Why, precisely, is argon used in neutrino experiments?












13












$begingroup$


Why is argon used in neutrino detectors? Other than liquid argon being denser than water or oil, what are its advantages?










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$endgroup$








  • 1




    $begingroup$
    Note: the new SNO+ experiment is using a linear alkyl benzene scintillator, which has a lower energy threshold for detectable neutrino interactions en.wikipedia.org/wiki/SNO%2B
    $endgroup$
    – llama
    Mar 27 at 20:31
















13












$begingroup$


Why is argon used in neutrino detectors? Other than liquid argon being denser than water or oil, what are its advantages?










share|cite|improve this question











$endgroup$








  • 1




    $begingroup$
    Note: the new SNO+ experiment is using a linear alkyl benzene scintillator, which has a lower energy threshold for detectable neutrino interactions en.wikipedia.org/wiki/SNO%2B
    $endgroup$
    – llama
    Mar 27 at 20:31














13












13








13


1



$begingroup$


Why is argon used in neutrino detectors? Other than liquid argon being denser than water or oil, what are its advantages?










share|cite|improve this question











$endgroup$




Why is argon used in neutrino detectors? Other than liquid argon being denser than water or oil, what are its advantages?







experimental-physics neutrinos elements






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share|cite|improve this question













share|cite|improve this question




share|cite|improve this question








edited Mar 27 at 4:53









Qmechanic

107k121991239




107k121991239










asked Mar 27 at 4:20









Kurt HikesKurt Hikes

33817




33817








  • 1




    $begingroup$
    Note: the new SNO+ experiment is using a linear alkyl benzene scintillator, which has a lower energy threshold for detectable neutrino interactions en.wikipedia.org/wiki/SNO%2B
    $endgroup$
    – llama
    Mar 27 at 20:31














  • 1




    $begingroup$
    Note: the new SNO+ experiment is using a linear alkyl benzene scintillator, which has a lower energy threshold for detectable neutrino interactions en.wikipedia.org/wiki/SNO%2B
    $endgroup$
    – llama
    Mar 27 at 20:31








1




1




$begingroup$
Note: the new SNO+ experiment is using a linear alkyl benzene scintillator, which has a lower energy threshold for detectable neutrino interactions en.wikipedia.org/wiki/SNO%2B
$endgroup$
– llama
Mar 27 at 20:31




$begingroup$
Note: the new SNO+ experiment is using a linear alkyl benzene scintillator, which has a lower energy threshold for detectable neutrino interactions en.wikipedia.org/wiki/SNO%2B
$endgroup$
– llama
Mar 27 at 20:31










3 Answers
3






active

oldest

votes


















24












$begingroup$

There are many different types of neutrino detectors, using various techniques to turn a neutrino interaction into an electrical signal. Detectors that use a large quantity of water or oil, like Super-Kamiokande in Japan and MiniBooNE at Fermilab, are Cherenkov detectors. Their basic principle of operation is as follows: when neutrinos pass through the liquid and interact with it, they produce leptons that are energetic enough to move faster than the speed of light in the medium. When this happens, the leptons emit a cone of Cherenkov radiation, which is detected by photomultiplier tubes surrounding the medium; later, the intensity and relative timing of the light pulses are transformed into a reconstruction of the track of the charged lepton.



The neutrino detectors using liquid argon are called Liquid Argon Time Projection Chambers, or LArTPCs, and work in a different way. These detectors consist of a large volume of liquid argon, with a grid of high-voltage bare wires passing through the liquid and a set of scintillators and photomultiplier tubes surrounding the liquid. When a neutrino interacts with an argon atom, it, as before, creates a high-energy charged lepton. This charged lepton ionizes other argon atoms as it passes through the liquid, leaving a trail of free electrons and argon ions in its wake. The electrons are drawn into the wires by the strong electric field and register as a pulse of current in a particular wire. Since liquid argon's electronegativity is so low, it's essentially transparent to these slower-moving electrons. A free electron typically hits the wire that it's closest to, and the further away it is from the wire grid, the longer it takes to hit it. So by analyzing which wires received current pulses as a function of time, it is possible to reconstruct the track of the charged lepton. This is not possible with water- or oil-based detectors because both are too electronegative - the free electrons will react with the medium before reaching the wire.



The high-energy charged particle also causes the argon itself to act as a scintillator in the far ultraviolet (with a wavelength of around 128 nm). The argon is essentially transparent to the scintillation light, so it's received by the scintillators on the walls, which convert the ultraviolet radiation to visible light, which the photomultiplier tubes are far more efficient at amplifying. This extra information can also be used for reconstruction of the hgih-energy charged lepton track. Liquid argon can also be used as a Cherenkov detector, since it has a similar refractive index as water (1.24 versus water's 1.33); it's this triple redundancy in the signal which has made liquid argon TPCs so appealing.



