The force between two charges is given by Coulomb's law: F = k * (q1 * q2) / r^2. If charges are doubled (2q1, 2q2) and distance is halved (r/2), the new force becomes F' = k * (4q1 * q2) / (r/2)^2 = 16F, thus 16\phi.

In a uniform electric field, the forces on the positive and negative charges of the dipole are equal and opposite, resulting in a net force of zero. Therefore, the correct answer is that the resultant force acting on it always be zero.

The torque (τ) on a dipole is given by τ = pE sin(θ). Here, p = qL, where q is the charge and L is the length. Rearranging gives q = τ/(EL sin(θ)). Substituting τ = 4 N-m, E = 2 x 10^5 N/C, L = 0.02 m, and θ = 30°, we find q = 2 mC.

Using Gauss's law, the electric flux \( \Phi_E = \frac{Q}{\epsilon_0} \). Here, \( Q = 10 \mu C = 10 \times 10^{-6} C \) and \( \epsilon_0 \approx 8.85 \times 10^{-12} \frac{C^2}{Nm^2} \). Calculating gives \( \Phi_E \approx 1.88 \times 10^5 \frac{Nm^2}{C} \), matching the correct choice.

To find the orbital period of charge q2, we use the centripetal force due to electrostatic attraction. The formula derived leads to the periodic time T = \sqrt{\frac{4\pi^2mr^3}{kq_1q_2}}, confirming the correct choice.

The electric field E due to a line charge is given by E = (k * λ) / r. Rearranging gives λ = (E * r) / k. Substituting E = 3 x 10^8 N/C, r = 0.02 m, and k = 9 x 10^9 SI, we find λ = 333 μC/m, which is the correct answer.

Object A has electric field lines pointing towards it, indicating it is negatively charged (-). Object B has lines pointing away, indicating it is positively charged (+). Thus, the correct answer is -, +.