jse2000.dvi

Size: px

Start display at page:

Download "jse2000.dvi"

きょうすけまつかた
5 years ago
Views:

1 pn (800MHz) (12GHz) (CPUDSP ) 1: MOS (MOSFET) CCD MOSFET MES (MESFET) (HBT) (HEMT) GTO MOSFET (IGBT) (SIT) pn { pn 2 pn pn 1 2 sirafuji@dj.kit.ac.jp yoshimot@dj.kit.ac.jp 1

2 3 3.1 III Si(IV ) III ()p Si V V ()n Si 1(a) p Si( n Si) () 1: (a) p n (b) pn pn p n n p p n 1(b) p n (n p) p n V d ; V d = kt e ln n n0p p0 n 2 i! kt e ln N DN A n 2 i! : (1) p p0 n n0 n i p n p n (N D ) (N A ) 2

3 p n V V d 0 V 2(a) p n ()p n 0V V d + V 2(b) n p pn 2: pn (a) (b) pn - ev ev j = j 0 exp 0 1 j 0 exp kt kt (2) j 0 pn - pn pn pn d Poisson 2S 0 (V d 0 V )(N A + N D ) 1=2 d = (3) en A N D 3

4 p N A n N D S 0 d = 12S 0 (V d 0 V ) 1=3 (4) e(a 1 + a 2 ) N D (x) =N 0 +a 1 x N A (x) =N 0 0a 2 x C = S 0 d (5) 3.2 3(a) E G 3: (a) () (b) 3(b) pn ( ) pn ( ) ( 4(a) ) n p () 5 - V OC I SC I SC 4

5 4: (a) (b) I m V m R L = V m =I m P max P max = I m V m = I SC V OC FF (6) FF (Fill Factor) 1 - = I mv m P in = I SCV OCFF P in (7) P in (W) I (A) I photo V i + I i R + s V R sh R s = 0 R sh = 100 Ω or I I (A) I SC I m A V R s = 0 R sh = 100 Ω R s = 0 or 5 Ω R sh = V (V) R s = 5 Ω R sh = 0.04 P m = I m V m V m V OC V (V) 5: (a) -(b) (a) 4 ( ) () 5

6 3.3 3(a) () pn ( 4(b) ) ( ) 4 pn 2 2 ABC 3 pn 2: A B C [1 0 8] [9; 10] () - () 6

7 - ( 6 ) pn - A A V V 6: () 2- () - 1 pa(= A) 1 pn 7 -- ev I I 0 exp : (8) nkt n 7 (shunt) R sh (series) R s 1 I 0 n R sh R s 1 R sh R s 2 Si 3 (n ) 7

8 V i + I i I + R s V R sh I / I qv / kt I (ma) di / dv = R s V (V) di / dv = R sh -20 7: pn - 3- pn - ( 8 ) () - pn + G H L EXT. DC BIAS + 8: 2 1/C 2 (pf 02 cm 4 ) V (V) 1/C 3 -V 3 (3)(4)(5) 4 8

9 4 (3) (5) 5 (4) (5) 4-1{- (1) 2 () - () ( 1) (2) 5(b) 0 5k ( ) R s R sh 7 5 FF 4-2{ -- (1) 2 () - () ( 1) (2) () pn 9(a) (b) n + /p/p + (back surface eld; BSF ) p Si n + p + n + /p pn p/p + p Si ( I SC ) p/p + n + /p ( V OC ) 9

10 9: (BSF ) (a) (b) pn ( C) Host : Si N(x) / N ERFC GAUSS ERFC GAUSS D 1/2 ( µm / hr 1/2 ) P B x / (4Dt) 1/ x / (4Dt) 1/ / T (K -1 ) : Si N(x; t) =N 0 erfc x 2 p Dt (9) N(x; t) = N 0 p exp Dt 0 x2 4Dt! (10) x erfc D Si B P 10 N(x; t) 10 10

11 5.2.3 Al () () W Ta 11: Al p Si 3 n p Al ( ) Al Si pn Si Si (HF) HF () ( [1]-[2]) ( [3]-[8]) n + p + n p 3 (OCD PBF) 3 Si 11

12 12: 3 (PBF) (OCD) 4 B 2 O 3 P 2 O Si B P 3 12[6] p + n + HF HF 1 HF ( [9]-[10]) 11 Al Al

13 3: p + PBF (B) B 2 O 3 1.4wt% 3000 rpm C C 30 n + OCD (P) P 2 O 5 3g/100ml 4000 rpm C C 30 9 j= I/ S pn 10 B P Si 4: Si (T =300K) E G 1:12 ev n i 1: cm 03 N C 2: cm 03 N V 3: cm 03 S 11:9 pn 1. () 2. : () 3. : () 4. : () 5. S.M.Sze: () 6. : () 7. : () 1. : () 1. A.S.Grove: () 13

Similar documents

devicemondai

devicemondai c 2019 i 3 (1) q V I T ε 0 k h c n p (2) T 300 K (3) A ii c 2019 i 1 1 2 13 3 30 4 53 5 78 6 89 7 101 8 112 9 116 A 131 B 132 c 2019 1 1 300 K 1.1 1.5 V 1.1 qv = 1.60 10 19 C 1.5 V = 2.4 10 19 J (1.1)

More information

,,., (,, SiO 2, Si-N, ),,,,,.,.,,, (Schottky). [ ].,..,.,., 1 m µm 10., 10 5, [ ] (6N-103)..,.,. [ ] 1. (,, ) :,.,,.., (HF),.

