Ah, photons don't give a hoot about gravity. They just keep on zooming around at the speed of light, minding their own business. Gravity tries to pull them in, but those photons are like, "Sorry, I'm too busy being massless and waving to Einstein as I pass by."
Photons, despite having no mass, still experience the effects of gravity because they have energy and momentum, which are affected by gravitational fields according to the theory of general relativity.
Yes, photons are affected by gravity. According to the theory of general relativity, gravity can bend the path of light, causing it to be deflected as it passes near massive objects like stars or black holes. This phenomenon is known as gravitational lensing.
Well, isn't that just a fascinating question you've got there! Even though photons don't have mass, they can still be influenced by gravity because they have energy and momentum. As they travel through spacetime, they follow the curvature caused by massive objects like planets and stars. It's like they're dancing gracefully in the cosmic ballet of the universe!
Gas (hydrogren), gravity, and nuclear fusion (elements literally fuse and form helium thus releasing a small amount of pure energy and photons)..However, one can make the argument that fusion is due to a spectacular amount of gravity.
No, that statement is not true. The moon has gravity, which is about one-sixth that of Earth's, regardless of the presence of air. Gravity is a property of mass, and the moon's mass generates its own gravitational pull, independent of its atmosphere. Therefore, the lack of air does not mean there is no gravity.
If by "gravity neutral" you mean "not affected by gravity" the answer is none. Gravity is an attribute of curved space-time and thus everything in space-time is affected. Even massless photons curve in the presence of massive bodies.
Yes
Photons are affected by gravity because they have energy and momentum, which can be influenced by gravitational fields. Gravity can cause photons to change direction or lose energy as they travel through space. This effect is known as gravitational lensing.
Electromagnetic waves can behave like particles known as photons. Photons are the quanta of light and exhibit both particle-like and wave-like properties.
No, they don't. They "curve" around massive objects, but this is a function of the photon following the "bend" in spacetime that objects with massive gravity create. Photons have a mass equal to zero.
Yes, photons are affected by gravity. Gravity can cause light to bend around massive objects like stars or galaxies, a phenomenon known as gravitational lensing. This effect has been observed and confirmed through astronomical observations.
Photons behave more like a wave when they exhibit phenomena such as interference and diffraction, which are characteristics of wave behavior. This is evident in experiments like the double-slit experiment where photons create an interference pattern when passed through two slits.
Well, they're probably not really particles ... but they're called "photons".
Gravity will bend (influence) the path of photons (light). This effect is minimal: you would need A LOT of mass (like a black hole or a neutron star) and a very long distance for the photon to travel and to be measured to notice this effect. It is a little strange, as photons are considered to be massless, and should not be influenced by the mass (gravity) of another object. 1. Photons have energy; energy is mass (more or less); mass is affected by gravity. 2. Photons are probably affected by gravity, but you have to worry about refraction of light about a star. So, I think, the total angle is not due to gravity alone. Of course, maybe refraction is a gravity thing?
Yes, because the lack of photons affects the relative strength of gravity.
Magnetic photons interact with matter in the presence of a magnetic field by causing the alignment of electron spins within the material. This alignment can lead to changes in the material's properties, such as its conductivity or magnetic behavior.
When photons are observed in an experiment, they can behave like particles or waves, depending on how they are measured. They do not have a physical appearance like objects we can see with our eyes, but their behavior can be detected and studied using scientific instruments.