Red is the longest wavelength (lowest energy). Blue is the shortest (highest energy).
Red > Orange > Yellow > Green > Blue
This is why hotter flames (like a welding torch) are blue - they're emitting higher energy.
( Pink is not a natural colour, btw. :P )
The color of visible light depends on its wavelength. Different wavelengths of light appear as different colors to the human eye. Shorter wavelengths correspond to colors like blue and violet, while longer wavelengths correspond to colors like red and orange.
Each color has a wavelength and frequency associated with it. We're familiar with the colors of the rainbow: red, orange, yellow, green, blue and violet. These colors range from longer wavelength (lower frequency) red up through shorter wavelength (higher frequency) violet. As one moves up through those colors from red to violet, the color is an indication to relative wavelength.
Refraction of light occurs when light waves enter a medium with a different refractive index, causing them to change speed and direction. The amount of refraction depends on the wavelength of the light, with shorter wavelengths (such as blue) being refracted more than longer wavelengths (such as red). This dispersion of colors in a prism is due to the varying refractive indices of different wavelengths of light.
The first color is red and the last color is violet. The visible spectrum of light ranges from longer wavelengths (red) to shorter wavelengths (violet), with colors like orange, yellow, green, and blue in between.
The wavelength of a color is directly related to the rate of photosynthesis, with longer wavelengths leading to higher rates of photosynthesis.
No, green wavelengths are shorter than orange wavelengths. In the electromagnetic spectrum, longer wavelengths correspond to colors such as red and orange, while shorter wavelengths correspond to colors like blue and green.
Yes, light of different wavelengths appears as different colors to the human eye. This is due to how our eyes perceive the different wavelengths of light as different colors, ranging from red at longer wavelengths to violet at shorter wavelengths. This phenomenon is known as color perception.
Wavelengths between 360nm and 760nm are within the visible spectrum of light, which is responsible for the colors we perceive. Different wavelengths within this range correspond to different colors, with shorter wavelengths appearing as blue/violet and longer wavelengths as red.
Humans can see different wavelengths of light as different colors. Shorter wavelengths appear as violet and blue, while longer wavelengths appear as red and orange. The entire spectrum of visible light includes colors from red to violet.
The color of light is determined by its wavelength. Different wavelengths of light correspond to different colors in the visible spectrum, with shorter wavelengths being perceived as blue and longer wavelengths as red. Mixing different wavelengths of light can create all the colors of the rainbow.
A range of different colors and wavelengths can be found in the visible spectrum of light, which includes colors like red, orange, yellow, green, blue, indigo, and violet. Each color corresponds to a different wavelength of light, with red having longer wavelengths and violet having shorter wavelengths.
The property of light that determines color is its wavelength. Different wavelengths of light correspond to different colors in the visible spectrum. For example, shorter wavelengths are associated with colors like blue and violet, while longer wavelengths are associated with colors like red and orange.
Color is determined by the wavelength of light in the electromagnetic spectrum. Different wavelengths of light correspond to different colors that we see. Shorter wavelengths are associated with colors like blue and violet, while longer wavelengths are associated with colors like red and orange.
The wavelength of particular light determines its color. Shorter wavelengths correspond to colors like blue and violet, while longer wavelengths correspond to colors like red and orange.
No, different colors have different frequencies. Colors are determined by the wavelengths of light, with shorter wavelengths corresponding to higher frequencies and hence different colors. For example, red light has a longer wavelength and lower frequency compared to blue light.
Yes, wavelength is a characteristic feature that determines the color of light. Different wavelengths of light correspond to different colors in the visible spectrum, with shorter wavelengths corresponding to colors like blue and violet, and longer wavelengths corresponding to colors like red and orange.
False. A prism separates the colors of sunlight into a spectrum because each wavelength of light has its own index of refraction, not because wavelengths are affected more or less by the prism.