Anderson ( ) Anderson / 14
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1 Anderson ( ) Anderson / 14
2 Anderson ( ) Anderson / 14
3 Anderson P.W.Anderson 1958 ( ) Anderson / 14
4 Anderson tight binding Anderson tight binding Z d u (x) = V i u t (u(x) u(y)) y: y x =1 = Hu = u + λvu ( ) Anderson / 14
5 Anderson tight binding Anderson tight binding Z d u (x) = V i u t V (u(x) u(y)) y: y x =1 = Hu = u + λvu {V ω (x)} x Z d V ω (x) g(v) 0 g(v) M ( ) Anderson / 14
6 Anderson tight binding Anderson tight binding Z d u (x) = V i u t V (u(x) u(y)) y: y x =1 = Hu = u + λvu {V ω (x)} x Z d V ω (x) g(v) 0 g(v) M R d ( ) Anderson / 14
7 Dynamical localization (mean square displacement) r(t) 2 = x Z d x 2 u (t, x) 2 ( ) Anderson / 14
8 Dynamical localization (mean square displacement) V = 0 r(t) 2 = x Z d x 2 u (t, x) 2 r(t) 2 Ct 2 as t ( ) Anderson / 14
9 Dynamical localization (mean square displacement) V = 0 r(t) 2 = x Z d x 2 u (t, x) 2 r(t) 2 Ct 2 as t Dynamical localization r(t) 2 C as t ( ) Anderson / 14
10 Dynamical localization (mean square displacement) V = 0 r(t) 2 = x Z d x 2 u (t, x) 2 r(t) 2 Ct 2 as t Dynamical localization r(t) 2 C as t Brown motion r(t) 2 Ct as t ( ) Anderson / 14
11 H = H = E 0 E Σ (de ), (Σ (de ) ) ( ) Anderson / 14
12 H = H = E Σ (de ), (Σ (de ) ) E 0 Schrödinger ) ( ) u(t, ) = (e ith u 0 ( ) = e ite Σ (de ) u 0 ( ) E 0 ( ) Anderson / 14
13 H = H = E Σ (de ), (Σ (de ) ) E 0 Schrödinger ) ( ) u(t, ) = (e ith u 0 ( ) = e ite Σ (de ) u 0 ( ) E 0 Σ (de ) E point mass H u 0 E φ u(t, ) = e ite φ ( ) = t u(t, ) ( ) Anderson / 14
14 H = H = E Σ (de ), (Σ (de ) ) E 0 Schrödinger ) ( ) u(t, ) = (e ith u 0 ( ) = e ite Σ (de ) u 0 ( ) E 0 Σ (de ) E point mass H u 0 E φ u(t, ) = e ite φ ( ) = t u(t, ) Σ (de ) u(t, x) t u (t, x) 2 = u 0 (x) 2 = u(t, ) t x Z d x Z d ( ) Anderson / 14
15 H = H = E Σ (de ), (Σ (de ) ) E 0 Schrödinger ) ( ) u(t, ) = (e ith u 0 ( ) = e ite Σ (de ) u 0 ( ) E 0 Σ (de ) E point mass H u 0 E φ u(t, ) = e ite φ ( ) = t u(t, ) Σ (de ) u(t, x) t u (t, x) 2 = u 0 (x) 2 = u(t, ) t x Z d x Z d Σ (de ) Σ (de ) = Σ ac (de ) Σ sc (de ) Σ p (de ) Σ (de ) = Σ p (de ) Σ (de ) = Σ ac (de ) (extended states) ( ) Anderson / 14
16 1D, 2D 3D ( ) Anderson / 14
17 1D, 2D 3D 3D ( ) Anderson / 14
18 K.Ishii: Localization of eigenstates and transport phenomena in 1-dim. disordered systems, Prog.Theor.Phys.Suppl. 53(1973) Σ ω ac (de ) = 0 ( ) Anderson / 14
19 K.Ishii: Localization of eigenstates and transport phenomena in 1-dim. disordered systems, Prog.Theor.Phys.Suppl. 53(1973) Σ ω ac (de ) = 0 I.Goldseid,S.Molchanov,L.Pastur: A pure point spectrum of the stochastic 1-dimensional Schröinger equation. Funct. Anal. Appl. 11(1977) Σ ω (de ) = Σ ω p (de ) ( ) Anderson / 14
