Kinetic energy of an alpha particle

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Taylor_1989
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Homework Statement



During the ##\alpha## decay of ##^{238}_{92}U## an ##\alpha## particle is fromed inside the nucleus. Given that the last 4 nucleons in ##^{238}_{92}U## have an average binding energy per nucleon of ##6.1MeV##, estimate the kinetic energy of the ##\alpha## particle when it is formed.

Addtional information
Mass of ##\alpha=4.00260amu##
Mass of neutron =##1.00866amu##
Mass of Proton = ##1.00783amu##
amu = ##1.66054\cdot10^{-27}##

Homework Equations


##Q=B.E_f-B.E_i##

3. The Attempt at a Solution

I am been trying visulise this question and the best way I have come with is as follow:

Using the standard alpha decay equation

$$^{232}_92U\rightarrow^{230}_{90}X+\alpha$$

Now if I thing of separating the LHS of the equation I would gee the following

$$B.E_x+mc^2_x +B.E_{\alpha 1}+mc^2_{\alpha 1}=B.E_x+mc^2_x+B.E_{\alpha 2}+mc^2_{\alpha 2}$$

Where ##B.E_{\alpha 1}## is the energy of the last four nucleons.

So from this the LHS ##B.E_x+mc^2_x## will cancel with the ##B.E_x+mc^2_x## on RHS and I will be left with:$$B.E_{\alpha 1}+mc^2_{\alpha 1}=B.E_{\alpha 2}+mc^2_{\alpha 2}$$

So as the total number of protons and neutrons are equal on both sides the the following equation can be formed:

$$mc^2_{\alpha 1}-mc^2_{\alpha 2}=B.E_{\alpha 2}-B.E_{\alpha 1}$$

Where the LHS of the equation is the Q value hence

$$Q=B.E_{\alpha 2}-B.E_{\alpha 1}$$

Calculating the B.E for ##B.E_{\alpha 2}## give the following

$$B.E_{\alpha 2}=2n+2p=28.29MeV$$

pluggin into my Q value equation

$$Q=29.29MeV-4*6.1MeV=3.89MeV$$

Is this the correct method, and through process in solving this equation, or have I viewed it in the wrong way?
 
Last edited:
on Phys.org
The "standard" alpha decay equation ##^{232}_{92}U \rightarrow^{230}_{90}X+\alpha## does not make sense. The number of nucleons on the right side is 230 in ##X## and 4 in the alpha particle for a total of 234. However, you start with 232 on the left side. Furthermore, the question says that you have ##^{238}_{92}U##.

You are correct in saying that the ##mc^2## terms will cancel. If I were you, I would calculate the total binding energy on each side and get ##Q## that way. You are given 6.1 MeV/nucleon that you can use for ##^{238}_{92}U## and ##^{234}_{90}X## and you can look up the binding energy of ##^{4}_{2}He##. I think you will get the same answer because the daughter nuclide has the same binding energy as the parent.
 
Ok so I have made some typos in my workings, which I will correct, sorry for that. I will also redo more working in a more clearer manner.

Question:

During the ##\alpha## decay of ##^{238}_{92}U## an ##\alpha## particle is fromed inside the nucleus. Given that the last 4 nucleons in ##^{238}_{92}U## have an average binding energy per nucleon of ##6.1MeV##, estimate the kinetic energy of the ##\alpha## particle when it is formed.

My new working are as follows:
$$^{238}_{92}U\rightarrow^{234}_{90}X+\alpha_2$$

My view is that the LHS can be broken down like so:

$$^{234}_{90}X+\alpha_1\rightarrow^{234}_{90}X+\alpha_2 + Q$$

Because I have the binding energy of the last 4 nucleons, which I have designated ##alpha_1##, so that leaves the binding energy of the remaining 234 nucleons within that nucleus.

As I am looking for the Q value of the alpha particle I will start with the summation equation for Q

$$Q=\sum _{intial}mc^2-\sum _{final}mc^2$$

I then calculated the mass energy for each individual part for LHS and RHS

$$m(^{234}_{90}X)c^2=90m_p+144m_n)c^2-B.E_x$$
This would be for RHS also

$$m(^4_2\alpha)c^2=2n+2p-(4*6.1MeV)$$

RHS
$$m(^4_2\alpha)c^2=2n+2p-B.E_{\alpha}$$

So subbing into the Q equation that I have given I will have the follwoing

$$Q=B.E_{\alpha}-(4*6.1Mev)$$

Using the calculated value of ##B.E_{alpha}=28.1MeV##

I make the Q value ##Q=3.7MeV##

I have edited the original question also.