A wire carrying electric current becomes hot due to the resistance in the wire. As the electric current flows through the wire, the resistance causes some of the electrical energy to be converted into heat energy, which raises the temperature of the wire.
A current-carrying wire is a wire through which electric current flows. The wire serves as a medium for the flow of electrons, which carry the electric charge. It is an essential component in electrical circuits for delivering power to various devices.
A wire carrying a current is not normally charged; it carries a flow of electric charge as a current. Charging refers to the process of adding or removing excess electrons from an object, which is not typically the case for a wire carrying a current.
The needle of a compass will deflect from its original position when a wire carrying an electric current is placed across it. This is due to the magnetic field created by the current in the wire, which interacts with the magnetic field of the compass needle, causing it to move.
A magnetic field is created around the wire when electric current flows through it. This magnetic field is known as the magnetic field of the current-carrying wire.
A current-carrying wire is a conductor through which electric current flows. When a current flows through the wire, it generates a magnetic field around it according to the right-hand rule. This principle is the basis for various applications in electromagnetism and electronics.
Current carrying wires become hot due to resistance in the wire. As electric current flows through the wire, resistance causes some of the electrical energy to be converted into heat. This heat energy accumulates over time, causing the wire to become hot.
A current-carrying wire is a wire through which electric current flows. The wire serves as a medium for the flow of electrons, which carry the electric charge. It is an essential component in electrical circuits for delivering power to various devices.
A magnet cannot stop an electric current, but it can influence the flow of the current. Moving a magnet near a wire carrying an electric current can induce a voltage in the wire, which can affect the behavior of the current.
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A wire carrying a current is not normally charged; it carries a flow of electric charge as a current. Charging refers to the process of adding or removing excess electrons from an object, which is not typically the case for a wire carrying a current.
The needle of a compass will deflect from its original position when a wire carrying an electric current is placed across it. This is due to the magnetic field created by the current in the wire, which interacts with the magnetic field of the compass needle, causing it to move.
A magnetic field is created around the wire when electric current flows through it. This magnetic field is known as the magnetic field of the current-carrying wire.
A current-carrying wire is a conductor through which electric current flows. When a current flows through the wire, it generates a magnetic field around it according to the right-hand rule. This principle is the basis for various applications in electromagnetism and electronics.
The iron bar would become magnetized when inserted into a wire coil carrying an electric current. This is because the electric current induces a magnetic field in the coil, which in turn magnetizes the iron bar.
When a current-carrying wire is placed in a magnetic field, a force is exerted on the wire due to the interaction between the magnetic field and the electric current. This force causes the wire to move or experience a deflection, depending on the orientation of the wire and the magnetic field.
A magnetic field forms around a wire carrying an electric current. This magnetic field is created due to the movement of charged particles (electrons) through the wire. The direction of the magnetic field can be determined using the right-hand rule.
Put a wire carrying an electric current near a compass and it causes the needle to deflect.