Blue objects absorb wavelengths of light that correspond to other colors on the spectrum, typically orange or yellow. This means blue objects appear blue because they reflect blue light and absorb light of other colors.
If a red light is shined through a blue filter, the blue filter would absorb the red light since it is not in the transmitted light spectrum. This would result in very little to no light passing through the blue filter, creating darkness or a very dim output depending on the intensity of the red light source.
Carotenes absorb light most strongly in the blue and green wavelengths, around 400-500 nm. This is why they appear orange or red in color, as they absorb light in the blue-green part of the spectrum and reflect light in the orange-red part.
No, the color blue does not absorb light. In fact, blue objects appear blue because they reflect blue light and absorb other colors.
Red light absorbs wavelengths in the blue-green range, which are typically around 450-500 nanometers.
Yes, red light has a longer wavelength than blue light. Red light has a wavelength between approximately 620-750 nanometers, while blue light has a wavelength between approximately 450-495 nanometers.
If a red light is shined through a blue filter, the blue filter would absorb the red light since it is not in the transmitted light spectrum. This would result in very little to no light passing through the blue filter, creating darkness or a very dim output depending on the intensity of the red light source.
Carotenes absorb light most strongly in the blue and green wavelengths, around 400-500 nm. This is why they appear orange or red in color, as they absorb light in the blue-green part of the spectrum and reflect light in the orange-red part.
No, the color blue does not absorb light. In fact, blue objects appear blue because they reflect blue light and absorb other colors.
Red light absorbs wavelengths in the blue-green range, which are typically around 450-500 nanometers.
The wavelength of a transverse wave is the distance between adjacent crests or troughs (peaks or valleys).
The light of a wavelength 460nm appears blue to the human eye.
Red and blue light will not absorb the same light. Red objects reflect red light and absorb other colors, while blue objects reflect blue light and absorb other colors.
Red light has a longer wavelength and lower frequency compared to blue light. Blue light has a shorter wavelength and higher frequency, which is why it appears bluer in color to the human eye.
To find the wavelength of blue light, simply look at an electromagnetic spectrum, specifically the visible light portion. Blue light corresponds to a wavelength of around 475 nm.
Yes, red light has a longer wavelength than blue light. Red light has a wavelength between approximately 620-750 nanometers, while blue light has a wavelength between approximately 450-495 nanometers.
Blue does not absorb blue light; rather, it reflects blue light, giving it its color.
Green light is the least effective in driving photosynthesis because chlorophyll pigments absorb more strongly in the blue and red regions of the spectrum. This results in green light being poorly absorbed and utilized for photosynthesis in plants.