Question: Which of the following is a vector quantity? This question has multiple correct options A. Elect...

Question

Which of the following is a vector quantity?
This question has multiple correct options
A. Electric potential
B. Electric field
C. Magnetic potential
D. Magnetic field

Answer 1

Solution

Hint: Normally potentials are used to make the calculations simpler. Since they are scalar quantities. Vector quantities make complex calculations.

Complete step by step answer:
The electric potential at a point in an electric field is defined as the amount of work done to bring a unit positive charge from infinity to the point. Electric potential is a scalar quantity and its unit is volt. Based on the definition, the potential at infinity is zero. The electric potential is a characteristic of the electric field, regardless of whether a charged object has been placed in that field. It is defined everywhere in the space as a value, without direction.
Electric field is a region of space around the charged object, where the charge influences experiences. Existence of an electric field is a property of its source charge. It has direction in the direction of force that acts on the positive test charge.
Magnetic potential consists of magnetic scalar potential and magnetic vector potential. With the help of magnetic potential concept, we can represent the magnetic field by using a potential instead of actual magnetic vector field. Magnetic fields can be written as the gradient of magnetic scalar potential. The curl of magnetic vector potential is the magnetic field. Work is actually associated with magnetic scalar potential.
Magnetic field is a form of representation of magnetic forces. It helps to visualize the strength and direction of the magnetic field. It is a vector field.
So electric fields and magnetic fields are vector quantities. Therefore, the option B and D are correct.

Note: In electrostatics, the electric field $E$ is derivable from the electric potential $V$ . So,
$\overrightarrow{E}=-\nabla V$
Here, $V$ is a scalar quantity and it is easier to handle than an electric field, which is a vector quantity.
In magnetostatics, magnetic scalar potential can be used to find the magnetic field.
$\overrightarrow{B}=-\nabla {{\varphi }_{m}}$
${{\varphi }_{m}}$ is the magnetic scalar potential.
Magnetic vector potential is a special case. Hence, we can use magnetic scalar potential for magnetic potential in the question.