That's really going to have something to do with the brightness of the source.
Whatever color you want to talk about, the sun probably turns out more photons
of it every second than a kitchen match does.
Light is produced it does not produce. It is produced by the excitement of subatomic particles called photons and propagated by radiation
A filament is heated by an electric current and photons are emitted.
Increasing the intensity of light will increase the number of photons arriving per second. Increasing intensity has no effect on photon energy.
Photons are pieces of light. If you see a light, then there are photons.
Red light has less energy per photon than blue light, so to get the same energy we would need more red photons.
Light is produced it does not produce. It is produced by the excitement of subatomic particles called photons and propagated by radiation
A filament is heated by an electric current and photons are emitted.
A filament is heated by an electric current and photons are emitted.
A great energy and light is produced by the supernovas. Therefore, a great number of photons is produced.
Increasing the intensity of light will increase the number of photons arriving per second. Increasing intensity has no effect on photon energy.
Photons are emitted (light energy) and infrared energy.
Photons are pieces of light. If you see a light, then there are photons.
Accelerating electrons emit photons of light.
Red light has less energy per photon than blue light, so to get the same energy we would need more red photons.
Light particles are called Photons.
Light is composed of very small packages of electromagnetic energy called photons. We are able to see objects because light photons from the sun (or other light source) reflect off of the atoms within the object and some of these reflected photons reach the light sensors in our eyes and we can see the objects. It takes many millions of photons entering our eyes each second for us to view the world. When photons of light hit the atoms within an object three things can happen. First, the photons can bounce back from the atoms in the object; we call this reflection. Second, the photons can pass through an object such as glass and we call them transparent. Three, the photons can be stopped by the atoms within the object and the photon energy is converted to heat; we call this absorption.
Given the wavelength of the photons from above, 3000 nm you just calculate how many joules each photon has and divide that into 100 joules per second.