Structure and Function of the ATLAS Detector
Here, you'll learn the structure of the ATLAS detector and how particles interact with the detector
material in order to be detected at all. You can decide whether you want to learn this with the help
of videos or texts.
Products of proton-proton collisions are detected by the ATLAS detector (ATLAS stands for A
Toroidal LHC ApparatuS). In the middle of ATLAS, two particle bunches (each with 100 billion protons) collide
with each other after they have been accelerated in opposite directions in the LHC.
Thereby it is neither possible to predict which parts of one proton will collide with which parts of another nor which protons collide at all.
In the collisions, scattering (deviation of protons) and collisions may occur.
In the latter case, new particles are formed. From the data, physicists are able to say which physical
processes took place during the collisions. They can only do this when they have understood the detector
and its function. So let's look at those points, now.
ATLAS via Video
ATLAS via Text and Picture
In the following picture gallery, you'll find a short description of the structure and function of each
part of the detector.
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The ATLAS detector is a multi purpose detector. It is used at the Large Hadron Collider (LHC) to
look for new insights into how the universe was formed and of what it is made up. With the help of the
ATLAS detector, physicists want to detect particles formed during proton-proton collisions and
determine their properties. These properties are, for instance, momentum, electric charge, and energy.
For this, a detector was built, which has a breathtaking size: a length of 44 meters and a
diameter of 25 meters. The detector consists of different detector elements, each has a specific
task. They are arranged in an "onion-skin" structure around the beam pipe in which the protons circulate.
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The trackers detect particles with electric charge. They measure their positions at different times.
Since the trackers are permeated by a homogeneous magnetic field, charged particles are deflected.
With the help of the curvature one can calculate the momentum and determine the electric charge. The
interaction between the particles produced during the collision and the detector material of the
trackers is very small. Thus particles only deposit a small amount of energy there.
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In the electromagnetic calorimeter (LAr electromagnetic barrel), particles and their antiparticles,
which interact electromagnetically, are detected. These are mainly electrons and photons. The whole energy of a particle flying
through the electromagnetic detector is absorbed and transformed
into an electronical signal. The strength of the signal is a measure for the energy of the particle.
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In the hadronic calorimeter (Tile barrel), strongly interacting particles, that are built up of quarks
and/or antiquarks, - so-called hadrons – are detected, for example protons or neutrons.
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Muons deposit only a small amount of their energy in the calorimeters, and are the only
"visible" particles which pass through every layer of the ATLAS detector. Therefore, there are muon chambers located at the outermost
part of ATLAS to identify muons. The muon chambers are situated in an additional magnetic field to measure the momentum
more precisely than with the trackers. This magnetic field is produced by huge toroidal coils (thus the "T" in the name "ATLAS").
The muon chambers are made up of thousands of long tubes filled with gas.
There is a wire in the middle of each tube. Incident muons create free charge carriers in the gas via ionisation.
These carriers move towards the outer wall or towards the wire because of a large voltage difference between the tube and the wire,
thereby creating an electronically readable signal.
