研究室ガイダンス(H28)福山研.pdf
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2 He M. Roger et al., JLTP 112, 45 (1998)
3 A.F. Andreev and I.M. Lifshitz, Sov. Phys. JETP 29, 1107 (1969) Born in 2004 (hcp 4 He) E. Kim and M.H.W. Chan, Nature 427, 225 (2004); Science 305, 1941 (2004) Alexander F. Andreev Ilya M. Lifshitz torsional oscillator = Died (?) in 2012 Kim and M.H.W. Chan, PRL 109, (2012) ρ s / ρ 0.01 Moses Chan
4 total areal density: ρ (nm -2 ) S. Nakamura et al.,arxiv: v2 C2 + IC2 L2 + C2 L2 G2 + L2 14 (gas+liquid) 4 He/ 4 He/graphite IC2 (IC solid) C2 (uniform liquid) F2 (uniform fluid) 3rd layer promotion C2 phase nd layer promotion T (K) 1.6
5 S. Nakamura et al.,arxiv: v2 4 He/ 4 He/graphite Y. Shibayama et al. J. Phys. 150, (2009); to appear (2016) IC2 C2 + IC2 L2 + C2 L2 C2 F2 P.A. Crowell and J. D. Reppy, PRB 53, 2701 (1996) G2 + L2 promotion to 2nd layer (11.8 nm -2 )
6 Supersolid research after 2012 DC superflow measurement through a solid 4 He crystal Ye. Vekhov, W.J. Mullin, and R.B. Hallock, PRL 113, (2014) Ye. Vekhov and R.B. Hallock, PRB 92, (2015) 3 He plug for 1D superfluid channel? 3 He atom 1D S.F. network along screw dislocation cores M. Boninsegni et al., PRL 99, (2007). winding-circle map by PIMC calculation
7 RVB (resonating valence bond) P.W. Anderson (1973, 1987) gapful (Δ J) singlet pair
8 K. Ishida et al., PRL 79, 3451 (1997) C / R C T nm nm -2 MSE model bcc solid 3 He (24.13 cm 3 /mol) ΔS N 2 k B ln2 C T T (mk)
![3 He/HD/HD/gr χ T -1/3! C T 2/3! χ T -1/3 C T 2/3 χ T -1/3 C T 2/3 Ref. [2] Ref.](/docs-images/87/96563965/images/9-5.jpg "[1] This work [1] H. Ikegami et al., PRL 85, 5146 (2000) [2] R. Masutomi, et al.")
9 3 He/HD/HD/gr χ T -1/3! C T 2/3! χ T -1/3 C T 2/3 χ T -1/3 C T 2/3 Ref. [2] Ref. [1] This work [1] H. Ikegami et al., PRL 85, 5146 (2000) [2] R. Masutomi, et al., PRL 92, (2004)
10 S. Nakamura et al.,arxiv: v1 D. Sato et al., JLTP 158, 201 (2010); to appear IC2 ( ) F2 (fluid) Y. Onishi and K. Miyake, JPSJ 68, 3927 (1999) H. Takahashi and D.S. Hirashima, JLTP 121, 1 (2000) C2 + IC2 C2 L2 + C2? non FL QCP? s-wave? p-wave d-wave 2nd layer promotion L2 T F * G2 + L ρ (nm -2 ) (0.6 ρ 6 nm -2 )
11 ε k K K ε F Y. Niimi et al., Appl. Surf. Sci. 241, 43 (2005); PRB 73, (2006) T. Matsui et al., PRL 94, (2005)
12 T. Matsui et al., to appear (2016) 90 T = 80 K in UHV 60 Pressure Gauge to Rotary Pump sample Furnace Furnace Matching Box Copper Coil Flow Meter H 2 gas
13 0.07 nm 0.14 nm + 1 LL n = 1 n = 0 n = -1 D.A. Abanin et al., Sol. State Comm. 143, 77 (2007) (n 0 LL) ( ) (n = 0 LL) zz lower terrace zz- upper terrace T = 4.7 K B = 13 T T. Matsui et al., to appear (2016) n 0 LL l B = 7.1 nm LL0,-1 n = 0 LL (i) ZZ (EF ) (ii)
