Where has all of the Antimatter Gone? - PowerPoint PPT Presentation

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Where has all of the Antimatter Gone?

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Title: Where has all of the Antimatter Gone?


1
Where has all of the Antimatter Gone?
  • Kevin Pitts
  • University of Illinois
  • September 26, 2001

2
Outline
  • Why do we think the antimatter is missing?
  • Quarks, gluons and all that
  • the early universe
  • The Fermilab Tevatron
  • The CDF Detector
  • What its like to collaborate
    with 500 others
  • What the future holds

I. Physics II. Technology III. Sociology
3
The Standard Model
  • 6 quarks
  • quarks combine to make hadrons
  • puud, ?ud
  • 6 leptons
  • free particles
  • electron, electron neutrino
  • Bosons carry force
  • W,Z,?,g

baryons
4
Masses
  • Masses are heirerarchical
  • strange heavier than down
  • bottom heavier than strange
  • More massive particles more difficult to produce
    in accelerators
  • converting energy to matter
  • more energy more difficult
  • Aside in Standard Model, neutrinos are massless.
  • Experimental evidence indicates that neutrinos do
    have mass

5
Mass/Energy
  • Einstein was right
  • the speed of light, c, is a constant
  • therefore, we have an equivalence between mass
    and energy
  • Implications
  • the kinetic energy of the collisions can be
    converted to mass!
  • Example pp ? tt X
  • kinetic energy of proton/antiproton gets
    converted into top quark mass
  • Massive particles can decay to products with less
    mass
  • Example t ? b ??
  • m(top) gtgt m(b) m(?) m(?)
  • the remaining mass/energy of the top goes into
    kinetic energy of the b, ?, and ?

E mc2
6
Universal Evolution
  • The early universe (tlt1sec) was quite hotso hot
    that there was a soup of quarks, photons and
    gluons
  • reaction ?? ? qq proceeded in both directions
  • photons creating matter/antimatter (need
    high-energy photons)
  • matter/antimatter annihilation (can be low
    energy quarks)
  • these types of reactions are quite frequent in
    particle accelerators and are well measured
  • The universe cooled ? lower energy ?
  • cool universe qq ? ?? and not the opposite
    direction!
  • Produce equal amounts of matter and antimatter.
    Annihilation requires equal amounts of matter and
    antimatter.
  • Q Why isnt the universe full of photons?
  • Q Why arent there equal amounts of matter and
    antimatter left?

7
Today
  • First experiment
  • do you know of anyone or anything that has
    annihilated?
  • Locally, we are quite sure that there is
    virtually no antimatter
  • exception small amounts of antimatter are
    produced when cosmic rays interact in the
    atmosphere
  • Non-locally, astronomers see no evidence for
    annihilating stars or galaxies
  • if there is antimatter, then it has to be
    isolated
  • unlikely, because there would have to have been a
    segregation in the early universe.
  • Actually, our universe is full of photons
  • N?/Nbaryon 109
  • after annihilations 100000001 quark for every
    1000000000 antiquark

8
Sakarhovs Conditions
  • Soviet physicist Andrei Sakarhov put forth three
    conditions required for a matter/antimatter
    asymmetry in the universe
  • Baryon number violation
  • example proton decay (not seen)
  • CP violation
  • some force of nature treats matter and antimatter
    differently!
  • Phase transition
  • at some point, a phase transition froze out
    this asymmetry

9
CP Violation
  • CP violation is jargon for a force that doesnt
    treat matter and antimatter the same.
  • In the 1960s, everybody thought CP was conserved
    (not violated)
  • Then in 1964, CP violation was (unexpectedly)
    observed in the decays of mesons containing
    strange quarks.
  • More than 35 years later, we still dont really
    understand this phenomena,
  • but now we have a new system to study CP
    violation
  • the strange quark has a heavy brother bottom

10
Why Study Bs
  • 1964 CP violation was (unexpectedly) observed in
    the decays of mesons containing strange quarks.
  • Since the bottom quark is a heavy version of a
    strange quark, should see CP violation in B
    decays, too.
  • Also, the bottom is quite interesting (unique)
    for other reasons
  • 1. It wants to decay to top, but cant.
  • 2. It has a long lifetime. (It lives on
    average .45mm)
  • 3. It can mix with its anti-partner (B /B
    mixing)

11
How to Measure B Decays
  • Need an accelerator
  • particle is massive
  • mB 5mp
  • doesnt occur naturally
  • at least in a detectable way
  • accelerator produce it via high energy collisions
  • Need a detector
  • must measure the collisions
  • Bs are more rare than most things, less rare
    than others (like top, W/Z, Higgs?)
  • Need lots of readout electronics and data
    acquisition
  • high rates
  • require fast processing
  • Need lots of computing power and storage
  • data sizes in PetaByte range
  • kB,MB,GB,TB,PB
  • lots of cpu cycles to process large data samples
  • Need lots of people!
  • To make it all happen

12
The Fermilab Tevatron
  • Collides proton-antiprotons
  • Energy
  • 2.0 TeV 2000 mp
  • highest energy in the world
  • Rate
  • collisions occur every 396ns
  • 2.5M collisions/second!
  • 1000 Bs /second!
  • Technology
  • superconducting magnets
  • Size
  • 4 miles in circumference