There are several other advantages to using liquid argon as opposed to water or oil. Liquid argon is, as you remarked, denser than either water or oil, which leads to a higher interaction frequency for the same incident neutrino intensity, which speeds up the data-taking rate (given that neutrino experiments have a very slow data-taking rate, this is the main bottleneck that determines how long an experiment must be run to collect a statistically-useful dataset). Argon is also a noble element, which means that it doesn't tend to interact with either impurities or the container it's stored in, so it's also somewhat easier to purify and keep clean, reducing the background that analyses have to account for and making it easier to see a signal.



Given that all of the above advantages also apply to the heavier noble gases such as krypton and xenon, you may be wondering why argon is used instead of those. The answer is simple: argon is much cheaper than the heavier noble gases, which allows you to build a bigger detector for the same budget.






share|cite|improve this answer









$endgroup$









  • 5




    $begingroup$
    "argon is much cheaper than the heavier noble gases" Yep. The nitrogen liquifying industry has to deal with non-trivial quantities of the stuff as a byproduct. They love to find someplace to sell it. And because the welding industry also uses it they have sufficient incentive to capture and keep it.
    $endgroup$
    – dmckee
    Mar 27 at 19:44



















4












$begingroup$

I think we're getting confused. Using Chlorine to trigger transitions to Argon is a way of detecting neutrinos are present.



Using a volume of liquid Noble element to detect the passage of charged particles is a technique of calorimetry. In my old experiment (NA48) we used a liquid Krypton calorimeter.




  • A denser medium gives more ionisation per unit length (hence greater resolution).

  • Electrons liberated by ionisation are able to drift long distances in a noble element (this is how we detect the ionisation).


So hundreds of litres of liquid Kr provides a very dense medium that is good for tracking ionising particles.



However, liquid krypton is expensive - six times more expensive than single malt whisky. Luckily, we had a Russian team on our collaboration. In the 90s, the Russians had no money, but they did have plenty of raw materials, so they supplied the LKr (it's a by-product of producing liquid O2 for the steel industry).






share|cite|improve this answer









$endgroup$









  • 2




    $begingroup$
    Liquid nobel gas TPCs use the stuff for the neutrino interaction medium, the ionization and transport medium and the scintillating medium (for establishing event timing in detectors where the drift time far exceeds the coarsest beam structure).
    $endgroup$
    – dmckee
    Mar 27 at 19:46



















0












$begingroup$

There is a very specific reaction between a chlorine nucleus and a neutrino which produces an argon nucleus. By detecting the production of argon in a very large volume of chlorine, the presence of a neutrino can be deduced. This means that an extremely sensitive neutrino detector can be designed around a great volume of chlorine which is periodically swept through an argon detector.






share|cite|improve this answer









$endgroup$













  • $begingroup$
    Is this design actually used in current neutrino detectors? I don't seem to recall any at the moment that use extremely large volumes of chlorine - in fact, most of them that I can think of (IceCube notwithstanding) use extremely large volumes of argon (or xenon) surrounded by scintillators and photomultipliers, which is exactly backwards from what you have written here.
    $endgroup$
    – probably_someone
    Mar 27 at 7:08












  • $begingroup$
    @probably See en.wikipedia.org/wiki/Homestake_experiment "Upon interaction with an electron neutrino, a chlorine-37 atom transforms into a radioactive isotope of argon-37".
    $endgroup$
    – PM 2Ring
    Mar 27 at 7:25










  • $begingroup$
    one of the original neutrino detectors used a gigantic vat of dry cleaning fluid (rich in chlorine) deep underground, which would be swept at regular intervals to look for argon.
    $endgroup$
    – niels nielsen
    Mar 27 at 7:27






  • 1




    $begingroup$
    @PM2Ring Ok, but do you have another example of this design being used in any modern context, i.e. not in a detector that's at this point 60 years old (I couldn't find another one on en.wikipedia.org/wiki/List_of_neutrino_experiments)? Given that the OP is asking about the use of liquid argon in neutrino experiments (plural), I'm fairly certain this isn't particularly relevant.
    $endgroup$
    – probably_someone
    Mar 27 at 7:29












  • $begingroup$
    I went with argon and did not specifically consider liquid argon. eager to hear inputs from experts on this. -NN
    $endgroup$
    – niels nielsen
    Mar 27 at 7:42












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3 Answers
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active

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3 Answers
3






active

oldest

votes









active

oldest

votes






active

oldest

votes









24












$begingroup$

There are many different types of neutrino detectors, using various techniques to turn a neutrino interaction into an electrical signal. Detectors that use a large quantity of water or oil, like Super-Kamiokande in Japan and MiniBooNE at Fermilab, are Cherenkov detectors. Their basic principle of operation is as follows: when neutrinos pass through the liquid and interact with it, they produce leptons that are energetic enough to move faster than the speed of light in the medium. When this happens, the leptons emit a cone of Cherenkov radiation, which is detected by photomultiplier tubes surrounding the medium; later, the intensity and relative timing of the light pulses are transformed into a reconstruction of the track of the charged lepton.



