Figure. shows three rigions of magnetic field each of area `A`, and in each rigion, magnitude of mqagnetic field decreases rate `alpha`. If `vec(E)` is the induced electric field, then the vlue of the line `ointvec(E).dvec(r )` along the given loop is equal to

Figure shows a circular region of radius R in which uniform magnetic field B exists. The magnetic field is increasing at a rate (dB)/(dt) . The induced electric field at a distance r from the centre for r lt R is

Figure shows electric lines of force. If E_(x) and E_(y) are the magnitudes of electric field at points x and y respectively, then

Assertion : An emf vec(E) is induced in a closed loop where magnetic flux is varied. The induced vec(E) is not a conservative field. Reason : The line intergral vec(E).vec(dl) around the closed loop is non-zero.

In fig, two particles, each of charge -q are arranged symmetrically about the y-axis, each producing an electric field at point P on the y-axis. . (a) Are the magnitudes of the fields at P equal? (b) Is each electric field directed towards or away form the charge producing it ? (c ) Is the magnitude of the net electric field at P equal to the sum of the magnitudes E of the two field vectors (is it equal to 2E)? (d) Do the x-components of those two field vectors add or cancel? (e ) Do their y-components add or cancel? (f) Is the diretion of the net field at P that of the canceling components or the adding components? (g) What is the direction of the net field?

Figure shows five lettered regions in which a uniform magnetic field extends directly either out of the page (as in region a ) or into he page. The field is increasing in magnitude at the same steady rate in all five regions, the regions are identical in area. Also shows are four numbered paths along which oint vec(E). vec(dl) has the magnitudes given below in terms of a quantity mag. Determine whether the magnetic fields in regions b through e are directed into ot out of the page. ? |{:("Path",1,2,3,4),(oint vec(E).vec(dl),mag,2(mag),3(mag),0):}|

Figure shows the path of an electron in a region of uniform magnetic field. The path consists of two straight sections, each between a pair of uniformly charged plates and two half circles. The electric field exists only between the plates

A: The electric field induced due to changing magnetic field is non-conservative, R: The line integral of the electric field induced due to changing magnetic field along a closed loop is always zero.

A time varying magnetic field B = Kr^(3)t is existing in a cylindrical region of radius 'R' as shown (where k is a constant). The induced electric field 'E' at r (R )/(2) is

Statement I: no electric current will be present within a region having uniform and constant magetic field. Statement II: Within a region of unifrom and cinstant magnetic field vec(B) , the path integral of magnetic field oint vec(B).dvec(l) along any closed path is zero. Hence, from Ampere cirauital law oint vec(B).dvec(l) = mu_(0)I (where the given terms ahve usual meaning), no current can be present within a region having uniform and constant magnetic field .

The figure shows electric field lines. If E_(A) and E_(B) are electric fields at A and B and distance AB is r, then