That's going to depend on which pole of the magnet is sticking out towards
the beta stream (there are two choices), and also on the direction in which
the electrons are flowing past the magnet (there are two choices).
They have a RAVE, BABY!
No, no matter what, magnets have poles. In other words, magnets will always have a positive and negative side. If you cut you magnet in half, those two new magnets will both have + and - sides. Do this infinity times until you have a magnet 1 atom thick. The atom will still have a positive and negative pole. Hope this helps.
The net force on the mass of all the pullers is 10.0N southward. This is found by subtracting the force pulling north (12000.0N) from the force pulling south (12010.0N).
Yes, electron do have poles, since the rotation of electrons are set as up or down, and its rotation is quantized. Theses rotations about an axis, results in minute electromagnetic forces that attracts oppositely spinning electrons to the same energy level. There are many rules governing the configuration of electrons within the electron shell, the most important are the Pauli exclusion principle, which states no two electrons may occupy the same orbital with identical spins, and Hund's Rule, which states the electrons fill in order of orbitals to prevent the occupation of a orbital by two electrons, unless there is no more orbitals to place the new electron.
the two poles of a magnet have opposite properties. one of them points towards north and the other points away from it (towards south). that's why poles of the same sign repel each other, whereas poles of opposite signs attract each other.
The end of a magnet that points towards the Earth's Geographic North Pole is labeled as the North Pole of the magnet, while the end that points towards the South Pole is labeled as the South Pole of the magnet.
South Pole of another Magnet or towards the South Pole of the Earth
When a magnet is freely suspended at its center it will set itself along the north-south direction. The tip pointing towards the geographical north direction is called the north pole and the other tip is called the south pole.
A freely suspended magnet will align itself in the north-south direction due to Earth's magnetic field. The north pole of the magnet will point towards the geographic north pole, and the south pole will point towards the geographic south pole.
If a bar magnet is suspended vertically, it will align itself in the north-south direction due to Earth's magnetic field. The north pole of the magnet will point towards the geographic north and the south pole towards the geographic south.
The main difference is their orientation: the north pole of a magnet points towards the geographic north pole, while the south pole points towards the geographic south pole. In terms of magnetic properties, the north pole of one magnet will attract the south pole of another magnet, while like poles (north-north or south-south) will repel each other.
The north of the compass points to Earth's magnetic south pole, which is to the north.
If there is a magnet beside a compass, the compass needle would be influenced by the magnetic field of the magnet rather than Earth's magnetic field. The needle would point towards the opposite pole of the magnet, so if the magnet's north pole is beside the compass, the compass needle would point towards the south.
A magnet's north pole will attract the south pole of a compass needle (i.e. the end of the needle that points to Magnetic South).
The south pole of a magnet is typically determined by observing its attraction or repulsion to the north pole of another magnet. The Earth's magnetic field can also help identify the south pole of a magnet, as the north-seeking pole of a compass needle will point towards the Earth's magnetic south pole.
In the tan B position, the direction of the magnet depends on the specific orientation of the magnet. The north pole of the magnet points towards the geographical North Pole, while the south pole points towards the geographical South Pole. The direction can also be determined by using a compass, as the needle aligns with the magnetic field lines.
No, being a magnet, it has a north pole and a south pole. The two can't be separated in a magnet. If you cut the magnet in half, each half will still have a north pole and a half pole.No, being a magnet, it has a north pole and a south pole. The two can't be separated in a magnet. If you cut the magnet in half, each half will still have a north pole and a half pole.No, being a magnet, it has a north pole and a south pole. The two can't be separated in a magnet. If you cut the magnet in half, each half will still have a north pole and a half pole.No, being a magnet, it has a north pole and a south pole. The two can't be separated in a magnet. If you cut the magnet in half, each half will still have a north pole and a half pole.