Frederick Herschel was born in Hanover, Germany, in 1738. As a young man, he grew into a gifted musician and astronomer. It was Herschel who discovered the planet Uranus in 1781, the first new planet discovered in almost 2,000 years. In late 1799 Herschel began a study of solar light. He often used color filters to isolate parts of the light spectrum for these studies and noted that some filters grew hotter than others. Curious about this heat in solar radiation, Herschel wondered if some colors naturally carried more heat than others.
To test this idea, Herschel built a large prism. In a darkened room, he projected the prism's rainbow light spectrum onto the far wall and carefully measured the temperature inside each of these separate col ored light beams.
Herschel was surprised to find that the temperature rose steadily from violet (coolest) to a maximum in the band of red light. On a sudden impulse, Herschel placed a thermometer in the dark space right next to the band of red light (just be yond the light spectrum).This thermom eter should have stayed cool. It was not in any direct light. But it didn't.
This thermometer registered the most heat of all.
Herschel was amazed. He guessed that the sun radiated heat waves along with light waves and that these invisible heat rays refract slightly less while traveling through a prism than do light rays. Over the course of several weeks, he tested heat rays and found that they refracted, reflected, bent, etc., exactly like light. Because they appeared below redlight, Herschel named them infrared (mean ing below red).
Johann Ritter was born in 1776 in Ger many and became a natural science philosopher. His central beliefs were that there was unity and symmetry in nature and that all natural forces could be traced back to one prime force, Urkraft. In 1801, Ritter read about Herschel's discovery of infrared radiation. Ritter had worked on sunlight's effect on chemical reactions and with electrochemistry (the effect of electrical currents on chemicals and on chemical reactions). During this work he had tested
light's effect on silver chloride and knew that exposure to light turned this chemical from white to black. (This discovery later became the basis for photography.)
Ritter decided to duplicate Herschel's experiment, but to see if all colors darkened silver chloride at the same rate. He coated strips of paper with silver chloride. In a dark room he repeated Herschel's set up. But instead of measuring temperature in each color of the rainbow spectrum projected on wall, Ritter timed how long it took for strips of silver chlo-
ride paper to turn black in each color of the spectrum.
He found that red hardly turned the paper black at all. He also found that violet darkened paper the fastest. Again mimicking Herschel's experiment, Ritter placed a silver chloride strip in the
dark area just be yond the band of violet light. This strip blackened the fastest of all! Even though this strip was not exposed to visible light, some radiation had acted on the chemicals to turn them black.
Ritter had discovered radiation beyond violet (ultra violet) just as Herschel had discovered that radiation existed below the red end of the visible spectrum (infrared).
