Physics question

[DoraM]

In 8th grade we were asked what would happen if a strangelet crossed the event horizon of a black hole. I answered C).

 

[M Paquette]

In 8th grade we were asked what would happen if a strangelet crossed the event horizon of a black hole. I answered C).

Then there are the 'universal answers':

5

KVAR load increases.

Power follows steam demand.

 

[nun]

Gravity is really a red herring here. Let's consider our universe to be a few of angstroms wide. It's obvious that the EM force between the atoms is far larger than the gravitational force and than the atoms will sink into a nice cozy potential well. Now as we increase the separation it becomes a question of whether the EM force due to the slight polariztion of the H atoms becomes less than the gravitational force.

 

[arebelspy]

When the atoms collide... Would they make a sound?

 

[Gumby]

Then there are the 'universal answers':

Power follows steam demand.

Why yes. Yes it does. But I thought the other answer was 7

 

[Nords]

Power follows steam demand.

Why yes. Yes it does. But I thought the other answer was 7

... for a saturated steam system. (Which I always left off my answers, and which always cost me a minimum of two points.)

I'm surprised no one has brought up "42" yet.

 

[FIRE'd@51]

Gravity is really a red herring here. Let's consider our universe to be a few of angstroms wide. It's obvious that the EM force between the atoIf we use a model for the hydrogen atom (as many do) that it is a spherical proton (positively charged) surround by a negatively charged spherical shell electron cloud, then by Gauss' Law it follows that outside the spherical shells the electrostatic attraction would be zero since the net charge contained within the spherical shells is zero. Only when the atoms actually penetrate each other would there be any electrostatic forces. The diameter of the atom is about 1 angstrom, so even if they were a few angstroms apart, the atoms would be outside each other's Gaussian surfaces, and, therefore, experience no electrostatic forces.ms is far larger than the gravitational force and than the atoms will sink into a nice cozy potential well. Now as we increase the separation it becomes a question of whether the EM force due to the slight polariztion of the H atoms becomes less than the gravitational force.

If we use a model for the hydrogen atom (as most do) that it is a spherical proton (positively charged) surrounded by a negatively charged spherical shell electron cloud, then by Gauss' Law it follows that outside the spherical shells the electrostatic attraction would be zero since the net charge contained within their respective Gaussian surfaces (i.e., the spherical shells) is zero. Only when the atoms actually penetrate each other would there be any electrostatic forces. The diameter of the hydrogen atom is about 1 angstrom, so even if they were a few angstroms apart, the atoms would be outside each others Gaussian surfaces, and, therefore, experience no electrostatic forces.

 

[JoshTrent]

Wait.. is the cat dead? or alive..?

 

[Gumby]

Both

 

[GregLee]

It's unclear.

 

[HFWR]

Everything is relative to the speed of light through warm tapioca...