13
Fermi National Accelerator Laboratory (Fermilab)
Wilson Hall and accelerator complex
Aerial view of the laboratory
14
Accelerator Components
Linear accelerator (LINAC)
Tevatron tunnel
Antiproton ring
15
Antimatter
  • Antiprotons are indeed antimatter
  • We use part of the accelerator chain to produce
    and store antiprotons
  • Antiprotons constantly cycled through another ring

Antiproton source
16
The CDF Detector
  • Specifically designed to measure Tevatron
    collisions
  • Size
  • 4 stories tall
  • 5000 tons
  • Sensitivity
  • 1 million channels
  • each channel 1 piece of info
  • Detector is cylindrical in shape
  • need to cover entire interaction region

17
The CDF Detector
Central Endplug detectors
Detector rolling off of the beamline
18
Detector Strategy
CDF II Detector cross section
  • Precise measurements close-in
  • track trajectories, vertices
  • Coarse measurements further out
  • calorimeters measure total energy
  • Muon detectors last
  • muons penetrate deeply
  • High speed DAQ and trigger electronics

19
Assembly of Vertex Detector
Silicon strips surround the beampipe. Provide
VERY precise measurements (50?m) at at distance
of 2-10 cm from the beam line.
20
Schematic of CDF Detector
Measures trajectory of charged particles
21
Stringing the COT
COT Central Outer Tracker 70,000 wires strung
between endplates. Measures trajectory of
charged tracks as the pass through the chamber.
22
A High Energy Collision
A high energy collision as seen by the previous
version of the CDF detector Lines represent
reconstructed trajectories Charged particles
bend in magnetic field big bend?low momentum
23
Triggering and Readout
  • Need to reduce rate
  • 2.5M collisions per second
  • can write data from 50-100 collisions per second
  • must decide which 2.4999M events to discard each
    second in real time !
  • What if the B decays arent part of the 100?
  • Trigger is the fast logic used to make these
    decisions
  • Response time is too short to use standard
    computers
  • We build dedicated electronics for these purposes
  • hardware computers
  • utilize memory, processors, fast logic
  • not arbitrarily programmable

24
Illinois XTRP Trigger System
  • Dedicated system to combine info from other
    system
  • tracks
  • energy clusters
  • muons
  • The XTRP system brings this info together
  • Pipelined system
  • new data every 33ns
  • 4 events in the boards at a time

XTRP test stand
25
Computing and Data Rates
  • Rates
  • Each event about 250kB
  • Write 100 events/sec?disk
  • 25MB of data every second
  • Acquire data at a higher rate
  • 250MB/sec sustained rate
  • burst rates higher
  • Incoming data processed by a farm of PCs running
    Linux (300 dual-processor machines)

Tape robot in computing center
26
UIUC Students at Work
Graduate students Raeghan Byrne and Trevor
Vickey hard at work on the CDF muon systems
H40feet
27
The CDF Collaboration
  • 500 physicists
  • students, postdocs, faculty
  • 35 institutions
  • US, Italy, Japan, Korea, Great Britain, France
  • many support personnel
  • engineers
  • technicians
  • support staff

28
Sociology
  • Although the experiments are big, the work gets
    done in small groups (2-4 people).
  • Its also a great environment and opportunity to
    be constantly interacting with physicists from
    around the world.
  • I like the variety, too. In addition to physics,
    we dabble in things like
  • computing, mechanical engineering, electrical
    engineering
  • budgets, conflict management

29
Other Experiments
  • ee? ? b b
  • Different accelerators/ environment
  • Many techniques are similar
  • Three accelerators
  • Cornell
  • Stanford (SLAC)
  • Japan (KEK)

30
Experimental Status
  • CDF made one of the first measurements
  • Now, BaBar and Belle have made more precise
    measurements
  • Ultimate goal make very precise measurements of
    CP violation in many different ways. We then can
    test the theory for
  • 1. Results
  • 2. Self-consistency

Standard model Higgs branching ratio versus mass
31
Summary--Final Thoughts
  • This is an exciting time for particle physics
  • There are many other interesting subjects and
    measurements that we perform
  • CDF has published well over 100 papers on a
    variety of topics, such as
  • top quark physics
  • Quantum Chromodynamics (QCD)
  • Electroweak phenomena (W/Z production and decay)
  • bottom quark physics
  • searches for new phenomena (supersymmetry,
    technicolor, quantum gravity)
  • the list goes on

32
Top 10 Great Things About Particle Physics
  • 1. You straight can use the words, squarks,
    gluinos, WIMPs and technirho with a face.
  • 2. For exercise, you can run around your
    experiment.
  • 3. Collaborate with institutions like Harvard
    and Yale and then ask them about their sports
    teams.
  • 4. 4500 Amps of current and 1000 cubic meters
    of flammable gas.
  • 5. Two words beam dump.
  • 6. Create more W bosons before 9am than most
    people do in a whole day.
  • 7. Seven truckloads of LN2 per day.
  • 8. Al Gore didnt invent the internet.we did!
  • 9. Find out if irradiated objects really glow!
  • 10. Actually have to worry about the speed of
    light.
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