Vector.
A magnetic field is neither: it is a vector field with both direction and quantity.
When one refers to the strength of a magnetic field, they're usually referring to the scalar magnitude of the magnetic field vector, so no.
Charge is not a vector.
No,because electric field (force/charge) is a vector quantity, i.e. , it has both magnitude as well as direction.
Magnetism is a force. Vector notation is required to indicate magnitude and direction of a force.
A magnetic field is neither: it is a vector field with both direction and quantity.
When one refers to the strength of a magnetic field, they're usually referring to the scalar magnitude of the magnetic field vector, so no.
Money is a scalar quantity because it can be used in any field[no particular direction]
Charge is not a vector.
I think light could not be recoginzed as a vector. However, I think the light intensity could be devided into the x-y axises.
No,because electric field (force/charge) is a vector quantity, i.e. , it has both magnitude as well as direction.
A quantity that has both magnitude and direction often has an arrow drawn over the unit of measurement. This is known as a vector quantity, as opposed to a scalar quantity which has no direction.
Magnetic field induction at a point is defined as the FORCE experienced by a unit north pole placed at that point. Since force is a vector quantity, manetic field induction also becomes a vector quantitiy.
Both, E=Es + Ev = cB therefore, B= Es/c + Ev/c = Bs + Bv. The electric and magnetic fields are quaternion fields consisting of a scalar field and a vector field. Contemporary Physics has not realized this yet. Correct Relativity Theory is a manifestation of quaternion fields, consisting of a scalar field and three vector fields. This shows up in the Energy Momentum four vector, E= Es +cmV. Actually the Lorentz Force is both scalar and vector: F=qvB = - qv.B + qvxB it makes no sense consider only qvxB and to ignore qv.B.
The strength of the electric field is a scalar quantity. But it's the magnitude of thecomplete electric field vector.At any point in space, the electric field vector is the strength of the force, and thedirection in which it points, that would be felt by a tiny positive charge located there.
Magnetism is a force. Vector notation is required to indicate magnitude and direction of a force.
Magnetism is a force. Vector notation is required to indicate magnitude and direction of a force.