14 K. Nakayama, et. al., to appear (2016) gas inlet Δ Grafoil (A = 35 m 2 ) exfoliated graphene μ μ 1 cm lead wires suspended graphene suspended on SiO 2 F. Munoz-Rojas et al., PRL 102, (2009) graphene I + I - V + V -
15 M. Bockrath et al., Nature 397, 598 (1999) raw data CB corrected T. Fujimori et al., Nat. Commun. 4, 2162 (2013) 5 nm bulk contact S@SWCNT S@DWCNT 2 nm 2 nm CNT S CNT CNT S CNT 500 nm
16 K. Nakayama, et. al., to appear (2016) empty-dwcnt-ag R T α H = 0 R lnt α = 0.24 for CNT Egger et al., PRL 79, 5082 (1997) Kane et al., PRL 79, 5086 (1997) outer CNT: 1.4 nmφ metallic 99% inner CNT: 0.7 nmφ undefined
17
18 Y. Matsumoto et al., J. Low Temp. Phys. 134, 61 (2004); Physica B , 146 (2003) μ μ Temperature (mk) Magnetic field (Tesla)
19 HSW-1A HSW-2A PNS-2 HSW-1A PNS-1 PNS-2 HSW-2A HSW-2B HSW-1B PNS mm HSW-2B HSW-1B 100 mm
20
研究室ガイダンス(H29)福山研v2.pdf
J.M. Kosterlitz and D.J. Thouless, Phys. 5, L124 (1972); ibid. 6, 1181 (1973) David J. Thouless J. Michael Kosterlitz + ρ T s KT D.J. Bishop and J.D. Reppy, PRL 40, 1727 (1978) ( ) = 2k B m2 T KT π 2 T
19 σ = P/A o σ B Maximum tensile strength σ % 0.2% proof stress σ EL Elastic limit Work hardening coefficient failure necking σ PL Proportional
19 σ = P/A o σ B Maximum tensile strength σ 0. 0.% 0.% proof stress σ EL Elastic limit Work hardening coefficient failure necking σ PL Proportional limit ε p = 0.% ε e = σ 0. /E plastic strain ε = ε e
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1 9 v.0.1 c (2016/10/07) Minoru Suzuki T µ 1 (7.108) f(e ) = 1 e β(e µ) 1 E 1 f(e ) (Bose-Einstein distribution function) *1 (8.1) (9.1)
1 9 v..1 c (216/1/7) Minoru Suzuki 1 1 9.1 9.1.1 T µ 1 (7.18) f(e ) = 1 e β(e µ) 1 E 1 f(e ) (Bose-Einstein distribution function) *1 (8.1) (9.1) E E µ = E f(e ) E µ (9.1) µ (9.2) µ 1 e β(e µ) 1 f(e )
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Masafumi Udagawa Dept. of Physics, Gakushuin University Mar. 8, 16 @ in Gakushuin University Reference M. U., L. D. C. Jaubert, C. Castelnovo and R. Moessner, arxiv:1603.02872 Outline I. Introduction:
C 3 C-1 Cu 2 (OH) 3 Cl A, B A, A, A, B, B Cu 2 (OH) 3 Cl clinoatacamite S=1/2 Heisenberg Cu 2+ T N 1 =18K T N 2 =6.5K SR T N 2 T N 1 T N 1 0T 1T 2T 3T
C 3 C-1 Cu 2 (OH) 3 Cl A, B A, A, A, B, B Cu 2 (OH) 3 Cl clinoatacamite S=1/2 Heisenberg Cu 2+ T N 1 =18K T N 2 =6.5K SR T N 2 T N 1 T N 1 0T 1T 2T 3T 4T 5T 6T C (J/K mol) 20 18 16 14 12 10 8 6 0 0 5 10
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References: 3 June 21, 2002 K. Hukushima and H. Kawamura, Phys.Rev.E, 61, R1008 (2000). M. Matsumoto, K. Hukushima,
References: 3 mailto:hukusima@issp.u-tokyo.ac.jp June 21, 2002 K. Hukushima and H. Kawamura, Phys.Rev.E, 61, R1008 (2000). M. Matsumoto, K. Hukushima, and H. Takayama, cond-mat/0204225. Typeset by FoilTEX
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