Can Helium-3 and Antimatter Deuterons Achieve Quantum Superposition?

  • Context: Graduate 
  • Thread starter Thread starter Rade
  • Start date Start date
  • Tags Tags
    Quantum Superposition
Click For Summary

Discussion Overview

The discussion revolves around the possibility of achieving quantum superposition between a nucleon cluster of matter helium-3 and antimatter deuterons. Participants explore theoretical implications, mathematical frameworks, and potential experimental approaches related to this concept.

Discussion Character

  • Exploratory
  • Technical explanation
  • Conceptual clarification
  • Debate/contested
  • Mathematical reasoning

Main Points Raised

  • One participant questions whether a mathematical formalism exists in nuclear physics for the superposition of matter and antimatter clusters.
  • Another participant asserts that a superposition is possible, likening the scenario to the thought experiment of Schrödinger's Cat.
  • A different participant discusses the initial conditions of a collision between the two systems, suggesting that while annihilation is likely, there may be scenarios where the system could escape annihilation.
  • Further inquiry is made into whether there is a mathematical argument that could support the formation of a superposed state rather than annihilation during a collision.
  • One participant mentions the existence of bound states between matter and antimatter, referencing positronium as an example, but questions the relevance to the original inquiry.
  • Another participant expresses interest in the specific conditions under which helium-3 and antimatter deuterons could form a stable superposition, referencing a cluster model by Ronald Brightsen that suggests such a possibility.

Areas of Agreement / Disagreement

Participants express differing views on the feasibility of achieving quantum superposition versus forming bound states. There is no consensus on whether a successful collision could lead to superposition or if annihilation is the more likely outcome.

Contextual Notes

Participants note the lack of published mathematical dynamics to support the proposed superposition, and there are unresolved questions regarding the experimental attempts to test these ideas.

Who May Find This Useful

This discussion may be of interest to those studying quantum mechanics, nuclear physics, and antimatter interactions, as well as researchers exploring theoretical models of matter-antimatter behavior.

Rade
I need some help with a problem that involves the concept of quantum superposition. Suppose you have a nucleon cluster of matter helium-3 [PNP] and you attempt to combine with antimatter deuterons [N^P^], where ^ represents antimatter. Would it be possible that the two could form wavefunctions that allow for a quantum superposition rather than complete annihilation of the matter and antimatter quarks ? Thanks for any comments you can provide.
 
Physics news on Phys.org
Would the lack any of response to my initial post indicate that no current mathematical formalism exists in nuclear physics for possible superposition of a matter fermion cluster [PNP] with an antimatter boson cluster [N^P^] ? :confused:
 
Yeah, of course a superposition is possible. You're asking the Schroedinger's Cat question.

Carl
 
Rade,

Your own words

... and you attempt to combine with antimatter deuterons ...

can be translated as if you were preparing an experimental collision between the two systems. Right? Then, this means that the initial condition you consider is a superposition of the mixed states for the composite system. At the start the superposition is separable. But with evolution of this system all possible outcome will enter into the state vector of the system. However, if the collision is successful, some component -annihilation- may dominate the picture: annihilation is nearly certain. Conversely, if the collision is a little bit too much off-target the system will almost surely escape annihilation. This picture may be complemented by other possible outcomes ...
 
lalbatros said:
...if the collision is successful, some component -annihilation- may dominate the picture: annihilation is nearly certain. Conversely, if the collision is a little bit too much off-target the system will almost surely escape annihilation.
Thank you albatros. It is the second part of your above statement that I now try to understand from both the physics and more importantly the mathematics. Are you aware of any mathematical argument that would allow the collision to be successful, and for matter [PNP] + antimatter [N^P^] to form superposed union, and escape annihilation ? Perhaps some form of one of the Dirac equations ? If not, is there a mathematical argument that proves such collision as stated above impossible ? On first glance, one may think that collision of matter [PNP] + antimatter [N^P^], would just yield a [P], with the rest involved in annihilation and lots of gamma ray energy released. But, this would not happen if the two can form a superposition, this is what I try to understand mathematically, how such a superposition may be possible. Finally, has CERN or other experimental labs that work with antimatter ever tried this experiment ? It is really a very simple system to test, collision between matter helium-3 [PNP] with antimatter deuteron [N^P^], at different collision energies--does anyone know if this experiment has been conducted ?
 
Are you really interested in whether they can form a superposition or whether they can form a bound state? Matter and antimatter can form bound states, for example. See this article which talks about positronium. It's very short lived but can exist. It's not really clear from your question why exactly you are asking and knowing that would help us give you the information you need.
 
David said:
Are you really interested in whether they can form a superposition or whether they can form a bound state? It's not really clear from your question why exactly you are asking and knowing that would help us give you the information you need.
Thank you David. I am really interested if matter helium-3 [PNP] can form a stable superposition with antimatter anti--deuteron [N^P^], where I use ^ =antimatter. The positronium that you mention is very unstable, so only very weakly "bound".

I am interested because there is a cluster model by the late nuclear physicist Ronald Brightsen (MIT, 1950, worked under Dr. Charles Coryell at MIT on isotopes) that predicts that the above matter + antimatter superposition is possible--but he never published on the mathematical dynamics that would explain how the superposition would occur. He only mentioned that the outcome is two superposed states (1) what we call the proton [P], and (2) a hidden state with matter+antimatter {[NP][N^P^]}. I search for someone with the interest and time to take on the task of developing the required mathematics. I have posted the link to the model at many other threads, but here it is again: http://www.brightsenmodel.phoenixrising-web.net
 
Last edited by a moderator:

Similar threads

Graduate Matter + Antimatter Bound State Mathematics
  • · Replies 4 ·
Replies
4
Views
2K
Graduate Can anyone give me the details of creating a cat state in Circuit QED?
  • · Replies 16 ·
Replies
16
Views
4K
Graduate Superposition in quantum computing
  • · Replies 1 ·
Replies
1
Views
2K
Graduate Cause of spontaneous emission?
  • · Replies 15 ·
Replies
15
Views
4K
Undergrad About quantum interference: space and time
  • · Replies 30 ·
2
Replies
30
Views
4K
Graduate How Can We Manipulate 8 Quantum Combinations with Qubit Computing?
  • · Replies 1 ·
Replies
1
Views
1K
Graduate Structure of Matter in Quantum Field Theory
  • · Replies 75 ·
3
Replies
75
Views
10K
My inspirational epic -- Enjoy, correct and criticize to your heart's content
  • · Replies 3 ·
Replies
3
Views
2K
Graduate Can entanglement be detected in a single Bell pair?
  • · Replies 1 ·
Replies
1
Views
2K
Graduate Fermions, Monopoles & Quantum Hall: New Advances
  • · Replies 12 ·
Replies
12
Views
6K