Solve

Guides

0

You visited us 0 times! Enjoying our articles? Unlock Full Access!

Question

In the study of Geiger-Marsdon experiment on scattering of $α$ -particles by a thin foil of gold, draw the trajectory of $α$ -particles in the coulomb field of target nucleus. Explain briefly how one gets the information on the size of the nucleus from this study.
From the relation $R = R_{0} A^{1 / 3}$ , where $R_{0}$ is constant and A is the mass number of the nucleus, show that nuclear matter density is independent of A.
OR
Distinguish between nuclear fission and fusion. Show how in both these processes energy is released.
Calculate the energy release in MeV in the deuterium-tritium fusion reaction:
$_{1}^{2} H +_{1}^{3} H ⟶_{2}^{4} H e + n$
Using the data:
$m (_{1}^{2} H) = 2.014102 u$
$m (_{1}^{3} H) = 3.016049 u$
$m (_{2}^{4} H e) = 4.002603 u$
$m_{n} = 1.008665 u$
$1 u = 931.5 M e V / c^{2}$

Open in App

Solution

Verified by Toppr

Consider an alpha particle with initial $K . E = \frac{1}{2} m v^{2}$ directed towards the center of nucleus of an atom.
The force that exists between nucleus and $α$ particle is coulomb's repulsive force. On account of this force, at the distance of closest approach $r_{0}$ , the particle stops and cannot go further closer to the nucleus. And K.E gets converted to P.E

That is,

$\frac{1}{2} m v^{2} = \frac{Z e (2 e)}{4 π ϵ_{0} r_{0}}$

$⟹$ $r_{0} = \frac{Z e (2 e)}{4 π ϵ_{0} (\frac{1}{2} m v^{2})}$

Hence, we can see that the size of the nucleus is approximately equal to the distance of the closest approach, $r_{0}$ .

Now,

If $^{'} m^{'}$ is the average mass of the nucleon and $^{'} r^{'}$ ,the radius of the nucleus, then

Mass of the nucleus $= m A$ ; where $A$ is the mass number of the element

Volume of the nucleus, $v = \frac{4}{3} π r^{3}$
This implies,

$v = \frac{4}{3} π (R_{0} A^{\frac{1}{3}})^{3}$

$⟹$ $v = \frac{4}{3} π R_{0}^{3} A$

$D e n s i t y$ $o f$ $n u c l e a r$ $matter= Mass of nucleus /Volume of nucleus

That is,

$ρ = \frac{m A}{\frac{4}{3} π R_{0}^{3} A}$

$⟹$ $ρ =$ $\frac{3 m}{4 π R_{0}^{3} A}$

Therefore, the nuclear density id independent of mass number A.

Was this answer helpful?

0

Similar Questions

Q1

In the study of Geiger-Marsdon experiment on scattering of

α

-particles by a thin foil of gold, draw the trajectory of

α

-particles in the coulomb field of target nucleus. Explain briefly how one gets the information on the size of the nucleus from this study.
From the relation

R = R_{0} A^{1 / 3}

, where

R_{0}

is constant and A is the mass number of the nucleus, show that nuclear matter density is independent of A.
OR
Distinguish between nuclear fission and fusion. Show how in both these processes energy is released.
Calculate the energy release in MeV in the deuterium-tritium fusion reaction:

_{1}^{2} H +_{1}^{3} H ⟶_{2}^{4} H e + n

Using the data:

m (_{1}^{2} H) = 2.014102 u

m (_{1}^{3} H) = 3.016049 u

m (_{2}^{4} H e) = 4.002603 u

m_{n} = 1.008665 u

1 u = 931.5 M e V / c^{2}

View Solution

Q2

In the study of Geiger-Marsdon experiment on scattering of

α - p a r t i c l e s

by a this foil of gold, draw the trajectory of

α - p a r t i c l e s

in the coulomb field of target nucleus. Explain briefly how one gets the information on the size of the nucleus from this study:
From the relation

R = R_{0} A^{1 / 3}

, where

R_{0}

is constant and A is the mass number of the nucleus, show that nuclear matter density is independently of A

View Solution

Q3

Distinguish between nuclear fission and fusion. Show how in both these processes energy is released. Calculate the energy release in MeV in the deuterium-tritium fusion reaction :

_{1}^{2} H +_{1}^{3} H \to_{1}^{4} H e +_{0} n^{1}

Using the data:

m (_{1}^{2} H) = 2.014102 u

m (_{1}^{3} H) = 3.016049 u

m (_{2}^{4} H e) = 4.002603 u

m n = 1.008665 u

l u = 931.5 M e V / c 2

View Solution

Q4

(a) In a typical nuclear reaction e.g

_{1}^{2} H +_{1}^{2} H \to_{2}^{3} H +_{0}^{1} n + 3.27 M e V

,
although number of nucleons is conserved, yet energy is released, How? Explain.
(b) Show that nuclear density in a given nucleus is independent of mass number A.

View Solution

Q5

From the relation R =

R_{0} A^{\frac{1}{3}}

, where

R_{0}

is a constant and A is the mass number of a nucleus, show that the nuclear matter density is nearly constant (i.e. independent of A).

View Solution