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1 Based on N. Nagata, S. Shirai, JHEP 1403 (2014) 049.

2 Ø Ø Y. Okada, M. Yamaguchi, T. Yanagida (1991), H. E. Haber, R. Hempfling (1991) J. R. Ellis, G. Ridolfi, F. Zwirner (1991)

3 Scalar Par cles Gravi no Higgsinos M S = 10 (2-4) TeV Gauginos ( ) Gluino Bino Wino O(1) TeV pure gravity media.on, M. Ibe, T. T. Yanagida (2012) simply unnatural supersymmetry, N. Arkani- Hamed, et.al. (2012) spread supersymmetry, L. J. Hall and Y. Nomura (2012) mini- split, A. Arvanitaki, et.al. (2012)

4 q i q I q j g g g γ (g) q J u L ũ L t L t R ũ R u R q j q i M S O(10 2 )TeV T. Moroi and M. Nagai (2013), D. McKeen, M. Pospelov, A. Ritz (2013) W. Altmannshofer, R. Harnik, J. Zupan (2013), K. Fuyuto, J. Hisano, N. Nagata, K. Tsumura (2013)

α 1 50 40 30 SU(2) U(1) α 1 28 27 26 High- scale

16 Scale (GeV) Zoom 25 10 16 Scale (GeV) Low-

5 α SU(2) U(1) α High- scale SUSY SU(3) Scale (GeV) Zoom Scale (GeV) Low- scale SUSY J. Hisano, T. Kuwahara, N. Nagata (2013).

6 U i U k d R (s R ) u R t R τ R H C H C E j D l H u Hd lifetime (years) M S = μ M 2 = 3 TeV M 16 = GeV tanβ = 3 tanβ = 5 Hc tanβ = 10 tanβ = 30 tanβ = 50 s L (d L ) (b) (ν τ ) L T. Goto and T. Nihei (1999) V. Lucas and S. Raby (1997) M S (TeV) J. Hisano, D. Kobayashi, T. Kuwahara, N. Nagata (2013).

7 Ø Ø

8 Sfermion Flavor Viola^on s ν µ,ν τ δ Q L 13 t b δ Q L 13 ũ d g u d

9 /Γ(p K + ν) [year] δ Q L 13 δ Q L 12 M S = 100 TeV, M 1 = 600 GeV," M 2 = 300 GeV, M 3 = -2 TeV," μ = M S, M Hc = GeV," tanβ = 5" δũr 13 δ Q L 23 SK Limit δ N. Nagata, S. Shirai (2013).

10 Minimal Flavor Violation lifetime (years) lifetime (years)

11 U i D j U k E l X X Q k L l Q i Q j

12 /Γ(p π 0 µ + ) [year] δ Q L 13 δ Q L 12 δũr 13 SK Limit M S = 100 TeV, M 1 = 600 GeV," M 2 = 300 GeV, M 3 = -2 TeV," μ = M S, M Hc = GeV," tanβ = 5" δ N. Nagata, S. Shirai (2013).

13 Summary

14 Backup

15 Theory Experiment δ Q L 23 = δũr 23 =0.9 Q L 3 =4 tan β m 0 [TeV] N. Nagata, S. Shirai (2013).

16 q i q I q j g g q j q J q i Uppuer bound 0.1 δũr 13 = δũr 23 (D0 ) δ d R 13 (Bd 0) δ d R 23 (Bs) m 0 [TeV] δ d R 12 (K 0 ) δũr 12 (D0 ) δ d R 13 = δ d R 23 (K 0 ) Uppuer bound 0.01 δũr 13 = δũr 23 = δ Q L 13 = δ Q L 23 (D0 ) δ d R 13 = δ Q L 13 (B0 d ) δ d R 23 = δ Q L 23 (B0 s) m 0 [TeV] δ d R 12 = δ Q L 12 (K0 ) δũr 12 = δ Q L 12 (D0 ) δ d R 13 = δ d R 23 = δ Q L 13 = δ Q L 23 (K0 ) N. Nagata, S. Shirai (2013).

17 1 Uppuer bound 0.1 m 0 [TeV] d R 12 = QL 12 ũr 12 = Q L 12 d R 13 = QL 13 Q L 13 ũr 13 = g γ (g) u L ũ L t L t R ũ R u R N. Nagata, S. Shirai (2013).

18 M Hc M 3 /M 2 = 3 M 3 /M 2 = 9 M 3 /M 2 = μ H = M S M 2 = 3TeV tanβ = 3 M S (TeV) J. Hisano, T. Kuwahara, N. Nagata, Phys. Le_. B723 (2013) 324.

19 S. Dimopoulos and H. Georgi (1981) N. Sakai (1981) (M HC : )

20 Q i Q k U i U k H C H C H C H C LLLL Q i L l E j D l RRRR LLLL RRRR

21 LLLL RRRR

23 Sfermion Flavor Viola^on

24 -< 0 (ud) R u L p> < 0 (ud) L u L p> <K 0 (us) R u L p> <K 0 (us) L u L p> -<K + (us) R d L p> <K + (us) L d L p> -<K + (ud) R s L p> <K + (ud) L s L p> -<K + (ds) R u L p> -<K + (ds) L u L p> < (ud) R u L p> < (ud) L u L p> N f =2+1 "direct" N f =2+1 "indirect" W 0 (µ=2gev) [GeV 2 ] Y. Aoki, E. Shintani, and A. Soni, arxiv:

25 10 35 Γ 1 (p K + ν)[year] Long-Distance Theory Short-Distance δ Q L 13 N. Nagata, S. Shirai (2013).

26 s ν τ B s δ Q L 23 b ν τ t b δ Q L 13 δ Q L 13 ũ d g u d

27 ηµ + ηe + K + ν K 0 µ + K 0 e + π + ν M S = 100 TeV, M 1 = 600 GeV," M 2 = 300 GeV, M 3 = -2 TeV," μ = M S, M X = GeV," tanβ = 5" π 0 µ + π 0 e Γ 1 [year]

28 Dim- 5 proton decay via Planck suppressed operators 12 M scalar, no f mixing 11 m h excl tan 1 Log 10 MScalar GeV m h excl tan 2 Hyper K p K excl Hyper K 7 p e excl Log 10 M ino M Scalar M. Dine, P. Draper, W. Shepherd, arxiv:

29 Soudan Frejus Kamiokande IMB Super-K p e + 0 n e + n + - p + 0 n + p + n 0 p e + p + n p e + 0 n e + n 0 p + 0 p + p e + p + n p e + K 0 n e + K - n e - K + p + K 0 n + K - p K + n K 0 p e + K*(892) 0 p K*(892) + n K*(892) /B (years) Super- Kamiokande

30 1 0.1 Uppuer bound 0.01 δ Q L 13 δ Q L 12 δ Q L 23 M S = 100 TeV, M 1 = 600 GeV," M 2 = 300 GeV, M 3 = -2 TeV," μ = M S, M Hc = GeV," tanβ = 5" m 0 [TeV] δũr 13 N. Nagata, S. Shirai (2013).

pptx

pptx Based on J. Hisano, T. Kuwahara, N. Nagata, Phys. Lett. B723 (2013) 324, J. Hisano, D. Kobayashi, T. Kuwahara, N. Nagata, JHEP 1307 (2013) 038, N. Nagata, S. Shirai, JHEP 1403 (2014) 049. 1. Introduc+on