QMI_10.dvi
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1 ... black body radiation black body black body radiation Gustav Kirchhoff W. Wien O.R. Lummer cavity radiation ν ν +dν f T (ν) f T (ν)dν = 8πν2 c 3 kt dν (Rayleigh Jeans) (.) f T (ν) spectral energy density k Boltzmann constant f T ν 0
2 2 Max Planck ν E = hν (.2) f ( ) T ν [ 0 8 Js/m 3 ] T = 000 K Rayleigh-Jeans Planck h = J s (.3) Planck constant ν ν +dν f T (ν) ν [ THz ].: f T (ν) f T (ν)dν = 8πhν3 c 3 ( hν exp kt ) dν (Planck) (.4) f T (ν) (.4) (.). (.4) hν ( ) hν exp kt + hν kt + ( ) hν kt h (.) (.4) ν λ = c/ν λ λ +dλ u T (λ) T u T (λ)dλ = 8πhc λ 5 ( hc exp λkt ) dλ (Planck) (.5) u T (λ) SI [J m 4 ] λ [J m 3 ] u T (λ).2 T = 4000 K 5000 K 6000 K 7000 K
3 .. 3 λ λ+dλ da z c c z θ c cos θ u T (λ) ccos θ 4π dω = sin θ dθ dϕ u T (λ)dλda c cos θ dω 4π. θ 0 π/2 ϕ 0 2π π/2 0 cos θ sin θ dθ = 2, 2π 0 dϕ =2π u ( ) T λ [ kj/m 4 ] λ [ nm ].2: u T (λ) (c/4) u T (λ)dλda T λ λ +dλ s T (λ)dλ = c 4 u T (λ)dλ. (.6) u T (λ) λ λ max λ max T = m K (.7) Wilhelm Wien Wien s displacement law u T (λ) (.5) λ du T (λ) = 6π2 h 2 ( c 2π hc e 2π hc/λk B T ) dλ λ 6 λk B T (e 2π hc/λk B T ) 5 2 e 2π hc/λk B T =0, x = 2π hc λk B T x 5=0 e x x
4 4 Stefan-Boltzmann law I T I = σt 4, σ = k 4 B 60π h 3 c 2 = Wm 2 K 4. (.8) σ Stefan-Boltzmann constant I = s T (λ)dλ x =2π hc/(λk B T ) I = c 4 8π (k B T )4 (2π hc) 3 0 x 3 e x dx = kb π h 3 c 2 T 4 I = σt 4 (.8) ( 0 x 3 ) π4 e x dx = 5..2 P.E.A. Lenard 905 ν hν h photon
5 .. 5 E E = hν (.9) hν.3 hν φ 2 mv2 = hν φ (.0).3: φ ev electron volt, φ work function ev ev = J. (.) R.A. Millikan.4 M M M e V [ V ] V.4: ν [ 0 4 s - ].5: Na M M V (.0) 2 mv2 = hν φ V 0 V V = hν φ. (.2) ν V
6 6 V =0 ν 0 φ φ = hν 0. (.3).5 ν V V =0 ν 0 = s φ =.8 ev.5 h h..3 A.H. Compton X Compton scattering momentum, momenta E = hν, p = hν c. (.4) X E + mc 2 = E + E e p +0 = p + p e. (.5) E p E p E e p e mc 2 E 2 e = (E E + mc 2 ) 2 = c 2 p 2 + c 2 p 2 2c 2 pp +2mc 3 (p p )+m 2 c 4 p 2 e = (p p ) 2 = p 2 + p 2 2pp cos θ (.4) θ Ee 2 = c 2 pe 2 + m 2 c 4 Δλ = λ λ = h ( cos θ ) (.6) mc λ = h/p λ = h/p h mc = m (.7) (.6) θ Δλ X
