A straight wire of mass \(200~\text{g}\) and length \(1.5~\text{m}\) carries a current of \(2~\text{A}\). It is suspended in mid-air by a uniform horizontal magnetic field \(B\) (shown in the figure). What is the magnitude of the magnetic field?
1. | \(0.65~\text{T}\) | 2. | \(0.77~\text{T}\) |
3. | \(0.44~\text{T}\) | 4. | \(0.20~\text{T}\) |
In a region of space, magnetic field is parallel to the positive \(y\text-\)axis and the charged particle is moving along the positive \(x\text-\)axis (as shown in the figure). The directions of Lorentz force for an electron (negative charge) and proton (positive charge) are respectively:
1. | \(-z\text-\)axis, \(+z\text-\)axis | 2. | \(+z\text-\)axis, \(-z\text-\)axis |
3. | \(-z\text-\)axis, \(-z\text-\)axis | 4. | \(+z\text-\)axis, \(+z\text-\)axis |
The radius of the path of an electron and frequency (mass and charge ) moving at a speed of \(3\times10^7\) m/s in a magnetic field of \(6\times10^{-4}\) T perpendicular to it are respectively:
1. \(24\) cm, \(4\) MHz
2. \(22\) cm, \(4\) MHz
3. \(28\) cm, \(2\) MHz
4. \(26\) cm, \(2\) MHz
An electron is moving at a speed of 3 ×107 m/s in a magnetic field perpendicular to it. The energy of the electron in keV is: ( 1 eV = 1.6 × 10–19 J)
1. 2.5 keV
2. 3.5 keV
3. 20 keV
4. 3.0 keV