The brightness of a light bulb is directly affected by the voltage applied to it. Light bulbs, specifically incandescent bulbs, work based on a principle called Joule heating or resistive heating. Here's how voltage affects the brightness of a light bulb:
Joule Heating: In an incandescent light bulb, a filament is heated to a high temperature by passing an electric current through it. This filament emits visible light as a result of its high temperature. The heat is generated due to the resistance of the filament to the flow of electric current. This phenomenon is known as Joule heating.
Voltage and Resistance: The resistance of the filament is relatively constant for a given type of bulb. According to Ohm's Law (V = I * R), where V is voltage, I is current, and R is resistance, if the resistance remains constant, an increase in voltage will lead to an increase in current.
Temperature and Brightness: As the current flowing through the filament increases, the filament's temperature also increases. The filament becomes hotter, and as it reaches higher temperatures, it emits more intense visible light. This is why an incandescent bulb appears brighter when it's operated at a higher voltage.
Life Span: However, running a light bulb at a higher voltage than it's designed for can significantly reduce its lifespan. The higher temperature can cause the filament to degrade more quickly, leading to a shorter overall bulb life.
It's important to note that this explanation primarily applies to traditional incandescent bulbs. Modern lighting technologies, such as compact fluorescent lamps (CFLs) and light-emitting diodes (LEDs), operate differently and have electronic components that regulate the current and brightness, making their behavior more complex. For instance, in LEDs, current is regulated to control brightness, and increasing voltage might not necessarily increase brightness in the same straightforward manner as in incandescent bulbs.