17 2 2.1,,., (,, SiO 2, Si-N, ),,,,,.,.,,, (Schottky). [ ].,..,.,., 1 m 3 0.1 µm 10., 10 5, 10 7. [ ] (6N-103)..,.,. [ ] 1. (,, ) :,.,,.., (HF),. 18 2,,.,,. 2.,,,.,,. 2.1. 19 2.1.1 1. 1, (Schottky),,,.

More information

MOSFET HiSIM HiSIM2 1

MOSFET HiSIM HiSIM2 1 MOSFET 2007 11 19 HiSIM HiSIM2 1 p/n Junction Shockley - - on-quasi-static - - - Y- HiSIM2 2 Wilson E f E c E g E v Bandgap: E g Fermi Level: E f HiSIM2 3 a Si 1s 2s 2p 3s 3p HiSIM2 4 Fermi-Dirac Distribution

More information

(4.15a) Hurwitz (4.15a) {a j } (s ) {a j } n n Hurwitz a n 1 a n 3 a n 5 a n a n 2 a n 4 a n 1 a n 3 H = a n a n 2. (4.16)..... a Hurwitz H i H i i H

(4.15a) Hurwitz (4.15a) {a j } (s ) {a j } n n Hurwitz a n 1 a n 3 a n 5 a n a n 2 a n 4 a n 1 a n 3 H = a n a n 2. (4.16)..... a Hurwitz H i H i i H 6 ( ) 218 1 28 4.2.6 4.1 u(t) w(t) K w(t) = Ku(t τ) (4.1) τ Ξ(iω) = exp[ α(ω) iβ(ω)] (4.11) (4.1) exp[ α(ω) iβ(ω)] = K exp( iωτ) (4.12) α(ω) = ln(k), β(ω) = ωτ (4.13) dϕ/dω f T 4.3 ( ) OP-amp Nyquist Hurwitz

More information

<4D F736F F D B B BB2D834A836F815B82D082C88C602E646F63>

<4D F736F F D B B BB2D834A836F815B82D082C88C602E646F63> 入門モーター工学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. http://www.morikita.co.jp/books/mid/074351 このサンプルページの内容は, 初版 1 刷発行当時のものです. 10 kw 21 20 50 2 20 IGBT IGBT IGBT 21 (1) 1 2 (2) (3) ii 20 2013 2 iii iv...

More information

(1) (2) (3) (4) (5) 2.1 ( ) 2

(1) (2) (3) (4) (5) 2.1 ( ) 2

More information

橡Taro11-卒業論文.PDF

橡Taro11-卒業論文.PDF Recombination Generation Lifetime 13 9 1. 3. 4.1. 4.. 9 3. Recombination Lifetime 17 3.1. 17 3.. 19 3.3. 4. 1 4.1. Si 1 4.1.1. 1 4.1.. 4.. TEG 3 5. Recombination Lifetime 4 5.1 Si 4 5.. TEG 6 6. Pulse

More information

. ev=,604k m 3 Debye ɛ 0 kt e λ D = n e n e Ze 4 ln Λ ν ei = 5.6π / ɛ 0 m/ e kt e /3 ν ei v e H + +e H ev Saha x x = 3/ πme kt g i g e n

. ev=,604k m 3 Debye ɛ 0 kt e λ D = n e n e Ze 4 ln Λ ν ei = 5.6π / ɛ 0 m/ e kt e /3 ν ei v e H + +e H ev Saha x x = 3/ πme kt g i g e n 003...............................3 Debye................. 3.4................ 3 3 3 3. Larmor Cyclotron... 3 3................ 4 3.3.......... 4 3.3............ 4 3.3...... 4 3.3.3............ 5 3.4.........

More information

untitled

untitled SPring-83 22(2010)730 MBE PLD MBE 0.002% PLD p Π n p n PF PF = S 2 S =V/ΔT V: [V] ΔT: [K] S[V/K], T[K], σ[s/m] TeBi 2 Te 3 (Bi,Se) 2 Te 3 (n-type) Ar KrF Ar gas 2. A. 3. c-si a-si InP GaAs 1g (μm) PV(W/g

More information

4‐E )　キュリー温度を利用した消磁：熱消磁

4‐E )　キュリー温度を利用した消磁：熱消磁 ( ) () x C x = T T c T T c 4D ) ) Fe Ni Fe Fe Ni (Fe Fe Fe Fe Fe 462 Fe76 Ni36 4E ) ) (Fe) 463 4F ) ) ( ) Fe HeNe 17 Fe Fe Fe HeNe 464 Ni Ni Ni HeNe 465 466 (2) Al PtO 2 (liq) 467 4G ) Al 468 Al ( 468

More information

2006122 2/13

2006122 HEMT IT 1/13 2006122 2/13 2006122 3/13 2006122 4/13 2006122 5/13 2006122 Dingle 9 GaAs 6/13 2006122 7/13 2006122 8/13 2006122 9/13 2006122 10/13 2006122 4 11/13 2006122 GaAs MOSFET HEMT HEMT MBE

