Advertisements
Advertisements
प्रश्न
Deuteron is a bound state of a neutron and a proton with a binding energy B = 2.2 MeV. A γ-ray of energy E is aimed at a deuteron nucleus to try to break it into a (neutron + proton) such that the n and p move in the direction of the incident γ-ray. If E = B, show that this cannot happen. Hence calculate how much bigger than B must E be for such a process to happen.
Advertisements
उत्तर
Given the binding energy of a deuteron, B = 2.2 MeV
Let kinetic energy and momentum of neutron and proton be Kn, KP and pn, pp respectively.
From the conservation of energy,
`E - B = K_n + K_p = p_n^2/(2m) + p_p^2/(2m)` ......(i)
Now applying conservation of momentum,
`p_n + p_p = E/C` ......(ii)
As E = B, equation (i) `p_n^2 + p_p^2` = 0
It only happens if pn = pp.
So, the equation. (ii) cannot be satisfied and the process cannot take place.
Let us take E = B + x, where x << B for the process to take place.
Putting the value of p, from equation (ii) in equation (i), we get
or `2p_p^2 - ((2E)/c)p_p + (E^2/c^2 - 2mx)` = 0
Solving the quadratic equation, we get
`p_p = (2E)/c + sqrt((4E^2)/c^2 - 8(E^2/c^2 - 2mx))/4`
For the real value pp the discriminant is positive
`(4E^2)/c^2 = 8(E^2/c^2 - 2mx)`
`16mx = (4E^2)/c^2`
⇒ `x = E^2/(4mc^2)`
But x << B, hence E ≅ B
⇒ `x ≈ B^2/(4mc^2)`
APPEARS IN
संबंधित प्रश्न
Two stable isotopes of lithium `""_3^6"Li"` and `""_3^7"Li"` have respective abundances of 7.5% and 92.5%. These isotopes have masses 6.01512 u and 7.01600 u, respectively. Find the atomic mass of lithium.
Obtain approximately the ratio of the nuclear radii of the gold isotope `""_97^197 "Au"` and the silver isotope `""_47^197"Ag"`.
Find the Q-value and the kinetic energy of the emitted α-particle in the α-decay of `""_88^226 "Ra"`.
Given `"m"(""_88^226"Ra")` = 226.02540 u, `"m"(""_86^222 "Rn")` = 222.01750 u,
`"m"(""_86^220 "Rn")`= 220.01137 u, `"m"(""_84^216 "Po")`= 216.00189 u.
Name a material which is used in making control rods in a nuclear reactor.
Two nuclei have mass numbers in the ratio 1: 2. What is the ratio of their nuclear densities?
The mass number of a nucleus is
Potassium-40 can decay in three modes. It can decay by β−-emission, B*-emission of electron capture. (a) Write the equations showing the end products. (b) Find the Q-values in each of the three cases. Atomic masses of `""_18^40Ar` , `""_19^40K` and `""_20^40Ca` are 39.9624 u, 39.9640 u and 39.9626 u respectively.
(Use Mass of proton mp = 1.007276 u, Mass of `""_1^1"H"` atom = 1.007825 u, Mass of neutron mn = 1.008665 u, Mass of electron = 0.0005486 u ≈ 511 keV/c2,1 u = 931 MeV/c2.)
What is a neutrino?
Atomic mass unit (u) is defined as ________ of the mass of the carbon (12C) atom.
Nuclear species or nuclides are shown by the notation ________ where X is the chemical symbol of the species.
\[\ce{^197_79Au}\] contains ______.
All nuclides with same mass number A are called ______.
The valance electrons in alkali metal is a:-
The mass number of a nucleus is equal to the number of:-
Are the nucleons fundamental particles, or do they consist of still smaller parts? One way to find out is to probe a nucleon just as Rutherford probed an atom. What should be the kinetic energy of an electron for it to be able to probe a nucleon? Assume the diameter of a nucleon to be approximately 10–15 m.
A nuclide 1 is said to be the mirror isobar of nuclide 2 if Z1 = N2 and Z2 = N1. (a) What nuclide is a mirror isobar of 1123 Na? (b) Which nuclide out of the two mirror isobars have greater binding energy and why?
Mass numbers of two nuclei are in the ratio of 4 : 3. Their nuclear densities will be in the ratio of ______.
Which of the following are the constituents of the nucleus?
1 amu is defined as:
