## NCERT Solutions for Class 12 Physics Chapter 14 Semiconductor Electronics Materials Devices And Simple Circuits â€“ FREE PDF Download

CoolGyan provides All Chapter 14 Semiconductor Electronics Materials Devices And Simple Circuits Exercise Questions with Solutions to help you to revise complete Syllabus and Score More marks.

**NCERT Solutions for Class 12 Physics Chapter 14 Semiconductor Electronics Materials Devices And Simple Circuits**Â includes all the important topics with detailed explanation that aims to help students to understand the concepts better. Students who are preparing for their Class 12 exams must go through NCERT Solutions forÂ **Class 12 Physics Chapter 14 Semiconductor Electronics Materials Devices And Simple Circuits**. Going through the solutions provided on this page will help you to know how to approach and solve the problems.

Revision Notes Class 12 Physics

NCERT Solutions Class 12 Physics

**Subtopics involved in class 12 physics chapter 14 Semiconductor ElectronicsÂ are:**

- Introduction
- Classification Of Metals, Conductors And Semiconductors
- Intrinsic Semiconductor
- Extrinsic Semiconductor
- P-n Junction
- p-n Junction formation

- Semiconductor Diode
- p-n junction diode under forward bias
- p-n junction diode under reverse bias

- Application Of Junction Diode As A Rectifier
- Special Purpose P-n Junction Diodes
- Zener diode
- Optoelectronic junction devices

- Junction Transistor
- Transistor: structure and action
- Basic transistor circuit configurations and transistor characteristics
- Transistor as a device
- Transistor as an Amplifier (CE-Configuration)
- Feedback amplifier and transistor oscillator

- Digital Electronics And Logic Gates
- Logic gates
- Integrated Circuits.

## Class 12 Physics NCERT Solutions Semiconductor Electronic: Material, Devices And Simple Circuits Questions

**NCERT Exercises**

**Question 1.**

in an n-type silicon, which of the following statement is true?

(a)Â Electrons are majority carriers and trivalent atoms are the dopants.

(b)Â Electrons are minority carriers and pentavalent atoms are the dopants.

(c)Â Holes are minority carriers and pentavalent atoms are the dopants.

(d)Â Holes are majority carriers and trivalent atoms are the dopants.

in an n-type silicon, which of the following statement is true?

(a)Â Electrons are majority carriers and trivalent atoms are the dopants.

(b)Â Electrons are minority carriers and pentavalent atoms are the dopants.

(c)Â Holes are minority carriers and pentavalent atoms are the dopants.

(d)Â Holes are majority carriers and trivalent atoms are the dopants.

**Solution:**

**(c)**Â For n-type silicon statementÂ

**(c)**Â is true.

**Question 2.**

Which of the statements given in previous question is true for p-type semiconductors?

Which of the statements given in previous question is true for p-type semiconductors?

**Solution:**

**(d)**Â For p-type semiconductors statementÂ

**(d)**Â is true.

**Question 3.**

Carbon, silicon and germanium have four valence electrons each.These are characterised by valence and conduction bands separated by energy band gap respectively equal to (E

Carbon, silicon and germanium have four valence electrons each.These are characterised by valence and conduction bands separated by energy band gap respectively equal to (E

_{g})_{câ€™}Â (E_{g})_{si}Â and (E_{g})_{Ge}. Which of the following statements is true?**Solution:**

**(c)**Â

**:**Â The energy band gap is largest for carbon, less for silicon and least for germanium. So, the correct statement isÂ

**(c)**.

(E

_{g})

_{c}Â > (E

_{g})

_{si}Â > (Eg)

_{Ge}

**Question 4.**

In an unbiased p-n junction, holes diffuse from the p-region to n-region because

(a)Â free electrons in the n-region attract them.

(b)Â they move across the junction by the potential difference.

(c)Â hole concentration in p-region is more as compared to n-region.

(d)Â all of the above.

In an unbiased p-n junction, holes diffuse from the p-region to n-region because

(a)Â free electrons in the n-region attract them.

(b)Â they move across the junction by the potential difference.

(c)Â hole concentration in p-region is more as compared to n-region.

(d)Â all of the above.

**Solution:**

**(c) :**Â In the unbiased p-n junction, holes diffuse from the p-region to n-region because holes concentration in the p-region is high as compared to n-region.

**Question 5. When a forward bias is applied to a p-n junction, it (a)Â raises the potential barrier. (b)Â reduces the majority carrier current to zero. (c)Â lowers the potential barrier. (d)Â none of the above **

**Solution:**

**(c) :**Â Under forward biasing the moveÂ¬ment of majority charge carriers across the junction reduces the width of depletion layer or lowers the potential barrier.

