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.
The longer the wavelength, the redder the light is. Violet has the shortest wavelength.
Light of different colors is light that has different frequencies; or equivalently, different wavelengths.
The color of a star is related with the wavelength of the light observed. Wien's Law states that: Peak Wavelength x Surface Temperature = 2.898x10-3 Peak Wavelength is the wavelength of the highest intensity light coming from a star.
Ok, so this goes back to the inverse relationship between wavelength and frequency ( energy). As wavelength increases , frequency decreases, the relationship between the two is a inverse relationship. the Red light, wavelength of approx. 700 m^-7 , has a greater wavelength then of the blue light, 400m ^-7. This means , due to frequency and wavelength having an inverse relationship, blue light has a greater frequency (energy) than red light. This is why blue light, no matter how dim, will impart more energy to an electron , then a red light would.
Resolving power of microscope is inversely related to the wavelength of the light used. So shorter the wavelength, greater the resolving power.
Red is the longest wavelength of visible light
Light with a lower frequency will have a longer wavelength. Frequency and wavelength are inversely proportional to each other (i.e. as one increases, the other decreases and vice-a-versa). The product of frequency and wavelength is the speed of light.
The color of an object is the frequency/wavelength of the light it reflects. The light it reflects is the light it receives minus the light it absorbs.
The color of a star is related with the wavelength of the light observed. Wien's Law states that: Peak Wavelength x Surface Temperature = 2.898x10-3 Peak Wavelength is the wavelength of the highest intensity light coming from a star.
There is no relationship whatsoever. There are puny lights in both red and violet, and there are overpowering ones of each color too.
The color, the frequency, and the wavelength.
freq x wavelength = c (light speed)
Wavelength and frequency are inversely proportional.
If you are talking specifically about visible light, the wavelength is between approximately 380 nm and 760 nm, depending on the color.
Energy,E=h*c/Wavelength h is Planks const.,c is velocity of light
inversely related
The wavelength of visible light is approximately between 400 and 700 nm; if you divide the speed of light by that value, you will get the corresponding frequencies.
Ok, so this goes back to the inverse relationship between wavelength and frequency ( energy). As wavelength increases , frequency decreases, the relationship between the two is a inverse relationship. the Red light, wavelength of approx. 700 m^-7 , has a greater wavelength then of the blue light, 400m ^-7. This means , due to frequency and wavelength having an inverse relationship, blue light has a greater frequency (energy) than red light. This is why blue light, no matter how dim, will impart more energy to an electron , then a red light would.
By the light's wavelength.