no red is
Microwaves are the band of the electromagnetic spectrum that can be diffracted most easily due to their longer wavelengths. This property allows microwaves to bend around obstacles and spread out, making them suitable for applications like radar and microwave ovens.
The blue part of the spectrum has more energy than the red part.
Violet light is diffracted more than red light because shorter wavelengths are diffracted more than longer wavelengths.
There is no 'wrong angle' - it either passes through the prism or it doesn't. The blue or violet waves will be the most diffracted.
Yes, red light has a longer wavelength than blue light. In the visible light spectrum, red light has a longer wavelength and lower frequency compared to blue light. This difference in wavelength is due to how light waves interact with various materials and how they are diffracted within the atmosphere.
The graph suggests that chlorophyll absorbs light most efficiently in the blue and red regions of the spectrum. This is because chlorophyll molecules absorb light most strongly in these regions, which corresponds to the wavelengths most useful for photosynthesis.
White light is comprised of a variety of wavelengths of light. The spectrum: Red, Orange, Yellow, Green, Blue, Indigo, Violet shows you these different wavelengths as they are diffracted through a prism. Red light is the longest wavelength of light - roughly 750nanometres (that 750EXP-9m) and blue light is one of the shortest at around 450nanometres.
White dwarfs have a broad spectrum, ranging from ultraviolet to near-infrared. However, they are most prominent in the blue and ultraviolet part of the spectrum, due to their high surface temperatures.
Chlorophyll a absorbs the most energy in the red and blue-violet regions of the electromagnetic spectrum, around 430 nm and 662 nm respectively. These wavelengths are most effective for driving the photosynthetic process in plants.
The most deviated color in the solar spectrum is blue. This is because the shorter wavelengths of blue light are scattered more easily by the Earth's atmosphere, causing them to appear more spread out compared to longer wavelengths like red.
Indigo is the color that comes between violet and blue in the spectrum.
To find the frequency of diffracted waves, one can use the formula: f_d = (v_sound / λ_d) where: f_d is the frequency of the diffracted wave, v_sound is the speed of sound in the medium, and λ_d is the wavelength of the diffracted wave.