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Impact of quark flavour violation on the decay in the MSSM K. Hidaka Tokyo Gakugei University / RIKEN, Wako Collaboration with A. Bartl, H. Eberl, E. Ginina,

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Presentation on theme: "Impact of quark flavour violation on the decay in the MSSM K. Hidaka Tokyo Gakugei University / RIKEN, Wako Collaboration with A. Bartl, H. Eberl, E. Ginina,"— Presentation transcript:

1 Impact of quark flavour violation on the decay in the MSSM K. Hidaka Tokyo Gakugei University / RIKEN, Wako Collaboration with A. Bartl, H. Eberl, E. Ginina, W. Majerotto Reference: Phys. Rev. D 91 (2015) 015007 [arXiv:1411.2840 [hep-ph] ] The 40th general meeting of the ILC physics working group, 24 Jan 2015, KEK

2 Contents 1. Introduction 2. MSSM with Quark Flavour Violation (QFV) 3. Constraints on the MSSM 4. Benchmark QFV Scenario 5. h → c cbar at full 1-loop level 6. Numerical results 7. Theoretical and Experimental errors 8. Conclusion

3 1. Introduction What is the SM-like Higgs boson discovered at LHC? It can be the SM Higgs boson. It can be a Higgs boson of New Physics. This is the most important issue in the present particle physics world! Here we study a possibility that it is the lightest Higgs boson of Minimal Supersymmetric Standard Model (MSSM) focusing on the width of the decay. We compute the width at full one-loop level in the scheme in the MSSM with non minimal Quark Flavor Violation (QFV). We find that the difference of the MSSM and SM predictions for the width can be quite significant compared with expected experimental errors at future lepton colliders such as ILC.

4 2. MSSM with QFV The basic parameters of the MSSM with QFV: tan  M 1 M 2 M 3  M 2 Q,  M 2 U,  M 2 D,  T U  T D   tan  m A,  M 1  M 2  M 3,  M 2 Q,   M 2 U,   M 2 D,   T U   T D    at Q = scale  (  u, c, t or d, s, b)   at Q = m h scale  (  u, c, t or d, s, b) tan  ratio of VEV of the two Higgs doublets / tan   ratio of VEV of the two Higgs doublets / m A : CP odd Higgs boson mass (pole mass) M 1, M 2,M 3 : U(1), SU(2),SU(3) gaugino masses  higgsino mass parameter   higgsino mass parameter M 2 Q,  left squarksoft mass matrix M 2 Q,   left squark  soft mass matrix M 2 U  right up-type squarksoft mass matrix M 2 U   right up-type squark  soft mass matrix M 2 D  right down-type squarksoft mass matrix M 2 D   right down-type squark  soft mass matrix T U  trilinear coupling matrix of up-type squark and Higgs boson T U   trilinear coupling matrix of up-type squark and Higgs boson T D  trilinear coupling matrix of down-type squark and Higgs boson T D     trilinear coupling matrix of down-type squark and Higgs boson

5 Key parameters in this study are: QFV parameters:  LL 23,  uRR 23,  uRL 23,  uLR 23 QFC parameter:  uRL 33

6 We respect the following experimental and theoretical constraints: (1) the recent LHC limits on the masses of squarks, gluino, charginos and neutralinos. tan  (2) the constraint on ( m A, tan  ) from the recent MSSM Higgs boson search at LHC. (3)the constraints on the QFV parameters from the B meson data. etc. (4) the constraints from the observed Higgs boson mass at LHC (allowing for theoretical uncertainty): 122.7 GeV < m_h 0 < 127.6 GeV. (5) theoretical constraints from the vacuum stability conditions for the QFC/QFV trilinear couplings T Uab. (6) The experimental limit on SUSY contributions to the electroweak  parameter  (SUSY) < 0.0012. 3. Constraints on the MSSM

7 4. Benchmark QFV Scenario Sizable QFV parameters large mixing scenario (large top-trilinear-coupling scenario) decoupling Higgs scenario

8 Physical masses in our benchmark scenario

9 Benchmark QFV scenario mass-splitting due to large mixing

10 Main features of our scenario: - Large scharm-stop mixing terms M 2 Q23,  M 2 U23, T U ,T U  - Large QFV/QFC trilinear couplings T U ,T U , T U  The gluino loop contributions to the width are enhanced! (see next page) Large deviation of the MSSM prediction for from the SM prediction! This makes it easier to discover the QFV SUSY effects in this decay !

11 In this large & mixing scenario; Gluino loop contributions can be large! In our scenario “trilinear couplings“ (,, couplings) = (T U  T U , T U  ) are large! couplings are large!

