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What’s the Matter in the Universe? Richard Schnee Syracuse University Quarknet Lecture July 13, 2012 The Search for Dark Matter.

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Presentation on theme: "What’s the Matter in the Universe? Richard Schnee Syracuse University Quarknet Lecture July 13, 2012 The Search for Dark Matter."— Presentation transcript:

1 What’s the Matter in the Universe? Richard Schnee Syracuse University Quarknet Lecture July 13, 2012 The Search for Dark Matter

2 Richard Schnee Quarknet Lecture - Dark Matter sun r Is there Mass where there is no Light? If mass of solar sytem is where the light is, M(r) is constant, so v = k / √r In the solar system, >99.7% of the mass is where the light (i.e. the sun) is. The (dark) planets don’t count for much… Solar system M m

3 Richard Schnee Is there Mass where there is no Light? * M m Galaxy If mass of galaxy is where the light is, M(r) is constant for r > r edge, so v = k / √r * Galaxy image from DSS2 5” x 5” r 10 kpc Quarknet Lecture - Dark Matter

4 Richard Schnee M m Is there Mass where there is no Light? Must be mass where there is no light: Dark Matter density  DM ≥ 10  stars * Galaxy image from DSS2 5” x 5” § Rotation curve for the galaxy NGC3198 from Begeman 1989 § Galaxy r If mass of galaxy is where the light is, M(r) is constant for r > r edge, so v = k / √r * 10 kpc Quarknet Lecture - Dark Matter

5 Richard Schnee 6 Li 7 Li 9 Be No stable nuclei Can determine total amount of protons and neutrons (“baryons”) in the universe by how much deuterium formed in first 30 minutes of universe More protons and neutrons would make reactions go faster, resulting in less “leftover” 2 H, 3 He trace 10 -10 1H1H 75% 2H2H 0.006% 3 He 0.004% 4 He 24% Energy per nucleon Could the Dark Matter be “Normal” Stuff? Quarknet Lecture - Dark Matter

6 Richard Schnee Gas clouds between a quasar and Earth absorb some of a quasar’s light –Absorption line from each cloud is redshifted a different amount since it travels a different distance to us –We can learn about protogalactic clouds by studying these absorption lines Quasars Light Up the Early Universe Relatively nearby quasar Distant quasar

7 Richard Schnee Gas clouds between a quasar and Earth absorb some of a quasar’s light –Absorption line from each cloud is redshifted a different amount since it travels a different distance to us –We can learn about protogalactic clouds by studying these absorption lines Quasars Light Up the Early Universe quasar Gas clouds Each absorption line is H from a different cloud, redshifted a different amount

8 Richard Schnee Deuterium Measurements Measure the amount of deuterium relative to hydrogen in some of these gas clouds –Compare number of photons absorbed by Hydrogen to number absorbed by Deuterium Tytler et al. Nature 381, 207 (1996) Quarknet Lecture - Dark Matter

9 Richard Schnee Baryon Density Precisely measured deuterium abundance tells us the baryon density – Observations of other light element abundances consistent –Normal matter is only ~20% of the total mass in galaxies or clusters, as measured from gravitational effects Percentage of total mass 4% 8% 20% 4 He prediction D prediction 3 He prediction prediction Quarknet Lecture - Dark Matter

10 Richard Schnee “Non-Baryonic” Dark Matter Unusual stuff… to us –Not made of atoms! –No such matter with the right properties has ever been observed! Something new must exist! Particle physics would make a lot more sense if these additional particles exist… and these particles may be 80% of the mass density of the universe –Axions (searches I won’t discuss are in progress) –WIMPs - Weakly Interacting Massive Particles Massive: source of gravity Weakly-interacting: not star-forming Arise naturally under supersymmetry (and other favored extensions to the standard model of particle physics) Quarknet Lecture - Dark Matter

11 Richard Schnee Definition: cross section  probability of collision Quarknet Lecture - Dark Matter

12 Richard Schnee Definition: cross section  probability of collision.... electron WIMP Quarknet Lecture - Dark Matter

13 Richard Schnee How are WIMPs Produced? Early Universe is a Particle Factory Convert energy to mass E=mc 2 time distance WIMP quark anti-quark When Universe expands/cools enough that particles have energy less than mc 2, WIMP production stops (to produce some today requires an expensive particle accelerator) (part of proton) Quarknet Lecture - Dark Matter

14 Richard Schnee Still around? WIMP quark anti-quark time distance Expanding Universe and Weak Interactions – annihilations stop if cross sections are small enough There may be lots of WIMPs still around today. Rough calculation suggests WIMPs would be ~80% of universe’s mass! Quarknet Lecture - Dark Matter

15 Richard Schnee Still around? WIMPs would be most of the mass of our Galaxy NUTRITIONAL WARNING: may contain ten 60-GeV WIMPs. 20 million WIMPs may pass through each second. Expanding Universe and Weak Interactions – annihilations stop if cross sections are small enough Quarknet Lecture - Dark Matter There may be lots of WIMPs still around today. Rough calculation suggests WIMPs would be ~80% of universe’s mass!

