NCERT Exemplar Solutions for CBSE Class 12 Physics, Chapter 1: Electric Charges and Fields (Part IV)
NCERT Exemplar Solutions for CBSE Class 12 Physics, Chapter 1: Electric Charges and Fields are available here. In this article, you will get solutions from question number 1.20 to question number 1.25. These are basically solutions of short answer type questions. Solutions of other questions are available in further parts.
NCERT Exemplar Solutions for Class 12 Physics, Chapter 1: Electric Charges and Fields are available here. Here, you will find solutions of short answer type questions of the chapter (i.e., from question number 1.20 to 1.25). These questions are important for CBSE Class 12 Physics board exam and other competitive exams like JEE Main, NEET etc.
NCERT Exemplar Solutions for Class 12 Physics, Chapter 1: Electric Charges and Fields (from from question no. 1.20 to 1.25 are given below:
Question 1.20: A paisa coin is made up of Al-Mg alloy and weighs 0.75g. It has a square shape and its diagonal measures 17 mm. It is electrically neutral and contains equal amounts of positive and negative charges.
Treating the paisa coins made up of only Al, find the magnitude of equal number of positive and negative charges. What conclusion do you draw from this magnitude?
Given, Mass of one paisa coin = 0.75 g
We know that atomic mass of aluminium = 26.9815 g
Now, Avogadro's number = 6.023 × 1023
26.9815 g of aluminium contains 6.023 × 1023 atoms of aluminium
Number of atoms in (0.75 g of aluminium or) one paisa coin = [0.75 × 6.023 × 1023]/26.9815 = 1.6742 × 1022
One Aluminum atom contains 13 protons or 13 electrons and magnitude of charge of one atom =
Now, magnitude of charge one paisa coin = (Number of atoms in one paisa coin) × Charge of one atom) = (1.6742 × 1022) × [13 × (1.6 × 10‒19)] = 34.8 kC.
From this one can easily understand that ordinary atom has large amount of charge.
Question 1.21: Consider a coin of Example 1.20. It is electrically neutral and contains equal amounts of positive and negative charge of magnitude 34.8 kC. Suppose that these equal charges were concentrated in two point charges separated by
(i) 1 cm [ ̴ (1/2) × diagonal of the one paisa coin].
(ii) 100 m ( ̴ length of a long building), and
(iii) 106 m (radius of the earth).
Find the force on each such point charge in each of the three cases. What do you conclude from these results?
Suppose, q be the magnitude of the charge and r1, r2 and r3 be the distances in first, second and third case respectively.
According to the question,
q = ± 34.8 RC =± 3.48 × 104 C
r1 = 1 cm = 10‒2 m
r2 = 100 m
r3 = 106 m
Suppose, F1, F2 and F3 are forces in first, second and third case respectively, then by using
|F| = q2/(4πεor2)
We have, F1 = 1.09 × 1023 N
F2 = 1.09 × 1015 N
F3 = 1.09 × 107 N
Conclusion: When separated as point charges these charges exert an enormous force. It is not easy to disturb electrical neutrality.
Question 1.22: Fig. 1.10 represents a crystal unit of cesium chloride, CsCl. The cesium atoms, represented by open circles are situated at the corners of a cube of side 0.40 nm, whereas a Cl atom is situated at the centre of the cube. The Cs atoms are deficient in one electron while the Cl atom carries an excess electron.
(i) What is the net electric field on the Cl atom due to eight Cs atoms?
(ii) Suppose that the Cs atom at the corner A is missing. What is the net force now on the Cl atom due to seven remaining Cs atoms?
(i) From the given figure, we can observe that Cl‒ atom is at the centre whereas Cs+ atoms are at eight corners at equal distance. So, by symmetry net force on Cl‒ atom due to other Cs+ atoms is zero. Due to which, net electric field due to other Cs+ atoms is also zero (as, |E| = F/q)
(ii) In the given question, removing Cs atom at the corner A is equivalent to adding a singly charged negative Cs ion at point A.
Net force = q2/(4πεor2)
Here, q = charge on electron, r = distance between Cl and Cs atoms
Applying Pythagoras theorem, we have
The direction of force is from A to Cl‒
Question 1.23: Two charges q and –3q are placed fixed on x-axis separated by distance‘d’. Where a third charge 2 q should be placed such that it will not experience any force?
The situation given in question is shown in the figure given below:
Question 1.24: Fig. 1.11 shows the electric field lines around three point charges A, B and C.
(a) Which charges are positive?
(b) Which charge has the largest magnitude? Why?
(c) In which region or regions of the picture could the electric field be zero? Justify your answer.
(i) near A, (ii) near B, (iii) near C, (iv) nowhere.
(a) Charges A and C are positive since lines of force emanate from them.
(b) Charge C has the largest magnitude since maximum numbers of field lines are associated with it.
(c) (1) near A. There is no neutral point between a positive and a negative charge. A neutral point may exist between two like charges. From the figure we see that a neutral point exists between charges A and C. Also between two like charges the neutral point is closer to the charge with smaller magnitude. Thus, electric field is zero near charge A.
Question 1.25: Five charges, q each are placed at the corners of a regular pentagon of side ‘a’ (Fig. 1.12).
(a) (i) What will be the electric field at O, the centre of the pentagon?
(ii) What will be the electric field at O if the charge from one of the corners (say A) is removed?
(iii) What will be the electric field at O if the charge q at A is replaced by –q?
(b) How would your answer to (a) be affected if pentagon is replaced by n-sided regular polygon with charge q at each of its corners?