Quizzes & Puzzles0 min ago
Plank Lengths
How many Planck lengths would it take to cover the side of a square Barn?
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No best answer has yet been selected by beso. Once a best answer has been selected, it will be shown here.
For more on marking an answer as the "Best Answer", please visit our FAQ.And that's only for the side length -- to get to cover the entire bar you then square that.
Oh, for an edit function... or I could just be cheeky and delete my wrong answers :P
But, anyway:
A length of Plancks along the bottom of a barn = 6.187*10^20 = 619 million trillion plancks.
A whole barnside of Plancks = 3.8*10^41 square Plancks. Or ten times that if you imagine Planks of Plancks as in a 10:1 length:width ratio.
Hope that all clears that up, and remember don't hesitate to get in touch if you want me to screw up something simple again :)
Oh, for an edit function... or I could just be cheeky and delete my wrong answers :P
But, anyway:
A length of Plancks along the bottom of a barn = 6.187*10^20 = 619 million trillion plancks.
A whole barnside of Plancks = 3.8*10^41 square Plancks. Or ten times that if you imagine Planks of Plancks as in a 10:1 length:width ratio.
Hope that all clears that up, and remember don't hesitate to get in touch if you want me to screw up something simple again :)
// jim surely a cross section of the nucleus of a Uranium atom would be circular?? //
I didn't feel like replying to this yesterday, apologies for the delay.
Just want to make a couple of points, hopefully useful in future:
1. It's probably a fair assumption that a nucleus is roughly spherical in shape, but it's also worth being careful about what assumptions you make. Atomic nuclei are very complicated, and also dynamic, objects, so they may even change shape, undulating as the particles within the nuclei move around. Although that said I don't do nuclear physics so maybe I have just spouted a whole lot of bilge.
2. But anyway, for a calculation like this, you should barely care about the difference between squares and circles. A circle with diameter D has area (pi/4)*D^2, compared with a square of side D having area D^2, and pi/4 is about 79%. Obviously a 20% difference is a lot if you are trying to get an *exact* answer, but if you're just looking for a rough-and-ready approximation, a chance to work out what the approximate size of things are, then you may as well take pi/4=1 and be done with it. Approximation is your ally!
I didn't feel like replying to this yesterday, apologies for the delay.
Just want to make a couple of points, hopefully useful in future:
1. It's probably a fair assumption that a nucleus is roughly spherical in shape, but it's also worth being careful about what assumptions you make. Atomic nuclei are very complicated, and also dynamic, objects, so they may even change shape, undulating as the particles within the nuclei move around. Although that said I don't do nuclear physics so maybe I have just spouted a whole lot of bilge.
2. But anyway, for a calculation like this, you should barely care about the difference between squares and circles. A circle with diameter D has area (pi/4)*D^2, compared with a square of side D having area D^2, and pi/4 is about 79%. Obviously a 20% difference is a lot if you are trying to get an *exact* answer, but if you're just looking for a rough-and-ready approximation, a chance to work out what the approximate size of things are, then you may as well take pi/4=1 and be done with it. Approximation is your ally!
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