A quick lesson in the scale of the cosmos.

[EnsignParis]

Earth is about 8000 miles in diameter.
Jupiter is about 88000 miles in diameter.
The sun is about 865000 miles in diameter (and it is only a medium sized star).

The sun is 93 million miles away. This is called 1 AU, or 1 Astronomical Unit. It takes light moving at 186000 miles per second 7 minutes to travel this distance.

Pluto's average distance away from the sun is about 39.7 AU, or 3692100000 miles (about 3.5 billion miles).

After this distance, AU become almost obsolete, because anything all that significant past pluto is trillions upon trillions of miles away. After this distance, we usually approximate things with lightyears or ly. Lightyears are NOT a measure of time, but a measure of distance. It is the distance light travels in 1 year in a vacuum, about 63000 AU/year or about 5.8 trillion miles.

The nearest star (other than our sun) is about 4.2 lightyears away

The milky way is about 100,000 lightyears, and contains billions of stars.

The visible universe is about 15 billion lightyears across. This is only the visible universe, remember, the universe could be MUCH larger than that. At 15 billion ly away we cannot see any more, because light simply has not had enough time since the beginning of the universe to reach us!

Also, one more thing to ponder. When we look at objects billions upon billions of lightyears away, like quasars and radio galaxies, it is quite possible that those objects no longer exist. It has taken light billions of years to reach us from those objects, so we are just now only able to see them the way they were billions of years ago.

Also, don't use any of this information in an essay, because I cannot guarantee the accuracy of the information above, I didn't double check my sources...but this is pretty much common knowledge, so I don't think you should have a problem with the information above.

[EnsignParis]

This is the only topic on this page without a reply as of right now. That's kind of sad. Am I the only one who finds this fascinating?

Hehe, whatever, I don't really care.

*burps*

[Gladiator]

[EnsignParis]

It's not all that complicated once you sit down and think about it, it's simple math really.

To see something, we need light reflecting on it, and the light reflecting off of that object we are seeing is moving approximately 186000 miles per second (the speed of light).

Now, we are so incredibly far away from some things in the universe, some objects are 13, 14 or even 15 billion lightyears away. It takes the light that was reflected off of these objects 13, 14 or 15 billion years to reach us from its source, so we are now just seeing these objects that are so far away.

But it took up to 15 billion years for the produced/reflected light (stars produce their own light, but it still moves at the same speed) to reach us from the source. In the span of 15 billion years, a lot can happen, including the death/birth of stars, supernovae, galaxies are even affected. Things like radio galaxies and quasars are only found at incredible distances, implying that they were only around during the first years of the universe, 15 billion years ago.



Oh, I know plenty of more stuff, ask away and we'll see if I can answer it.

[Gladiator]

That was pure genius so basically we can see into the past at far distances like a time machine .

What do you know about small particles...like electrons, neutrons, protons and even smaller stuff?

[EnsignParis]

Well, there is a lot to be discussed about protons, neutrons electrons and such, in fact there is a study of it. Chemistry .

Once you get into smaller things other than protons, neutrons and electrons, we start to get into quantum physics, higher dimensional space (ie more than the 3 spatial dimensions you are probably familiar with and the 1 temporal dimension (time)).

Quantum physics is well out of my leauge, and I once tried reading a book that touched on higher dimensional space, and I couldn't really comprehend what the author was talking about once I got further into the book.

If you want to get it it's called Hyperspace by Michio Kaku. It is quite thought provoking, but it definately gets quite hard to read toward the middle (which is where I stopped).

Back to your original question about protons/neutrons/electrons though. I need a bit more detail on what exactly it is you want to know, because there is quite a bit. One could write a book on it.

[Gladiator]

[EnsignParis]

[webtaz99]

[quote="EnsignParis"]
Of course though, nothing humans know of would be able to detect such small differences. We can barely find entire planets many times bigger than Jupiter outside of our solar system. Focusing on something as small as the earth from 60 lightyears away would be impossible with our current technology.
[quote]

Not quite true. The ability to detect Earth-sized objects at 60 lightyears is not limited by current technology; it is limited by money. By using very large arrays and long-baseline interferometry current technology could (and soon will) both image and spectrograph planets of other stellar systems.

[Kyre]

[Gladiator]

[quote="EnsignParis"][quote="Gladiator"]

[EnsignParis]

[quote="Gladiator"][quote="EnsignParis"]

[EnsignParis]

[Dax Orien]

Alright, alright, I have a serious question: I haven't heard much on this but are we the only solar system with Terran planets? I mean, are we the only solid planet solar system?

[EnsignParis]

[Monkey]

come on i learned this stuff in the second grade it's not that amazing

[EnsignParis]

Yeah? Well I didn't.