More information

Microsoft Word - 章末問題

Microsoft Word - 章末問題 1906 R n m 1 = =1 1 R R= 8h ICP s p s HeNeArXe 1 ns 1 1 1 1 1 17 NaCl 1.3 nm 10nm 3s CuAuAg NaCl CaF - - HeNeAr 1.7(b) 2 2 2d = a + a = 2a d = 2a 2 1 1 N = 8 + 6 = 4 8 2 4 4 2a 3 4 π N πr 3 3 4 ρ = = =

More information

untitled

untitled MOSFET 17 1 MOSFET.1 MOS.1.1 MOS.1. MOS.1.3 MOS 4.1.4 8.1.5 9. MOSFET..1 1.. 13..3 18..4 18..5 0..6 1.3 MOSFET.3.1.3. Poon & Yau 3.3.3 LDD MOSFET 5 3.1 3.1.1 6 3.1. 6 3. p MOSFET 3..1 8 3.. 31 3..3 36

More information

ダイオード中小型編　応用上の注意

ダイオード中小型編　応用上の注意 2-1 : 2. 2.1.1 2.1 1 1.5~2 AC1 V 2 V AC2 V 4 V AC1 V 4 V AC2~24 V 6~8 V 2.1.2 18 (Tj max) ( ) ( 2.1) ( 2.2) Ta max ( C) 16 14 12 1 8 6 4 2 18 Ta max I F (AV) カラスエホキシ (t=1.6mm) 基板実装 1 2 基板サイス 5mm 5mm

More information

t = h x z z = h z = t (x, z) (v x (x, z, t), v z (x, z, t)) ρ v x x + v z z = 0 (1) 2-2. (v x, v z ) φ(x, z, t) v x = φ x, v z

t = h x z z = h z = t (x, z) (v x (x, z, t), v z (x, z, t)) ρ v x x + v z z = 0 (1) 2-2. (v x, v z ) φ(x, z, t) v x = φ x, v z I 1 m 2 l k 2 x = 0 x 1 x 1 2 x 2 g x x 2 x 1 m k m 1-1. L x 1, x 2, ẋ 1, ẋ 2 ẋ 1 x = 0 1-2. 2 Q = x 1 + x 2 2 q = x 2 x 1 l L Q, q, Q, q M = 2m µ = m 2 1-3. Q q 1-4. 2 x 2 = h 1 x 1 t = 0 2 1 t x 1 (t)

More information

Mｏｔｔ散乱によるParity対称性の破れを検証

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

More information

untitled

untitled (a) (b) (c) (d) Wunderlich 2.5.1 = = =90 2 1 (hkl) {hkl} [hkl] L tan 2θ = r L nλ = 2dsinθ dhkl ( ) = 1 2 2 2 h k l + + a b c c l=2 l=1 l=0 Polanyi nλ = I sinφ I: B A a 110 B c 110 b b 110 µ a 110

More information

MO 2 E 2 POM -248/16 ev. 1.3_2 L D WP V GND 2* D IN LOD / W D OU OMP LOD 3 Min. yp. Max. V IN Y V IH V = V V = V V IL V = V 2 V =

MO 2 E 2 POM -248/16 ev. 1.3_2 L D WP V GND 2* D IN LOD / W D OU OMP LOD 3 Min. yp. Max. V IN Y V IH V = V V = V V IL V = V 2 V = ev. 1.3_2 MO 2 E 2 POM -248/16 8-Pin DIP ( DP8-DP8-E) 8-Pin OP ( FJ8-DFJ8-E) :µ Max. (V =5.5 V) :.8 m Max. (V =5.5 V, f=4khz).4 m Max. (V =4.5 V, f=1khz) :2.5 5.5 V :1.8 5.5 V 16 (-248, -2416) GN 1 2 8-Pin

More information

27

More information

ohpr.dvi

ohpr.dvi 2003/12/04 TASK PAF A. Fukuyama et al., Comp. Phys. Rep. 4(1986) 137 A. Fukuyama et al., Nucl. Fusion 26(1986) 151 TASK/WM MHD ψ θ ϕ ψ θ e 1 = ψ, e 2 = θ, e 3 = ϕ ϕ E = E 1 e 1 + E 2 e 2 + E 3 e 3 J :

More information

MOSFET 6-2 CMOS 6-2 TTL Transistor Transistor Logic ECL Emitter Coupled Logic I2L Integrated

1 -- 7 6 2011 11 1 6-1 MOSFET 6-2 CMOS 6-2 TTL Transistor Transistor Logic ECL Emitter Coupled Logic I2L Integrated Injection Logic 6-3 CMOS CMOS NAND NOR CMOS 6-4 6-5 6-1 6-2 CMOS 6-3 6-4 6-5 c 2011 1/(33)

More information

服用者向け_資料28_0623

服用者向け_資料28_0623 1 2 3 1. 2. 4 3. 4. 1. 5 2. 3. 4. 5. 6 6. 7. 8. 7 9. 10. 11. 8 12. 9 10 11 12 Q-1 : OC Q-2 : OC Q-3 : 21 OC 28 OC 13 Q-4 : OC Q-5 : OC Q-6 : OC 14 Q-7 : Q-8 : OC Q-9 : OC Q-10 : OC Q-11 : OC 15 Q-12 :

More information

untitled

untitled

More information

01_教職員.indd

01_教職員.indd T. A. H. A. K. A. R. I. K. O. S. O. Y. O. M. K. Y. K. G. K. R. S. A. S. M. S. R. S. M. S. I. S. T. S. K.T. R. T. R. T. S. T. S. T. A. T. A. D. T. N. N. N. Y. N. S. N. S. H. R. H. W. H. T. H. K. M. K. M.

