Concept explainers
(a)
The conserved quantities in the reaction.
(a)
Answer to Problem 24P
The conserved quantities in the reaction are baryon number, charge, electron lepton number and tau lepton number.
Explanation of Solution
Write the reaction.
Check the conservation of baryon number for the reaction on both sides.
Check the conservation of charge for the reaction on both sides.
Check the conservation of electron lepton number for the reaction on both sides.
Check the conservation of muon lepton number for the reaction on both sides.
Check the conservation of tau lepton number for the reaction on both sides.
Check the conservation of strangeness for the reaction on both sides.
Conclusion:
Thus, the conserved quantities in the reaction are baryon number, charge, electron lepton number and tau lepton number.
(b)
The conserved quantities in the reaction.
(b)
Answer to Problem 24P
The conserved quantities in the reaction are baryon number, charge, electron lepton number, muon lepton number and tau lepton number.
Explanation of Solution
Write the reaction.
Check the conservation of baryon number for the reaction on both sides.
Check the conservation of charge for the reaction on both sides.
Check the conservation of electron lepton number for the reaction on both sides.
Check the conservation of muon lepton number for the reaction on both sides.
Check the conservation of tau lepton number for the reaction on both sides.
Check the conservation of strangeness for the reaction on both sides.
Conclusion:
Thus, the conserved quantities in the reaction are baryon number, charge, electron lepton number, muon lepton number and tau lepton number.
(c)
The conserved quantities in the reaction.
(c)
Answer to Problem 24P
The conserved quantities in the reaction are charge, electron lepton number, muon lepton number, tau lepton number and strangeness.
Explanation of Solution
Write the reaction.
Check the conservation of baryon number for the reaction on both sides.
Check the conservation of charge for the reaction on both sides.
Check the conservation of electron lepton number for the reaction on both sides.
Check the conservation of muon lepton number for the reaction on both sides.
Check the conservation of tau lepton number for the reaction on both sides.
Check the conservation of strangeness for the reaction on both sides.
Conclusion:
Thus, the conserved quantities in the reaction are charge, electron lepton number, muon lepton number, tau lepton number and strangeness.
(d)
The conserved quantities in the reaction.
(d)
Answer to Problem 24P
The conserved quantities in the reaction are baryon number, charge, electron lepton number, muon lepton number, tau lepton number and strangeness.
Explanation of Solution
Write the reaction.
Check the conservation of baryon number for the reaction on both sides.
Check the conservation of charge for the reaction on both sides.
Check the conservation of electron lepton number for the reaction on both sides.
Check the conservation of muon lepton number for the reaction on both sides.
Check the conservation of tau lepton number for the reaction on both sides.
Check the conservation of strangeness for the reaction on both sides.
Conclusion:
Thus, the conserved quantities in the reaction are baryon number, charge, electron lepton number, muon lepton number, tau lepton number and strangeness.
(e)
The conserved quantities in the reaction.
(e)
Answer to Problem 24P
The conserved quantities in the reaction are baryon number, charge, electron lepton number, muon lepton number, tau lepton number and strangeness.
Explanation of Solution
Write the reaction.
Check the conservation of baryon number for the reaction on both sides.
Check the conservation of charge for the reaction on both sides.
Check the conservation of electron lepton number for the reaction on both sides.
Check the conservation of muon lepton number for the reaction on both sides.
Check the conservation of tau lepton number for the reaction on both sides.
Check the conservation of strangeness for the reaction on both sides.
Conclusion:
Thus, the conserved quantities in the reaction are baryon number, charge, electron lepton number, muon lepton number, tau lepton number and strangeness.
(f)
The conserved quantities in the reaction.
(f)
Answer to Problem 24P
The conserved quantities in the reaction are baryon number, charge, electron lepton number, muon lepton number, tau lepton number and strangeness.
Explanation of Solution
Write the reaction.
Check the conservation of baryon number for the reaction on both sides.
Check the conservation of charge for the reaction on both sides.
Check the conservation of electron lepton number for the reaction on both sides.
Check the conservation of muon lepton number for the reaction on both sides.
Check the conservation of tau lepton number for the reaction on both sides.
Check the conservation of strangeness for the reaction on both sides.
Conclusion:
Thus, the conserved quantities in the reaction are baryon number, charge, electron lepton number, muon lepton number, tau lepton number and strangeness.
(g)
The reactions that cannot occur.
(g)
Answer to Problem 24P
The reactions that cannot occur are (a), (b) and (c).
Explanation of Solution
Write the reaction (a).
Reaction (a) cannot occur because muon lepton number and strangeness are not conserved.
Write the reaction (b).
Reaction (b) cannot occur because strangeness is not conserved.
Write the reaction (c).
Reaction (c) cannot occur because baryon number is not conserved.
Conclusion:
Thus, the reactions that cannot occur are (a), (b) and (c).
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Chapter 46 Solutions
Physics for Scientists and Engineers With Modern Physics
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- A. Compiete the following nuclear reactions and identify the cosmic phase (big bang, stellar formation, stellar explosion) in which the reaction occurred! DON'T FORGET TO IDENTIFY IF ITS BIGBANG, STELLAR FORMATION OR STELLAR EXPLOSION 1. p+ H + y 2. He+H→+p - Si + Y Ca + Y 3. Mg+ - 4. 3Ar+ 5. 1Cd+ in-→ 48arrow_forwardNuclear Fission: 1. n+ 2U → ? + 3gSr + 2n 2. n+ 235U → 1I 137 + 33Y+ ?narrow_forwardFor the following two reactions, the first may occur but the second cannot. Explain.arrow_forward
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