16 Richard Schnee Annihilation implies Scattering WIMP quark anti-quark time distance WIMP Terrestrial Particle Detector energy transferred appears in ‘ wake ’ of recoiling nucleus WIMP-Nucleus Scattering Occasionally, one of these billions of WIMPs might interact. Quarknet Lecture - Dark Matter

17 Richard Schnee Annihilation implies Scattering WIMP quark distance time WIMP Terrestrial Particle Detector energy transferred appears in ‘ wake ’ of recoiling nucleus WIMP-Nucleus Scattering Big Problem: weakly interacting. Expect less than one-a-year in a kilogram detector Occasionally, one of these billions of WIMPs might interact. Quarknet Lecture - Dark Matter

18 Richard Schnee Background Radioactivity: It’s in the air Collect dust particles on filter paper by vacuuming room air: Quarknet Lecture - Dark Matter

19 Richard Schnee Background Radioactivity: It’s in the air Then count the rate of radioactive decays with a Geiger counter: Quarknet Lecture - Dark Matter

20 Richard Schnee What Nature has to Offer What we hope for! D. S. Akerib Quarknet Lecture - Dark Matter

21 Richard Schnee LiF Elegant V&VI NEWAGE TEXONO CsI IGEX Gran Sasso DAMA/LIBRA CRESST I/II CUORE XENON10/100 WArP DArkSIDE CanFranc IGEX ROSEBUD ANAIS EDELWEISS I/II EURECA Soudan CoGeNT CDMS II/ SuperCDMS XMASS KIMS ORPHEUS COUPP SNOLAB Picasso DEAP-1/3600 MiniCLEAN ArDM LUX WIMP Detection Experiments Worldwide Boulby NaIAD ZEPLIN I/II/III DRIFT 1/2/3 Quarknet Lecture - Dark Matter

22 Richard Schnee SuperCDMS:Really Cool Detectors Detectors sensitive to individual particle interactions. Cooled in 3 He- 4 He dilution refrigerators using liquid nitrogen and liquid helium to 0.04° above absolute zero (“cryogenic”) Tell WIMPs from non-WIMPs by measuring heating and ionization. Hockey puck of Ge with surface photolithography (like Si chips, but much larger) Our experiment is called the Cryogenic Dark Matter Search (CDMS/SuperCDMS) 1  tungsten 380  x 60  aluminum fins 3 in. 1 cm Quarknet Lecture - Dark Matter

23 Richard Schnee Measuring Ionization E An applied Electric field drifts the charges to the surface, yielding a voltage signal An incoming particle scatters off of either an electron or a nucleus The recoiling electron or nucleus frees electrons as it travels through the semiconductor Quarknet Lecture - Dark Matter

24 Richard Schnee Measuring Deposited Energy An incoming particle scatters off the crystal depositing energy Energy spreads to the surface and is collected in aluminum “fins” Energy diffuses into a superconducting transition-edge sensor Side view Not to scale! Quarknet Lecture - Dark Matter

25 Richard Schnee How CDMS Gets Rid of the Haystack WIMPs ‘look’ different –Photons and electrons collide with electrons low mass so move quickly, ionize efficiently produce more “fast” phonons –WIMPs (and neutrons) collide with nuclei higher mass so move slowly, ionize much less Energy Ionization Ionization/ Recoil Energy Background Signal Ionization Yield Quarknet Lecture - Dark Matter

26 Richard Schnee Reducing the “Hay” ’s’s  ’s’s  Quarknet Lecture - Dark Matter Put experiment deep underground (Soudan Mine, Minnesota) so no cosmic rays, very few muons reach it Use clean, low-radioactivity (= screened) materials Surround detectors with clean shielding Especially important for getting rid of neutrons (since neutrons interact with the nucleus, just like WIMPs)

27 Richard Schnee Outside the Shielding Quarknet Lecture - Dark Matter

28 Richard Schnee Sweet Lecture - Dark Matter

29 Richard Schnee Inside the Shielding Quarknet Lecture - Dark Matter

30 Richard Schnee Quarknet Lecture - Dark Matter Status and Projections of Dark Matter Detection Particle Physicists calculate what range of mass and cross section is possible for a given candidate particle –Big range of possibilities!

31 Richard Schnee Quarknet Lecture - Dark Matter Status and Projections of Dark Matter Detection Particle Physicists calculate what range of mass and cross section is possible for a given candidate particle –Big range of possibilities! No compelling evidence of WIMPs yet –Cross sections above curves are ruled out

32 Richard Schnee Quarknet Lecture - Dark Matter Status and Projections of Dark Matter Detection Particle Physicists calculate what range of mass and cross section is possible for a given candidate particle –Big range of possibilities! No compelling evidence of WIMPs yet –Cross sections above curves are ruled out New technologies making steady progress –Improved rejection –Increase mass to ton- scale Stay tuned for new results coming soon!

33 Richard Schnee Thanks for listening! Visit us on the web at cdms.syr.edu Quarknet Lecture - Dark Matter

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