How onions have inspired particle physicists to design their detectors

in #steemstem7 years ago

I was planning to release a lot of material before the steemstem meetup at CERN, and I only partially managed to do so at the end of the day. I have however decided to finish this series no matter what, even if we are all today back from CERN for more than a week. In this way. I will be 100% ready for episode 2, if we organize an episode 2 of course.

In the former post of this series, I introduced four different classes of objects when one was considering the detector standpoint: stable particles, unstable particles, jets and invisible stuff.

In order to be sensitive to all of these, a typical detector located at a particle collider features an onion-like structure. Like onions , they are organized into layers, and each layer has a different role. Okay, I admit, this is where the comparison with onions breaks down, as any single layer of an onion in principle tastes the same.

Joke asides, this is the topic that I will give details about today. However, I will stay very general. I am a theorist and not an experimentalist, and since we have one particle physics experimentalist here on steemit, I leave her this task :)


TYPES OF OBJECTS THAT CAN BE DETECTED

Before moving further, it is useful to provide a short reminder about the objects that can be observed in a detector like one of those around the Large Hadron Collider.


[image credits: CERN]

First, there is a bunch of stable objects, on detector time-scales, that could be detected as such. Strictly speaking, those guys could be unstable, but they must then decay outside the detector.

There are three classes of such stable particles: electrons, photons and muons. They can thus be directly observed.

Secondly, we have particles that are unstable, and short-lived enough so that they will decay within the detector. I think here about weak bosons, Higgs bosons or top quarks, for instance, or most new physics particles that are searched for.

These particles will decay promptly into other stuff called daughter particles, and these daughter particles will either be the stable guys, or will further decay. We will however be able to go back to the initial particle (the mother particle) from the properties of the daughters.

Our detectors are built in such a way that they are precise enough to accomplish this task.

The third class of particles of interest consists of jets of strongly interacting particles. All quarks but the top quarks, as well as the gluon will radiate each other, a high energies. This will form a shower of particles which when taken together make a jet of composite states named hadrons.

Those hadrons are composite objects made of quarks, by virtue of the theory of the strong interactions. Quarks can indeed not be observed freely in nature.

And finally, there exist a last class of particles that are the invisibles. This includes of course the neutrinos of the Standard Model, but also any particle that could play the role of dark matter.

Thanks to energy and momentum conservation, the invisible can be seen as missing energy and momentum in the detector. This indirect derivation stems from the initial state the is more or less perfectly known.


TRACKING AND CALORIMETRY


[image credits: CMS]

The above picture is an onion. The CMS detector onion. But ATLAS works the same. And many other detectors.The magenta circles emphasize the onion-like structure of the detector.

The collision here occurs perpendicularly to the shown slice of the detector. In other words, the screen on which this post is read is within the plane perpendicular to the collision axis. In the middle of the CMS picture lies our collision point.

Right around the collision point lies a subdetector called a tracker. The goal here is to reconstruct the tracks of all charged particles. This is achieved by relying on the fact that a charged particle ionizes a medium when it travels through it. And from the products of ionanization, we can go back to the what happened.

Thanks to tracks, we can reconstruct the charge and the momentum of the particles that induced the tracks.

Now, let us move away from the tracker and focus on the ECAL and HCAL modules of the figure.

Around the tracker stand the electromagnetic and the hadronic calorimeters. Their role consists of stopping the particles that go through them, so that their energy could be measured. The electromagnetic calorimeter (ECAL) is dedicated to electrons and photons whilst the hadronic calorimeter (HCAL) is dedicated to jets.

Around the calorimeters lies a magnet that will.. surprize surprize… generate a magnetic field. This magnetic field is necessary to bend the trajectories of the particles. This faeture is crucial for the identification of all particles and the measurement of their properties, as the amplitude of the bending carries a lot of information.

Finally, the only (detectable) particles managing to pass both calorimeters almost intact are the muons. Therefore, dedicated muonic systems are installed to detect them and measure their properties. The M in CMS stands for muons. CMS is indeed really good at measuring the properties of the muons. ;)


TAKING A PICTURE WITH ALL SUB-DETECTORS ALL TOGETHER

By putting the information extracted from the tracker, the two calorimeters and the muon systems, one is able to reconstruct what happened in a collision.

For instance, an electron leaves tracks in the tracker and energy deposits in the electromagnetic calorimeter, whereas a photon will only yield deposits in the latter. Hadrons leave an imprint in the tracker if they are charged, and in the hadronic calorimeter in all cases. And so on.

