THE NALTA PROJECT - PowerPoint PPT Presentation

1 / 34
About This Presentation
Title:

THE NALTA PROJECT

Description:

Title: Slide 1 Author: pinfold Last modified by: Richard Soluk Created Date: 6/6/2003 9:51:51 PM Document presentation format: On-screen Show Company – PowerPoint PPT presentation

Number of Views:109
Avg rating:3.0/5.0
Slides: 35
Provided by: pinf4
Category:

less

Transcript and Presenter's Notes

Title: THE NALTA PROJECT


1
THE NALTA PROJECT A NORTH AMERICAN NETWORK OF
SPARSE VERY LARGE AREA AIR SHOWER ARRAYS A
research project that involves students
(high-school, undergraduate graduate),
teachers and Universities in North
America James Pinfold University of Alberta
James Pinfold Prague June 2004

2
  • The cosmic ray energy spectrum
  • The GZK limit and Ultra High Energy Cosmic Rays
  • Detecting cosmic rays Extended air showers
    (EAS)
  • Cosmic ray experiments around the world a brief
    look
  • Tantalizing hints of a non-random component of
    high energy cosmic rays
  • Sparse very large area EAS array network
  • Sparse very large area educational arrays
  • NALTA
  • The ALTA network , an example
  • The proposed EEE array in Italy
  • Closing remarks

James Pinfold Prague June 2004

3
A list of Fundamental Questions
  • How is the HECR spectrum made up?
  • What is the dominant source for CR below the
    knee?
  • What is the origin of the knee of the CR
    spectrum?
  • What is the origin of particles above the knee?
  • At what energy are the fluxes of galactic
    extra-galactic cosmic rays are equal?
  • What are the sources of extra galactic rays?
  • What is happening at the GZK cut-off around the
    ankle?
  • What is the nature of the exotic (centauro, etc.)
    events observed largely at high altitudes?
  • Is there any evidence of non-random component of
    cosmic rays (large area coincidences, bursts,
    sources, etc)

James Pinfold Prague June 2004

4
The Energy Range
  • High energy cosmic rays consist of protons,
    nuclei, gammas,
  • Measured flux extends to
    s1/2 400 TeV
  • Highest energy particles are extremely rare
  • Supernova shock fronts can accelerate particles
    upto 1015 eV
  • Above 1015 eV, presumably acceleration is in
    AGNs (?)
  • How do UHECR protons evade the GZK cut-off at 7
    x 1019 eV (if source is gt100Mps away)?

1/m2/s
Knee
1/m2/year
GZK Cut-off
Ankle
1/km2/year
James Pinfold Prague June 2004

5
Mysteries of the Spectrum
  • Protons are trapped in our Galaxy (mG B-fields)
    up to 1017 - 1018eV
  • Protons can travel straight above 1020eV
  • Supernova shockwave acceleration up to 1015 eV
  • Above the knee the acceleration mechanism is
    essentially unknown AGNs, massive black holes
    systems, gamma ray bursts ?

1018 eV
GZK land
1020 eV
James Pinfold Prague June 2004

6
Acceleration of CRs above the Knee
  • Up to the knee Fermi acceleration (FA) in
    supernova shock fronts can explain the
    spectrum
    Emax RSNR x Z x B x bsh
  • This can be used to constrain the size and
    magnetic field requirement if acceleration
    mechanism is 1st order FA.
  • Only AGNs and GRBs have sufficient R x B to be
    candidate acceleration sites
  • However, we have a lack of candidate sites for
    energies above 1020 eV.

The HILLAS Plot
James Pinfold Prague June 2004

7
The Mysteries of an Opaque Universe
  • The universe is opaque to UHECR
  • In the case of the GZK cut-off a 5x1019 eV
    proton has a mfp of 50 mpc due to interaction
    with photons in the the CMB.
  • But no nearby sources have been identified,
  • How are the protons with energy gt EGZK
    getting to us? There are two
    scenarios
  • BOTTOM UP acceleration in AGNs, gamma rays
    bursters, etc. then production of a neutral (n,
    so,..?).
  • BOTTOM UP with GZK cut-off relaxed by violation
    of Lorentz Invariance, etc.
  • Or TOP DOWN topological defects (cosmic strings,
    monopoles, etc.) or massive relics, etc.