More information

More information

K 1 mk(

K 1 mk( R&D ATN K 1 mk(0.01 0.05 = ( ) (ITS-90)-59.3467 961.78 (T.J.Seebeck) A(+ T 1 I T 0 B - T 1 T 0 E (Thermoelectromotive force) AB =d E(AB) /dt=a+bt----------------- E(AB) T1 = = + + E( AB) α AB a b ( T0

More information

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

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)

More information

c 03 MOSFET n MOSFET 0, I Dn = β n VGSn V thn V ] DSn VDSn, β n (V GSn V thn ), () p MOSFET 0, ] I Dp = β p V GSp V thp VDSp V DSp, βp (V GSp V thp ),

CMOS original:0//0, revised:03// CMOS CMOS CMOS NOT V in 0 n MOSFET p MOSFET V out V DD V in V DD n MOSFET p MOSFET V out 0 : CMOS CMOS c 03 MOSFET n MOSFET 0, I Dn = β n VGSn V thn V ] DSn VDSn, β n (V

More information

1 No.1 5 C 1 I III F 1 F 2 F 1 F 2 2 Φ 2 (t) = Φ 1 (t) Φ 1 (t t). = Φ 1(t) t = ( 1.5e 0.5t 2.4e 4t 2e 10t ) τ < 0 t > τ Φ 2 (t) < 0 lim t Φ 2 (t) = 0

1 No.1 5 C 1 I III F 1 F 2 F 1 F 2 2 Φ 2 (t) = Φ 1 (t) Φ 1 (t t). = Φ 1(t) t = ( 1.5e 0.5t 2.4e 4t 2e 10t ) τ < 0 t > τ Φ 2 (t) < 0 lim t Φ 2 (t) = 0 0 < t < τ I II 0 No.2 2 C x y x y > 0 x 0 x > b a dx

More information

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..................

More information

original: 2011/11/5 revised: 2012/10/30, 2013/12/ : 2 V i V t2 V o V L V H V i V i V t1 V o V H V L V t1 V t2 1 Q 1 1 Q

original: 2011/11/5 revised: 2012/10/30, 2013/12/2 1 1 1: 2 V i V t2 V o V L V H V i V i V t1 V o V H V L V t1 V t2 1 Q 1 1 Q 2 2 1 2 1 c 2013 2 2: V i Q 1 I C1 V C1 V B2 I E V E V E Q 1 Q 1 Q 2 Q 2 Q

More information

6 2 T γ T B (6.4) (6.1) [( d nm + 3 ] 2 nt B )a 3 + nt B da 3 = 0 (6.9) na 3 = T B V 3/2 = T B V γ 1 = const. or T B a 2 = const. (6.10) H 2 = 8π kc2

6 2 T γ T B (6.4) (6.1) [( d nm + 3 ] 2 nt B )a 3 + nt B da 3 = 0 (6.9) na 3 = T B V 3/2 = T B V γ 1 = const. or T B a 2 = const. (6.10) H 2 = 8π kc2 1 6 6.1 (??) (P = ρ rad /3) ρ rad T 4 d(ρv ) + PdV = 0 (6.1) dρ rad ρ rad + 4 da a = 0 (6.2) dt T + da a = 0 T 1 a (6.3) ( ) n ρ m = n (m + 12 ) m v2 = n (m + 32 ) T, P = nt (6.4) (6.1) d [(nm + 32 ] )a

More information

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

More information

Microsoft Word - 海岸紹介new.doc

Microsoft Word - 海岸紹介new.doc

More information

untitled

untitled 20101221JST (SiC - Buried Gate Static Induction Transistor: SiC-BGSIT) SOURCE GATE N source layer p + n p + n p + n p+ n drift layer n + substrate DRAIN SiC-BGSIT (mωcm 2 ) 200 100 40 10 4 1 Si limit

More information

More information

縺縺8 縺, [ 縺ﾁ : () () () 4 ﾁ93799; () "64": ｨｬ 9997ｨ

縺縺8 縺, [ 縺ﾁ : () () () 4 ﾁ93799; () 64: ｨｬ 9997ｨ 34978 998 3. 73 68, 86 ﾀ7 9 9989769 438 縺48 縺 378364 ﾀ縺473 399-4 8 637744739 683 6744939 3.9. 378,.. 68 ｨ 349 889 3349947 89893 683447 4 334999897447 (9489) 67449, 6377447 683, 74984 7849799 34789 83747

More information

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 ( ) 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

More information

2.1: n = N/V ( ) k F = ( 3π 2 N ) 1/3 = ( 3π 2 n ) 1/3 V (2.5) [ ] a = h2 2m k2 F h2 2ma (1 27 ) (1 8 ) erg, (2.6) /k B 1 11 / K

