X 1 1.1.............................. 1 1.2.................................. 3 1.3........................ 3 2 4 2.1.................................. 6 2.2 n ( )............. 6 3 7 3.1 ( ).....................