Transcript Slide 1
India-based Neutrino Observatory (INO)
A world-class underground laboratory to study fundamental issues in physics
Neutrinos
• Neutrinos are tiny, neutral, elementary particles which interact
with matter via the “weak force”.
• The Sun produces over two hundred trillion trillion trillion
neutrinos every second, and a supernova can release 1000 times
more neutrinos than the Sun will produce in its 10-billion year
lifetime.
• Matter is almost transparent to neutrinos.
• Billions of neutrinos stream through our body every second,
yet perhaps only one or two of the higher energy neutrinos will
scatter from you in your lifetime!
• At least 3 types or “flavours” of neutrinos and anti-particles
exist in nature, which have a very tiny mass whose value is still
not known.
• Neutrinos hold the key to several important and fundamental
questions on the origin of the universe and energy production in
stars.
Detecting Neutrinos
•Neutrinos detectors have to be situated deep underground
to prevent the comparatively huge background from cosmic
rays and natural radioactivity at the earth’s surface.
•Neutrino detectors have to be enormous in size, as the
probability of interaction with matter is so small.
•First atmospheric neutrinos were detected at Kolar Gold
Fields, in 1965 by a TIFR group
The INO project
Goals:
• Study neutrinos from various natural and lab sources
• Development of detector technology and its applications
• Eventually: a centre for other studies in physics, biology,
geology, etc., all which benefit from special conditions that
exist deep underground
Schematic of underground experimental cavern
Size of cavern : 150 m 22 m 30 m
Panoramic view of site near Theni, Tamil Nadu
In the first phase of its operation a magnetised iron
calorimeter detector, weighing about 50 ktons, will
be used for studying neutrinos produced from
cosmic rays in Earth’s atmosphere.
More Information
http://www.ino.tifr.res.in
Resistive Plate Chamber Detectors
• Resistive Plate Chambers are rugged, lowcost gas detectors extensively used in high
energy and astroparticle physics experiments
for the detection of charged particles.
2 mm thick spacer
• Excellent spatial and temporal resolution
leading to applications for time of flight
measurements, tracking detectors and digital
calorimetry due to large signal amplitudes.
Glass plates
• RPC is composed of two parallel electrodes
usually made of glass or bakelite, separated
by suitable spacers.
• A special gas mixture flows through the
chamber, and a high voltage is applied across
the electrodes uniformly.
• A passing charged particle induces an
avalanche, whose location can be detected on
the x-y pickup strips.
• A total of 28800 RPCs of dimension 2m X 2m
will be needed for the INO experiment!
Two 2 mm thick float Glass
Separated by 2 mm spacer
Pickup strips
Large area RPC prototype
Graphite coating on the outer surfaces of glass
Complete RPC
How does the RPC work
Glass
Plates
Signal pickup (y)
Graphite
Spacers
RPC gas mixture
Freon 134a : 95.5%
Isobutane : 4.2%
SF6
: 0.3%
8 KV
Graphite
A passing charged particle induces an avalanche, which
develops into a spark. The discharge is quenched when
all of the locally available charge in an area 0.1 cm2 is
Before
After
consumed.
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The discharged area recharges slowly through the highresistivity glass plates.
A RPC detector and DAQ system
tracking cosmic ray muons