7 A.J. Angstrom 884 J.J. Balmer λ n = n 2 n 2 4 nm ( n =3, 4, 5, 6 ) (.8) λ λ λ 2 λ 3 /λ /λ 2 /λ 3 C. Runge J.R. Rydberg λ mn = λ n R m 2 ( m = n +,n+2, ) (.9) n λ n n R W. Ritz m A m λ mn = A m A n. (.20) combination principle.6 λ n = R H n 2 ( n =, 2, 3, ) (.2) λ n R H Rydberg constant R H = cm λ
8 8 0 2 /λ [ 0 4 cm - ] : ( = R λ H n n 2 ) n =, 2, 3, n 2 (.22) n = n +,n +2,n +3, E. Rutherford H. Geiger E. Marsden N. Bohr () stationary state
9 .2. 9 (2) transition E = hν +e e m r v F = ma = mv2 r = e 2 4πε 0 r 2 (.23) e 2 /(4πε 0 r) e2 E = 2 mv2 e2 4πε 0 r = 8πε 0 r (.24) (.23) (.2) n n = n =2 n = n i n = n f n i >n f E = hc ( λ = E i E f = e2 ). (.25) 8πε 0 r f r i n 2 (.22) n r n = a B n 2 ( n =, 2, 3, ) (.26) a B n = Bohr radius E n = e 2 8πε 0 a B n 2 ( n =, 2, 3, ) (.27) (.2) a B = e 2 8πε 0 hcr H (.28)
10 0 R H a B +e +Q λ = me2 Q 2 ( 8ε0 2 ) ch3 ni 2 (.29) +e Q =+2e n f =4 n i =5, 6, 7, n i =6, 8, 0, +e e Q =+2e He + (.25) n 2 f hν nm = E n E m (.30) E n E m r n v n (.23) v n = 4πε 0 e 2 mr n T n =2πr n /v n ν n = = v n = e 2 T n 2πr n 2π 4πε 0 mab 3 n 3. (.3) (.25) r f = r n = a B n 2 r i = r m = r n+l l n ν n = E n+l E n e 2 [ ] = h 8πε 0 ha B n 2 e 2 (n + l) 2 4πε 0 ha B n 3 (.32) (.3) /n 3 n correspondence principle (.32) (.3) e 2 = e 2 4πε 0 ha B 2π 4πε 0 mab 3
11 .2. a B = ε 0 h2 πme 2 = 4πε 0 h 2 me 2 = m, (.33) e 2 ( ) 2 me 4 E = = 8πε 0 a B 4πε 0 2 h 2 = J = ev (.34) n r n = a B n 2 (.35) e v n = 2 4πε 0 ma B n = h (.36) ma B n r n p n = n h (.37) p n = mv n angular momentum 2π h (.37) (.37) Bohr s quantum condition L. de Broglie E = hν E = mc 2 p λ = h p (.38)
12 2 λ E = cp E = hν E = cp = hν = hc λ (.38) E = cp hν 0 m 0 ν 0 hν 0 = m 0 c 2. (.39) f 0 sin 2πν 0 t 0 t 0 v t 0 t ( t 0 = t vx ) (v/c) 2 c 2. [ ( 2πν f(x, t) sin 0 (v/c) 2 ν = (.40) ν 0 (v/c) 2, λ = u ν = c2 v t vx c 2 ) ] [ ( = sin 2πν t x )] u u = c2 v (v/c) 2 hν hν = (.40) (.4) ν 0 (.42) hν 0 = m 0 c 2 = (v/c) 2 (v/c) 2 mc2 (.43) E = mc 2 λ = hc2 (v/c) 2 = hc2 v hν 0 v mc 2 = h mv = h p (.44) v u = c 2 /v v<c u>c v u