12 5. h 0 → c cbar at full 1-loop level We compute the width at full 1-loop level in the renormalization scheme in the MSSM with QFV. We take the normalization scale as Q =. We study the normalization scale Q dependences of the width in the range. For details, see Phys. Rev. D 91 (2015) 015007 [arXiv:1411.2840 [hep-ph] ]

13 Invariant decay amplitude : M inv = M tree + M 1-loop +... = + + + +... M 1-loop = M SUSY QCD-loops + M EW-loops = M(gluon-loop) + M(gluino-loop) + + M(neutralino/chargino/squark - loop) (Note) M EW-loops is small. (Note) In our benchmark scenario, M(gluino-loop) is significantly larger than M(gluon-loop): M(gluon-loop): M(gluino-loop) ~ 1 : 2

14 Main one-loop contributions with SUSY particles

15 The decay width : ~ |M inv | 2 = (M tree + M 1-loop +...) * (M tree + M 1-loop +...) = | M tree | 2 + 2 Re(M tree * M 1-loop ) +... Each 1-loop diagram contributes to the width separately without interfering with each other! (Note) We include real photon /gluon emissions in the width in order to cancel the IR divergences. (Note) We improve gluon loop contribution by including gluonic contributions. (See Spira, hep-ph9705337)

16 Contour plot of the deviation of the MSSM prediction from the SM prediction (PDG2014) in plane - The MSSM prediction is very sensitive to the QFV parameters ! - The deviation of the MSSM prediction from the SM prediction can be very large (as large as ~ - 35%)! 5. Numerical results mixing parameter

17 Contour plots of the deviation of the MSSM prediction from the SM prediction in plane - The MSSM prediction is very sensitive to the QFV parameters ! - The deviation of the MSSM prediction from the SM prediction can be very large (as large as ~ 20%)! mixing parameter

18 Contour plots of the deviation of the MSSM prediction from the SM prediction in plane - The MSSM prediction is very sensitive to the QFV parameters ! - The deviation of the MSSM prediction from the SM prediction can be very large (as large as ~ - 30%)! mixing parameter

19 QFV parameter dependences of one-loop, improved g, and EW contributions to - The gluino loop contribution is sensitive to the QFV parameters! - The gluino loop contribution can be very large (up to 45%)!

20 If we switch off all the QFV parameters in our benchmark QFV scenario, then the MSSM prediction becomes nearly equal to the SM prediction!: The QFC supersymmetric contributions change the width by only ~ -1.5% compared to the SM value. Comment on QFC SUSY contributions

21 7. Theoretical and Experimental Errors (a) 6% See; arXiv:1310.8361: Higgs WG Report Snowmass2013 arXiv:1307.1347: Report of the LHC Higgs Cross Section Working Group arXiv:1311.6721v3: Phys. Rev. D 89 (2014) 033006 arXiv:1404.0319: Lepage-Mackenzie-Peskin (b) 6% (for our benchmark QFV scenario) * uncertainties due to error of charm quark mass : 5.2% * uncertainties due to error of QCD coupling : 2% * uncertainties due to errors of the other SM input parameters, such as, are negligible. * uncertainties due to renormalization scale Q dependences of the width: 0.5% (see next plot)

22 The renormalization scale Q dependence of the MSSM width in the range The renormalization scale Q dependence of the MSSM width is small; it results in ~ 0.5% theoretical uncertainties.

23 (c) 3% (5.6%) (at ILC (500GeV) with 1600 fb-1 (500 fb-1 ) ) See; ILC Higgs White Paper, arXiv:1310.0763 J. Tian and K. Fujii, PoS(EPS-HEP2013) 316, arXiv:1311.6528 The deviation of the MSSM prediction from the SM width can be very large (as large as ~ 35%) as shown above! Such a large deviation can be observed at ILC (500GeV), even if we take into account the theoretical uncertainties of the predictions! (Note) A measurement of the width at LHC (even at HL-LHC) is very difficult due to the difficulty in charm-tagging.

24 8. Conclusion - We have calculated the width of the SM like Higgs boson decay h -> c cbar at full one-loop level (in the DRbar renorm. scheme) in the MSSM with non minimal QFV. - The QFV effect (i.e. scharm-stop mixing effect) on the width can be quite large despite the very strong constraints on QFV from the B meson data. - The deviation of the MSSM prediction from the SM width can be strongly enhanced (up tp ~ 35%) by the QFV effect! - The deviation of the MSSM prediction from SM width can be quite significant compared with the expected experimental errors at ILC(500GeV), even if we take into account the theoretical uncertainties of the predictions! -Therefore, we have a good chance to discover the QFV SUSY effect in this decay h -> c cbar at ILC!

25 -Our analysis suggests the following: PETRA/TRISTAN discovered virtual Z 0 effect for the first time. Similarly, ILC could discover virtual SUSY effects for the first time!

26 END

27 Backup Slides

28 Constraints on the MSSM parameters from B meson data and Higgs boson mass

29 Example of gluonic contributions

30 Gluino mass limit from LHC(7/8 TeV) x x x Our benchmark QFV scenario:

31 STOP mass limit from LHC(7/8 TeV) x x Our benchmark QFV scenario:

32 From Hewett’s talk at LCWS2013

33

34 Black area is an excluded region in pMSSM = (MSSM with MFV) x Squark - gluino mass limit from LHC(7/8 TeV) Our benchmark QFV scenario: = (degenerate mass of 1 st & 2 nd generation squarks)

35

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