At the end of the day, we know exactly what happened and we are thus armed to investigate whether we have to deal with some (boring) Standard Model stuff or some new phenomenon, like dark matter.

There is no way to know exactly which one of the potential processes leading to a given final state occurred. This is where statistics comes into the game. After billions of collisions, we can start to be picky about the type of electrons we are interested in, how they must be separated from each other, how the photons should be energetic, etc.

This level of pickiness will allow to select a lot of signal collisions (what we are interested in) and hopefully kill as much background as possible (what we do not care about but yields the same imprint in the detector).

This is the game of designing a great new physics analysis :)


SUMMARY

In this post, I tried to give basic details how general-purpose detectors around collider experiments are made. Starting from the outside, a general-purpose detector consists in several layers respectively dedicated to the measurement of the properties of the muons, to measure the energy of jets, photons and electrons. Finally, the most inner element of a detector aims to reconstruct the tracks of all charged particles that have been created in a collision.

Those detectors are cutting-edge technology designed with a given purpose: reconstructing those collision events in a sufficiently good enough way, so that they could be used to unravel some interesting new phenomena and revolutionize our vision of the world of the elementary particles.


SteemSTEM

SteemSTEM is a community-driven project that now runs on Steemit for more than a year. We seek to build a community of science lovers on Steemit and to promote well written/informative Science Technology Engineering and Mathematics (STEM) postings in order to make Steemit a place for fascinating STEM content.

More information can be found on the @steemstem blog and on the Steemit chat and in our last project report.

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Just saw the documentary about ATLAS on their own youtube page. I was looking for the conclusions and then I saw the article. I really hope that Steemit can be used to make science more friendly to the new generations.
That these kinds of quests to explore the unknown are a catalyst to more science. I will promote SteemSTEM in my country too, I have a plan to reach a broader audience. Cheers!

Thanks a lot for doing this. Do you mind sharing information about this plan? :)

I wrote more about it in my previous articles: here and here
I am shy and I never wrote anything before Steemit, but someone has to do this.

Long story short: I am living in Eastern Europe, major systems are falling here (political, financial,social and educational). Huge gaps are being created between the lucky few and the rest. We have created a Romanian curation group & my current plan is to use Steemit and it's financial benefits to:

  • Use our limited time but higher resources to promote Steemit to the rural and poor communities(where most of the people are still living on social support and even with absolute zero income).
  • Use local people, close to the communities we try to engage to keep contact and provide basic curation and tech support.
  • Use the time of the retired educated people (most of which are forgotten and living in extreme poverty, even in most cities) to educate, curate and engage others, also benefiting their own mental health and wallets through activities.
  • Create the framework for further exposure of their problems to the lucky few; engage in educational activities and promotion of science and prosocial behavior to reduce the acute alienation feeling they experience now.
  • Give them ideals and advice for their own development. Stop parents from going to work abroad abandoning their children and their education.
  • Connect to the NGO's that support education and even contribute ourselves to distribute tablets to empower them to join.

Our government has failed us. But I think it's our duty to intervene if we have the means!
The group is online and I hope that in a week we can delegate the SP and start the curation effort. When I will have a first result (first Case Study starts soon in a rural community) I will tell you more, since I know you share the vision.

Until then I am open to more questions, I spend a lot of time in SteemSTEM Discord.
Thanks for the time!

Thanks for the summary. I indeed missed the posts. This project is really nice and I wish you good luck. Don't hesitate to come to me for discussing how steemstem could help you :)

First I have to get the project started and see about its feasibility. I would only bother you once it's already proven to work at a small scale at least. :D

Seriously, never knew this blog exist I would have been following you from the beginning been a Physicist and lover of science, CERN will truly she'd sonmych light on our understanding of particles and matterd thereby helping us to k of how and what it can be made into.
Am reading and saving all your blogs right away.

Thanks a lot! I am existing for many years (and 20 months on steemit) :)

Although I typically don't plug that agressively, take a look at my posts as well. Just like @lemouth, I'm existing for many years already, but only very recently joined steemit :)

I advertised you directly in my post by the way ;)

Around the tracker stand the electromagnetic and the hadronic calorimeters. Their role consists of stopping the particles that go through them, so that their energy could be measured....
With respect to this 👆


electromagnetic and the hadronic calorimeters will they also be able to measure the amount of energy carried along the solar wind?

