U-238 to Th-234 Decay: Exploring Energy Uncertainties

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In summary, the conversation discusses the decay of U-238, with 79% of the time resulting in the ground state of Th-234 emitting a 4.198 MeV alpha ray. The remaining decay energy is carried off by the Th-234 daughter nucleus, with the missing 72 keV being the recoil energy. The intensity of the gamma rays represents the probability of obtaining that energy, and if one component is excited, the energy is not kinetic at the time of reaction.
  • #1
Marioqwe
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Hello, I need some help understanding this.

http://atom.kaeri.re.kr/cgi-bin/decay?U-238 A

it says that 79% of the time U-238 goes to the ground state of Th-234 emitting a 4.198 MeV alpha ray. But the difference between the ground state of U-238 and Th-234 is more than 4.198 MeV. What happened to the rest of the decay energy? Does it have anything to do with uncertainties? Thanks.
 
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  • #2
Wikipedia gives the decay energy as 4.270 MeV. Is that any better?
 
  • #3
Thank you for replying Bill_K.
The website also gives the decay energy as 4.270 MeV. I wanted to know what happened to the remaining 72 keV.
 
  • #5
The missing 72 keV is the recoil energy carried off by the Th-234 daughter nucleus.
 
  • #6
Newton's third law of motion, for every action there is an equal and opposite reaction.
Momentum must be conserved, so if you take the system, the momentum change from the decay must be 0.
So, when you split a He off a U238, you have the total energy of the mass difference, which must be divided between the He and the Th234 in such a way that the momentum is still 0. So, the He, being 58.5 times lighter, must have much higher velocity imparted, but the Th must also have some.
 
  • #7
... and the reaction products share the energy in inverse proportion to their masses. Thus the Th-234 gets 4.270 MeV / 58.5 = 73 keV
 
  • #8
Makes sense. Thank you.

One last thing. For the gamma rays, do the intensities represent the probability of getting that gamma ray energy? They appear to be very low since U-238 does not decay to the ground state of Th-234 ~21% of the time. I would think that Th-234 needs to be in its ground state before it can decay to Pa-234 but I might be wrong.
 
  • #9
Marioqwe said:
One last thing. For the gamma rays, do the intensities represent the probability of getting that gamma ray energy? They appear to be very low since U-238 does not decay to the ground state of Th-234 ~21% of the time. I would think that Th-234 needs to be in its ground state before it can decay to Pa-234 but I might be wrong.
If one of the components is excited, then that excitation energy is not kinetic at the reaction time, so the actual energy of the decay is used.

Later, the excited state will decay to the ground state, and give off a gamma ray in the process. Just like the alpha decay, momentum must be preserved, so the Gamma ray will have most of the energy, but the nucleus must have exactly the same momentum in the opposite direction as the gamma ray.
 

Related to U-238 to Th-234 Decay: Exploring Energy Uncertainties

What is U-238 to Th-234 decay?

U-238 to Th-234 decay is a radioactive process in which the isotope uranium-238 (U-238) decays into thorium-234 (Th-234) through a series of alpha and beta decays.

Why is exploring energy uncertainties important in this decay process?

Exploring energy uncertainties in U-238 to Th-234 decay is important because it helps us understand the energy released during the decay process and the potential risks associated with handling radioactive materials.

What are the factors that contribute to energy uncertainties in this decay process?

The factors that contribute to energy uncertainties in U-238 to Th-234 decay include the initial energy of the decaying isotope, the branching ratio of different decay modes, and the energy of the emitted particles.

How do scientists measure and calculate energy uncertainties in this decay process?

Scientists measure and calculate energy uncertainties in U-238 to Th-234 decay through experiments and mathematical models. They use detectors to measure the energy of emitted particles and statistical methods to analyze the results and estimate uncertainties.

What are the practical applications of studying U-238 to Th-234 decay and its energy uncertainties?

The study of U-238 to Th-234 decay and its energy uncertainties has practical applications in fields such as nuclear energy, environmental monitoring, and medical imaging. It also helps us better understand the behavior of radioactive materials and their potential impact on the environment and human health.

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