Tag: electric current, potential difference and resistance

Conventionally, the current flows in the direction of flow of positive charge or opposite to the flow of negative charge (electrons).

Direction of current is taken as direction of flow of positive charge.
Opposite to the direction of flow of electrons.

Electrons are negatively charged particles. So, by convention, the direction of current is considered as the opposite to the direction of motion of electrons.

Answer is A.
When an electric field is applied across the metallic conductors the randomly moving electrons are subjected to electrical forces along the direction of the field. Due to this field, the electrons do not give up their randomness of motion, but they will be shifting towards higher potential. That means the electrons will drift towards higher potential along with their random motions. 
In semiconductors, in addition to electrons, the travelling vacancies in the valence-band electron population (called 'holes'), act as mobile positive charges and are treated as charge carriers. Electrons and holes are the charge carriers in semiconductors.
Hence, electric current is due to drift of electrons in metallic conductors.

In series connection same current will flow through each one of them.

Conventional Current assumes that current flows out of the positive terminal, through the circuit and into the negative terminal of the source. This was the convention chosen during the discovery of electricity.
Not from high electron density to low electron density.

By convention a positively charged body is always at a higher potential as compared to negatively charged body . If positive charges like protons or positive ions are free to move they would move from higher potential point to lower potential point.

Current through a resistance (R) is given by, $V=i*R _{eq}$
$i=150/30$
$i=5$ ampere