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Color. Isaac Newton passed a beam of sunlight through a prism and this resulted in a patch of colors on a white piece of paper. He called this spread of colors a spectrum. Color. Sunlight is an example of white light. White light consists of all the colors of the spectrum.
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Color • Isaac Newton passed a beam of sunlight through a prism and this resulted in a patch of colors on a white piece of paper. • He called this spread of colors a spectrum.
Color • Sunlight is an example of white light. White light consists of all the colors of the spectrum. • White is not a color in itself, but a combination of all colors. • Black is not a color in itself but the absence of light.
Color by reflection • Colors of most objects are due to the way that the objects reflect light. • When white light falls on an object some frequencies are absorbed and some are reflected.
Color by reflection • The frequencies that are reflected combine to give the colors that we see.
Color by reflection • The color of the object depends on which frequencies are reflected. • A white object reflects all frequencies. • A black object absorbs all frequencies. • A red object absorbs light at most frequencies reflects primarily red light.
Color by reflection • Only frequencies present in the incident light can be reflected. • Colors of objects depend on the illuminating light. • For example colors appear different when seen in candlelight , fluorescent light, and daylight.
Color by transmission • The color of a transparent object depends on the color of the light transmitted. • For example, red glass absorbs all the colors of white light except for the red. Blue glass absorbs all the colors of white light except for the blue. • Materials in glass that selectively absorb light are called pigments.
Sunlight • The brightest colors in sunlight are in the yellow green region. • The yellow green combination is the one that our retina is the most sensitive to.
Combining colors • The combination of different colors results in new colors.
Combining colors • The combination of different colors results in new colors.
Combining colors • The combination of different colors results in new colors. • Combining red green and blue results in white. • Combining red and green results in yellow. • Combining red and blue results in magenta. • Combining green and blue results in cyan.
Combining colors • When two colors added together produce white, they are called complementary colors. • If you begin with white light and subtract a color from it the resulting color will be the complement of that color.
Combining colors • Mixing colored light is called color mixing by addition. • The primary additive colors are red, blue, and green. • Mixing different pigments that reflect different colors is called color mixing by subtraction. • The primary subtractive colors are magenta, yellow, and cyan.
Why is the sky blue • Molecules of nitrogen and oxygen absorb sunlight and reemit it in all directions.
Combining colors • Of the visible frequencies violet light is scattered the most, followed by blue, green, yellow, orange, and red.
Combining colors • Our eyes are more sensitive to blue than violet, so we see a blue sky. • If dust and other particles are present, other colors are scattered and the sky takes on a whitish appearance.
Combining colors • Water droplets in clouds are of many different sizes, and scatter many different wavelengths of light. As a result the clouds appear white.
Why are sunsets red? • At sunrise and sunset sunlight goes through a thicker layer of atmosphere. This causes more blue light to be scattered and as a result the remaining light appears to be more red. Therefore the sun appears to be red at sunrise and sunset.
Why is water greenish blue? • Water molecules resonate somewhat in the visible red frequencies. • About 30m below the surface of water, all the red color is absorbed from visible light, and a greenish blue (cyan) color remains.
Summary • The sky is blue because blue from sunlight is reemitted in all directions by molecules in the atmosphere. • Water is greenish blue because red is absorbed from sunlight by the water.
Atomic spectra. • When atoms in a sample of matter are far enough apart and their vibrations do not interfere with each other, their true colors are emitted. • This happens when atoms are made to glow in the gaseous state. • In the solid state the atoms are crowded together and their individual colors a smudged together to produce a continuous spectrum.
Atomic spectra. • The light emitted by the atoms can be analyzed by a device called a spectroscope. • A spectroscope produces a line spectrum. • Sophisticated spectroscopes are used to study light from various sources in the cosmos.
Atomic spectra. • Every element produces its own characteristic line spectrum.
Summary • Light is absorbed when its matches the natural frequency of the electrons in the material being illuminated. • Transparent materials absorb some frequencies and transmit others, and this results in different colors being transmitted. • Opaque materials absorb some frequencies and reflect others, and this results in different colors being reflected.
Summary • Color mixing by addition is the mixing of light of different frequencies. • Color mixing by subtraction is the mixing of colored paints or dyes that absorb all frequencies except for the ones that give them their color. • Red green and blue are the primary additive colors. • Cyan magenta and yellow are the primary subtractive colors.
Summary • Scattering of blue and violet frequencies gives the sky its blue color. • When light travels through a long path in the atmosphere the lower frequencies pass through, and the longer ones are scattered out. • Atoms of each element have characteristic line spectra.