2.1: n = N/V ( ) k F = ( 3π 2 N ) 1/3 = ( 3π 2 n ) 1/3 V (2.5) [ ] a = h2 2m k2 F h2 2ma (1 27 ) (1 8 ) erg, (2.6) /k B 1 11 / K 2 2.1? [ ] L 1 ε(p) = 1 ( p 2 2m x + p 2 y + pz) 2 = h2 ( k 2 2m x + ky 2 + kz) 2 n x, n y, n z (2.1) (2.2) p = hk = h 2π L (n x, n y, n z ) (2.3) n k p 1 i (ε i ε i+1 )1 1 g = 2S + 1 2 1/2 g = 2 ( p F

More information

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

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 2 ), ϕ(t) = B 1 cos(ω 1 t + α 1 ) + B 2 cos(ω 2 t

More information

2 2 1990 17 000 2002 3 22 000 12 5 000 2 10 2 1999 2000 2 ii 2 2 MOS 2001 8 2002 3 2 2 iv (*2002 3 ) vi vii () 1 * 1 1.1 2 1.1.1 2 1.1.2 2 1.2 4 1.2.1 4 1.2.2 1 6 1.2.3 2 9 1.2.4 10 1.2.5 () a b, c 13

More information

More information

表紙

More information

0201

0201 2018 10 17 2019 9 19 SI J cal 1mL 1ºC 1999 cal nutrition facts label calories cal kcal 1 cal = 4.184 J heat capacity 1 K 1 J K 1 mol molar heat capacity J K mol (specific heat specific heat capacity) 1

More information

untitled

untitled MPPC 18 2 16 MPPC(Multi Pixel Photon Counter), MPPC T2K MPPC T2K (HPK) CPTA, MPPC T2K p,π T2K > 5 10 5 < 1MHz > 15% 200p.e. MIP 5p.e. p/π MPPC HPK MPPC 2 1 MPPC 5 1.1...................................

More information

kawa (Spin-Orbit Tomography: Kawahara and Fujii 21,Kawahara and Fujii 211,Fujii & Kawahara submitted) 2 van Cittert-Zernike Appendix A V 2

kawa (Spin-Orbit Tomography: Kawahara and Fujii 21,Kawahara and Fujii 211,Fujii & Kawahara submitted) 2 van Cittert-Zernike Appendix A V 2 Hanbury-Brown Twiss (ver. 1.) 24 2 1 1 1 2 2 2.1 van Cittert - Zernike..................................... 2 2.2 mutual coherence................................. 3 3 Hanbury-Brown Twiss ( ) 4 3.1............................................

More information

H8.6 P.4-202-

H8.6 P.4-202-

More information

PS2701-1, PS2701-2, PS DS

PS2701-1, PS2701-2, PS DS Photocoupler SOP NEPOC PS2701-1, PS2701-2, PS2701-4 GaAs LED IC BV = 3 7 Vr.m.s. SOP tr = 3 µs TYP., tf = 5 µs TYP. 1 PS2701-1-E3, E4, F3, F4 UL No. E72422 (S) VDE0884 IC PS2701-1 4 SOP PS2701-2 8 SOP

More information

‘¬”R.qx

‘¬”R.qx

More information

4.6 (E i = ε, ε + ) T Z F Z = e βε + e β(ε+ ) = e βε (1 + e β ) F = kt log Z = kt log[e βε (1 + e β )] = ε kt ln(1 + e β ) (4.18) F (T ) S = T = k = k

4.6 (E i = ε, ε + ) T Z F Z = e ε + e (ε+ ) = e ε ( + e ) F = kt log Z = kt loge ε ( + e ) = ε kt ln( + e ) (4.8) F (T ) S = T = k = k ln( + e ) + kt e + e kt 2 + e ln( + e ) + kt (4.20) /kt T 0 = /k (4.20)

More information

1 12 ( )150 ( ( ) ) x M x 0 1 M 2 5x 2 + 4x + 3 x 2 1 M x M 2 1 M x (x + 1) 2 (1) x 2 + x + 1 M (2) 1 3 M (3) x 4 +

1 12 ( )150 ( ( ) ) x M x 0 1 M 2 5x 2 + 4x + 3 x 2 1 M x M 2 1 M x (x + 1) 2 (1) x 2 + x + 1 M (2) 1 3 M (3) x 4 + ( )5 ( ( ) ) 4 6 7 9 M M 5 + 4 + M + M M + ( + ) () + + M () M () 4 + + M a b y = a + b a > () a b () y V a () V a b V n f() = n k= k k () < f() = log( ) t dt log () n+ (i) dt t (n + ) (ii) < t dt n+ n

More information

1

More information

note2.dvi

note2.dvi 8 216614 2.4 Joh Bardee, William Shockley, Walter Brattai. 1948 Bell William Shockley BrattaiBardee Shockley 1947 (12/16 23)Shockley BrattaiBardee (Trasistor, TrasferResistor ) Shockley 1/23 1 [2] 2.4.1

More information

25 7 18 1 1 1.1 v.s............................. 1 1.1.1.................................. 1 1.1.2................................. 1 1.1.3.................................. 3 1.2................... 3