20 K.Ishii: Localization of eigenstates and transport phenomena in 1-dim. disordered systems, Prog.Theor.Phys.Suppl. 53(1973) Σ ω ac (de ) = 0 I.Goldseid,S.Molchanov,L.Pastur: A pure point spectrum of the stochastic 1-dimensional Schröinger equation. Funct. Anal. Appl. 11(1977) Σ ω (de ) = Σ ω p (de ) coupling λ ( ) Anderson / 14
21 J.Frölich, T.Spencer: Absence of diffusion in the Anderson tight-binding model for large disorder or low energy, CMP. 88(1983) λ 1 = λ = 0 = ( ) Anderson / 14
22 J.Frölich, T.Spencer: Absence of diffusion in the Anderson tight-binding model for large disorder or low energy, CMP. 88(1983) λ 1 = λ = 0 = (Green G E = (H E ) 1 ( ) Anderson / 14
23 J.Frölich, T.Spencer: Absence of diffusion in the Anderson tight-binding model for large disorder or low energy, CMP. 88(1983) λ 1 = λ = 0 = (Green G E = (H E ) 1 Wegner Λ Z d H Λ = H Λ Prob (dist (E, sph Λ ) δ) n λ (E )δ Λ, n λ (E ) = ( ) Anderson / 14
24 J.Frölich, T.Spencer: Absence of diffusion in the Anderson tight-binding model for large disorder or low energy, CMP. 88(1983) λ 1 = λ = 0 = (Green G E = (H E ) 1 Wegner Λ Z d H Λ = H Λ Prob (dist (E, sph Λ ) δ) n λ (E )δ Λ, n λ (E ) = Combes-Thomas dist (E, sph Λ ) = κ (E C) G Λ,E (x, y) κ 1 e cκ x y, c ( ) Anderson / 14
25 J.Frölich, T.Spencer: Absence of diffusion in the Anderson tight-binding model for large disorder or low energy, CMP. 88(1983) λ 1 = λ = 0 = (Green G E = (H E ) 1 Wegner Λ Z d H Λ = H Λ Prob (dist (E, sph Λ ) δ) n λ (E )δ Λ, n λ (E ) = Combes-Thomas dist (E, sph Λ ) = κ (E C) G Λ,E (x, y) κ 1 e cκ x y, c Resolvent H = H 0 + H 1 = G E = G 0,E G 0,E H 1 G E ( ) Anderson / 14
26 J.Frölich, T.Spencer: Absence of diffusion in the Anderson tight-binding model for large disorder or low energy, CMP. 88(1983) λ 1 = λ = 0 = (Green G E = (H E ) 1 Wegner Λ Z d H Λ = H Λ Prob (dist (E, sph Λ ) δ) n λ (E )δ Λ, Combes-Thomas n λ (E ) = dist (E, sph Λ ) = κ (E C) G Λ,E (x, y) κ 1 e cκ x y, c Resolvent H = H 0 + H 1 = G E = G 0,E G 0,E H 1 G E Multiscale analysis: H 0 = H Λ H Λ c { 1 if x y = 1, x Λ, y Λ H 1 (x, y) = c or vise versa 0 otherwise Resolvent ( ) Anderson / 14
27 J.Frölich, T.Spencer: Absence of diffusion in the Anderson tight-binding model for large disorder or low energy, CMP. 88(1983) λ 1 = λ = 0 = (Green G E = (H E ) 1 Wegner Λ Z d H Λ = H Λ Prob (dist (E, sph Λ ) δ) n λ (E )δ Λ, Combes-Thomas n λ (E ) = dist (E, sph Λ ) = κ (E C) G Λ,E (x, y) κ 1 e cκ x y, c Resolvent H = H 0 + H 1 = G E = G 0,E G 0,E H 1 G E Multiscale analysis: H 0 = H Λ H Λ c { 1 if x y = 1, x Λ, y Λ H 1 (x, y) = c or vise versa 0 otherwise Resolvent Green GE ω (0, y) c ω e c y ( ) Anderson / 14
28 Erdös, Lázló- Salmhofer, Manfred- Yau, Horng-Tzer: Towards the quantum Brownian motion. Mathematical physics of quantum mechanics, , Lecture Notes in Phys., 690, Springer, Berlin, d, 1 λ = r(t) 2 Dt if λ 2 t λ 2 ε for ε > 0 r(t) 2 Ct 2 if t λ 2 ( ) Anderson / 14
