This is really a medical question, but it worries me that you're even asking. The answer is that depends on where the current is flowing. If it's across your chest, even a few milli-amperes can send your heart into cardiac arythmia, causing a heart attack ( or death by stupidity, as I'd say). If you want to play with electricity (and I do not like your playground), keep it below your waist. And if anyone even suggests using a regular wall plug, you should run immediately! I'm not kidding! That will burn you severely for sure, and probably kill you. Be careful.
Electric current is a scalar quantity as it only has magnitude (typically measured in amperes) and no direction.
Increasing the electric field magnitude along a wire will increase the current density. This is because a higher electric field will cause more electrons to move through the wire, resulting in a higher flow of electric current.
When a flow of electric charge passes through a wire, it creates an electric current. This current is caused by the movement of electrons within the wire, which carry the charge from one point to another. The magnitude of the current is measured in amperes (A).
A magnetic field is formed around the conductor when an electric current flows through it. The strength of the magnetic field is directly proportional to the magnitude of the current flowing through the conductor.
An electric current through a wire produces a magnetic field around the wire due to the movement of electric charges. This phenomenon is known as electromagnetism and is a fundamental principle in physics. The strength of the magnetic field is directly proportional to the magnitude of the current flowing through the wire.
Electric current is a scalar quantity as it only has magnitude (typically measured in amperes) and no direction.
Increasing the electric field magnitude along a wire will increase the current density. This is because a higher electric field will cause more electrons to move through the wire, resulting in a higher flow of electric current.
The strength of a magnet(electromagnet) made by flowing electric current through a conducting coil depends on magnitude of current. . .
Nothing but magnitude. By millions of times.
It is impossible to separate the two. The voltage determines the magnitude of the current, and the current causes the damage. So, they are both responsible for electric shock.
Electric current, magnetic field intensity, length of the conductor, angle between the electric current and magnetic field
The unit used to measure the magnitude of current is the ampere (A). It represents the flow of electric charge through a circuit.
When a flow of electric charge passes through a wire, it creates an electric current. This current is caused by the movement of electrons within the wire, which carry the charge from one point to another. The magnitude of the current is measured in amperes (A).
You can increase the magnitude of the magnetic field of an electromagnet by increasing the number of turns in the coil, increasing the current flowing through the coil, and using a ferromagnetic core material within the coil. These factors collectively enhance the strength of the magnetic field generated by the electromagnet.
The purpose of an ammeter is to sense and display the magnitude of the current flowing through it. When connected in series with a branch of an electrical circuit, the meter displays the magnitude (and direction) of the current in that path ... which you can't otherwise tell just by looking at the circuit.
A magnetic field is formed around the conductor when an electric current flows through it. The strength of the magnetic field is directly proportional to the magnitude of the current flowing through the conductor.
An electric current through a wire produces a magnetic field around the wire due to the movement of electric charges. This phenomenon is known as electromagnetism and is a fundamental principle in physics. The strength of the magnetic field is directly proportional to the magnitude of the current flowing through the wire.