(S-4) The Many Colors of Sunlight

Color: What is it?

    Isaac Newton showed that not only can a triangular prism separate a beam of sunlight into rainbow colors (that had already been known), but also that, when a second prism brings the different colors together again, white light is once more obtained. Therefore white light is a combination of all the rainbow colors, and the prism separates its colors because the angle by which a beam of light is bent, when it enters glass, differs from one color to the next.

    [For the same reason, a simple glass lens brings different colors to a focus at different distances. In Newton's time, if an astronomer focused a telescope to give (say) a sharp yellow image of a star, that image would be surrounded by unfocused patches of red and green. Newton thought the problem was insoluble, and proceeded to invent a new kind of telescope, based not on lenses but on concave mirrors, which reflect all colors equally. In later times optics were created which focused all colors together, using a combination of several lenses made of different kinds of glass, and these are nowadays found in cameras, projectors and small telescopes. However, all big modern telescopes follow Newton's idea and use mirrors.]

Perceived Color

    (1) In light emitted from solids, liquids or extensive bodies of dense gas such as the Sun, the colors are distributed continuously. Their exact distribution ("black body spectrum") depends on the temperature at which it is produced--a warm hand radiates mostly in the infra-red, a glowing bar of iron is cherry-red, a lightbulb filament is bright yellow, and sunlight is white-hot.

    [Also of this type is the distribution of microwave radiation left over from the "big bang" when the universe apparently began, a radiation observed by NASA's COBE satellite, the Cosmic Background Explorer. When the observed COBE spectrum was first shown before a meeting of astronomers, it caused a great stir. Observed values generally show some experimental error, but here they were so close to the predicted theoretical curve that the first impression of the viewers was that the presenters had drawn the curve first and then placed their points on top of it.]

    Most light sources we use are of two kinds: The light is created either by heat--e.g. in the hot filament in a common flashlight--or by glowing gas, as in fluorescent lighting. Sources of the second kind give more light per unit energy, but that light is concentrated in a few preferred colors, so colored objects may appear somewhat un-natural.

    For street lighting true color is less important, so in general glowing vapors of soldium or mercury is used. Sodium emits orange-yellow light, and a spectrograph reveals the color comes from two closely spaced spectral lines (see middle part of 2nd strip in the image above). Mercury vapor emits a bluish light (see middle of bottom strip above), but no red.

    Because of the lack of red in such a light, pink skin seen by it seems unnaturally pale. Fluorescent lightbulbs also contain mercury (a spectroscope will show mercury "lines"), but to create softer and more pleasant light (and to put the UV light, usually wasted, to good use), they have a fluorescent coating ("phosphor") inside the glass, which absorbs the harsh mercury colors (including UV) and re-radiates them in a more even distribution of color(in above image see "Mercury W/phos"). Neon lights operate in a similar way, with small amounts of other gases producing appropriate colors.

    [We postpone addressing the question "crest of what? " Early physicists did not know the answer, either--they just knew that when two crests overlapped, the light was brighter, while when crest met "valley" (crest in the opposite direction), the waves cancelled each other, giving a darkening.]

    The wavelength determines the extent to which a wave can be confined to certain locations. Because light waves are so short, we can also visualize a light wave limited to a well-defined beam. However, outlines begin to blur when we look at small objects through a powerful microscope, magnifying several thousand times, because light waves cannot define details smaller than their wavelength. That is where electron microscopes become useful, using not light but beams of electrons.