The neutrino detectors using liquid argon are called Liquid Argon Time Projection Chambers, or LArTPCs, and work in a different way. These detectors consist of a large volume of liquid argon, with a grid of high-voltage bare wires passing through the liquid and a set of scintillators and photomultiplier tubes surrounding the liquid. When a neutrino interacts with an argon atom, it, as before, creates a high-energy charged lepton. This charged lepton ionizes other argon atoms as it passes through the liquid, leaving a trail of free electrons and argon ions in its wake. The electrons are drawn into the wires by the strong electric field and register as a pulse of current in a particular wire. Since liquid argon's electronegativity is so low, it's essentially transparent to these slower-moving electrons. A free electron typically hits the wire that it's closest to, and the further away it is from the wire grid, the longer it takes to hit it. So by analyzing which wires received current pulses as a function of time, it is possible to reconstruct the track of the charged lepton. This is not possible with water- or oil-based detectors because both are too electronegative - the free electrons will react with the medium before reaching the wire.



The high-energy charged particle also causes the argon itself to act as a scintillator in the far ultraviolet (with a wavelength of around 128 nm). The argon is essentially transparent to the scintillation light, so it's received by the scintillators on the walls, which convert the ultraviolet radiation to visible light, which the photomultiplier tubes are far more efficient at amplifying. This extra information can also be used for reconstruction of the hgih-energy charged lepton track. Liquid argon can also be used as a Cherenkov detector, since it has a similar refractive index as water (1.24 versus water's 1.33); it's this triple redundancy in the signal which has made liquid argon TPCs so appealing.



There are several other advantages to using liquid argon as opposed to water or oil. Liquid argon is, as you remarked, denser than either water or oil, which leads to a higher interaction frequency for the same incident neutrino intensity, which speeds up the data-taking rate (given that neutrino experiments have a very slow data-taking rate, this is the main bottleneck that determines how long an experiment must be run to collect a statistically-useful dataset). Argon is also a noble element, which means that it doesn't tend to interact with either impurities or the container it's stored in, so it's also somewhat easier to purify and keep clean, reducing the background that analyses have to account for and making it easier to see a signal.



Given that all of the above advantages also apply to the heavier noble gases such as krypton and xenon, you may be wondering why argon is used instead of those. The answer is simple: argon is much cheaper than the heavier noble gases, which allows you to build a bigger detector for the same budget.






share|cite|improve this answer









$endgroup$









  • 5




    $begingroup$
    "argon is much cheaper than the heavier noble gases" Yep. The nitrogen liquifying industry has to deal with non-trivial quantities of the stuff as a byproduct. They love to find someplace to sell it. And because the welding industry also uses it they have sufficient incentive to capture and keep it.
    $endgroup$
    – dmckee
    Mar 27 at 19:44
















24












$begingroup$

There are many different types of neutrino detectors, using various techniques to turn a neutrino interaction into an electrical signal. Detectors that use a large quantity of water or oil, like Super-Kamiokande in Japan and MiniBooNE at Fermilab, are Cherenkov detectors. Their basic principle of operation is as follows: when neutrinos pass through the liquid and interact with it, they produce leptons that are energetic enough to move faster than the speed of light in the medium. When this happens, the leptons emit a cone of Cherenkov radiation, which is detected by photomultiplier tubes surrounding the medium; later, the intensity and relative timing of the light pulses are transformed into a reconstruction of the track of the charged lepton.



The neutrino detectors using liquid argon are called Liquid Argon Time Projection Chambers, or LArTPCs, and work in a different way. These detectors consist of a large volume of liquid argon, with a grid of high-voltage bare wires passing through the liquid and a set of scintillators and photomultiplier tubes surrounding the liquid. When a neutrino interacts with an argon atom, it, as before, creates a high-energy charged lepton. This charged lepton ionizes other argon atoms as it passes through the liquid, leaving a trail of free electrons and argon ions in its wake. The electrons are drawn into the wires by the strong electric field and register as a pulse of current in a particular wire. Since liquid argon's electronegativity is so low, it's essentially transparent to these slower-moving electrons. A free electron typically hits the wire that it's closest to, and the further away it is from the wire grid, the longer it takes to hit it. So by analyzing which wires received current pulses as a function of time, it is possible to reconstruct the track of the charged lepton. This is not possible with water- or oil-based detectors because both are too electronegative - the free electrons will react with the medium before reaching the wire.



The high-energy charged particle also causes the argon itself to act as a scintillator in the far ultraviolet (with a wavelength of around 128 nm). The argon is essentially transparent to the scintillation light, so it's received by the scintillators on the walls, which convert the ultraviolet radiation to visible light, which the photomultiplier tubes are far more efficient at amplifying. This extra information can also be used for reconstruction of the hgih-energy charged lepton track. Liquid argon can also be used as a Cherenkov detector, since it has a similar refractive index as water (1.24 versus water's 1.33); it's this triple redundancy in the signal which has made liquid argon TPCs so appealing.



