Ok thats easy.Under the influence of an adequately strong magnetic field, the salt solution will have a slower rate of flow than the tap water
The hypothesis that salt solution has a lower flow rate than tap waterunder the influence of a magnetic field is proven to be true.
One of the demonstrations and possible applications of diamagnetism is in levitation. Diamagnetic materials can be levitated in a strong magnetic field when a state of equilibrium is achieved. The levitation of diamagnetic materials has been demonstrated in laboratories using pyrolytic graphite, water and even a live frog.
Tell me "Why" is it so..!!
Please
some one
Magnetic fields can be created by charges or the flow of current.
A resistor inhibits the flow of electricity by varying degrees, depending on value.Total inhibition is provided by an insulator.Resistance or Impediance (magnetic fields), or a combination of both impede electrical flow.
One way to produce an electric field is through the presence of charged particles. When charged particles, such as electrons or protons, are stationary or in motion, they generate an electric field around them. Another way to produce an electric field is through changing magnetic fields. According to Faraday's law of electromagnetic induction, a changing magnetic field induces an electric field, causing the flow of electric charges.
One of them is how many coils go around the electromagnet. also the amout of current flow< and the type of core material.
The correct spelling is electrodynamics. Electrodynamics is a branch of mechanics. It is the study that is concerned with the moving electric charges and the interactions with magnetic fields.
Does current affect electromagnetism? No. Does current affect magnetic fields? Yes. The laws (Maxwell's Equations) pertaining to electromagnetism is constant and will not change regardless of current applied. However, Maxwell's equations does dictate that a change in current will essentially result in a change in magnetic fields. Current flow will produce a magnetic field perpendicular to the current direction.
No. Current flow creates electromagnetic fields in space. Electromagnetic fields, in turn, can create current flow in conductors. The electric fields do not directly create magnetic fields, nor do magnetic fields directly create electric fields.
Magnetic fields can be created by charges or the flow of current.
Electrical flow creates magnetic fields around the wires. The distance helps prevent interruptions and problems in the flow.
I think it is a mistake to refer to magnetic field 'flowing. Magnetic fields just are, they can change, and these disturbances might move in space, but the field itself does not flow. That being said, and assuming you meant to ask in which direction a magnetic field points the answer is that a magnetic field points towards the south pole of a magnet and away from the north pole. A magnetic field cannot be divergent (i.e. there are no sources) and any field line must be closed.
A resistor inhibits the flow of electricity by varying degrees, depending on value.Total inhibition is provided by an insulator.Resistance or Impediance (magnetic fields), or a combination of both impede electrical flow.
no
Electricity is created by a rotating magnetic field captured by a coil. The flow of electrons creates a magnetic field.
They will combine to make a single magnetic field.
D. Wetstone has written: 'Experiments on supersonic plasma flow along magnetic fields. II'
The flow of electricity, which is a current of electrons, or simply electron flow, creates a magnetic field around its path of travel. This is a fundamental property of charged particles. Magnetic fields are always present in the vicinity of moving charges, and moving charges always create magnetic fields. One of the four fundamental forces we know in nature is the electromagnetic force. And this is probably one of the best examples of the inseparability of current flow and a magnetic field.
In an AC circuit it is the fluctuation of the sine wave which causes a varying magnetic field which in turn induces a current to flow in the secondary.