to 1 bulbs 1.5 and and if large florecent 3.5..
this is correct
It means flow of electrons is possible through the wirei.e no cuts/breaks/no high resistance is offered by wire.
ELECT. CURRENT IS BASICALLY THE FLOW OF ELECTRONS FROM ONE POINT TO ANOTHER POINT IN THE CIRCUIT. IN, AC IT IS "PUSHED" THROUGH THE WIRE BY THE MAGNETIZED COIL. ELECTRONS ARE AFFECTED BY MAGNETISM. IN DC, ON PART OF THE BATTERY HAS LESS ELECTRONS THAN THE OTHER. WHEN THESE TWO ARE CONNECTED, THE ELECTRONS FLOWS TO THE HUNGRIER ATOMS. THESE PRODUCES CURRENT OR ELECTRICITY IN THE WIRE.
You get more voltage with higher speed and more amperage with more turns of wire. Also by adding more coils of wire carrying current around the iron core
See voltage means potential difference. Electrons move from higher potential to lower potential always. In wire same thing happens. So electrons flow because there is potential difference and flow of electrons causes current to flow. current is nothing but flow of electrons. reply if u r satisfied @ rahul.khaladkar@rediffmail.com
To conduct the flow of electrons/electricity from the battery to the bulb and back.
The number of electrons flowing through a wire depends on the current passing through it. One ampere of current corresponds to approximately 6.24 x 10^18 electrons flowing through the wire per second.
Electrons themselves do not pass through electricity; rather, they are the charged particles that flow within a conductor in response to an electric field. This flow of electrons constitutes an electric current, which is the movement of charge through a conductor such as a wire.
Yes, more current will typically pass through a thick wire compared to a thin wire because the thicker wire offers lower resistance to the flow of electricity. This lower resistance allows more electrons to flow through the wire more easily, resulting in a higher current.
Yes, static electricity can pass through wires by creating a flow of electrons. However, the ability of static electricity to pass through wires depends on the voltage and conductivity of the wire.
Because the thick wire is, of course, thicker, it has more area than the thinner wire. This means more electrons can flow through. It's like a highway, the wider it is, the more cars that can pass through.
To calculate the number of electrons passing through a wire carrying a current of 0.7 A per second, you can use the formula I = Q/t, where I is the current, Q is the charge, and t is the time. Since the charge of one electron is approximately 1.6 x 10^-19 C, you can calculate the number of electrons passing through the wire per second by dividing the current by the charge of one electron. So, the number of electrons passing through a wire carrying a current of 0.7 A per second would be approximately 4.4 x 10^18 electrons.
Not necessarily. The amount of energy transferred by a wire primarily depends on the current flowing through it, not just the number of electrons. The current is determined by both the number of electrons and their speed, so a wire carrying fewer electrons at a higher speed could transfer more energy than a wire carrying more electrons at a slower speed.
When electrons flow through a conductor such as a wire, it is called, "Electricity".
Not around... moving THROUGH a magnetic field forces electrons to flow through a wire.
Copper wire is a common metal wire that allows electrons to flow through it easily due to its high electrical conductivity.
Not necessarily.More energy is transferred through a wire when the product of(number of electrons carried) times (voltage between the ends of the wire)is greater.
An electromagnetic field is generated around a wire as electrons flow through it. This field has both electric and magnetic components and is responsible for the transmission of energy along the wire.