More information

-5 -

-5 -

More information

別冊　各分野における虐待事例と分析

別冊　各分野における虐待事例と分析

More information

1 2 3 4 5 6 0.4% 58.4% 41.2% 10 65 69 12.0% 9 60 64 13.4% 11 70 12.6% 8 55 59 8.6% 0.1% 1 20 24 3.1% 7 50 54 9.3% 2 25 29 6.0% 3 30 34 7.6% 6 45 49 9.7% 4 35 39 8.5% 5 40 44 9.1% 11 70 11.2% 10 65 69 11.0%

More information

熊本県数学問題正解

熊本県数学問題正解 00 y O x Typed by L A TEX ε ( ) (00 ) 5 4 4 ( ) http://www.ocn.ne.jp/ oboetene/plan/. ( ) (009 ) ( ).. http://www.ocn.ne.jp/ oboetene/plan/eng.html 8 i i..................................... ( )0... (

More information

[ ] Table

[ ] Table [] Te P AP OP [] OP c r de,,,, ' ' ' ' de,, c,, c, c ',, c mc ' ' m' c ' m m' OP OP p p p ( t p t p m ( m c e cd d e e c OP s( OP t( P s s t (, e e s t s 5 OP 5 5 s t t 5 OP ( 5 5 5 OAP ABP OBP ,, OP t(

More information

30 (11/04 )

30 (11/04 ) i, 1,, II I?,,,,,,,,, ( ),,, ϵ δ,,,,, (, ),,,,,, 5 : (1) ( ) () (,, ) (3) ( ) (4) (5) ( ) (1),, (),,, () (3), (),, (4), (1), (3), ( ), (5),,,,,,,, ii,,,,,,,, Richard P. Feynman, The best teaching

More information

DCV ACV DCI ACI DCV ACV DCI ACI DCV ACV DCI ACI DCV ACV DCI ACI Excel JIS Microsoft Excel I-V START I-V Excel I-V JIS C-8913 Excel Excel I-V ISC Isc J

Agilent Technologies B2900A Microsoft Excel I-V GP-IB Agilent SMU B2900A Series DC 6V/3.03A 21V/1.515A 210V/0.105A JIS 1 2 DARK I-V I-V DCV ACV DCI ACI DCV ACV DCI ACI DCV ACV DCI ACI DCV ACV DCI ACI Excel

More information

I-2 (100 ) (1) y(x) y dy dx y d2 y dx 2 (a) y + 2y 3y = 9e 2x (b) x 2 y 6y = 5x 4 (2) Bernoulli B n (n = 0, 1, 2,...) x e x 1 = n=0 B 0 B 1 B 2 (3) co

I-2 (100 ) (1) y(x) y dy dx y d2 y dx 2 (a) y + 2y 3y = 9e 2x (b) x 2 y 6y = 5x 4 (2) Bernoulli B n (n = 0, 1, 2,...) x e x 1 = n=0 B 0 B 1 B 2 (3) co 16 I ( ) (1) I-1 I-2 I-3 (2) I-1 ( ) (100 ) 2l x x = 0 y t y(x, t) y(±l, t) = 0 m T g y(x, t) l y(x, t) c = 2 y(x, t) c 2 2 y(x, t) = g (A) t 2 x 2 T/m (1) y 0 (x) y 0 (x) = g c 2 (l2 x 2 ) (B) (2) (1)

More information

2004

2004 2008 3 20 400 1 1,222 7 1 2 3 55.8 54.8 3 35.8 6 64.0 50.5 93.5 1 1,222 1 1,428 1 1,077 6 64.0 52.5 80.5 56.6 81.5 30.2 1 2 3 7 70.5 1 65.6 2 61.3 3 51.1 1 54.0 2 49.8 3 32.0 68.8 37.0 34.3 2008 3 2 93.5

More information

pdf

pdf http://www.ns.kogakuin.ac.jp/~ft13389/lecture/physics1a2b/ pdf I 1 1 1.1 ( ) 1. 30 m µm 2. 20 cm km 3. 10 m 2 cm 2 4. 5 cm 3 km 3 5. 1 6. 1 7. 1 1.2 ( ) 1. 1 m + 10 cm 2. 1 hr + 6400 sec 3. 3.0 10 5 kg

More information

genron-3

genron-3 " ( K p( pasals! ( kg / m 3 " ( K! v M V! M / V v V / M! 3 ( kg / m v ( v "! v p v # v v pd v ( J / kg p ( $ 3! % S $ ( pv" 3 ( ( 5 pv" pv R" p R!" R " ( K ( 6 ( 7 " pv pv % p % w ' p% S & $ p% v ( J /

More information

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.