There are several other advantages to using liquid argon as opposed to water or oil. Liquid argon is, as you remarked, denser than either water or oil, which leads to a higher interaction frequency for the same incident neutrino intensity, which speeds up the data-taking rate (given that neutrino experiments have a very slow data-taking rate, this is the main bottleneck that determines how long an experiment must be run to collect a statistically-useful dataset). Argon is also a noble element, which means that it doesn't tend to interact with either impurities or the container it's stored in, so it's also somewhat easier to purify and keep clean, reducing the background that analyses have to account for and making it easier to see a signal.



Given that all of the above advantages also apply to the heavier noble gases such as krypton and xenon, you may be wondering why argon is used instead of those. The answer is simple: argon is much cheaper than the heavier noble gases, which allows you to build a bigger detector for the same budget.






share|cite|improve this answer









$endgroup$









  • 5




    $begingroup$
    "argon is much cheaper than the heavier noble gases" Yep. The nitrogen liquifying industry has to deal with non-trivial quantities of the stuff as a byproduct. They love to find someplace to sell it. And because the welding industry also uses it they have sufficient incentive to capture and keep it.
    $endgroup$
    – dmckee
    Mar 27 at 19:44














24












24








24





$begingroup$

There are many different types of neutrino detectors, using various techniques to turn a neutrino interaction into an electrical signal. Detectors that use a large quantity of water or oil, like Super-Kamiokande in Japan and MiniBooNE at Fermilab, are Cherenkov detectors. Their basic principle of operation is as follows: when neutrinos pass through the liquid and interact with it, they produce leptons that are energetic enough to move faster than the speed of light in the medium. When this happens, the leptons emit a cone of Cherenkov radiation, which is detected by photomultiplier tubes surrounding the medium; later, the intensity and relative timing of the light pulses are transformed into a reconstruction of the track of the charged lepton.



The neutrino detectors using liquid argon are called Liquid Argon Time Projection Chambers, or LArTPCs, and work in a different way. These detectors consist of a large volume of liquid argon, with a grid of high-voltage bare wires passing through the liquid and a set of scintillators and photomultiplier tubes surrounding the liquid. When a neutrino interacts with an argon atom, it, as before, creates a high-energy charged lepton. This charged lepton ionizes other argon atoms as it passes through the liquid, leaving a trail of free electrons and argon ions in its wake. The electrons are drawn into the wires by the strong electric field and register as a pulse of current in a particular wire. Since liquid argon's electronegativity is so low, it's essentially transparent to these slower-moving electrons. A free electron typically hits the wire that it's closest to, and the further away it is from the wire grid, the longer it takes to hit it. So by analyzing which wires received current pulses as a function of time, it is possible to reconstruct the track of the charged lepton. This is not possible with water- or oil-based detectors because both are too electronegative - the free electrons will react with the medium before reaching the wire.



The high-energy charged particle also causes the argon itself to act as a scintillator in the far ultraviolet (with a wavelength of around 128 nm). The argon is essentially transparent to the scintillation light, so it's received by the scintillators on the walls, which convert the ultraviolet radiation to visible light, which the photomultiplier tubes are far more efficient at amplifying. This extra information can also be used for reconstruction of the hgih-energy charged lepton track. Liquid argon can also be used as a Cherenkov detector, since it has a similar refractive index as water (1.24 versus water's 1.33); it's this triple redundancy in the signal which has made liquid argon TPCs so appealing.



There are several other advantages to using liquid argon as opposed to water or oil. Liquid argon is, as you remarked, denser than either water or oil, which leads to a higher interaction frequency for the same incident neutrino intensity, which speeds up the data-taking rate (given that neutrino experiments have a very slow data-taking rate, this is the main bottleneck that determines how long an experiment must be run to collect a statistically-useful dataset). Argon is also a noble element, which means that it doesn't tend to interact with either impurities or the container it's stored in, so it's also somewhat easier to purify and keep clean, reducing the background that analyses have to account for and making it easier to see a signal.



Given that all of the above advantages also apply to the heavier noble gases such as krypton and xenon, you may be wondering why argon is used instead of those. The answer is simple: argon is much cheaper than the heavier noble gases, which allows you to build a bigger detector for the same budget.






share|cite|improve this answer









$endgroup$



There are many different types of neutrino detectors, using various techniques to turn a neutrino interaction into an electrical signal. Detectors that use a large quantity of water or oil, like Super-Kamiokande in Japan and MiniBooNE at Fermilab, are Cherenkov detectors. Their basic principle of operation is as follows: when neutrinos pass through the liquid and interact with it, they produce leptons that are energetic enough to move faster than the speed of light in the medium. When this happens, the leptons emit a cone of Cherenkov radiation, which is detected by photomultiplier tubes surrounding the medium; later, the intensity and relative timing of the light pulses are transformed into a reconstruction of the track of the charged lepton.



