Answered: How much energy is released in the… | bartleby

Related questions

Question

How much energy is released in the following fission process?
3592U + n → 14156Ba + ⁹²36Kr+ 3n
92
The atomic mass of 23592U is 235.04395 u, the binding energy per nucleon of 141¹,
X MeV
¹56Ba is 8.326 MeV/nucleon and the binding energy per nucleon of 9236Kr is 8.513 MeV/nucleon.

Expert Solution

Step by step

Solved in 2 steps with 2 images

SEE SOLUTION Check out a sample Q&A here

Blurred answer

Similar questions

Please have computer typed.
The experimentally measured mass of the 200Hg atom is 199.968316 u. Find the binding energy per nucleon predicted by the semiempirical binding energy formula and compare with the actual value of e for this nucleus
Binding energy per nucleon (MeV) 10 He He H Fo Part A 50 131, 50 100 150 Number of nucleons, A (mass number) Sn Value 200 Units U Estimate the total binding energy for Cu, using the figure. Express your answer to two significant figures and include the appropriate units. 250
Use the following data to calculate the binding energy per nucleon in MeV of the Rhodium-103 nuclide Mass of atom = 102.905503 u Mass of proton = 1.007276 u Mass of n Use the following data to calculate the binding energy per nucleon in MeV of the Rhodium-103 nuclide Mass of atom = 102.905503 u Mass of proton = 1.007276 u Mass of neutron = 1.008664 u Mass of electron = 0.00054858 u 1 u = 931.494 MeV eutron = 1.008664 u Mass of electron = 0.00054858 u 1 u = 931.494 MeV
One of the ways that 235U can fission is by means of the following reaction: In +235 U 141 Ba + Kr + 3 n 56 Atomic masses of the reactants and products are as follows: n 235 U 92 92 Kr 36 141 Ba 56 1.008665 u 235.043930 u 91.926156 u 140.9144035 u a) Determine the energy in MeV that is released when one 23592U nucleus fissions. Assume that the incoming neutron is very slow. b) Find the total energy released in MeV if 2.8 kg of 23592U were to undergo fission entirely by this reaction.
Archeologist extracted 179 gm of carbon from an animal bone from an archeological site. The carbon shows an activity of 15 decays/s. (Half-life of 146C = 5730 years, 1 year = 3.156 x 107 seconds, Avogadro's number = 6.02 x 1023 atoms/mol) (A) Total number of atoms in this carbon sample = . (B) Decay constant of 146C, λ = . (C) Number of 146C atoms in this sample = . (D) Activity of 146C at time (t = 0) = . (E) Age of the animal =
Question 3. Two nuclei having the same mass number are known as isobars. (a)Calculate the difference in binding energy per nucleon for the following two isobars Na and Mg. (b) How do you account for this difference? (The mass of ?3Mg = 22.994 127 u.) 23
Time 0 t₁2 20₁2 3₁/12 Number of nuclides, N x 10³ 1000 750 500 90/2 10/₁2 250 125 0 12 212 312 412 512 612 7h2 8h2 9h12 10/2 Time in multiples of t₁/2 The figure shows a typical radioactive decay (amount of undecayed nucleus (N) vs. time (t)) from a heavy nucleus. Such a decay may be best expressed by an equation like : ON = N₂ (xt) ON=N₂/λt -λt ON = N₂e N = N₂ e-1/At N 1,000,000 500,000 250,000 125,000 62,500 31,250 15,625 7,813 3,906 1,953 977 412 5/₁/2 61₁2 7h2 81/2
What is the the total binding energy of 6 28 Ni. It isotope mass is 59.930786 u. The mass of a neutron is 1.008665 u and the mass of H is 1.007825 u. a. О b. 526.9 MeV С. 0.565594 u d. 8.781 MeV O e. 59.930786 u
Consider the fission reaction 141 n + U -> 235, 92U syXe + 92 38Sr +3n The masses of the components are 235 235.04393 세 xe| 140.여 2678 92 5 91.911 038 n 1.00 866 U Find the energy released in MeV Use the editor to format your answer
One of the fusion reactions that takes place as a star ages is called the triple alpha process. 3 42He → 126C Calculate the mass defect (in u) and the energy produced (in MeV) each time the reaction takes place.
It is known that the mass of the alpha particle He is 4.002603u, Estimate the binding energy and binding energy per nucleon obtained directly from the reaction channel: I. 2р + 2n He II. Proton emission (Sp) Neutron emission (S,) 1.008665u dan m, I. = 1.007825u, 1u = 1.67 x 10-27kg.