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

More information

1 1

1 1

More information

1

More information

176 B B.1: ( ) ( ) ( ) (2 2 ) ( ) ( ) ( ) (quantitative nondestructive evaluation:qnde) (1) X X X X CT(computed tomography)

B 1) B.1 B.1.1 ( ) B.1 1 50 100 m B.1.2 (nondestructive testing:ndt) (nondestructive inspection:ndi) (nondestructive evaluation:nde) 175 176 B B.1: ( ) ( ) ( ) (2 2 ) ( ) ( ) ( ) (quantitative nondestructive

More information

<4D F736F F D B B83578B6594BB2D834A836F815B82D082C88C602E646F63>

<4D F736F F D B B83578B6594BB2D834A836F815B82D082C88C602E646F63> スピントロニクスの基礎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. http://www.morikita.co.jp/books/mid/077461 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 1 2 ii 3 5 4 AMR (anisotropic magnetoresistance effect) GMR (giant magnetoresistance

More information

(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

(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 1 1 1.1 1.) T D = T = D = kn 1. 1.4) F W = F = W/ = kn/ = 15 kn 1. 1.9) R = W 1 + W = 6 + 5 = 11 N. 1.9) W b W 1 a = a = W /W 1 )b = 5/6) = 5 cm 1.4 AB AC P 1, P x, y x, y y x 1.4.) P sin 6 + P 1 sin 45

More information

KT

More information

Hanbury-Brown Twiss (ver. 2.0) van Cittert - Zernike mutual coherence

Hanbury-Brown Twiss (ver. 2.0) van Cittert - Zernike mutual coherence Hanbury-Brown Twiss (ver. 2.) 25 4 4 1 2 2 2 2.1 van Cittert - Zernike..................................... 2 2.2 mutual coherence................................. 4 3 Hanbury-Brown Twiss ( ) 5 3.1............................................

More information

入試の軌跡

入試の軌跡 4 y O x 4 Typed by L A TEX ε ) ) ) 6 4 ) 4 75 ) http://kumamoto.s.xrea.com/plan/.. PDF) Ctrl +L) Ctrl +) Ctrl + Ctrl + ) ) Alt + ) Alt + ) ESC. http://kumamoto.s.xrea.com/nyusi/kumadai kiseki ri i.pdf

More information

31, 21% 24, 17% 8, 5% 23, 16% 24, 16% 91, 62% 19, 13% 39, 27% 33, 23% 73 48 57 51 31 1 9 13.0% 7.4% 5.3% 12.5% 17.1% 13.2% 17.9% 4.5% 36.4% 56.5% 40.7% 36.8% 50.0% 67.1% 56.3% 65.8% 75.0% 26.0% 37.0%

More information

37 27.0% 26 19.0% 74 54.0% 9 6.4% 13 9.2% 28 19.9% 26 18.4% 37 26.2%. 24 17.0% 99 69 75 59 39 1 6 4.5% 1.4% 7.7% 2.9% 25.0% 17.9% 20.8% 50.0% 41.7% 47.0% 51.4% 54.3% 61.5% 57.1% 55.6% 42.4% 50.0% 58.3%

More information

% 32.3 DI DI

% 32.3 DI DI 2011 7 9 28.1 41.4 30.5 35.8 31.9% 32.3 DI 18.2 2.4 8.1 3.5 DI 9.4 32.2 0.0 25.9 2008 1 3 2 3 34.8 65.2 46.753.8 1 2 8.82.9 43.1 10 3 DI 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25

More information

2 DI 28 7 1 37 28 4 18 27 11 21 5 2 26 4 5 1 15 2 25 3 35 4 17 7 5 48 76 31 47 17 2 92 12 2 2 4 6 8 1 12 1 2 4 1 12 13 18 19 3 42 57 57 1 2 3 4 5 6 1 1 1 3 4 4 5 5 5.5 1 1.5 2 2.5 3 3.5 4 4.5 5

More information

3 DI 29 7 1 5 6 575 11 751, 13 1,1,25 6 1,251,5 2 1,51,75 1,752, 1 2,2,25 2,252,5 2,53, 3,3,5 3,5 5 1 15 2 25 3 5 6 575 12 751, 21 1,1,25 27 1,251,5 9 1,51,75 1,752, 1 2,2,25 2 2,252,5 2,53, 2 3,3,5

More information

I ( ) 2019

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,

More information

IA

IA 31 4 11 1 1 4 1.1 Planck.............................. 4 1. Bohr.................................... 5 1.3..................................... 6 8.1................................... 8....................................

More information

パソコン接続マニュアル P-01F 日本語

パソコン接続マニュアル P-01F 日本語 P-01F 1 2 3 4 5 1 2 +m1111 1 2 3 4 5 6 6 1 1 111 2 1 3 1 1 1 2 1 7 3 8 1 2 1 111 3 4 5 9 1 m111 m1111 c 2 3 4 5 10 1 1 111 2 1 3 1 1 1 2 1 3 1 m111 m1111 2 3 1 11 12 1 2 3 1 2 3 13 1 2 3 4 5 14 6 7 8 9

More information

2

Rb Rb Rb :10256010 2 3 1 5 1.1....................................... 5 1.2............................................. 5 1.3........................................ 6 2 7 2.1.........................................

