The charge on north pole is Positive (+ve) and south pole has a Negative (-ve) charge.
That is not correct. Electric field lines originate from positive charges and terminate on negative charges. In the case of a uniform electric field, the field lines run from the positive plate to the negative plate.
The third law of magnetism states that magnetic poles always come in pairs - a north pole and a south pole. This law is similar to the concept of electric charge in that opposite poles attract each other, while like poles repel.
A negative charge will repel a negative charge.
Polar molecules like water do have distinct positive and negative poles due to an uneven distribution of charge within the molecule. In the case of water, the oxygen atom has a partial negative charge, while each hydrogen atom has a partial positive charge, resulting in a polar molecule.
When like poles of magnets are placed near each other, they repel each other. This occurs because both poles have the same magnetic charge—either north or north, or south or south—causing a force that pushes them apart. This phenomenon is a fundamental principle of magnetism, illustrating that opposite poles attract while like poles repel.
no
yes
no
Opposite poles attract, like poles repel. (same with electric charge)
No, a magnet's poles do not have the same charge. One pole is a north pole and the other pole is a south pole, resulting in opposite charges.
Magnetic poles and electric charges both act the same as in:"opposites attract and same repel."Electric charge is the source of magnetic poles. The Magnetic pole is W=zq where z is the free space impedance 375 Ohms and q is the charge. W units is the Weber or volt-second.
both sides (poles) of a magnet have the same magnetic charge
That is not correct. Electric field lines originate from positive charges and terminate on negative charges. In the case of a uniform electric field, the field lines run from the positive plate to the negative plate.
The contrast between the two poles of a neuron is called polarization. Just like a battery has positive and negative poles that create an electrical potential difference, a neuron's polarization refers to the difference in electric charge between its dendrites and axon. This difference in charge allows for the transmission of electrical impulses along the neuron.
The third law of magnetism states that magnetic poles always come in pairs - a north pole and a south pole. This law is similar to the concept of electric charge in that opposite poles attract each other, while like poles repel.
A negative charge will repel a negative charge.
No, in a dipole moment the poles have opposite charges. One pole will be positive and the other pole will be negative. This creates a net dipole moment.