13 : x x ( ) f (x, t) = a sin(kx ωt), f 2 (x, t) = a sin (k + Δk)x (ω + Δω)t. u = ω k, u 2 = ω + Δω k + Δk phase velocity Δω ω Δk k f(x, t) = f (x, t)+f 2 (x, t) = [( 2a sin k + Δk ) x 2 ( ω + Δω 2 ) ] ( Δk t cos 2 x Δω ) 2 t (.45) t = t.8 t = t.8: ( Δk A(x, t ) = 2a cos 2 x Δω ) 2 t Δk/2 A(x, t ) [( f(x, t ) = A(x, t ) sin k + Δk ) ( x ω + Δω ) ] t 2 2
14 4 k + Δk/2 A(x, t ) t x v g = Δω Δk, (.46) group velocity = ω k, dω = dk (.47) ω = 2πν = 2πν 0 (v/c) 2, ω = 2π λ = 2πν 0 v/c c (v/c) 2 (.48) ω k = 2πν 0 (v/c) 2 c (v/c) 2 2πν 0 v/c = c2 v (.4) β = v/c dω dβ = 2πν 0 β ( β 2 ) 3/2, dk dβ = 2πν 0 c ( β 2 ) 3/2 v g = dω/dβ dk/dβ = βc = v. (.49) v
II
II 28 5 31 3 I 5 1 7 1.1.......................... 7 1.1.1 ( )................ 7 1.1.2........................ 12 1.1.3................... 13 1.1.4 ( )................. 14 1.1.5................... 15
4. ϵ(ν, T ) = c 4 u(ν, T ) ϵ(ν, T ) T ν π4 Planck dx = 0 e x 1 15 U(T ) x 3 U(T ) = σt 4 Stefan-Boltzmann σ 2π5 k 4 15c 2 h 3 = W m 2 K 4 5.
A 1. Boltzmann Planck u(ν, T )dν = 8πh ν 3 c 3 kt 1 dν h 6.63 10 34 J s Planck k 1.38 10 23 J K 1 Boltzmann u(ν, T ) T ν e hν c = 3 10 8 m s 1 2. Planck λ = c/ν Rayleigh-Jeans u(ν, T )dν = 8πν2 kt dν c
4 2 Rutherford 89 Rydberg λ = R ( n 2 ) n 2 n = n +,n +2, n = Lyman n =2 Balmer n =3 Paschen R Rydberg R = cm 896 Zeeman Zeeman Zeeman Lorentz
2 Rutherford 2. Rutherford N. Bohr Rutherford 859 Kirchhoff Bunsen 86 Maxwell Maxwell 885 Balmer λ Balmer λ = 364.56 n 2 n 2 4 Lyman, Paschen 3 nm, n =3, 4, 5, 4 2 Rutherford 89 Rydberg λ = R ( n 2 ) n
IA
IA 31 4 11 1 1 4 1.1 Planck.............................. 4 1. Bohr.................................... 5 1.3..................................... 6 8.1................................... 8....................................
(Blackbody Radiation) (Stefan-Boltzmann s Law) (Wien s Displacement Law)
( ) ( ) 2002.11 1 1 1.1 (Blackbody Radiation).............................. 1 1.2 (Stefan-Boltzmann s Law)................ 1 1.3 (Wien s Displacement Law)....................... 2 1.4 (Kirchhoff s Law)...........................