More information

吸収分光.PDF

吸収分光.PDF 3 Rb 1 1 4 1.1 4 1. 4 5.1 5. 5 3 8 3.1 8 4 1 4.1 External Cavity Laser Diode: ECLD 1 4. 1 4.3 Polarization Beam Splitter: PBS 13 4.4 Photo Diode: PD 13 4.5 13 4.6 13 5 Rb 14 6 15 6.1 ECLD 15 6. 15 6.3

More information

A (1) = 4 A( 1, 4) 1 A 4 () = tan A(0, 0) π A π

4 4.1 4.1.1 A = f() = f() = a f (a) = f() (a, f(a)) = f() (a, f(a)) f(a) = f 0 (a)( a) 4.1 (4, ) = f() = f () = 1 = f (4) = 1 4 4 (4, ) = 1 ( 4) 4 = 1 4 + 1 17 18 4 4.1 A (1) = 4 A( 1, 4) 1 A 4 () = tan

More information

More information

微粒子合成化学・講義

微粒子合成化学・講義 http://www.tagen.tohoku.ac.jp/labo/muramatsu/mura/main.html E-mail: mura@tagen.tohoku.ac.jp 1 Derjaguin Landau Verway Overbeek B.V.Derjaguin and L.Landau;Acta Physicochim.,URSS, 14, 633 1941. E.J.W.Verwey

More information

More information

untitled

untitled 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

More information

微粒子合成化学・講義

微粒子合成化学・講義 http://www.tagen.tohoku.ac.jp/labo/muramatsu/mura/main.html E-mail: mura@tagen.tohoku.ac.jp 1 2 1 mol/l KCl 3 4 Derjaguin Landau Verway Overbeek B.V.Derjaguin and L.Landau;Acta Physicochim.,URSS, 14, 633

More information

Pa Pa Pa MPa Pa Pa Pa Pa Pa Pa MPa 0 0.01739 0.1087d.0126 V L 2 V d 2 g 2 d 4Q 2 4 d ッ 1.85 Q k 4.87 D k Q k 4.87 D k 1.85 /min Q /min Pt Pe Pf Pv Pn EL 90 TB 90 GV CV RV ST DV AL

More information

( ) ,

( ) , II 2007 4 0. 0 1 0 2 ( ) 0 3 1 2 3 4, - 5 6 7 1 1 1 1 1) 2) 3) 4) ( ) () H 2.79 10 10 He 2.72 10 9 C 1.01 10 7 N 3.13 10 6 O 2.38 10 7 Ne 3.44 10 6 Mg 1.076 10 6 Si 1 10 6 S 5.15 10 5 Ar 1.01 10 5 Fe 9.00

More information

pall_news116

pall_news116 PALL NEWS 2013 SPRING Vol.117 LED NEW 316L NW40 NW50 O - 316 L 316 L nm (38 O C ) 3 nm 75 slpm 0.72 MPa 100 O C O - 1 1/4 VCR 2 ISO NW40 NW50 2 2013 SPRING Pall News ol.117 D mm L CK4000I40H 55 49 Flow

More information

スライド 1

スライド 1 Matsuura Laboratory SiC SiC 13 2004 10 21 22 H-SiC ( C-SiC HOY Matsuura Laboratory n E C E D ( E F E T Matsuura Laboratory Matsuura Laboratory DLTS Osaka Electro-Communication University Unoped n 3C-SiC

More information

Acrobat Distiller, Job 2

Acrobat Distiller, Job 2 2 3 4 5 Eg φm s M f 2 qv ( q qφ ) = qφ qχ + + qφ 0 0 = 6 p p ( Ei E f ) kt = n e i Q SC = qn W A n p ( E f Ei ) kt = n e i 7 8 2 d φ( x) qn = A 2 dx ε ε 0 s φ qn s 2ε ε A ( x) = ( x W ) 2 0 E s A 2 EOX

More information

2 0.1 Introduction NMR 70% 1/2

Y. Kondo 2010 1 22 2 0.1 Introduction NMR 70% 1/2 3 0.1 Introduction......................... 2 1 7 1.1.................... 7 1.2............................ 11 1.3................... 12 1.4..........................

More information

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

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

More information

AD8515: 1.8 V 低電力 CMOS レール to レール入力／出力オペアンプ

AD8515: 1.8 V 低電力 CMOS レール to レール入力／出力オペアンプ REV. REVISION 15-6891 1-16-1 3 542 82 532-3 3-5-36 MT 2 6 635 6868 AD8515 1.8V CMOS to 1.8 5V 6mV SOT23 2.7V/µs 5MH to 2pA 1.8V 45µA PCMCIA PDA AD8515 1.8Vto SOT23-5L AD8515 5MHz 1.8V1mV to 2.7V/µs ASIC

More information

B1 Ver ( ), SPICE.,,,,. * : student : jikken. [ ] ( TarouOsaka). (, ) 1 SPICE ( SPICE. *1 OrCAD

B1 Ver ( ), SPICE.,,,,. * : student : jikken. [ ] ( TarouOsaka). (, ) 1 SPICE ( SPICE. *1 OrCAD B1 er. 3.05 (2019.03.27), SPICE.,,,,. * 1 1. 1. 1 1.. 2. : student : jikken. [ ] ( TarouOsaka). (, ) 1 SPICE ( SPICE. *1 OrCAD https://www.orcad.com/jp/resources/orcad-downloads.. 1 2. SPICE 1. SPICE Windows

More information

AN8032

AN8032 IC,,,, 1 IC,,,,, MOSFET, MOSFET,,, TH 2.5 V V REF 23.3±0.3 U.V.L.O. comp. 6.0±0.3 1/8 V 9 6 2.4±0.25 9 8 7 6 5 4 3 2 1 0.3 +0.1 0.05 3.3±0.25 0.5±0.1 2.54 1.5±0.25 1.5±0.25 SIP009-P-0000C V CC Unit : mm

More information

To make this website work, we log user data and share it with processors. To use this website, you must agree to our Privacy Policy, including cookie policy.