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PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365609 On increasing temperature, the conductivity of pure semiconductors

1 Decreases

2 Increases

3 Remains unchanged

4 Becomes zero

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365610 The relation between number of free electrons (\(n\)) in a semiconductor and temperature (\(T\)) is given by

1 \(n \propto T\)

2 \(n \propto {T^2}\)

3 \(n \propto \sqrt T \)

4 \(n \propto {T^{3/2}}\)

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365611 The value indicated by Fermi energy level in an intrinsic semiconductor is

1 The average energy of electrons and holes

2 The energy of electrons in conduction band

3 The energy of holes in valence band

4 The energy of forbidden region

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365612 A \(Ge\) specimen is doped with \(Al\). The concentration of acceptor atoms is \({10^{21}}\,atoms/{m^3}.\) Given that the intrinsic concentration of electron-hole pairs is \({10^{19}}/{m^3},\) the concentration of electrons in the specimen is

1 \({10^{17}}/{m^3}\)

2 \({10^{15}}/{m^3}\)

3 \({10^4}/{m^3}\)

4 \({10^2}/{m^3}\)

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365613 An intrinsic semiconductor has

1 Equal amounts of negative and positive charges

2 No minority charge carriers

3 No majority charge carriers

4 No free charges

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365609 On increasing temperature, the conductivity of pure semiconductors

1 Decreases

2 Increases

3 Remains unchanged

4 Becomes zero

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365610 The relation between number of free electrons (\(n\)) in a semiconductor and temperature (\(T\)) is given by

1 \(n \propto T\)

2 \(n \propto {T^2}\)

3 \(n \propto \sqrt T \)

4 \(n \propto {T^{3/2}}\)

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365611 The value indicated by Fermi energy level in an intrinsic semiconductor is

1 The average energy of electrons and holes

2 The energy of electrons in conduction band

3 The energy of holes in valence band

4 The energy of forbidden region

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365612 A \(Ge\) specimen is doped with \(Al\). The concentration of acceptor atoms is \({10^{21}}\,atoms/{m^3}.\) Given that the intrinsic concentration of electron-hole pairs is \({10^{19}}/{m^3},\) the concentration of electrons in the specimen is

1 \({10^{17}}/{m^3}\)

2 \({10^{15}}/{m^3}\)

3 \({10^4}/{m^3}\)

4 \({10^2}/{m^3}\)

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365613 An intrinsic semiconductor has

1 Equal amounts of negative and positive charges

2 No minority charge carriers

3 No majority charge carriers

4 No free charges

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365609 On increasing temperature, the conductivity of pure semiconductors

1 Decreases

2 Increases

3 Remains unchanged

4 Becomes zero

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365610 The relation between number of free electrons (\(n\)) in a semiconductor and temperature (\(T\)) is given by

1 \(n \propto T\)

2 \(n \propto {T^2}\)

3 \(n \propto \sqrt T \)

4 \(n \propto {T^{3/2}}\)

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365611 The value indicated by Fermi energy level in an intrinsic semiconductor is

1 The average energy of electrons and holes

2 The energy of electrons in conduction band

3 The energy of holes in valence band

4 The energy of forbidden region

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365612 A \(Ge\) specimen is doped with \(Al\). The concentration of acceptor atoms is \({10^{21}}\,atoms/{m^3}.\) Given that the intrinsic concentration of electron-hole pairs is \({10^{19}}/{m^3},\) the concentration of electrons in the specimen is

1 \({10^{17}}/{m^3}\)

2 \({10^{15}}/{m^3}\)

3 \({10^4}/{m^3}\)

4 \({10^2}/{m^3}\)

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365613 An intrinsic semiconductor has

1 Equal amounts of negative and positive charges

2 No minority charge carriers

3 No majority charge carriers

4 No free charges

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365609 On increasing temperature, the conductivity of pure semiconductors

1 Decreases

2 Increases

3 Remains unchanged

4 Becomes zero

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365610 The relation between number of free electrons (\(n\)) in a semiconductor and temperature (\(T\)) is given by

1 \(n \propto T\)

2 \(n \propto {T^2}\)

3 \(n \propto \sqrt T \)

4 \(n \propto {T^{3/2}}\)

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365611 The value indicated by Fermi energy level in an intrinsic semiconductor is

1 The average energy of electrons and holes

2 The energy of electrons in conduction band

3 The energy of holes in valence band

4 The energy of forbidden region

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365612 A \(Ge\) specimen is doped with \(Al\). The concentration of acceptor atoms is \({10^{21}}\,atoms/{m^3}.\) Given that the intrinsic concentration of electron-hole pairs is \({10^{19}}/{m^3},\) the concentration of electrons in the specimen is

1 \({10^{17}}/{m^3}\)

2 \({10^{15}}/{m^3}\)

3 \({10^4}/{m^3}\)

4 \({10^2}/{m^3}\)

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365613 An intrinsic semiconductor has

1 Equal amounts of negative and positive charges

2 No minority charge carriers

3 No majority charge carriers

4 No free charges

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365609 On increasing temperature, the conductivity of pure semiconductors

1 Decreases

2 Increases

3 Remains unchanged

4 Becomes zero

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365610 The relation between number of free electrons (\(n\)) in a semiconductor and temperature (\(T\)) is given by

1 \(n \propto T\)

2 \(n \propto {T^2}\)

3 \(n \propto \sqrt T \)

4 \(n \propto {T^{3/2}}\)

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365611 The value indicated by Fermi energy level in an intrinsic semiconductor is

1 The average energy of electrons and holes

2 The energy of electrons in conduction band

3 The energy of holes in valence band

4 The energy of forbidden region

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365612 A \(Ge\) specimen is doped with \(Al\). The concentration of acceptor atoms is \({10^{21}}\,atoms/{m^3}.\) Given that the intrinsic concentration of electron-hole pairs is \({10^{19}}/{m^3},\) the concentration of electrons in the specimen is

1 \({10^{17}}/{m^3}\)

2 \({10^{15}}/{m^3}\)

3 \({10^4}/{m^3}\)

4 \({10^2}/{m^3}\)

PHXII14:SEMICONDUCTOR ELECTRONICS- MATERIALS- DEVICES AND SIMPLE CIRCUITS

365613 An intrinsic semiconductor has

1 Equal amounts of negative and positive charges

2 No minority charge carriers

3 No majority charge carriers

4 No free charges

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Question Bank Series

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