(Compton Scattering) Beaming 1 exp [i (k x ωt)] k λ k = 2π/λ ω = 2πν k = ω/c k x ωt ( ω ) k α c, k k x ωt η αβ k α x β diag( + ++) x β = (ct, x) O O x
![(Compton Scattering) Beaming 1 exp [i (k x ωt)] k λ k = 2π/λ ω = 2πν k = ω/c k x ωt ( ω ) k α c, k k x ωt η αβ k α x β diag( + ++) x β = (ct, x) O O x](/thumbs/104/162595168.jpg "(Compton Scattering) Beaming 1 exp [i (k x ωt)] k λ k = 2π/λ ω = 2πν k = ω/c k x ωt ( ω ) k α c, k k x ωt η αβ k α x β diag( + ++) x β = (ct, x) O O x")
Compton Scattering Beaming exp [i k x ωt] k λ k π/λ ω πν k ω/c k x ωt ω k α c, k k x ωt η αβ k α x β diag + ++ x β ct, x O O x O O v k α k α β, γ k γ k βk, k γ k + βk k γ k k, k γ k + βk 3 k k 4 k 3 k
QMI13a.dvi
I (2013 (MAEDA, Atsutaka) 25 10 15 [ I I [] ( ) 0. (a) (b) Plank Compton de Broglie Bohr 1. (a) Einstein- de Broglie (b) (c) 1 (d) 2. Schrödinger (a) Schrödinger (b) Schrödinger (c) (d) 3. (a) (b) (c)
5 5.1 E 1, E 2 N 1, N 2 E tot N tot E tot = E 1 + E 2, N tot = N 1 + N 2 S 1 (E 1, N 1 ), S 2 (E 2, N 2 ) E 1, E 2 S tot = S 1 + S 2 2 S 1 E 1 = S 2 E
5 5.1 E 1, E 2 N 1, N 2 E tot N tot E tot = E 1 + E 2, N tot = N 1 + N 2 S 1 (E 1, N 1 ), S 2 (E 2, N 2 ) E 1, E 2 S tot = S 1 + S 2 2 S 1 E 1 = S 2 E 2, S 1 N 1 = S 2 N 2 2 (chemical potential) µ S N
B 1 B.1.......................... 1 B.1.1................. 1 B.1.2................. 2 B.2........................... 5 B.2.1.......................... 5 B.2.2.................. 6 B.2.3..................
I ( ) 1 de Broglie 1 (de Broglie) p λ k h Planck ( Js) p = h λ = k (1) h 2π : Dirac k B Boltzmann ( J/K) T U = 3 2 k BT
I (008 4 0 de Broglie (de Broglie p λ k h Planck ( 6.63 0 34 Js p = h λ = k ( h π : Dirac k B Boltzmann (.38 0 3 J/K T U = 3 k BT ( = λ m k B T h m = 0.067m 0 m 0 = 9. 0 3 kg GaAs( a T = 300 K 3 fg 07345
V(x) m e V 0 cos x π x π V(x) = x < π, x > π V 0 (i) x = 0 (V(x) V 0 (1 x 2 /2)) n n d 2 f dξ 2ξ d f 2 dξ + 2n f = 0 H n (ξ) (ii) H
199 1 1 199 1 1. Vx) m e V cos x π x π Vx) = x < π, x > π V i) x = Vx) V 1 x /)) n n d f dξ ξ d f dξ + n f = H n ξ) ii) H n ξ) = 1) n expξ ) dn dξ n exp ξ )) H n ξ)h m ξ) exp ξ )dξ = π n n!δ n,m x = Vx)
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Mott散乱によるParity対称性の破れを検証
Mott Parity P2 Mott target Mott Parity Parity Γ = 1 0 0 0 0 1 0 0 0 0 1 0 0 0 0 1 t P P ),,, ( 3 2 1 0 1 γ γ γ γ γ γ ν ν µ µ = = Γ 1 : : : Γ P P P P x x P ν ν µ µ vector axial vector ν ν µ µ γ γ Γ ν γ
A = A x x + A y y + A, B = B x x + B y y + B, C = C x x + C y y + C..6 x y A B C = A x x + A y y + A B x B y B C x C y C { B = A x x + A y y + A y B B
9 7 A = A x x + A y y + A, B = B x x + B y y + B, C = C x x + C y y + C..6 x y A B C = A x x + A y y + A B x B y B C x C y C { B = A x x + A y y + A y B B x x B } B C y C y + x B y C x C C x C y B = A
Gmech08.dvi
145 13 13.1 13.1.1 0 m mg S 13.1 F 13.1 F /m S F F 13.1 F mg S F F mg 13.1: m d2 r 2 = F + F = 0 (13.1) 146 13 F = F (13.2) S S S S S P r S P r r = r 0 + r (13.3) r 0 S S m d2 r 2 = F (13.4) (13.3) d 2
4/15 No.
