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Physics-

General

Easy

Question

An electron moving with velocity V along the axis approaches a circular current carrying loop as shown in the figure. The magnitude of magnetic force on electron at this instant is

$\frac{μ_{0}}{2} \frac{e v i R^{2} x}{{(x^{2} + R^{2})}^{3 / 2}}$
$μ_{0} \frac{e v i R^{2} x}{{(x^{2} + R^{2})}^{3 / 2}}$
$\frac{μ_{0}}{4 π} \frac{e v i R^{2} x}{{(x^{2} + R^{2})}^{3 / 2}}$
0

The correct answer is: 0

$F equals q left square bracket v left parenthesis negative stack i with hat on top right parenthesis right square bracket cross times B left parenthesis stack i with hat on top right parenthesis right square bracket equals 0$
Because B as well as v is are along axis of circular loop.

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If the magnetic field at 'P' in the given figure can be written as K tan $open parentheses fraction numerator alpha over denominator 2 end fraction close parentheses$ then K is

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physics-General

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Consider two different metallic strips (1 and 2) of the same material. Their lengths are the same, widths are $w subscript 1 end subscript$ and $w subscript 2 end subscript$ and thicknesses are $d subscript 1 end subscript$ and $d subscript 2 end subscript$ , respectively. Two points K and M are symmetrically located on the opposite faces parallel to the x-y plane (see figure). $V subscript 1 end subscript$ and $V subscript 2 end subscript$ are the potential differences between K and M in strips 1 and 2 , respectively. Then, for a given current I flowing through them in a given magnetic field strength B, the correct statement(s) is (are).

In a thin rectangular metallic strip a constant current I flows along the positive x-direction, as shown in the figure. The length, width and thickness of the strip are l, w and d, respectively. A uniform magnetic field B $rho$ is applied on the strip along the positive y-direction. Due to this, the charge carries experience a net deflection along the z-direction. This results in accumulation of charge caries on the surface PQRS and appearance of equal and opposite charges on the face opposite to PQRS. A potential difference along the z-direction is thus developed. Charge accumulation continues until the magnetic force is balanced by the electric force. The current is assumed to be uniformly distributed on the cross section of the strip and carried by electrons.

Consider two different metallic strips (1 and 2) of the same material. Their lengths are the same, widths are $w subscript 1 end subscript$ and $w subscript 2 end subscript$ and thicknesses are $d subscript 1 end subscript$ and $d subscript 2 end subscript$ , respectively. Two points K and M are symmetrically located on the opposite faces parallel to the x-y plane (see figure). $V subscript 1 end subscript$ and $V subscript 2 end subscript$ are the potential differences between K and M in strips 1 and 2 , respectively. Then, for a given current I flowing through them in a given magnetic field strength B, the correct statement(s) is (are).

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A superconductor has $T subscript C end subscript$ (0) = 100 K. When a magnetic field of 7.5 Tesla is applied, its $T subscript C end subscript$ decreases to 75 K. For this material one can definitely say that when

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A superconductor has $T subscript C end subscript$ (0) = 100 K. When a magnetic field of 7.5 Tesla is applied, its $T subscript C end subscript$ decreases to 75 K. For this material one can definitely say that when

physics-General

parallel

In the graphs below, the resistance R of a superconductor is shown as a function of its temperature T for two different magnetic fields $B subscript 1 end subscript$ (sold line) and $B subscript 2 end subscript$ (dashed line). If $B subscript 2 s end subscript$ is larger than $B subscript 1 end subscript$ , which of the following graphs shows the correct variation of R with T in these fields? Electrical resistance of certain materials, known as superconductors, changes abruptly from a nonzero value to zero as their temperature is lowered below a critical temperature $T subscript C end subscript$ (0). An interesting property of superconductors is that their critical temperature becomes smaller than $T subscript C end subscript$ (0) if they are placed in a magnetic field, i.e., the critical temperature $T subscript C end subscript$ (B) is a function of the magnetic field strength B. The dependence of $T subscript C end subscript$ (B) on B is shown in the figure.

In the graphs below, the resistance R of a superconductor is shown as a function of its temperature T for two different magnetic fields $B subscript 1 end subscript$ (sold line) and $B subscript 2 end subscript$ (dashed line). If $B subscript 2 end subscript$ is larger than $B subscript 1 end subscript$ , which of the following graphs shows the correct variation of R with T in these fields?

In the graphs below, the resistance R of a superconductor is shown as a function of its temperature T for two different magnetic fields $B subscript 1 end subscript$ (sold line) and $B subscript 2 end subscript$ (dashed line). If $B subscript 2 s end subscript$ is larger than $B subscript 1 end subscript$ , which of the following graphs shows the correct variation of R with T in these fields? Electrical resistance of certain materials, known as superconductors, changes abruptly from a nonzero value to zero as their temperature is lowered below a critical temperature $T subscript C end subscript$ (0). An interesting property of superconductors is that their critical temperature becomes smaller than $T subscript C end subscript$ (0) if they are placed in a magnetic field, i.e., the critical temperature $T subscript C end subscript$ (B) is a function of the magnetic field strength B. The dependence of $T subscript C end subscript$ (B) on B is shown in the figure.

In the graphs below, the resistance R of a superconductor is shown as a function of its temperature T for two different magnetic fields $B subscript 1 end subscript$ (sold line) and $B subscript 2 end subscript$ (dashed line). If $B subscript 2 end subscript$ is larger than $B subscript 1 end subscript$ , which of the following graphs shows the correct variation of R with T in these fields?

physics-General

A thin flexible wire of length L is connected to two adjacent fixed points and carries a current I in the clockwise direction, as shown in the figure. When the system is put in a uniform magnetic field of strength B going into the plane of the paper, the wire takes the shape of a circle. The tension in the wire is :

A thin flexible wire of length L is connected to two adjacent fixed points and carries a current I in the clockwise direction, as shown in the figure. When the system is put in a uniform magnetic field of strength B going into the plane of the paper, the wire takes the shape of a circle. The tension in the wire is :

physics-General

A magnetic field $stack B with rightwards arrow on top equals B subscript 0 end subscript stack j with rightwards arrow on top$ exists in the region $a less than x less than 2 a$ and $stack B with rightwards arrow on top equals negative B subscript 0 end subscript stack j with bar on top$ in the region $2 a less than x less than 3 a$ , where $B subscript 0 end subscript$ is a positive constant. A positive point charge moving with a velocity $stack v with rightwards arrow on top equals v subscript 0 end subscript stack i with bar on top$ where $V subscript 0 end subscript$ is a positive constant, enters the magnetic field at x = a. The trajectory of the charge in this region can be like

A magnetic field $stack B with rightwards arrow on top equals B subscript 0 end subscript stack j with rightwards arrow on top$ exists in the region $a less than x less than 2 a$ and $stack B with rightwards arrow on top equals negative B subscript 0 end subscript stack j with bar on top$ in the region $2 a less than x less than 3 a$ , where $B subscript 0 end subscript$ is a positive constant. A positive point charge moving with a velocity $stack v with rightwards arrow on top equals v subscript 0 end subscript stack i with bar on top$ where $V subscript 0 end subscript$ is a positive constant, enters the magnetic field at x = a. The trajectory of the charge in this region can be like

physics-General

parallel

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