If a charge '\(q\)' moves with velocity \(v\), in a region where electric field (\(E\)) and magnetic field (\(B\)) both exist, then force on it is: 
1. \(q(\vec{v} \times \vec{B})\)

2. \(q \vec{E}+{q}(\vec{v} \times \vec{B})\)

3. \( q \vec{E}+q(\vec{B} \times \vec{v})\)

4. \(q\vec{B}+{q}(\vec{E} \times \vec{v})\)

A proton carrying 1 MeV kinetic energy is moving in a circular path of radius R in a uniform magnetic field. What should be the energy of an $\mathrm{\alpha }$-particle to describe a circle of the same radius in the same field?

1. 2 MeV                  2. 1 MeV

3. 0.5 MeV               4. 4 MeV

What is the magnitude of magnetic force per unit length on a wire carrying a current of \(8~\text{A}\) and making an angle of \(30^{\circ}\) with the direction of a uniform magnetic field of \(0.15~\text{T}?\)

A uniform electric field and a uniform magnetic field are acting in the same direction in a certain region. If an electron is projected in the region such that its velocity is pointed along the direction of fields, then the electron :

1. speed will decrease

2. speed will increase 

3. will turn towards the left of the direction of motion 

4. will turn towards right of direction a motion

Consider three quantities; \(x = E/B,\) \(y = \sqrt{1 / \mu_{0} \varepsilon_{0}},\) and \(z=\frac{ l }{ CR}.\) Here, \(l\) is the length of a wire, \(C\) is a capacitance and \(R\) is resistance. All other symbols have standard meanings. 

Choose the correct option from the given ones.