358718 A square loop of conducting wire is placed near a long straight current carrying wire as shown.
Match the column I and column II
Column I
Column II
A
If the magnitude of current \(l\) is increased
P
Induced current in the loop will be clockwise
B
If the magnitude of current \(l\) is decreased
Q
Induced current in the loop will be anticlockwise
C
If current \(l\) remains constant
R
Induced current is zero

358719 An induced current of \({2 A}\) flows through a coil. The resistance of the coil is \(10\,\Omega \). What is the change in magnetic flux associated with the coil in 1 ms ?

358720 A loop, having a constant resistance, is placed in a uniform magnetic field that is varying with time at a rate of \({1 {~T} / {s}}\). The area of loop is \({1 {~m}^{2}}\) and it has a single turn. If at some time \({t}\), the current in the loop is \({1 A}\), the rate of change of current would be

358721 Assertion :
The magnetic flux through a loop of conducting wire of a fixed resistance \(R\) changes by \(\Delta \phi_{B}\) in a time \(\Delta t\). Then \(\Delta \phi_{B}\) is proportional to the current I through the loop.
Reason :
\(I=\dfrac{\Delta \phi_{B}}{R}\)

358718 A square loop of conducting wire is placed near a long straight current carrying wire as shown.
Match the column I and column II
Column I
Column II
A
If the magnitude of current \(l\) is increased
P
Induced current in the loop will be clockwise
B
If the magnitude of current \(l\) is decreased
Q
Induced current in the loop will be anticlockwise
C
If current \(l\) remains constant
R
Induced current is zero

358719 An induced current of \({2 A}\) flows through a coil. The resistance of the coil is \(10\,\Omega \). What is the change in magnetic flux associated with the coil in 1 ms ?

358720 A loop, having a constant resistance, is placed in a uniform magnetic field that is varying with time at a rate of \({1 {~T} / {s}}\). The area of loop is \({1 {~m}^{2}}\) and it has a single turn. If at some time \({t}\), the current in the loop is \({1 A}\), the rate of change of current would be

358721 Assertion :
The magnetic flux through a loop of conducting wire of a fixed resistance \(R\) changes by \(\Delta \phi_{B}\) in a time \(\Delta t\). Then \(\Delta \phi_{B}\) is proportional to the current I through the loop.
Reason :
\(I=\dfrac{\Delta \phi_{B}}{R}\)

358718 A square loop of conducting wire is placed near a long straight current carrying wire as shown.
Match the column I and column II
Column I
Column II
A
If the magnitude of current \(l\) is increased
P
Induced current in the loop will be clockwise
B
If the magnitude of current \(l\) is decreased
Q
Induced current in the loop will be anticlockwise
C
If current \(l\) remains constant
R
Induced current is zero

358719 An induced current of \({2 A}\) flows through a coil. The resistance of the coil is \(10\,\Omega \). What is the change in magnetic flux associated with the coil in 1 ms ?

358720 A loop, having a constant resistance, is placed in a uniform magnetic field that is varying with time at a rate of \({1 {~T} / {s}}\). The area of loop is \({1 {~m}^{2}}\) and it has a single turn. If at some time \({t}\), the current in the loop is \({1 A}\), the rate of change of current would be

358721 Assertion :
The magnetic flux through a loop of conducting wire of a fixed resistance \(R\) changes by \(\Delta \phi_{B}\) in a time \(\Delta t\). Then \(\Delta \phi_{B}\) is proportional to the current I through the loop.
Reason :
\(I=\dfrac{\Delta \phi_{B}}{R}\)

358718 A square loop of conducting wire is placed near a long straight current carrying wire as shown.
Match the column I and column II
Column I
Column II
A
If the magnitude of current \(l\) is increased
P
Induced current in the loop will be clockwise
B
If the magnitude of current \(l\) is decreased
Q
Induced current in the loop will be anticlockwise
C
If current \(l\) remains constant
R
Induced current is zero

358719 An induced current of \({2 A}\) flows through a coil. The resistance of the coil is \(10\,\Omega \). What is the change in magnetic flux associated with the coil in 1 ms ?

358720 A loop, having a constant resistance, is placed in a uniform magnetic field that is varying with time at a rate of \({1 {~T} / {s}}\). The area of loop is \({1 {~m}^{2}}\) and it has a single turn. If at some time \({t}\), the current in the loop is \({1 A}\), the rate of change of current would be

358721 Assertion :
The magnetic flux through a loop of conducting wire of a fixed resistance \(R\) changes by \(\Delta \phi_{B}\) in a time \(\Delta t\). Then \(\Delta \phi_{B}\) is proportional to the current I through the loop.
Reason :
\(I=\dfrac{\Delta \phi_{B}}{R}\)