The Universe in microwave wavelengths is a place of unfamiliar brightness. If our eyes could see microwaves, the entire sky would radiate. Most peculiar of all, however, is that the brightness would be the same across the entire sky.
They conclude that ultraviolet looks like whitish blue or whitish violet depending on UV wavelength.
THE RADIO SKY
Instead of seeing point-like stars, we would see distant pulsars, star-forming regions, and supernova remnants would dominate the night sky.
If our vision could detect infrared radiation, our everyday experience would be transformed by shades of heat instead of color. In the daytime, objects would not just have their usual colors; they would have a heat signature visible to the naked eye.
The Universe in microwave wavelengths is a place of unfamiliar brightness. If our eyes could see microwaves, the entire sky would radiate.
Well, for one thing, we would be able to see our hand in front of our face in the dark! Our bodies actually emit IR light, which we experience as heat. If we could see in the IR, everything that gives off heat would suddenly be apparent to us, even if there were no visible light!
By exploring the universe at these high energies, scientists can search for new physics, testing theories and performing experiments that are not possible in Earth-bound laboratories. If we could see gamma rays, the night sky would look strange and unfamiliar.
Not only are the light frequencies much higher, but the highest one is only about twice the lowest one. The sound frequencies are much lower, and the highest one is a thousand times higher than the lowest one. So you can see that there's no direct match between the sound and light oscillations.
Microwaves are electromagnetic waves with a frequency of 300 MHz to 300 GHz, corresponding to wavelengths of 1 mm to 1 m. Beyond 30 GHz, the microwave frequency range overlaps with the radio frequency range. Because of the nature of microwaves, they are governed by the Federal Communications Commission (FCC).
Most animals that can see color can see UV. It's the norm, and we are the weirdos. Ultraviolet vision is so ubiquitous that much of nature must look different to most other animals. * Water scatters UV light, creating an ambient ultraviolet fog, against which fish can more easily see tiny UV-absorbing plankton.
The human eye can only see visible light waves. Infrared light has longer wavelengths and lower energy than visible light and cannot be seen with the human eye. Mosquitoes, vampire bats, bed bugs, and some snake and beetle species, however, can use portions of the infrared spectrum for vision.
But some animals, like snakes, frogs, bees and a few species of fish, can detect infrared waves in their environment. Then there's the pesky mosquito: Its IR perception detects areas of the body where the blood flows closest to the skin (more warmth at the surface means more blood).
Gamma-rays are the most energetic form of electromagnetic radiation, with over 10,000 times more energy than visible light photons. If you could see gamma-rays, the night sky would look strange and unfamiliar.
Wood is an example that resembles a maze for light waves; with its cellulose fibers and other organic compounds, it causes light to bounce around and be absorbed, preventing any possibility of the light traveling straight through. This inherent obstacle course within the wood is the reason we can't see through it.
Adults lose their ability to hear sounds above 15,000 Hz starting at the age of about 25. In laboratory conditions, the human hearing frequency range can go up to 28,000 Hz or as low as 12 Hz.
This phenomenon of turning sound into light is called sonoluminescence. We know that the light flashes are incredibly short, lasting only about 100 picoseconds, and are surprisingly high energy, meaning the collapsing bubbles may be up to 10 times hotter than the surface of the sun.
It can propagate through a vacuum by itself. Sound, on the other hand, is a longitudinal wave, whose oscillations are parallel to its direction of movement. This means that it requires a medium to propagate through and since there is no adequate medium in space, sound does not travel well in space.
All in all, a GRB within a few kiloparsecs, with its energy directed towards Earth, will mostly damage life by raising the UV levels during the burst itself and for a few years thereafter. Models show that the destructive effects of this increase can cause up to 16 times the normal levels of DNA damage.
Gamma rays can pass completely through the human body; as they pass through, they can cause ionizations that damage tissue and DNA.
Answer and Explanation: None known to date. The species with the widest known visible range is the mantis shrimp that can see into the UV range and down into the far infrared range of the EM spectrum (see Figure). Although this is a wide range, it is far from the wavelengths/frequencies of gamma rays.
The 'If You Could See UV' campaign uses a combination of hard-hitting and supportive creative assets. The campaign aims to increase sun protection behaviours among young people to reduce their lifetime risk of developing skin cancer .
Your brain interprets the various energies of visible light as different colors, ranging from red to violet. Red has the lowest energy and violet the highest.
Deer, like many other animals, do not have the ability to see infrared light. Deer are able to see colors, but the range of colors they can see is somewhat limited compared to humans.