Red light typically bends less than green light when it passes through a medium due to the different wavelengths of the two colors. This phenomenon is known as dispersion. Green light has a shorter wavelength compared to red light, causing it to refract more when passing through a medium.
Red light rays will bend the least when entering a drop of water, as red light has the longest wavelength of the visible light spectrum. Blue light rays will bend the most, as they have the shortest wavelength. Green light rays will bend somewhere in between red and blue.
A blue ray would bend light the most in a prism, as shorter wavelengths of light (like blue) are refracted more than longer wavelengths (like red or green) when passing through a medium like glass.
When light is split, blue light tends to bend the most and red light the least. This is because blue light has a shorter wavelength compared to red light, causing it to refract more when passing through a prism or other dispersive medium.
Red light will bend the least, blue light will bend the most. This is due to the phenomenon of dispersion, where different colors of light have different wavelengths and thus different indices of refraction in water, causing them to bend by varying amounts. Blue light has a shorter wavelength and thus a higher index of refraction compared to red light.
Blue light rays will bend the most and red light rays will bend the least when entering a drop of water simultaneously. This is because blue light has a shorter wavelength, leading to stronger interactions with the water molecules. Red light, with a longer wavelength, experiences less refraction.
Red light rays will bend the least when entering a drop of water, as red light has the longest wavelength of the visible light spectrum. Blue light rays will bend the most, as they have the shortest wavelength. Green light rays will bend somewhere in between red and blue.
A blue ray would bend light the most in a prism, as shorter wavelengths of light (like blue) are refracted more than longer wavelengths (like red or green) when passing through a medium like glass.
In case of visible region, VIBGYOR, violet has the maximum bending.
When light is split, blue light tends to bend the most and red light the least. This is because blue light has a shorter wavelength compared to red light, causing it to refract more when passing through a prism or other dispersive medium.
Red light will bend the least, blue light will bend the most. This is due to the phenomenon of dispersion, where different colors of light have different wavelengths and thus different indices of refraction in water, causing them to bend by varying amounts. Blue light has a shorter wavelength and thus a higher index of refraction compared to red light.
I suppose that the red light is more favorable.
Blue light rays will bend the most and red light rays will bend the least when entering a drop of water simultaneously. This is because blue light has a shorter wavelength, leading to stronger interactions with the water molecules. Red light, with a longer wavelength, experiences less refraction.
Light from a red laser will produce more widely spaced fringes of light when passed through a diffraction grating compared to light from a green laser. This is because red light has a longer wavelength than green light, causing it to diffract more.
Green light - Green, White light - Green, Red light - Black
Plants are green because the reflect green light. They do not use green light, they use red light to make food. Some plastic mulches are red to reflect red light onto plants to make them grow more.
When you mix light green and red together, you get a shade of brown. This is because red and green are complementary colors, which when combined in light form, create a more neutral or muted color.
A green leaf appears green in daylight because it reflects green light and absorbs other colors. In red light, the leaf appears dark because it does not reflect red light well, as it absorbs more of the red light. This phenomenon is due to the specific pigments present in the leaf that interact with different wavelengths of light.