The metal will melt if you do that.
As potential difference increases in a filament lamp, resistance also increases due to an increase in temperature. The relationship between resistance and potential difference in a filament lamp is non-linear due to the temperature-dependent nature of resistance in the filament material. At low voltages, the resistance is relatively low, but as the temperature of the filament increases with higher voltages, the resistance also increases.
When electrons travel through a filament, they collide with atoms in the filament material. These collisions cause the electrons to lose energy and heat up the filament, which then emits light. This process is how an incandescent light bulb produces light.
The filament in a light bulb produces light when an electric current passes through it. This causes the filament to heat up and glow, emitting visible light as a result of its high temperature. This process is known as incandescence.
it stays there. the electricity travels back and forth through the filament until you turn the lighbulb off.
As the bulb becomes brighter, more current flows through the filament, increasing its temperature. This increase in temperature causes the filament to glow more intensely, resulting in a brighter light output.
As the bulb becomes brighter, the temperature of the filament increases. This is due to the increased flow of electricity through the filament, causing it to heat up and emit more light. The relationship between brightness and temperature is direct - the brighter the bulb, the hotter the filament.
The filament breaks.
When electricity flows through the filament in a light bulb, the filament becomes very hot and starts to emit light due to the process of incandescence. The electricity heats up the filament to a high temperature, causing it to glow and produce light.
When the filament in a light bulb heats up, it emits light and heat energy. The filament is designed to reach a high temperature so that it glows and produces visible light. The heat generated is a byproduct of the light production process.
The bulb gets brighter because the filament is getting hotter. If the filament's temperature gets too high it will melt at some point and fall apart. The current will stop flowing and the bulb will "blow".
The temperature of a bulb filament when it is burning can range from 2,000 to 3,000 degrees Celsius (3,600 to 5,400 degrees Fahrenheit), depending on the type of bulb and the amount of electric current passing through it. This high temperature causes the filament to glow and produce light.
The temperature of the filament inside a working electric bulb can reach up to around 2,500 to 3,000 degrees Celsius. This high temperature is what allows the filament to emit light and heat up the surrounding area in an incandescent light bulb.
the bulb get fused
When an electric bulb heats up, it can stop glowing if the filament inside breaks due to the extreme temperature. The filament in a light bulb glows when an electric current passes through it, but if it breaks, the circuit is disrupted and the bulb will not light up. This can also happen if the filament is damaged by vibration or stress.
The metal will melt if you do that.
As potential difference increases in a filament lamp, resistance also increases due to an increase in temperature. The relationship between resistance and potential difference in a filament lamp is non-linear due to the temperature-dependent nature of resistance in the filament material. At low voltages, the resistance is relatively low, but as the temperature of the filament increases with higher voltages, the resistance also increases.