Direct Search for Dark Matter with XENON100

1. Direct Search for Dark Matter withXENON100 Oral Examination Ethan Brown June 16, 2009

2. Overview • Evidence for the existence of Dark Matter • Galactic Rotation Curves • Gravitational Lensing • Matter Distribution • Dark Matter Candidates • Properties of Dark Matter • The Neutralino • Detection Methods • Liquid Xenon Detectors • XENON Experiment • My PhD Project PUT A PICTURE HERE

3. Far from galactic center Newton says: Galactic Rotation Curves • Vera Rubin et al (1970) measured • Implies existence of Dark Halo

4. Gravitational Lensing

5. More Gravitational than Luminous Mass • Gravitational Lensing used to measure cluster mass • Compared to mass measured by X-ray observations • Implies Dark Gravitational Mass

6. Chandra image of the Bullet Cluster shows baryonic matter displaced from gravitational matter

7. WMAP measurement of CMB • Best Fit from WMAP : ΩBh2= 0.024 ± 0.001 ΩMh2= 0.14 ± 0.02 Remaining matter must be non baryonic Precision measurement of CMB anisotropy Measure both baryonic and non-baryonic matter densities

8. What is the Universe made of? 70% Dark Energy 25% Dark Matter 5% Ordinary Matter

9. What is Dark Matter? • A good candidate: • Has the correct abundance • Does not interact strongly with normal matter Charge and Color Neutral • Falls naturally out of larger theory • Is detectable by experiment Many proposed solutions: • WIMPS • MACHOS, Sterile Neutrinos, Mirror Matter, Extra Dimensions, Daemons... Heavy Particle m~100GeV Weak scale interactions with ordinary matter Thermal equilibrium at beginning of Universe Gives correct relic abundance

10. Physics We Already Know • Standard Model of Particle Physics Standard Model of Cosmology

11. SuperSymmetry (SUSY) • Extend Standard Model by imposing new symmetry between bosons and fermions • Doubles # of particles in SM

12. SUSY Dark Matter Particles and sparticles masses differ Breaks electroweak symmetry • Broken symmetry • Hierarchy Problem • Unification of forces • R-Parity • Neutral SUSY particles Difference between Higgs mass and Planck scale Modified couplings DO meet in 1 point Needs to be conserved LSP is stable 4 neutralinos mass eigenstates The lightest neutralino is stable and is an excellent dark matter candidate

13. Relic Density • Neutralino is Majorana Thermal Equilibrium Relic Abundance Remains

14. Indirect Detection Experiments • Search for signatures of WIMP annihilation • Ground based telescopes • VERITAS, ANTARES, IceCube • Space telescopes • Fermi Telescope, PAMELA

15. Direct Detection Experiments • Cryogenic Crystals • CDMS, CRESST, EDELWEISS • Measure Heat and Light • Liquid Noble Detectors (xenon, argon) • XENON, ZEPLIN, WARP, DEEP/CLEAN • Measure Charge and Light

16. Status of Direct Detection Search • XENON10 • σ < 8.8 x 10- 44 cm2 at 100GeV • CDMS • σ < 6.6 x 10- 44 cm2 at 60GeV

17. XENON Program • Liquid Xenon Detector • Direct Search for WIMP Nucleon Interactions • Located in Gran Sasso Underground Laboratory • Phased program • 10kg → 100kg → 1T...

18. Evolution of XENON • XENON10 • Published Results 2008 • XENON100 • Take Data This Fall • XENON100 Upgrade • Approved for Construction • XENON 1Ton • Proposal submitted • XAX / MAX 10Ton • Published concept 2008

19. Liquid Xenon Detectors

20. Electron Recoil Discrimination • S2/S1 Cut • Separates nuclear from electron recoils • Cut at nuclear recoil mean • 99.9% Rejection Xenon 10 Calibration

21. Self Shielding • Very short interaction length • Fiducial volume cut • Accept events from quiet center

22. WIMP Signal in Liquid Xenon

23. XENON100 Experiment • 170kg (50kg Fiducial) • Sensitivity σ ~ 2x10 - 45 cm2 at 100GeV

24. XENON100 Detector • Low Background Materials • Purified Xenon by removing Kr85 • 242 PMTs in TPC and Active Veto • mm Position Resolution