4/15 No. 1 4/15 No. 4/15 No. 3 Particle of mass m moving in a potential V(r) V(r) m i ψ t = m ψ(r,t)+v(r)ψ(r,t) ψ(r,t) = ϕ(r)e iωt ψ(r,t) Wave function steady state m ϕ(r)+v(r)ϕ(r) = εϕ(r) Eigenvalue problem
1 I 1.1 ± e = = - = C C MKSA [m], [Kg] [s] [A] 1C 1A 1 MKSA 1C 1C +q q +q q 1
![1 I 1.1 ± e = = - = C C MKSA [m], [Kg] [s] [A] 1C 1A 1 MKSA 1C 1C +q q +q q 1](/thumbs/94/121802164.jpg "1 I 1.1 ± e = = - = C C MKSA [m], [Kg] [s] [A] 1C 1A 1 MKSA 1C 1C +q q +q q 1")
1 I 1.1 ± e = = - =1.602 10 19 C C MKA [m], [Kg] [s] [A] 1C 1A 1 MKA 1C 1C +q q +q q 1 1.1 r 1,2 q 1, q 2 r 12 2 q 1, q 2 2 F 12 = k q 1q 2 r 12 2 (1.1) k 2 k 2 ( r 1 r 2 ) ( r 2 r 1 ) q 1 q 2 (q 1 q 2
p = mv p x > h/4π λ = h p m v Ψ 2 Ψ
II p = mv p x > h/4π λ = h p m v Ψ 2 Ψ Ψ Ψ 2 0 x P'(x) m d 2 x = mω 2 x = kx = F(x) dt 2 x = cos(ωt + φ) mω 2 = k ω = m k v = dx = -ωsin(ωt + φ) dt = d 2 x dt 2 0 y v θ P(x,y) θ = ωt + φ ν = ω [Hz] 2π
02-量子力学の復習
4/17 No. 1 4/17 No. 2 4/17 No. 3 Particle of mass m moving in a potential V(r) V(r) m i ψ t = 2 2m 2 ψ(r,t)+v(r)ψ(r,t) ψ(r,t) Wave function ψ(r,t) = ϕ(r)e iωt steady state 2 2m 2 ϕ(r)+v(r)ϕ(r) = εϕ(r)
) ] [ h m x + y + + V x) φ = Eφ 1) z E = i h t 13) x << 1) N n n= = N N + 1) 14) N n n= = N N + 1)N + 1) 6 15) N n 3 n= = 1 4 N N + 1) 16) N n 4
![) ] [ h m x + y + + V x) φ = Eφ 1) z E = i h t 13) x << 1) N n n= = N N + 1) 14) N n n= = N N + 1)N + 1) 6 15) N n 3 n= = 1 4 N N + 1) 16) N n 4](/thumbs/92/107866707.jpg ") ] [ h m x + y + + V x) φ = Eφ 1) z E = i h t 13) x << 1) N n n= = N N + 1) 14) N n n= = N N + 1)N + 1) 6 15) N n 3 n= = 1 4 N N + 1) 16) N n 4")
1. k λ ν ω T v p v g k = π λ ω = πν = π T v p = λν = ω k v g = dω dk 1) ) 3) 4). p = hk = h λ 5) E = hν = hω 6) h = h π 7) h =6.6618 1 34 J sec) hc=197.3 MeV fm = 197.3 kev pm= 197.3 ev nm = 1.97 1 3 ev
18 2 F 12 r 2 r 1 (3) Coulomb km Coulomb M = kg F G = ( ) ( ) ( ) 2 = [N]. Coulomb
![18 2 F 12 r 2 r 1 (3) Coulomb km Coulomb M = kg F G = ( ) ( ) ( ) 2 = [N]. Coulomb](/thumbs/93/114079295.jpg "18 2 F 12 r 2 r 1 (3) Coulomb km Coulomb M = kg F G = ( ) ( ) ( ) 2 = [N]. Coulomb")
r 1 r 2 r 1 r 2 2 Coulomb Gauss Coulomb 2.1 Coulomb 1 2 r 1 r 2 1 2 F 12 2 1 F 21 F 12 = F 21 = 1 4πε 0 1 2 r 1 r 2 2 r 1 r 2 r 1 r 2 (2.1) Coulomb ε 0 = 107 4πc 2 =8.854 187 817 10 12 C 2 N 1 m 2 (2.2)