Region restricted by GZK cut-off 100 Mpc
10,000Mpc
Size of observable universe
James Pinfold Prague June 2004

8
Life Above the GZK Cut-off?
Many events observed Above the GZK cut-off AGASA
(EAS ground Array) seems to violate The GZK
cut-off HI-RES (atmospheric. fluorescence )
seems to obey GZK theory However both expts see
events with E gt 1020eV Some debate as to
possible sources Some 6 doublets and 1 triplet
of events have been seen within 2o cones
Flys Eye Big event 3 x 1020eV (50J!)
HI-Res. AGASA
200 billion particles
?
UHECRs as of 2001
HiRes vs. AGASA
GZK
(4?10)x1019eV gt 1020 eV
James Pinfold Prague June 2004

9
Extended Air Showers
15 km
1016eV
Particle density at ground level
100m
Ne Nm correlation
Particles/m2
There are many ways of detecting cosmic rays
EAS properties can be used to estimate the mass
energy of the incident particle using MC
James Pinfold Prague June 2004

10
EAS -- the Atmosphere as a Calorimeter
Transverse profile
Longitudinal profile
  • Fluorescence Detectors
  • Atmosphere is sensing calorimeter
  • Measure the longitudinal distribution
  • Ground Arrays
  • Technique developed in the
    50s
  • Measure the lateral distribution at ground

Auger - measuring transverse Longtudinal
shower profiles
James Pinfold Prague June 2004

11
Measuring EASs
  • EAS measurement is an indirect method to
    determine
  • mass A of primary CR
  • energy E of primary CR.
  • These quantities are inferred from

James Pinfold Prague June 2004

12
Cosmic Rays Experiments Worldwide
Expts in space
Atmospheric flour. 2 site 14 km apart
100 detector surface array
EUSO or OWL
Artists impression
Cerenekov telecopes
Ice cerenkov
  • water det.
  • 4 atm. fluor. det.

James Pinfold Prague June 2004

13
Sensitivity of Future Detectors
James Pinfold Prague June 2004

14
Tantalizing Hints of Non-random Cosmic Ray
Phenomena
  • The Japanese LAAS array(2000), 8 stations sep. by
    50 km.
  • Anisotropy of successive air showers within a
    Dt of 20 minutes, a concentration of directions
    in the galactic plane is evident the chance
    probability is 0.077.
  • The Swiss array (1988-89) 4 detectors enclosing
    5K km2.
  • An excess of events in which each detector was
    hit within 0.62 ms was observed with a
    significance of 4.8s (prob 10-4).
  • The Irish (U.C. Dublin/Cork) Array (1975) 2
    stations each with 4 scintillators, separated by
    250 km.
  • Fegan et al reported an unusual simultaneous
    increase in the cosmic-ray shower rate at the two
    recording stations, the event lasted 20s
    statistical probability 3 x 10-5.
  • The Manitoba Air Shower Array (1980) consists
    of three 1m2 plastic scintillators enclosing an
    area 60 m2.
  • A burst of 32 EASs was observed within a 5-min
    period. This observation was the only one of its
    kind in an 18 month period in which 150K of such
    showers were recorded. Stat. prob. 10-35 !!

James Pinfold Prague June 2004

15
Sparse Very Large EAS Array Networks
  • Experimental purpose of such array networks is to
    look for a possible no-random component in cosmic
    rays
  • Look for coincident events in small windows
    around arrival time and direction at separated
    sites (DX from 1?500 kms) using GPS timing
  • One can detect and point very high energy,
    multiple primary, phenomena this way
  • When detectors are close enough (not more than a
    few kms) one can count and point UHECR