**Question 6.**

For transistor action, which of the following statements is/are correct:

(a)Â Base, emitter and collector regions should have similar size and doping concentrations.

(b)Â The base region must be very thin and lightly doped.

(c)Â The emitter junction is forward biased and collector junction is reverse biased.

(d)Â Both the emitter junction as well as the collector junction are forward biased.

For transistor action, which of the following statements is/are correct:

(a)Â Base, emitter and collector regions should have similar size and doping concentrations.

(b)Â The base region must be very thin and lightly doped.

(c)Â The emitter junction is forward biased and collector junction is reverse biased.

(d)Â Both the emitter junction as well as the collector junction are forward biased.

**Solution:**

**(b, c)Â**For a transistor circuit in action, statementsÂ

**(b)**Â andÂ

**(c)**Â are correct.

**Question 7.**

For a transistor amplifier, the voltage gain

(a)Â remains constant for all frequencies.

(b)Â is high at high and low frequencies and constant in the middle frequency range.

(c)Â is low at high and low frequencies and constant at mid frequencies.

(d)Â none of the above.

For a transistor amplifier, the voltage gain

(a)Â remains constant for all frequencies.

(b)Â is high at high and low frequencies and constant in the middle frequency range.

(c)Â is low at high and low frequencies and constant at mid frequencies.

(d)Â none of the above.

**Solution:**

**(c) :**Â The voltage gain in a transistor as amplifier is low at high and low frequencies and constant at mid frequencies.

**Question 8.**

In half-wave rectification, what is the output frequency if the input frequency is 50 Hz. What is the output frequency of a full-wave- rectifier for the same input frequency?

In half-wave rectification, what is the output frequency if the input frequency is 50 Hz. What is the output frequency of a full-wave- rectifier for the same input frequency?

**Solution:**

In half wave rectification, only one ripple is obtained per cycle in the output.

Output frequency of a half wave rectifier = input frequency = 50 Hz In full wave rectification, two ripples are obtained per cycle in the output.

Output frequency = 2 Ã— input frequency = 2 Ã— 50 = 100 Hz

**Question 9.**

For a CE-transistor amplifier, the audio signal voltage across the collector resistance of 2 kÎ© is 2 V. Suppose the current amplification factor of the transistor is 100, find the input signal voltage and base current, if the base resistance is 1 kâ„¦

For a CE-transistor amplifier, the audio signal voltage across the collector resistance of 2 kÎ© is 2 V. Suppose the current amplification factor of the transistor is 100, find the input signal voltage and base current, if the base resistance is 1 kâ„¦

**Solution:**

**Question 10.**

Two amplifiers are connected one after the other in series (cascaded). The first amplifier has a voltage gain of 10 and the second has a voltage gain of 20. If the input signal is 0. 01 volt, calculate the output ac signal.

Two amplifiers are connected one after the other in series (cascaded). The first amplifier has a voltage gain of 10 and the second has a voltage gain of 20. If the input signal is 0. 01 volt, calculate the output ac signal.

**Solution:**

Total voltage gain can be calculated as

**Question 11.**

A p-n photo diode is fabricated from a semiconductor with band gap of 2.8 eV. Can it detect a wavelength of 6000 nm?

A p-n photo diode is fabricated from a semiconductor with band gap of 2.8 eV. Can it detect a wavelength of 6000 nm?

**Solution:**

Energy of the incident photon with a band gap of 6000 nm.

The photo diode need an energy of 2.8 eV to give response to incident light. As E < E

_{g}, the given photo diode cannot detect the radiation of wavelength 6000 nm.

**Question 12.**

The number of silicon atoms per m

The number of silicon atoms per m

^{3}Â is 5 Ã— 10^{28}. This is doped simultaneously with 5 Ã— 10^{22}Â atoms per m^{3}Â of Arsenic and 5 Ã— 10^{20}Â per m^{3}Â atoms of Indium. Calculate the number of electrons and holes. Given that n, = 1.5 Ã— 10^{16}Â m^{3}. Is the material n-type or p-type?**Solution:**

We know that for each atom doped of Arsenic, one free electron is received. Similarly, for each atom doped of indium, a vacancy is created. So, the number of free electrons introduced by pentavalent impurity added n

_{e}Â = N

_{As}Â = 5 Ã— 10

^{22}Â m

^{-3}

The number of holes introduced by trivalent impurity added

**Question 13.**

In an intrinsic semiconductor the energy gap E

In an intrinsic semiconductor the energy gap E

_{g}Â is 1.2 eV. Its hole mobility is much smaller than electron mobility and independent of temperature. What is the ratio between conductivity at 600 K and that at 300 K? Assume that the temperature dependence of intrinsic carrier concentration n, is given by**Solution:**

Conductivity is given by Ïƒ = e (n

_{e}Â Î¼

_{e}Â +n

_{h}Â Î¼

_{h}) For intrinsic semiconductor n

_{e}Â = n

_{h}Â = n

_{i}Â Also mobility of holes (p,,) Â« mobility of electrons (pj So, conductivity a = enepe â€ž Temperature dependence of intrinsic carrier concentration

Conductivity increases rapidly with the rise of temperature.