25. QUPID Photo Detector • Increased Detector Size requires Lower Background • Low Activity Photo Sensor being developed • 3” Photo Tube • Quartz Structure • Small APD at Center • Necessary for Large Scale Detectors QUartz Photon Intensifying Device (QUPID)

26. XENON100 Upgrade • Next Phase of XENON Program • Already Approved and Funded • QUPIDs on bottom • R8520s on top • Run in Existing Shield in Gran Sasso

27. Ton Scale and Beyond • 1 Ton → 10 Ton Target • 4pi QUPID Coverage • XAX 10Ton Detector • Xenon and Argon Targets • Dark Matter, Neutrinoless DBD, pp Solar Neutrinos

28. My PhD Project • Final Assembly of XENON100 Detector • Software Development • PMT Calibrations • Complete Software Package • Monte Carlo Simulations • Signal Generation / Digitization • Reconstruction / Analysis • Analysis of XENON100 Data • R&D / Simulations for Large Scale Detectors

29. Final Detector Assembly

30. PMT Calibration • Illuminate PMTs in-situ with external LED • Measure Gain by single photo electron response

31. Complete Software Package • Simulate every physical process • Particle Interactions • Gamma, Neutron, WIMP • Photon Propagation (Light Collection) • Electron Drift including Diffusion • Proportional Scintillation (S2) • PMT Response • FADC Digitization • Run Analysis Software on MC and Data

32. Proportional Scintillation • Simulate Electron Trajectories near Anode • Generate S2 Photons by: N = 70(E/P – 1.3)P x • Use Light Simulations to Generate S2 Signal

33. QUPID Screening • Screened 4 Mechanical Samples in Gran Sasso Gator Gamma Detector < 0.91 mBq/QUPID 238U < 2.1 mBq/QUPID 232Th

34. QUPID Field Simulations • First Working • QUPID • Non-uniform electron collection

35. Electron Trajectory Simulations • 1T Detector with Conventional Wires 10T Detector with Acrylic Vessel

36. Light Collection Simulations

37. Summary • Strong Observational Evidence for Dark Matter • Rotation Curves • Gravitational Lensing • Matter Distribution • SUSY and WIMPs as Dark Matter • SUSY as Extension of Particle Physics • Neutralino a Natural Dark Matter Candidate • Detecting Dark Matter • XENON100 Dark Matter Search • Future Large Scale Dark Matter Detectors

38. BACK UP SLIDES

39. Precision measurements of 21cm Hydrogen line • 21cm Hyperfine Transition • Precisely measure redshift → velocity • Follows Dark Matter Halo Model

40. SUSY is Broken Symmetry • Broken SUSY implies particle and sparticle masses different • Automatically breaks Electroweak symmetry V = (|μ|2 + mH2)|H0|2 V = (|μ|2 + mHu2)|Hu0|2 + (|μ|2 + mHd2)|Hd0|2 – (BHu0Hd0 + c.c.) + 1/8 (g2 +g'2)(|Hu0|2 - |Hd0|2) Higgs Potential : Replaced by :

41. Gauge Hierarchy Problem • In SM, mh ~ Λ naturally • But mh ~ 100 GeV and Λ ~ 1019 GeV Cancellation of 1 part in 1034

42. SUSY Solves This • Extra term with opposite sign • Since SUSY is broken, cancellation not perfect

43. Unification of Forces • Couplings do not meet at high energy • In SUSY, Couplings are modified • SUSY also explains αEM < αweak < αS

44. Proton Decay and R Parity • SUSY allows Proton Decay • Forbid this with R Parity Conservation: • RP = (-1)2(B-L)+2S • Requires 2 super-particles in each interaction • Lightest SUSY Particle (LSP) is stable • Good Dark Matter Candidate

45. Neutral SUSY Particles

46. Power Spectrum Sensitive to Baryon Density • Ratio of 1st to 2nd peak gives baryon density. • Best fit from WMAP gives : • Remaining matter must be non-baryonic .

47. Particle Simulations • Gammas and Neutrons • From Radioactive Decays in Materials • From Sources for Calibration

48. Photon Propagation • Simulate UV Photons • Absorption in Xenon • Reflection off of Teflon and Liquid Surface • Estimate Collection Efficiency