Dt
James Pinfold Prague June 2004

16
Experimental Concept
  • Small air showers arrays operated independently
    at each site Typically a few to several small
    detectors at each site separated by 10m.
  • Local pointing with accuracies as good as 2o
  • GPS now provides the common clock with
    accuracies 20 ?50 ns over areas as large as
    North America.
  • Local coincidence data readout to a central site
    where an offline trigger involving direction,
    time and pulse height can be applied.
  • Standard data format and accessibility via the
    internet

James Pinfold Prague June 2004

17
The Mystery of Very Large Area Cosmic Ray
Phenomena
  • Correlated phenomena, Possibilities
  • Photo-disintegration of UHE nuclei in the
    photosphere of the Sun
  • VHE Gamma Rays from GRBs
  • Relativistic dust grains
  • Neutrino bursts
  • Primordial black holes
  • Cosmic strings
  • Ultra high energy (UHE) horizontal air showers
    (giving a coincidence between separated detectors
    thus faking a correlated event)

James Pinfold Prague June 2004

18
The LAAS Array
(First results 1999)
Okiyama University
Typically very small air showers arrays (10x10
m2) with about 8 detectors (0.25 m2) at each
site.
James Pinfold Prague June 2004

19
Sparse Very Large Area Networks of Educational
EAS Arrays.
  • Physics aims of these experiments are those of
    sparse very large area air shower arrays.
  • In this case the detectors are housed in
    high-schools and colleges and involve
    high-schools students and teachers
  • These arrays thus have BOTH an educational
    component as well as a research component
  • The ALTA project in Alberta was the first in
    North America ( the world?) to actively pursue
    an array that would satisfy equally these two
    aims.
  • The ALTA experience has been taken up across
    North America and in Europe.
  • ALTA now leads (along with CROP) a consortium of
    similar projects called NALTA (North American
    ALTA)

James Pinfold Prague June 2004

20
North American Large Area Time Coincidence Arrays
(NALTA)
  • ALTA U. of Alberta, Athabasca U, (Northeastern
    U, Boston)
  • BC-ALTA U. of BC
  • CANLACT U of Alberta, U. of Athabasca, UBC,
    Carleton U., U of Manitoba, U of Regina, U of
    Victoria
  • CosRayHC U. of Pittsburgh, Southern U. of
    Illinois at Edwardsville, Jackson State U.,
    Florida State U.
  • CROP U. of Nebraska
  • CHICOS Caltech, California State U at
    Northridge, U. of California at Irvine
  • SALTA SNOWMASS-2001, Colorado
  • SCROD Northeastern University
  • TECOSE University of Texas
  • WALTA University of Washington
  • MEXICO Groups around Mexico city

100 detector systems Across North America
James Pinfold Prague June 2004

21
ALTA The 1st Example of a Sparse Large Area
Educational ArrayNetwork
  • 20 Schools Involved
  • 13 detectors systems deployed in Alberta
  • 2 more being equipped
  • 2 more for next spring
  • 20 detector systems in place by the end of 2004
  • All timed together using the GPS system

James Pinfold Prague June 2004

22
The ALTA Detector Systems
GPS
The electronics readout
0.5 m2 Scint.
James Pinfold Prague June 2004

23
The System Cost
  • Detector cost 1,900 EUR
  • Readout electronics calibration
    system 5400 EUR
  • HV power supplies 600 EUR
  • Temp. mon. control 380 EUR
  • GPS Satellite receiver 630 EUR
  • DAQ Computer 950 EUR
  • Sundries 250 EUR
  • TOTAL 10,000 EUR

3 x
1 x
1 x
1 x
Data acquistion computer
Readout Electronics
GPS Receiver electronics
24
Properties of the Detector
  • LOCAL COINCIDENCE obtained using local system and
    hardwired electronics. Allows pointing of shower
    direction to ? 2-gt3 degrees.
  • GPS TIME STAMP is obtained when a local
    coincidence occurs. Timing is good to 15 ns over
    Alberta (NIM paper on this has been accepted).
  • MIP SENSITIVITY. Each detector should respond to
    a single MIP.
  • ENERGY THRESHOLD for the local detector with a
    10m triangle is 1014 eV (from Corsika)
  • OFFLINE TRIGGER timed stamped local
    coincidences, or events, are stored centrally for
    various offline studies.

