It has No magnetic interaction
Yes, magnetic field lines spread out from one pole and curve around to the other pole in a closed loop. This creates a continuous path for the magnetic field to flow from one pole to the other, forming a complete circuit.
When two magnets repel each other, the magnetic field lines will curve away from each other, showing a pattern of lines that do not intersect and point in opposite directions.
When two magnets attract each other, the magnetic field lines curve from one magnet to the other in a continuous loop, showing the path of the magnetic force between them.
All of the lines, in the field are uniformly spaced, because the fartherapartthe lines are, the weaker the field is, but if the field is the same all around, then the lines are also the same, all around the field.
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.
Yes, magnetic field lines spread out from one pole and curve around to the other pole in a closed loop. This creates a continuous path for the magnetic field to flow from one pole to the other, forming a complete circuit.
When two magnets repel each other, the magnetic field lines will curve away from each other, showing a pattern of lines that do not intersect and point in opposite directions.
When two magnets attract each other, the magnetic field lines curve from one magnet to the other in a continuous loop, showing the path of the magnetic force between them.
Yes. The field lines of a bar magnet emerge from one end, curve around, and stop at the other end. The field lines around a current-carrying wire are circles, with the wire passing through their centers.
Latitude lines are parallel straight lines that run east-west, while longitude lines are not parallel to each other and appear curved when projected onto a map. Longitude lines converge at the poles and are widest at the equator.
Magnetic field lines spread out from one pole, curve around the magnet, and return to the other pole.. . ah, they don't actually spread out from the poles, inside the magnet they are bunched together but they still form closed loops with the lines outside.
When two magnets are repelling each other, their magnetic fields interact in such a way that the field lines extend outward from the north pole of one magnet and do not enter the north pole of the other. Instead, the field lines curve around, indicating that the magnetic forces are pushing away from each other. This results in a pattern where the magnetic field lines are denser near the poles and sparse farther away, illustrating the repulsive interaction.
The patterns are made by the direction of travel of the lawnmower or roller. The dark lines are the machine moving toward you and the light lines by the machine moving in the other direction. This is caused by the light reflection on the grass.
There are three natural curves in the backbone. The cervical lordosis and the lumbar lordosis both curve toward the front of the body. The thoracic curve is toward the other direction.
If only one curves, then eventually the curve will intersect with the other line, even if it is way down into infinity ona graph. If both lines curve at the same angles at the same rate however, staying equidistant from each other, they are still parallel and will never intersect.
All of the lines, in the field are uniformly spaced, because the fartherapartthe lines are, the weaker the field is, but if the field is the same all around, then the lines are also the same, all around the field.
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.