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Would you prefer a material with a high work-function or a low work-function to be used as a cathode in a diode?
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An isolated metal sphere is heated to a high temperature. Will it become positively charged due to thermionic emission?
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A diode value is connected to a battery and a load resistance. The filament is heated, so that a constant current is obtained in the circuit. As the cathode continuously emits electrons, does it become more and more positively charged?
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Why does thermionic emission not take place in non-conductors?
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The cathode of a diode valve is replaced by another cathode of double the surface area. Keeping the voltage and temperature conditions the same, will the place current decrease, increase or remain the same?
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Let i0 be the thermionic current from a metal surface when the absolute temperature of the surface is T0. The temperature is slowly increased and the thermionic current is measured as a function of temperature. Which of the following plots may represent the variation in (i/i0) against (T/T0)?
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The anode of a thermionic diode is connected to the negative terminal of a battery and the cathode to its positive terminal.
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The constant A in the Richardson−Dushman equation for tungsten is 60 × 104 A m−2K−2. The work function of tungsten is 4.5 eV. A tungsten cathode with a surface area 2.0 × 10−5 m2 is heated by a 24 W electric heater. In steady state, the heat radiated by the heater and the cathode equals the energy input by the heater and the temperature becomes constant. Assuming that the cathode radiates like a blackbody, calculate the saturation current due to thermions. Take Stefan's Constant = 6 × 10−8 W m−2 K−1. Assume that the thermions take only a small fraction of the heat supplied.
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Write the range of the wavelength of the following electromagnetic radiations:
(a) Infrared rays
(b) Ultraviolet rays
(c) γ -rays
Write one use of each of the above.
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Define the term "Threshold frequency", in the context of photoelectric emission.
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Define the term "Intensity" in the photon picture of electromagnetic radiation.
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Identify the part of the electromagnetic spectrum used in (i) radar and (ii) eye surgery. Write their frequency range.
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Define the term wavefront. Using Huygen’s wave theory, verify the law of reflection.
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Answer the following question.
Write the four important properties of the magnetic field lines due to a bar magnet.
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Answer the following question.
Three photodiodes D1, D2, and D3 are made of semiconductors having band gaps of 2.5 eV, 2 eV, and 3 eV respectively. Which of them will not be able to detect light of wavelength 600 nm?
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Answer the following question.
Define the term "Threshold frequency", in the context of photoelectric emission.
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Answer the following question.
How is the drift velocity in a conductor affected with the rise in temperature?
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Answer the following question.
A charged particle q is moving in the presence of a magnetic field B which is inclined to an angle 30° with the direction of the motion of the particle. Draw the trajectory followed by the particle in the presence of the field and explain how the particle describes this path.
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Answer the following question.
Explain briefly how Rutherford scattering of α-particle by a target nucleus can provide information on the size of the nucleus.
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Answer the following question.
Define the term wavefront. Using Huygen's wave theory, verify the law of reflection.
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