Good question. Tjhe answer is 'no'. Particle accelerators are only aimed to detect what is going on when two beams of known particles are collided with each other. The solar winds do not enter here.

Thank you for your response, i was about to ask about aurora before.

Steemstem? What a blessing to today's generation
Never knew my chances of learning recent scientific discoveries could very much be made possible here on Steem.
Where is CERN?

CERN is located at the border of France and Switzerland, close to Geneva. This is the largest particle physisc laboratory in the world.

Oh which is why some of the pics had everyone crying .. onions ! LOL

On a more serious note, I am always amazed by the things we inspire from nature's designs

Everything, no? Humans are good in reproducing what they see :)

I wonder if 'sexyscience' would be a good name for a Smart Media Token.

Smile
What make you think of this?

a coincidence.
Steem, starts with an 'S'.
So does 'STEM' and so does Sexy, Science...

Is a simple trope in comics
Peter Parker
Bruce Banner
Matt Murdock
etc...

I am all in favor of it. In any case, this could be the SMT surname ;)

Awesome article! Also, it totally inspired me to make something with onions tonight- I'm thinking stir fry?

There will definitely be protons in it!

And neutrons! And electrons! :)

Also some cabbage.

Hello @lemouth

...Like onions , they are organized into layers, and each layer has a different role...

It is surprising to know that the structure of onion old motivate construction of something as complex as detectors. This is quite a huge feat.

I am not quite knowledgeable on the workings of a typical detector, hence this is an eye opener for me. Maybe be further research maybe necessary for me to come to terms with the whole concept. However, I appreciate this.

@eurogee, the founder of @euronation community & The Host, Show Us Your Witnesses Weekly Contest

Thanks for passing by!

I am not really sure the onion was the initial motivation. I guess the comparison appears afterwards. However, I have no information with this respect, unfortunately. Thus dates from before my time :)

Alright. The pleasure is mine✌️

The CMS experiment's blog is called the Cylindrical Onion so we've definitely embraced it, though :)

I didn't know that this was existing. That is a great choice :)

I recon cern is a disaster waiting to happen some cler stuff going on in there

Sorry, but I can't understand what you are saying. CERN is not a disaster. How trying to understand how the universe works would be a disaster?

And now you are making GMO onions to be your detectors! :)

A brief history of scientific disasters waiting to happen:
fire, pointy sticks, round throw-able stones, wheels, metal, cooked meat ... ... steam machine, cars, Titanic (ups..), airplanes... electricity, antibiotics, space rockets...
GMO, CERN

I don't know, maybe we should go back to not that pointy sticks. That would prevent many disasters, including the Titanic. Check-mate Science!

Let's all go back to the trees :D

nice trolling there @alexs1320, You forgot 911... I'm disappointed

Because there is no onion in there :)

Not that I understand it all but that anti-matter stuff just seems to be a dangerous thing to be messing with

Well, Earth is bombarded with antimatter (through cosmic rays) since the dawn of time. PET scan uses antimatter. And so on.... This is not that dangerous, as you can see :)

I'm producing antimatter while typing this:

Some copy-paste from Wiki:

Positrons are produced naturally in β+ decays of naturally occurring radioactive isotopes (for example, potassium-40) and in interactions of gamma quanta (emitted by radioactive nuclei) with matter. Antineutrinos are another kind of antiparticle created by natural radioactivity (β− decay).

and

40K occurs in natural potassium (and thus in some commercial salt substitutes) in sufficient quantity that large bags of those substitutes can be used as a radioactive source for classroom demonstrations. In healthy animals and people, 40K represents the largest source of radioactivity, greater even than 14C. In a human body of 70 kg mass, about 4,400 nuclei of 40K decay per second

And from this source:

it turns out that bananas pop out a positron every 75 minutes or so

it turns out that bananas pop out a positron every 75 minutes or so

WTF! :D

Bananas contain potassium, about 400-450 mg per banana.
Some 5 mg of which is potassium 40.

There are 3 types of decay, boring Beta(-), positive electron capture and... Beta(+)

Radioactivity of banana is about 15 Bq (31 Bq per 1 g of K), or 1/15 s x 0.001 for Beta(+) x 0.01 to kill % ~ 115 minutes or so, 1/75 min myth seems ok...

My exclamation was more about thinking to the idea than the idea itself! :)

nice physic argument