each of area A
Two plates, each of area A, are placed parallel to each other at a distance d. One plate is connected to a battery of emf E and its negative is earthed. The other plate is also earthed. The charge drawn by plate is.
08
Nov
Two plates, each of area A, are placed parallel to each other at a distance d. One plate is connected to a battery of emf E and its negative is earthed. The other plate is also earthed. The charge drawn by plate is. are placed parallel to each other at a distance d. One plate [...]
A battery (or batteries) connected to two parallel plates produces the equipotential lines between the plates as shown. Which of the following configurations is most likely to produce these equipotential lines?
08
Nov
A battery (or batteries) connected to two parallel plates produces the equipotential lines between the plates as shown. Which of the following configurations is most likely to produce these equipotential lines? are placed parallel to each other at a distance d. One plate is connected to a battery of emf E and its negative is [...]
Two identical conducting very large plates p1 and p2 having charges +4Q and +6Q are placed very closed to each other at seperation d. The plate area of either face of the plate is A . The potential difference between plates P1 and P2 is
08
Nov
Two identical conducting very large plates p1 and p2 having charges +4Q and +6Q are placed very closed to each other at seperation d. The plate area of either face of the plate is A . The potential difference between plates P1 and P2 is are placed parallel to each other at a distance d. [...]
Two plates, each of area A, are placed parallel to each other at a distance d. One plate is connected to a battery of emf E and its negative is earthed. The other plate is also earthed. The charge drawn by plate is
08
Nov
Two plates, each of area A, are placed parallel to each other at a distance d. One plate is connected to a battery of emf E and its negative is earthed. The other plate is also earthed. The charge drawn by plate is are placed parallel to each other at a distance d. One plate [...]
A charge Q1 is placed at O inside a hollow conducting sphere having inner and outer radii as 10 m and 11 m as shown. The force experienced by Q2 at P is F1 and Force experienced by Q2 when Q1 is placed at O1 is F2. Then F1/F2 is equal to
01
Nov
A charge Q1 is placed at O inside a hollow conducting sphere having inner and outer radii as 10 m and 11 m as shown. The force experienced by Q2 at P is F1 and Force experienced by Q2 when Q1 is placed at O1 is F2. Then F1/F2 is equal to are separated by [...]
A cavity of radius r is made inside a solid sphere. The volume charge density of the remaining sphere is ρ. An electron (charge e, mass m) is released inside the cavity from point P as shown in figure. The centre of sphere and centre of cavity are separated by a distance a. The time after which the electron again touches the sphere is
31
Oct
A cavity of radius r is made inside a solid sphere. The volume charge density of the remaining sphere is ρ. An electron (charge e, mass m) is released inside the cavity from point P as shown in figure. The centre of sphere and centre of cavity are separated by a distance a. The time [...]
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A cavity of radius r is made inside a solid sphere. The volume charge density of the remaining sphere is ρ. An electron (charge e ,
are separated by a distance d. Now ,
each of area A ,
the left plate is given a positive charge Q. A positive charge q of mass m is released from a point near the left plate. Find the time taken by the charge to reach the right plate. ,
Two parallel conducting plates ,
An infinite nonconducting sheet has surface charge density s. There is a small hole in the sheet as shown in the figure. A uniform rod of length l having linear charge density λ is hinged in the hole as shown. If the mass of the rod is m, then the time period of oscillation for small angular displacement is
31
Oct
An infinite nonconducting sheet has surface charge density s. There is a small hole in the sheet as shown in the figure. A uniform rod of length l having linear charge density λ is hinged in the hole as shown. If the mass of the rod is m, then the time period of oscillation for [...]
A charge Q is uniformly distributed in a dielectric sphere of radius R (having dielectric constant unity). This dielectric sphere is enclosed by a concentric spherical shell of radius 2R and having uniformly distributed charge 2Q. Which of the following graph correctly represents variation of electric field with distance r from the common centre?
31
Oct
A charge Q is uniformly distributed in a dielectric sphere of radius R (having dielectric constant unity). This dielectric sphere is enclosed by a concentric spherical shell of radius 2R and having uniformly distributed charge 2Q. Which of the following graph correctly represents variation of electric field with distance r from the common centre? are [...]
Two parallel conducting plates, each of area A, are separated by a distance d. Now, the left plate is given a positive charge Q. A positive charge q of mass m is released from a point near the left plate. Find the time taken by the charge to reach the right plate.
31
Oct
Two parallel conducting plates, each of area A, are separated by a distance d. Now, the left plate is given a positive charge Q. A positive charge q of mass m is released from a point near the left plate. Find the time taken by the charge to reach the right plate. are separated by [...]