The neutrino detectors using liquid argon are called Liquid Argon Time Projection Chambers, or LArTPCs, and work in a different way. These detectors consist of a large volume of liquid argon, with a grid of high-voltage bare wires passing through the liquid and a set of scintillators and photomultiplier tubes surrounding the liquid. When a neutrino interacts with an argon atom, it, as before, creates a high-energy charged lepton. This charged lepton ionizes other argon atoms as it passes through the liquid, leaving a trail of free electrons and argon ions in its wake. The electrons are drawn into the wires by the strong electric field and register as a pulse of current in a particular wire. Since liquid argon's electronegativity is so low, it's essentially transparent to these slower-moving electrons. A free electron typically hits the wire that it's closest to, and the further away it is from the wire grid, the longer it takes to hit it. So by analyzing which wires received current pulses as a function of time, it is possible to reconstruct the track of the charged lepton. This is not possible with water- or oil-based detectors because both are too electronegative - the free electrons will react with the medium before reaching the wire.



The high-energy charged particle also causes the argon itself to act as a scintillator in the far ultraviolet (with a wavelength of around 128 nm). The argon is essentially transparent to the scintillation light, so it's received by the scintillators on the walls, which convert the ultraviolet radiation to visible light, which the photomultiplier tubes are far more efficient at amplifying. This extra information can also be used for reconstruction of the hgih-energy charged lepton track. Liquid argon can also be used as a Cherenkov detector, since it has a similar refractive index as water (1.24 versus water's 1.33); it's this triple redundancy in the signal which has made liquid argon TPCs so appealing.



There are several other advantages to using liquid argon as opposed to water or oil. Liquid argon is, as you remarked, denser than either water or oil, which leads to a higher interaction frequency for the same incident neutrino intensity, which speeds up the data-taking rate (given that neutrino experiments have a very slow data-taking rate, this is the main bottleneck that determines how long an experiment must be run to collect a statistically-useful dataset). Argon is also a noble element, which means that it doesn't tend to interact with either impurities or the container it's stored in, so it's also somewhat easier to purify and keep clean, reducing the background that analyses have to account for and making it easier to see a signal.



Given that all of the above advantages also apply to the heavier noble gases such as krypton and xenon, you may be wondering why argon is used instead of those. The answer is simple: argon is much cheaper than the heavier noble gases, which allows you to build a bigger detector for the same budget.







share|cite|improve this answer












share|cite|improve this answer



share|cite|improve this answer










answered Mar 27 at 9:07









probably_someoneprobably_someone

18.8k12960




18.8k12960








  • 5




    $begingroup$
    "argon is much cheaper than the heavier noble gases" Yep. The nitrogen liquifying industry has to deal with non-trivial quantities of the stuff as a byproduct. They love to find someplace to sell it. And because the welding industry also uses it they have sufficient incentive to capture and keep it.
    $endgroup$
    – dmckee
    Mar 27 at 19:44














  • 5




    $begingroup$
    "argon is much cheaper than the heavier noble gases" Yep. The nitrogen liquifying industry has to deal with non-trivial quantities of the stuff as a byproduct. They love to find someplace to sell it. And because the welding industry also uses it they have sufficient incentive to capture and keep it.
    $endgroup$
    – dmckee
    Mar 27 at 19:44








5




5




$begingroup$
"argon is much cheaper than the heavier noble gases" Yep. The nitrogen liquifying industry has to deal with non-trivial quantities of the stuff as a byproduct. They love to find someplace to sell it. And because the welding industry also uses it they have sufficient incentive to capture and keep it.
$endgroup$
– dmckee
Mar 27 at 19:44




$begingroup$
"argon is much cheaper than the heavier noble gases" Yep. The nitrogen liquifying industry has to deal with non-trivial quantities of the stuff as a byproduct. They love to find someplace to sell it. And because the welding industry also uses it they have sufficient incentive to capture and keep it.
$endgroup$
– dmckee
Mar 27 at 19:44











4












$begingroup$

I think we're getting confused. Using Chlorine to trigger transitions to Argon is a way of detecting neutrinos are present.



Using a volume of liquid Noble element to detect the passage of charged particles is a technique of calorimetry. In my old experiment (NA48) we used a liquid Krypton calorimeter.




  • A denser medium gives more ionisation per unit length (hence greater resolution).

  • Electrons liberated by ionisation are able to drift long distances in a noble element (this is how we detect the ionisation).


So hundreds of litres of liquid Kr provides a very dense medium that is good for tracking ionising particles.



However, liquid krypton is expensive - six times more expensive than single malt whisky. Luckily, we had a Russian team on our collaboration. In the 90s, the Russians had no money, but they did have plenty of raw materials, so they supplied the LKr (it's a by-product of producing liquid O2 for the steel industry).






share|cite|improve this answer









$endgroup$









  • 2




    $begingroup$
    Liquid nobel gas TPCs use the stuff for the neutrino interaction medium, the ionization and transport medium and the scintillating medium (for establishing event timing in detectors where the drift time far exceeds the coarsest beam structure).
    $endgroup$
    – dmckee
    Mar 27 at 19:46
















4












$begingroup$

I think we're getting confused. Using Chlorine to trigger transitions to Argon is a way of detecting neutrinos are present.



