Because the primary purpose of a compass is to react to the magnetic field of the earth, it get affect by a nearby compass when the compass' magnetic field is stronger than that of the earth.
As the magnet is moved away, the strength of its field diminishes and the compass goes back to 'normal' - pointing north.
The compass is a magnet too; and magnets attract each other. More specifically, the north pole of one magnet is attracted by the south pole of another magnet.The compass is a magnet too; and magnets attract each other. More specifically, the north pole of one magnet is attracted by the south pole of another magnet.The compass is a magnet too; and magnets attract each other. More specifically, the north pole of one magnet is attracted by the south pole of another magnet.The compass is a magnet too; and magnets attract each other. More specifically, the north pole of one magnet is attracted by the south pole of another magnet.
Yes, magnet attraction is related to electron spin. Electrons possess a property called spin, which creates a magnetic moment. When electrons align their spins in the same direction, they create a magnetic field that can interact with other magnetic fields, leading to magnet attraction or repulsion.
The effect a magnet has on an atom is dependent on the magnetic properties of the atom, such as its electron configuration and spin. Atoms with unpaired electrons are more likely to interact with a magnet and exhibit magnetic properties.
A magnetic compass will not work near a magnet or any magnetic object. A magnetic compass doesn't work near the magnetic dip poles -- near Earth's local north magnetic poles or near Earth's south magnetic pole.
To make a simple electric motor, you will need a battery, copper wire, a magnet, and a base to hold the motor. By winding the copper wire around the base and connecting it to the battery, you create an electromagnet. When the base is placed between the poles of the magnet, the electromagnet will interact with the magnetic field to spin the motor. This simple motor demonstrates how electrical energy can be converted into mechanical motion.
The compass is a magnet too; and magnets attract each other. More specifically, the north pole of one magnet is attracted by the south pole of another magnet.The compass is a magnet too; and magnets attract each other. More specifically, the north pole of one magnet is attracted by the south pole of another magnet.The compass is a magnet too; and magnets attract each other. More specifically, the north pole of one magnet is attracted by the south pole of another magnet.The compass is a magnet too; and magnets attract each other. More specifically, the north pole of one magnet is attracted by the south pole of another magnet.
Yes. It's useful because when it's free to spin, it aligns itself with the Earth's magnetic field.
The needle of a compass is a magnet, and the earth is also a magnet. The side of the compass marked N is attracted to the north pole of the Earth, and the side marked S is attracted to Earth's south pole. The compass will spin to line itself up with the poles it is attracted to. However, if you have other magnets nearby, the compass can spin to line itself up with those instead.
Yes. It's useful because when it's free to spin, it aligns itself with the Earth's magnetic field.
Yes. Placing a rotating magnet below it can generate a magnetic field that creates a spin in the suspended magnet. If the magnet is mounted on a low-friction axis, bringing an opposite pole toward one side of the magnet, then removing it, will add force to spin it for awhile.
A compass has a magnetized needle that can spin freely.
A compass has a magnetized needle that can spin freely.
A compass would not work without a magnet. Inside the compass is a magnet which moves to line up with the Earth's natural magnetism. The north pole of the magnet is attracted to the south pole of the Earth. As such, the magnet moves to always be lining up in this way. When you use a magnet, you can see this in action as the needle moves around to always point northward and from knowing this, you can tell which way you are facing.
No.
Yes, magnet attraction is related to electron spin. Electrons possess a property called spin, which creates a magnetic moment. When electrons align their spins in the same direction, they create a magnetic field that can interact with other magnetic fields, leading to magnet attraction or repulsion.
It doesn't work like that. You can't make an electron have spin, remove its spin, or change the amount of its spin.What happens in a permanent magnet is that more electrons have their spin axis in one direction than in the opposite direction. Since the spin is associated with a magnetic field, that results in magnetism that can be observed externally.
A compass needle aligns itself with the magnetic field lines and points toward the magnetic north pole. The north-seeking end of the needle is attracted to the Earth's magnetic south pole, causing it to move and orient itself accordingly.