29 Erdös, Lázló- Salmhofer, Manfred- Yau, Horng-Tzer: Towards the quantum Brownian motion. Mathematical physics of quantum mechanics, , Lecture Notes in Phys., 690, Springer, Berlin, d, 1 λ = r(t) 2 Dt if λ 2 t λ 2 ε for ε > 0 r(t) 2 Ct 2 if t λ 2 3D 1 λ r(t) 2 Dt as t ( ) Anderson / 14
30 Erdös, Lázló- Salmhofer, Manfred- Yau, Horng-Tzer: Towards the quantum Brownian motion. Mathematical physics of quantum mechanics, , Lecture Notes in Phys., 690, Springer, Berlin, d, 1 λ = r(t) 2 Dt if λ 2 t λ 2 ε for ε > 0 r(t) 2 Ct 2 if t λ 2 3D 1 λ r(t) 2 Dt as t A.Klein: Extended states in the Anderson model on the Bethe lattice. Adv. Math. 133(1998) Bethe ( ) Anderson / 14
31 ( ) Anderson / 14
32 IDS 1 N(E ) = lim Λ Z Λ # { HΛ ω E } ( ) Anderson / 14
33 IDS Lyapounov 1 γ (E ) = lim x U ω (x + 1, E ) = 1 N(E ) = lim Λ Z Λ # { HΛ ω E } x log Uω (x, E ) 0, ( E V ω (x + 1) ) U ω (x, E ) ( ) Anderson / 14
34 IDS Lyapounov 1 γ (E ) = lim x U ω (x + 1, E ) = 1 N(E ) = lim Λ Z Λ # { HΛ ω E } x log Uω (x, E ) 0, ( E V ω (x + 1) ) U ω (x, E ) ( ) Anderson / 14
35 IDS Lyapounov 1 γ (E ) = lim x U ω (x + 1, E ) = 1 N(E ) = lim Λ Z Λ # { HΛ ω E } x log Uω (x, E ) 0, ( E V ω (x + 1) Σ ω (= suppσ ω (de )) = suppdn(e ) ) U ω (x, E ) ( ) Anderson / 14
36 IDS Lyapounov 1 γ (E ) = lim x U ω (x + 1, E ) = 1 N(E ) = lim Λ Z Λ # { HΛ ω E } x log Uω (x, E ) 0, ( E V ω (x + 1) ) U ω (x, E ) Σ ω (= suppσ ω (de )) = suppdn(e ) Σac ω (= suppσac ω (de )) = {E; γ (E ) = 0} ess ( ) Anderson / 14
37 IDS Lyapounov 1 γ (E ) = lim x U ω (x + 1, E ) = 1 N(E ) = lim Λ Z Λ # { HΛ ω E } x log Uω (x, E ) 0, ( E V ω (x + 1) ) U ω (x, E ) Σ ω (= suppσ ω (de )) = suppdn(e ) Σac ω (= suppσac ω (de )) = {E; γ (E ) = 0} ess m± ω Weyl m+(e ω + i0) = m ω (E + i0) a.e. {E; γ (E ) = 0} ( ) Anderson / 14
38 S R V ω (x) S V ω (x) ( ) Anderson / 14
39 S R V ω (x) S V ω (x) Mathieu (Hu) x = u x+1 + u x 1 + 2λ cos 2π (αx + ω) u x α : λ > 1 = λ = 1 = λ < 1 = André-Aubry, Avila, Jitomirskya, Last, Simon, ( ) Anderson / 14
40 S R V ω (x) S V ω (x) Mathieu (Hu) x = u x+1 + u x 1 + 2λ cos 2π (αx + ω) u x α : λ > 1 = λ = 1 = λ < 1 = André-Aubry, Avila, Jitomirskya, Last, Simon, ( ) Anderson / 14
41 ( ) Anderson / 14
42 ( ) Anderson / 14
43 e.g.:penrose ( ) Anderson / 14
44 e.g.:penrose ( ) Anderson / 14
45 e.g.:penrose ( ) Anderson / 14
46 e.g.:penrose ( ) Anderson / 14
47 e.g.:penrose ( ) Anderson / 14
48 e.g.:penrose d 2 x ω (t) dt 2 = grad V ω (x ω (t)) = {x ω (t)} = ( ) Anderson / 14
49 e.g.:penrose d 2 x ω (t) dt 2 = grad V ω (x ω (t)) = {x ω (t)} = e.g.: ( ) Anderson / 14
50 Isaac Newton Institute for Mathematical Sciences Mathematics and Physics of Anderson localization : 50 Years After 14 July - 19 December 2008 ( Spencer, T (IAS, Princeton) Anderson localisation: phenomenology and mathematics ( ) Anderson / 14
Black-Scholes [1] Nelson [2] Schrödinger 1 Black Scholes [1] Black-Scholes Nelson [2][3][4] Schrödinger Nelson Parisi Wu [5] Nelson Parisi-W