Using a volume of liquid Noble element to detect the passage of charged particles is a technique of calorimetry. In my old experiment (NA48) we used a liquid Krypton calorimeter.




  • A denser medium gives more ionisation per unit length (hence greater resolution).

  • Electrons liberated by ionisation are able to drift long distances in a noble element (this is how we detect the ionisation).


So hundreds of litres of liquid Kr provides a very dense medium that is good for tracking ionising particles.



However, liquid krypton is expensive - six times more expensive than single malt whisky. Luckily, we had a Russian team on our collaboration. In the 90s, the Russians had no money, but they did have plenty of raw materials, so they supplied the LKr (it's a by-product of producing liquid O2 for the steel industry).






share|cite|improve this answer









$endgroup$









  • 2




    $begingroup$
    Liquid nobel gas TPCs use the stuff for the neutrino interaction medium, the ionization and transport medium and the scintillating medium (for establishing event timing in detectors where the drift time far exceeds the coarsest beam structure).
    $endgroup$
    – dmckee
    Mar 27 at 19:46














4












4








4





$begingroup$

I think we're getting confused. Using Chlorine to trigger transitions to Argon is a way of detecting neutrinos are present.



Using a volume of liquid Noble element to detect the passage of charged particles is a technique of calorimetry. In my old experiment (NA48) we used a liquid Krypton calorimeter.




  • A denser medium gives more ionisation per unit length (hence greater resolution).

  • Electrons liberated by ionisation are able to drift long distances in a noble element (this is how we detect the ionisation).


So hundreds of litres of liquid Kr provides a very dense medium that is good for tracking ionising particles.



However, liquid krypton is expensive - six times more expensive than single malt whisky. Luckily, we had a Russian team on our collaboration. In the 90s, the Russians had no money, but they did have plenty of raw materials, so they supplied the LKr (it's a by-product of producing liquid O2 for the steel industry).






share|cite|improve this answer









$endgroup$



I think we're getting confused. Using Chlorine to trigger transitions to Argon is a way of detecting neutrinos are present.



Using a volume of liquid Noble element to detect the passage of charged particles is a technique of calorimetry. In my old experiment (NA48) we used a liquid Krypton calorimeter.




  • A denser medium gives more ionisation per unit length (hence greater resolution).

  • Electrons liberated by ionisation are able to drift long distances in a noble element (this is how we detect the ionisation).


So hundreds of litres of liquid Kr provides a very dense medium that is good for tracking ionising particles.



However, liquid krypton is expensive - six times more expensive than single malt whisky. Luckily, we had a Russian team on our collaboration. In the 90s, the Russians had no money, but they did have plenty of raw materials, so they supplied the LKr (it's a by-product of producing liquid O2 for the steel industry).







share|cite|improve this answer












share|cite|improve this answer



share|cite|improve this answer










answered Mar 27 at 9:05









Oscar BravoOscar Bravo

2,083416




2,083416








  • 2




    $begingroup$
    Liquid nobel gas TPCs use the stuff for the neutrino interaction medium, the ionization and transport medium and the scintillating medium (for establishing event timing in detectors where the drift time far exceeds the coarsest beam structure).
    $endgroup$
    – dmckee
    Mar 27 at 19:46














  • 2




    $begingroup$
    Liquid nobel gas TPCs use the stuff for the neutrino interaction medium, the ionization and transport medium and the scintillating medium (for establishing event timing in detectors where the drift time far exceeds the coarsest beam structure).
    $endgroup$
    – dmckee
    Mar 27 at 19:46








2




2




$begingroup$
Liquid nobel gas TPCs use the stuff for the neutrino interaction medium, the ionization and transport medium and the scintillating medium (for establishing event timing in detectors where the drift time far exceeds the coarsest beam structure).
$endgroup$
– dmckee
Mar 27 at 19:46




$begingroup$
Liquid nobel gas TPCs use the stuff for the neutrino interaction medium, the ionization and transport medium and the scintillating medium (for establishing event timing in detectors where the drift time far exceeds the coarsest beam structure).
$endgroup$
– dmckee
Mar 27 at 19:46











0












$begingroup$

There is a very specific reaction between a chlorine nucleus and a neutrino which produces an argon nucleus. By detecting the production of argon in a very large volume of chlorine, the presence of a neutrino can be deduced. This means that an extremely sensitive neutrino detector can be designed around a great volume of chlorine which is periodically swept through an argon detector.






share|cite|improve this answer









$endgroup$













  • $begingroup$
    Is this design actually used in current neutrino detectors? I don't seem to recall any at the moment that use extremely large volumes of chlorine - in fact, most of them that I can think of (IceCube notwithstanding) use extremely large volumes of argon (or xenon) surrounded by scintillators and photomultipliers, which is exactly backwards from what you have written here.
    $endgroup$
    – probably_someone
    Mar 27 at 7:08












