Describe briefly with the help of a circuit diagram, how the flow of current carries in a p-n-p transistor is regulated with emitter-base junction forward biased and base-collector junction reverse biased.
In the given block diagram of a receiver, identify the boxes labelled as X and Y and write their functions.
You are given three lenses L1, L2 and L3 each of focal length 20 cm. An object is kept at 40 cm in front of L1, as shown. The final real image is formed at the focus ‘I’ of L3. Find the separations between L1, L2 and L3.
Define the terms (i) ‘cut-off voltage’ and (ii) ‘threshold frequency’ in relation to the phenomenon of photoelectric effect.
Using Einstein’s photoelectric equation shows how the cut-off voltage and threshold frequency for a given photosensitive material can be determined with the help of a suitable plot/graph.Mention three ‘different modes of propagation used in communication system. Explain with the help of a diagram how long distance communication can be achieved by ionospheric reflection of radio waves.
Draw a plot of potential energy of a pair of nucleons as a function of their separations. Mark the regions where the nuclear force is (i) attractive and (ii) repulsive. Write any two characteristic features of nuclear forces.
In a Geiger–Marsden experiment, calculate the distance of closest approach to the nucleus of Z =80, when an a-particle of 8 MeV energy impinges on it before it comes momentarily to rest and reverses its direction.
How will the distance of closest approach be affected when the kinetic energy of the a-particle is doubled?
The ground state energy of hydrogen atom is – 13.6 eV. If an electron makes a transition from an energy level – 0.85 eV to –3.4 eV, calculate the wavelength of the spectral line emitted. To which series of hydrogen spectrum does this wavelength belong?
Using the formula,
For, n=1; E1 = - 13.6 eV
During the electron transmission, EA = - 0.85 eV to EB = -3.4 eV
So, from equation (i), we have
Therefore, electron transition takes place from n=4 to n=2 which corresponds to Balmer series.
We know,
Here,
nA = 4 ; nB = 2 ; R = 1.097 x 107 m-1
Then,
(a)
Write the expression for the force , acting on a charged particle of charge ‘q’, moving with a velocity in the presence of both electric field E and magnetic field B. Obtain the condition under which the particle moves un deflected through the fields.
(b)
A rectangular loop of size l × b carrying a steady current I is placed in a uniform magnetic field. Prove that the torque acting on the loop is given by is the magnetic moment of the loop.