QMI_09.dvi
25 3 19 Erwin Schrödinger 1925 3.1 3.1.1 3.1.2 σ τ 2 2 ux, t) = ux, t) 3.1) 2 x2 ux, t) σ τ 2 u/ 2 m p E E = p2 3.2) E ν ω E = hν = hω. 3.3) k p k = p h. 3.4) 26 3 hω = E = p2 = h2 k 2 ψkx ωt) ψ 3.5) h
QMI_10.dvi
25 3 19 Erwin Schrödinger 1925 3.1 3.1.1 σ τ x u u x t ux, t) u 3.1 t x P ux, t) Q θ P Q Δx x + Δx Q P ux + Δx, t) Q θ P u+δu x u x σ τ P x) Q x+δx) P Q x 3.1: θ P θ Q P Q equation of motion P τ Q τ σδx
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1 17 () BAC9ABC6ACB3 1 tan 6 = 3, cos 6 = AB=1 BC=2, AC= 3 2 A BC D 2 BDBD=BA 1 2 ABD BADBDA ABC6 BAD = (18 6 ) / 2 = 6 θ = 18 BAD = 12 () AD AD=BADCAD9 ABD ACD A 1 1 1 1 dsinαsinα = d 3 sin β 3 sin β
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Schrödinger I
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1 (Berry,1975) 2-6 p (S πr 2 )p πr 2 p 2πRγ p p = 2γ R (2.5).1-1 : : : : ( ).2 α, β α, β () X S = X X α X β (.1) 1 2
2005 9/8-11 2 2.2 ( 2-5) γ ( ) γ cos θ 2πr πρhr 2 g h = 2γ cos θ ρgr (2.1) γ = ρgrh (2.2) 2 cos θ θ cos θ = 1 (2.2) γ = 1 ρgrh (2.) 2 2. p p ρgh p ( ) p p = p ρgh (2.) h p p = 2γ r 1 1 (Berry,1975) 2-6
卒業研究報告 題 目 Hamiltonian 指導教員 山本哲也教授 報告者 汐月康則 平成 14 年 2 月 5 日 1
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ma22-9 u ( v w) = u v w sin θê = v w sin θ u cos φ = = 2.3 ( a b) ( c d) = ( a c)( b d) ( a d)( b c) ( a b) ( c d) = (a 2 b 3 a 3 b 2 )(c 2 d 3 c 3 d
A 2. x F (t) =f sin ωt x(0) = ẋ(0) = 0 ω θ sin θ θ 3! θ3 v = f mω cos ωt x = f mω (t sin ωt) ω t 0 = f ( cos ωt) mω x ma2-2 t ω x f (t mω ω (ωt ) 6 (ωt)3 = f 6m ωt3 2.2 u ( v w) = v ( w u) = w ( u v) ma22-9
Gauss Gauss ɛ 0 E ds = Q (1) xy σ (x, y, z) (2) a ρ(x, y, z) = x 2 + y 2 (r, θ, φ) (1) xy A Gauss ɛ 0 E ds = ɛ 0 EA Q = ρa ɛ 0 EA = ρea E = (ρ/ɛ 0 )e
7 -a 7 -a February 4, 2007 1. 2. 3. 4. 1. 2. 3. 1 Gauss Gauss ɛ 0 E ds = Q (1) xy σ (x, y, z) (2) a ρ(x, y, z) = x 2 + y 2 (r, θ, φ) (1) xy A Gauss ɛ 0 E ds = ɛ 0 EA Q = ρa ɛ 0 EA = ρea E = (ρ/ɛ 0 )e z
( ) ( 40 )+( 60 ) Schrödinger 3. (a) (b) (c) yoshioka/education-09.html pdf 1
2009 1 ( ) ( 40 )+( 60 ) 1 1. 2. Schrödinger 3. (a) (b) (c) http://goofy.phys.nara-wu.ac.jp/ yoshioka/education-09.html pdf 1 1. ( photon) ν λ = c ν (c = 3.0 108 /m : ) ɛ = hν (1) p = hν/c = h/λ (2) h