  • $begingroup$
    @probably See en.wikipedia.org/wiki/Homestake_experiment "Upon interaction with an electron neutrino, a chlorine-37 atom transforms into a radioactive isotope of argon-37".
    $endgroup$
    – PM 2Ring
    Mar 27 at 7:25










  • $begingroup$
    one of the original neutrino detectors used a gigantic vat of dry cleaning fluid (rich in chlorine) deep underground, which would be swept at regular intervals to look for argon.
    $endgroup$
    – niels nielsen
    Mar 27 at 7:27






  • 1




    $begingroup$
    @PM2Ring Ok, but do you have another example of this design being used in any modern context, i.e. not in a detector that's at this point 60 years old (I couldn't find another one on en.wikipedia.org/wiki/List_of_neutrino_experiments)? Given that the OP is asking about the use of liquid argon in neutrino experiments (plural), I'm fairly certain this isn't particularly relevant.
    $endgroup$
    – probably_someone
    Mar 27 at 7:29












  • $begingroup$
    I went with argon and did not specifically consider liquid argon. eager to hear inputs from experts on this. -NN
    $endgroup$
    – niels nielsen
    Mar 27 at 7:42
















0












$begingroup$

There is a very specific reaction between a chlorine nucleus and a neutrino which produces an argon nucleus. By detecting the production of argon in a very large volume of chlorine, the presence of a neutrino can be deduced. This means that an extremely sensitive neutrino detector can be designed around a great volume of chlorine which is periodically swept through an argon detector.






share|cite|improve this answer









$endgroup$













  • $begingroup$
    Is this design actually used in current neutrino detectors? I don't seem to recall any at the moment that use extremely large volumes of chlorine - in fact, most of them that I can think of (IceCube notwithstanding) use extremely large volumes of argon (or xenon) surrounded by scintillators and photomultipliers, which is exactly backwards from what you have written here.
    $endgroup$
    – probably_someone
    Mar 27 at 7:08












  • $begingroup$
    @probably See en.wikipedia.org/wiki/Homestake_experiment "Upon interaction with an electron neutrino, a chlorine-37 atom transforms into a radioactive isotope of argon-37".
    $endgroup$
    – PM 2Ring
    Mar 27 at 7:25










  • $begingroup$
    one of the original neutrino detectors used a gigantic vat of dry cleaning fluid (rich in chlorine) deep underground, which would be swept at regular intervals to look for argon.
    $endgroup$
    – niels nielsen
    Mar 27 at 7:27






  • 1




    $begingroup$
    @PM2Ring Ok, but do you have another example of this design being used in any modern context, i.e. not in a detector that's at this point 60 years old (I couldn't find another one on en.wikipedia.org/wiki/List_of_neutrino_experiments)? Given that the OP is asking about the use of liquid argon in neutrino experiments (plural), I'm fairly certain this isn't particularly relevant.
    $endgroup$
    – probably_someone
    Mar 27 at 7:29












  • $begingroup$
    I went with argon and did not specifically consider liquid argon. eager to hear inputs from experts on this. -NN
    $endgroup$
    – niels nielsen
    Mar 27 at 7:42














0












0








0





$begingroup$

There is a very specific reaction between a chlorine nucleus and a neutrino which produces an argon nucleus. By detecting the production of argon in a very large volume of chlorine, the presence of a neutrino can be deduced. This means that an extremely sensitive neutrino detector can be designed around a great volume of chlorine which is periodically swept through an argon detector.






share|cite|improve this answer









$endgroup$



There is a very specific reaction between a chlorine nucleus and a neutrino which produces an argon nucleus. By detecting the production of argon in a very large volume of chlorine, the presence of a neutrino can be deduced. This means that an extremely sensitive neutrino detector can be designed around a great volume of chlorine which is periodically swept through an argon detector.







share|cite|improve this answer












share|cite|improve this answer



share|cite|improve this answer










answered Mar 27 at 7:00









niels nielsenniels nielsen

21.1k53062




21.1k53062












  • $begingroup$
    Is this design actually used in current neutrino detectors? I don't seem to recall any at the moment that use extremely large volumes of chlorine - in fact, most of them that I can think of (IceCube notwithstanding) use extremely large volumes of argon (or xenon) surrounded by scintillators and photomultipliers, which is exactly backwards from what you have written here.
    $endgroup$
    – probably_someone
    Mar 27 at 7:08












  • $begingroup$
    @probably See en.wikipedia.org/wiki/Homestake_experiment "Upon interaction with an electron neutrino, a chlorine-37 atom transforms into a radioactive isotope of argon-37".
    $endgroup$
    – PM 2Ring
    Mar 27 at 7:25










  • $begingroup$
    one of the original neutrino detectors used a gigantic vat of dry cleaning fluid (rich in chlorine) deep underground, which would be swept at regular intervals to look for argon.
    $endgroup$
    – niels nielsen
    Mar 27 at 7:27






