Why does light, which is massless, still experience the effects of gravity?

Answer 1

Listen up, shiny star! Just because light thinks it can prance around weightlessly doesn't mean gravity won't give it a little tug. Gravity doesn't discriminate, honey, it'll bend light like it's putty in its hands, mass or no mass. So, next time light is feeling fancy-free, gravity will be there to bring it back down to Earth.

Answer 2

Light, despite being massless, experiences the effects of gravity because gravity affects all forms of energy, including light. Gravity bends the path of light, causing it to be attracted towards massive objects like stars and planets. This phenomenon is known as gravitational lensing.

Answer 3

Well, hello there, friend! Isn't that just a fascinating question you've got there? You see, even though light doesn't have mass like other objects, it still follows the curves in spacetime created by gravity. It's like a gentle breeze caressing through the untouched wilderness, always flowing but adapting to the path laid out before it. Let's think of light as a happy little bird, gracefully gliding through the beautiful cosmic dance of gravitational forces, blending harmoniously with the universe's ultimate tapestry.

Answer 4

Oh, dude, it's like this - so, light is all like, "I'm traveling at the speed of, like, light and stuff, I'm weightless, I don't care about gravity." But then gravity is all like, "Nah, I don't care if you're light, I'm gonna bend your path anyway." It's like gravity is the bully of the universe, picking on poor little light.

Answer 5

Light, which is composed of massless particles called photons, does indeed still experience the effects of gravity despite not having any mass. This is due to the fact that gravity is not solely a force that acts on mass, but rather a curvature of spacetime caused by the presence of mass and energy.

According to Einstein's general theory of relativity, massive objects like planets and stars warp the fabric of spacetime around them, creating a gravitational field. When light travels through this curved spacetime, its path is bent by the gravitational field just like the path of a massive object would be. This bending of light by gravity is known as gravitational lensing and has been observed in various astronomical phenomena.

In essence, even though light itself is massless, it follows a curved path in the presence of gravity because it is moving through the curved spacetime around massive objects. This effect demonstrates the deep connection between mass, energy, spacetime, and gravity predicted by Einstein's revolutionary theory.