Average size Of a 1014 ev shower
10m
James Pinfold Prague June 2004

25
First Data is Being Analyzed
Local coincidence rate
  • No physics results are ready as yet
  • However, we do have a nice result relating to the
    correlation between trigger rate and atmospheric
    pressure
  • It provides a nice way to check that detectors
    are working over a large area

Atmospheric pressure
(
James Pinfold Prague June 2004

26
North American Large Area Time Coincidence Arrays
(NALTA)
CANALTA
CANALTA
CANALTA
ALTA
BC-ALTA
CANALTA
CANALTA
CROP
SCROD
WALTA
CosRayHS
CosRayHS
SALTA
CosRayHS
CHICOS
TECOSE
CosRayHS
Detectors in place
Mexico City, etc.)
In preparation
In planning
James Pinfold Prague June 2004

27
An Example of a Proposed Array in Italy EEE
(Extreme Energy Event network))
  • Possibility of 4 sites in Italy.
  • Project run under the auspices of the Enrico
    Fermi Institute in Rome
  • Contact people Prof. A Zichichi Dr Rinaldo
    Baldini.
  • As part of this project Prof Zichichi has
    proposed a search for cosmic ray coincidences
    with ultra long baselines (between ALTA EEE)

James Pinfold Prague June 2004

28
Lets Network the Cosmic Rays Experiments
Worldwide
Internet based ALTA arrays in schools could be
networked with the Worlds largest Cosmic Ray
detector system
ALTA
CANALTA
  • ALTA type
  • projects in
  • 1) Czeck Republic (planning)
  • 2) Germany,
  • 3) Italy (planning)
  • 4) Denmark

NALTA
James Pinfold Prague June 2004

29
We Could Include Gravitational Wave Detectors in
the World Wide Network
James Pinfold Prague June 2004

30
ALTA Hand on Workshop Nov. 2001
  • Workshop held as introduction to the physics as
    well as hands on training with detectors.

The crowded workshop area
At the U of Alberta
Alberta high-school
James Pinfold Prague June 2004

31
The CROP Project (U. of Nebraska)
  • Major funding received from NSF (1.34M over 5
    years)
  • 11 high-schools involved in project so far (more
    to follow)
  • Basic detector setup has four plastic
    scintillators with separation 10m.
  • Enough PMTs scintillators, HV retrieved from
    Dugway to supply 300 schools.

CROP Workshop Participants July 2000
James Pinfold Prague June 2004

32
The CROP Project July Workshop
The Zoo School (Lincoln) team wrapping a CASA
scintillator 25 July 2000
James Pinfold Prague June 2004

33
The CHICOS Project (U. of California)
  • Proposing to involve 14 high-schools in the array
    in the Los Angeles area
  • Plan is to field detectors in schools in the San
    Gabriel valley in 2001
  • Prototype detectors stations are working
    (refurbished CYGNUS detectors)
  • 200 detectors and PMTS in hand from LANL.

James Pinfold Prague June 2004

34
Summary Conclusions
  • Around 15 universities 80 high-schools
    involved so far
  • 42 detector systems have been deployed (ALTA has
    9, CHICOS 18, CROP 11, WALTA 4) -- we expect to
    deploy 100 in a few years.
  • NALTA like efforts are now international with
    projects in Canada, China, Belgium, Czech
    Republic (?), Germany, Italy(?), UK and the USA
  • We will be working on making the NALTA network
    function as a unified system so that data can be
    shared and common standards set. Essentially
    NALTA could become a hyper-large area sparse
    array capable of looking at very large area
    and/or new cosmic ray phenomena.
  • We expect NALTA to excite and interest new
    generations of physicists with an educational
    paradigm utilizing distributed interactive
    learning/research systems that can be adapted to
    many areas the environment (air pollution
    measurements), geophysics (simple seismometers),
    meteorology (weather stations), etc.

James Pinfold Prague June 2004
Write a Comment
User Comments (0)
About PowerShow.com