Neutrino-Atom Elastic Scattering: Insights from Particle Physics

In summary, "Neutrino-Atom Elastic Scattering: Insights from Particle Physics" explores the interactions between neutrinos and atomic particles, emphasizing the fundamental principles of particle physics that govern these processes. The article discusses the significance of neutrino scattering experiments in understanding neutrino properties, such as mass and flavor, and their role in the universe. It highlights various experimental approaches and recent advancements in detection technology, which enhance the accuracy of measurements and deepen our knowledge of neutrino behavior. The insights gained from these studies contribute to broader implications in astrophysics and cosmology, underscoring the elusive nature of neutrinos and their impact on our understanding of matter and the fundamental forces of nature.
  • #1
Rayan
17
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What happens generally when a neutrino/anti-neutrino collides with a light vs heavy atom?

My guess is, since neutrinos have very low cross section, their interaction is weak and therefore it will be an elastic scattering! For example:

$$ \overline{\nu} + He^3 \rightarrow \overline{\nu} + He^3 $$

and

$$ \nu + C^{12} \rightarrow \nu + C^{12} $$

But since I'm new to Particle physics and trying to learn by my own I'm not very sure!
 
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  • #2
Elastic scattering is always possible, inelastic reactions can be possible depending on the target nucleus and the neutrino energy. ##\nu + T \rightarrow {}^3He + e^-## is possible at any neutrino energy, for example, because tritium already has enough energy to decay even without neutrino.
 
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  • #3
A few points.

We usually write nuclei as 50V..

Neutrinos and antineutrinos do different things. To a degree electron, muon and tau neutrinos do different things.

Interactions on matter can occur off a nuclear target or an electron target. The latter happens less often.

What you have drawn is called a "neutral current" event. They are less common than "charged current" events, when a neutrino comes in and a charged lepton goes out.
 
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Likes berkeman
  • #4
The neutrino was discovered in the interaction​
$${\bar\nu}+p\rightarrow n+e^+$$​
 

FAQ: Neutrino-Atom Elastic Scattering: Insights from Particle Physics

What is neutrino-atom elastic scattering?

Neutrino-atom elastic scattering is a process in which a neutrino interacts with an atom, causing the atom to recoil without any change in the internal structure of the atom or the neutrino. This type of interaction is a rare and subtle process that provides valuable insights into neutrino properties and atomic structure.

Why is studying neutrino-atom elastic scattering important?

Studying neutrino-atom elastic scattering is important because it helps scientists understand fundamental properties of neutrinos, such as their masses and interaction cross-sections. It also provides a unique way to probe atomic structure and test the Standard Model of particle physics under different conditions.

What experimental techniques are used to detect neutrino-atom elastic scattering?

Experimental techniques to detect neutrino-atom elastic scattering typically involve highly sensitive detectors that can measure the tiny recoils of atoms caused by neutrino interactions. These detectors often use cryogenic or scintillation technologies to achieve the necessary sensitivity and precision.

What are the challenges in observing neutrino-atom elastic scattering?

One of the main challenges in observing neutrino-atom elastic scattering is the extremely low probability of such interactions, requiring very sensitive and low-background detectors. Additionally, distinguishing the signal from background noise and other types of interactions is a significant experimental hurdle.

What insights have been gained from studying neutrino-atom elastic scattering?

Insights gained from studying neutrino-atom elastic scattering include improved measurements of neutrino properties, such as their interaction cross-sections and potential hints at their masses. These studies also provide tests of theoretical models in particle physics and help refine our understanding of atomic structure and fundamental forces.

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