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What happens when two wires with parallel current are placed in close proximity to each other?
When two wires with parallel currents are placed close to each other, they can create a magnetic field that interacts with each other. This interaction can cause the wires to either attract or repel each other, depending on the direction of the currents. This phenomenon is known as the Ampre's force law.
What is the Ampere force law and how does it relate to the interaction between electric currents?
The Ampere force law states that two parallel electric currents attract or repel each other depending on the direction of the currents. This law helps explain how electric currents interact with each other, either attracting or repelling based on their directions.
When electric currents flow in the same direction through two wires the wires attract each other why?
When electric currents flow through wires, they create magnetic fields around them. If the currents flow in the same direction, the magnetic fields produced by the wires will interact with each other, resulting in an attractive force between the wires. This phenomenon is known as the Ampère's force law.
Why opposite poles attract each other?
You would have to study Quantum Electrodynamics to understand that. Also given that magnetism is what happens when you apply relativity to electric fields, you would have to understand relativity. That beings said, the attraction has its roots in the fact that in electrostatics "like charges repel and unlike charges attract" The same ends up holding true for positive and negative magnetic poles. It is also related to the fact that when you have two parallel conductors and their currents are in the same direction, they attract, when the currents are in the opposite direction, they repel. When looking at magnetic field lines think of them as elastic bands wanting to shrink. In the related links is a page that discusses it.
How can you use the field lines to determine whether magnets will attract or repel each other?
You can use the direction of the magnetic field lines to determine if magnets will attract or repel each other. If the field lines are pointing in the same direction between two magnets, they will repel each other. If the field lines are pointing in opposite directions, the magnets will attract each other.
What happens when two wires with parallel current are placed in close proximity to each other?
When two wires with parallel currents are placed close to each other, they can create a magnetic field that interacts with each other. This interaction can cause the wires to either attract or repel each other, depending on the direction of the currents. This phenomenon is known as the Ampre's force law.
What is the Ampere force law and how does it relate to the interaction between electric currents?
The Ampere force law states that two parallel electric currents attract or repel each other depending on the direction of the currents. This law helps explain how electric currents interact with each other, either attracting or repelling based on their directions.
When electric currents flow in the same direction through two wires the wires attract each other why?
When electric currents flow through wires, they create magnetic fields around them. If the currents flow in the same direction, the magnetic fields produced by the wires will interact with each other, resulting in an attractive force between the wires. This phenomenon is known as the Ampère's force law.
Why opposite poles attract each other?
You would have to study Quantum Electrodynamics to understand that. Also given that magnetism is what happens when you apply relativity to electric fields, you would have to understand relativity. That beings said, the attraction has its roots in the fact that in electrostatics "like charges repel and unlike charges attract" The same ends up holding true for positive and negative magnetic poles. It is also related to the fact that when you have two parallel conductors and their currents are in the same direction, they attract, when the currents are in the opposite direction, they repel. When looking at magnetic field lines think of them as elastic bands wanting to shrink. In the related links is a page that discusses it.
What happens when you put a north and south pole to each other?
they attract
How can you use the field lines to determine whether magnets will attract or repel each other?
You can use the direction of the magnetic field lines to determine if magnets will attract or repel each other. If the field lines are pointing in the same direction between two magnets, they will repel each other. If the field lines are pointing in opposite directions, the magnets will attract each other.
Why do ships collide with each other?
There are hundreds of reasons, it be caused by currents, bad direction, strong wind.
What happens when you bring a positive and a neagative charge close to each other?
they would attract to each other
What happens to an object with a positive charge and an object with a negative chrage?
They attract each other.
What happens when you move unlike magnetic poles closer together?
They will attract each other.
What happens if magnetic forces come in contact with each other?
When magnetic forces come in contact with each other, they can either attract or repel each other depending on the orientation of the magnetic fields. If the magnetic fields are aligned in the same direction, they will attract each other, while if they are aligned in opposite directions, they will repel each other. The strength of the attraction or repulsion depends on the distance between the magnets and the strength of the magnetic fields.
Do all currents have the same characteristics?
No, not all currents have the same characteristics. There are different types of currents, such as direct current (DC) and alternating current (AC), which have distinct properties. DC flows in one direction continuously, while AC changes direction periodically. Additionally, the amplitude, frequency, and phase of currents can vary depending on the specific application and source.
