Between 1 nanometre and 1 micrometre (= 1000 nm).
80 percent of 450 = 36080% of 450= 80% * 450= 0.80* 450= 360
40% of 450 = 18040% of 450= 40% * 450= 0.40 * 450= 180
12.5% of 450= 12.5% * 450= 0.125 * 450= 56.25
15% of 450 = 15% * 450 = 0.15 * 450 = 67.5
The wavelength of the color violet is 450-400 nm, which can also be said as 450 to 400 nanometers.
This is the violet color (380-450 nm).
The wavelength of violet light typically ranges from 380 to 450 nanometers (nm).
green ~450
At 700 nm, red light is being absorbed. This wavelength corresponds to the red end of the visible light spectrum.
The colors of the rainbow and their corresponding wavelengths are: Red: 620-750 nm Orange: 590-620 nm Yellow: 570-590 nm Green: 495-570 nm Blue: 450-495 nm Indigo: 420-450 nm Violet: 380-420 nm
The wavelength ranges of the colors in the visible spectrum (VIBGYOR) are approximately: Violet (380-450 nm), Indigo (430-450 nm), Blue (450-495 nm), Green (495-570 nm), Yellow (570-590 nm), Orange (590-620 nm), Red (620-750 nm). These wavelengths represent the different colors that make up the visible light spectrum.
In general, materials that appear colored usually absorb light of certain colors while reflecting others. The color that is absorbed depends on the material's specific properties and pigments. Without more specific information about the material in question, it is difficult to determine which color will be absorbed from NM (presumably short for "New Mexico").
If the wall reflects light in the 400 to 500 nm range and absorbs light in the 600 to 700 nm range, it would appear to our eyes as a color that falls within the reflected range (blue-green) and not in the absorbed range. The absorbed light would not contribute to the perceived color of the wall.
Indigo has a wavelength range of approximately 450-420 nanometers, which corresponds to the blue-violet part of the visible spectrum.
Here you have the frequencies of BLUE and colors next to it:violet380-450 nmblue450-475 nmcyan476-495 nm
Violet light (400-450 nm) absorbs yellow and orange wavelengths. This is why violet objects appear to be violet because they reflect violet light and absorb others.