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003 7 14 Black-Scholes [1] Nelson [] Schrödinger 1 Black Scholes [1] Black-Scholes Nelson [][3][4] Schrödinger Nelson Parisi Wu [5] Nelson Parisi-Wu Nelson e-mail: takatoshi-tasaki@nifty.com kabutaro@mocha.freemail.ne.jp
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Journal of Differential Equations 96 (992), 70-84 Melnikov method and transversal homoclinic points in the restricted three-body problem Zhihong Xia Department of Mathematics, Harvard University Cambridge,
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127 3 II 3.1 3.1.1 Φ(t) ϕ em = dφ dt (3.1) B( r) Φ = { B( r) n( r)}ds (3.2) S S n( r) Φ 128 3 II S 1, S 2 Φ 1, Φ 2 Φ 1 = { B( r) n( r)}ds S 1 Φ 2 = { B( r) n( r)}ds (3.3) S 2 S S 1 +S 2 { B( r) n( r)}ds
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No.2 1 2 2 δs δs = r + δr r = δr (3) δs δs = r r = δr + u(r + δr, t) u(r, t) (4) δr = (δx, δy, δz) u i (r + δr, t) u i (r, t) = u i δx j (5) δs 2 = δx i δx i + 2 u i δx i δx j = δs 2 + 2s ij δx i δx j
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( ) ( 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
微分積分 サンプルページ この本の定価 判型などは, 以下の URL からご覧いただけます. このサンプルページの内容は, 初版 1 刷発行時のものです.
微分積分 サンプルページ この本の定価 判型などは, 以下の URL からご覧いただけます. ttp://www.morikita.co.jp/books/mid/00571 このサンプルページの内容は, 初版 1 刷発行時のものです. i ii 014 10 iii [note] 1 3 iv 4 5 3 6 4 x 0 sin x x 1 5 6 z = f(x, y) 1 y = f(x)
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Shunsuke Kobayashi 1 [6] [11] [7] u t = D 2 u 1 x 2 + f(u, v) + s L u(t, x)dx, L x (0.L), t > 0, Neumann 0 v t = D 2 v 2 + g(u, v), x (0, L), t > 0. x
![Shunsuke Kobayashi 1 [6] [11] [7] u t = D 2 u 1 x 2 + f(u, v) + s L u(t, x)dx, L x (0.L), t > 0, Neumann 0 v t = D 2 v 2 + g(u, v), x (0, L), t > 0. x](/thumbs/97/133795870.jpg "Shunsuke Kobayashi 1 [6] [11] [7] u t = D 2 u 1 x 2 + f(u, v) + s L u(t, x)dx, L x (0.L), t > 0, Neumann 0 v t = D 2 v 2 + g(u, v), x (0, L), t > 0. x")
Shunsuke Kobayashi [6] [] [7] u t = D 2 u x 2 + fu, v + s L ut, xdx, L x 0.L, t > 0, Neumann 0 v t = D 2 v 2 + gu, v, x 0, L, t > 0. x2 u u v t, 0 = t, L = 0, x x. v t, 0 = t, L = 0.2 x x ut, x R vt, x
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1 Surveys in Geometry 1980 2 6, 7 Harmonic Map Plateau Eells-Sampson [5] Siu [19, 20] Kähler 6 Reports on Global Analysis [15] Sacks- Uhlenbeck [18] Siu-Yau [21] Frankel Siu Yau Frankel [13] 1 Surveys
18 I ( ) (1) I-1,I-2,I-3 (2) (3) I-1 ( ) (100 ) θ ϕ θ ϕ m m l l θ ϕ θ ϕ 2 g (1) (2) 0 (3) θ ϕ (4) (3) θ(t) = A 1 cos(ω 1 t + α 1 ) + A 2 cos(ω 2 t + α
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B YES NO 5 7 6 1 4 3 2 BB BB BB AA AA BB 510J B B A 510J B A A A A A A 510J B A 510J B A A A A A 510J M = σ Z Z = M σ AAA π T T = a ZP ZP = a AAA π B M + M 2 +T 2 M T Me = = 1 + 1 + 2 2 M σ Te = M 2 +T
反D中間子と核子のエキゾチックな 束縛状態と散乱状態の解析
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