  • 1




    $begingroup$
    @PM2Ring Ok, but do you have another example of this design being used in any modern context, i.e. not in a detector that's at this point 60 years old (I couldn't find another one on en.wikipedia.org/wiki/List_of_neutrino_experiments)? Given that the OP is asking about the use of liquid argon in neutrino experiments (plural), I'm fairly certain this isn't particularly relevant.
    $endgroup$
    – probably_someone
    Mar 27 at 7:29












  • $begingroup$
    I went with argon and did not specifically consider liquid argon. eager to hear inputs from experts on this. -NN
    $endgroup$
    – niels nielsen
    Mar 27 at 7:42


















  • $begingroup$
    Is this design actually used in current neutrino detectors? I don't seem to recall any at the moment that use extremely large volumes of chlorine - in fact, most of them that I can think of (IceCube notwithstanding) use extremely large volumes of argon (or xenon) surrounded by scintillators and photomultipliers, which is exactly backwards from what you have written here.
    $endgroup$
    – probably_someone
    Mar 27 at 7:08












  • $begingroup$
    @probably See en.wikipedia.org/wiki/Homestake_experiment "Upon interaction with an electron neutrino, a chlorine-37 atom transforms into a radioactive isotope of argon-37".
    $endgroup$
    – PM 2Ring
    Mar 27 at 7:25










  • $begingroup$
    one of the original neutrino detectors used a gigantic vat of dry cleaning fluid (rich in chlorine) deep underground, which would be swept at regular intervals to look for argon.
    $endgroup$
    – niels nielsen
    Mar 27 at 7:27






  • 1




    $begingroup$
    @PM2Ring Ok, but do you have another example of this design being used in any modern context, i.e. not in a detector that's at this point 60 years old (I couldn't find another one on en.wikipedia.org/wiki/List_of_neutrino_experiments)? Given that the OP is asking about the use of liquid argon in neutrino experiments (plural), I'm fairly certain this isn't particularly relevant.
    $endgroup$
    – probably_someone
    Mar 27 at 7:29












  • $begingroup$
    I went with argon and did not specifically consider liquid argon. eager to hear inputs from experts on this. -NN
    $endgroup$
    – niels nielsen
    Mar 27 at 7:42
















$begingroup$
Is this design actually used in current neutrino detectors? I don't seem to recall any at the moment that use extremely large volumes of chlorine - in fact, most of them that I can think of (IceCube notwithstanding) use extremely large volumes of argon (or xenon) surrounded by scintillators and photomultipliers, which is exactly backwards from what you have written here.
$endgroup$
– probably_someone
Mar 27 at 7:08






$begingroup$
Is this design actually used in current neutrino detectors? I don't seem to recall any at the moment that use extremely large volumes of chlorine - in fact, most of them that I can think of (IceCube notwithstanding) use extremely large volumes of argon (or xenon) surrounded by scintillators and photomultipliers, which is exactly backwards from what you have written here.
$endgroup$
– probably_someone
Mar 27 at 7:08














$begingroup$
@probably See en.wikipedia.org/wiki/Homestake_experiment "Upon interaction with an electron neutrino, a chlorine-37 atom transforms into a radioactive isotope of argon-37".
$endgroup$
– PM 2Ring
Mar 27 at 7:25




$begingroup$
@probably See en.wikipedia.org/wiki/Homestake_experiment "Upon interaction with an electron neutrino, a chlorine-37 atom transforms into a radioactive isotope of argon-37".
$endgroup$
– PM 2Ring
Mar 27 at 7:25












$begingroup$
one of the original neutrino detectors used a gigantic vat of dry cleaning fluid (rich in chlorine) deep underground, which would be swept at regular intervals to look for argon.
$endgroup$
– niels nielsen
Mar 27 at 7:27




$begingroup$
one of the original neutrino detectors used a gigantic vat of dry cleaning fluid (rich in chlorine) deep underground, which would be swept at regular intervals to look for argon.
$endgroup$
– niels nielsen
Mar 27 at 7:27




1




1




$begingroup$
@PM2Ring Ok, but do you have another example of this design being used in any modern context, i.e. not in a detector that's at this point 60 years old (I couldn't find another one on en.wikipedia.org/wiki/List_of_neutrino_experiments)? Given that the OP is asking about the use of liquid argon in neutrino experiments (plural), I'm fairly certain this isn't particularly relevant.
$endgroup$
– probably_someone
Mar 27 at 7:29






$begingroup$
@PM2Ring Ok, but do you have another example of this design being used in any modern context, i.e. not in a detector that's at this point 60 years old (I couldn't find another one on en.wikipedia.org/wiki/List_of_neutrino_experiments)? Given that the OP is asking about the use of liquid argon in neutrino experiments (plural), I'm fairly certain this isn't particularly relevant.
$endgroup$
– probably_someone
Mar 27 at 7:29














$begingroup$
I went with argon and did not specifically consider liquid argon. eager to hear inputs from experts on this. -NN
$endgroup$
– niels nielsen
Mar 27 at 7:42




$begingroup$
I went with argon and did not specifically consider liquid argon. eager to hear inputs from experts on this. -NN
$endgroup$
– niels nielsen
Mar 27 at 7:42


















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