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I ( ) 2019 i 1 I,, III,, 1,,,, III,,,, (1 ) (,,, ), :...,, : NHK... NHK, (YouTube ),!!, manaba http://pen.envr.tsukuba.ac.jp/lec/physics/,, Richard Feynman Lectures on Physics Addison-Wesley,,,, x χ,
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This manuscript is modified on March 26, 2012 3 : 53 pm [1] 1 ( ) Figure 1: (longitudinal wave) (transverse wave). P 7km S 4km P S P S x t x u(x, t) t = t 0 = 0 f(x) f(x) = u(x, 0) v +x (Fig.2) ( ) δt
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QMII_10.dvi
65 1 1.1 1.1.1 1.1 H H () = E (), (1.1) H ν () = E ν () ν (). (1.) () () = δ, (1.3) μ () ν () = δ(μ ν). (1.4) E E ν () E () H 1.1: H α(t) = c (t) () + dνc ν (t) ν (), (1.5) H () () + dν ν () ν () = 1 (1.6)
.2 ρ dv dt = ρk grad p + 3 η grad (divv) + η 2 v.3 divh = 0, rote + c H t = 0 dive = ρ, H = 0, E = ρ, roth c E t = c ρv E + H c t = 0 H c E t = c ρv T
NHK 204 2 0 203 2 24 ( ) 7 00 7 50 203 2 25 ( ) 7 00 7 50 203 2 26 ( ) 7 00 7 50 203 2 27 ( ) 7 00 7 50 I. ( ν R n 2 ) m 2 n m, R = e 2 8πε 0 hca B =.09737 0 7 m ( ν = ) λ a B = 4πε 0ħ 2 m e e 2 = 5.2977
量子力学A
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master.dvi
4 Maxwell- Boltzmann N 1 4.1 T R R 5 R (Heat Reservor) S E R 20 E 4.2 E E R E t = E + E R E R Ω R (E R ) S R (E R ) Ω R (E R ) = exp[s R (E R )/k] E, E E, E E t E E t E exps R (E t E) exp S R (E t E )
(1.2) T D = 0 T = D = 30 kn 1.2 (1.4) 2F W = 0 F = W/2 = 300 kn/2 = 150 kn 1.3 (1.9) R = W 1 + W 2 = = 1100 N. (1.9) W 2 b W 1 a = 0
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meiji_resume_1.PDF
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4 1 1.1 ( ) 5 1.2, 2, d a V a = M (1.2.1), M, a,,,,, Ω, V a V, V a = V + Ω r. (1.2.2), r i 1, i 2, i 3, i 1, i 2, i 3, A 2, A = 3 A n i n = n=1 da = 3 = n=1 3 n=1 da n i n da n i n + 3 A ni n n=1 3 n=1
() x + y + y + x dy dx = 0 () dy + xy = x dx y + x y ( 5) ( s55906) 0.7. (). 5 (). ( 6) ( s6590) 0.8 m n. 0.9 n n A. ( 6) ( s6590) f A (λ) = det(a λi)
0. A A = 4 IC () det A () A () x + y + z = x y z X Y Z = A x y z ( 5) ( s5590) 0. a + b + c b c () a a + b + c c a b a + b + c 0 a b c () a 0 c b b c 0 a c b a 0 0. A A = 7 5 4 5 0 ( 5) ( s5590) () A ()