**Question 14.**

In a p-n junction diode, the current I can be

is called the reverse saturation current, V is the voltage across the diode and is positive for forward bias and negative for reverse bias, and I is the current through the diode, kB is the Boltzmann constant (8.6 Ã— 10

(a)Â What will be the forward current at a forward voltage of 0.6 V?

(b)Â What will be the increase in the current if the voltage across the diode is increased to 0.7 V?

(c)Â What is the dynamic resistance?

(d)Â What will be the current if reverse bias voltage changes from 1 V to 2 V?

In a p-n junction diode, the current I can be

is called the reverse saturation current, V is the voltage across the diode and is positive for forward bias and negative for reverse bias, and I is the current through the diode, kB is the Boltzmann constant (8.6 Ã— 10

^{-5}Â eV/K) and T is the absolute temperature. If for a given diode I_{0}Â = 5 Ã— 10^{-12}Â A and T= 300 K, then(a)Â What will be the forward current at a forward voltage of 0.6 V?

(b)Â What will be the increase in the current if the voltage across the diode is increased to 0.7 V?

(c)Â What is the dynamic resistance?

(d)Â What will be the current if reverse bias voltage changes from 1 V to 2 V?

**Solution:**

The current I through a junction diode is given as

**(a)**Â When V = 0.6 V

**(b)**Â When V = 0.7 V,

**(c)**

**(d)**Â For both the voltages, the current I will be almost equal to I

_{0,}Â showing almost infinite dynamic resistance in the reverse bias. I=-I

_{0}= â€“ 5 Ã— 10

^{-12}Â A.

**Question 15.**

YOU are given the two circuits as shown in figure. Show that circuit (a) acts as OR gate while the circuit (b) acts as AND gate.

YOU are given the two circuits as shown in figure. Show that circuit (a) acts as OR gate while the circuit (b) acts as AND gate.

**Solution:**

Let us first find the Boolean expression for logic circuit (a)

By De-Morganâ€™s theorem we know

so, above logic circuit provides output as AND gate

**Question 16.**

Write the truth table for a NAND gate connected as given in following figure.

Hence identify the exact logic operation carried out by this circuit.

Write the truth table for a NAND gate connected as given in following figure.

Hence identify the exact logic operation carried out by this circuit.

**Solution:**

The Boolean expression for NAND gate will be

**Question 17.**

You are given two circuits as shown in figure which consist of NAND gates. Identify the logic operation carried out by the two circuits.

You are given two circuits as shown in figure which consist of NAND gates. Identify the logic operation carried out by the two circuits.

**Solution:**

**(a)**Â Let us find Boolean expression for given logic circuit

**(b)**Â By De-Morganâ€™s theorem

so, the given logic circuit acts as OR gate.

**Question 18.**

Write the truth table for circuit given in figure below consisting of NOR gates and identify the logic operation (OR, AND, NOT) which this circuit is performing.

(Hint: A â€“ 0, B = 1 then A and B inputs of second NOR gate will be 0 and hence Y = 1. Similarly work out the values of Yfor other combinations of A and B. Compare with the truth table of OR, AND, NOT gates and find the correct one.)

Write the truth table for circuit given in figure below consisting of NOR gates and identify the logic operation (OR, AND, NOT) which this circuit is performing.

(Hint: A â€“ 0, B = 1 then A and B inputs of second NOR gate will be 0 and hence Y = 1. Similarly work out the values of Yfor other combinations of A and B. Compare with the truth table of OR, AND, NOT gates and find the correct one.)

**Solution:**

Let us find the Boolean expression for the logic circuit.

Hence, the output of given logic circuit shows that logic circuit act as OR gate. Truth Table

**Question 19.**

Write the truth table for the circuits given in figure consisting of NOR gates only. Identify the logic operations (OR, AND, NOT) performed by the two circuits.

Write the truth table for the circuits given in figure consisting of NOR gates only. Identify the logic operations (OR, AND, NOT) performed by the two circuits.

**Solution:**

Boolean expression for logic circuit (a)

Here the given NOR gate with short circuit input is acting as NOT gate. Its truth table is

Boolean expression for logic circuit (b)

Hence, the logic circuit acts like AND gate. Its truth table is