Starship Asterisk*

Chris Peterson wrote:

karlhein wrote:Someone in this string was talking about the 'climatic effect' on the Jovian atmosphere. I seem to recall reading a long time ago that someone had estimated that the presence of Jupiter decreased the number of impacts on the Earth, secondary to the size, location and gravitational influence of Jupiter; and that this may have had a favorable effect on the climate and the evolution life on Earth.

Jupiter can sweep up some incoming comets. But it can also divert material towards us, and it is the primary gravitational perturber in the Solar System, certainly responsible for a lot of the smaller stuff that hits us. I've never seen anything one way or the other that really convinced me that Jupiter could be considered either a positive or negative force (in the balance) for how conditions evolved on Earth.

http://en.wikipedia.org/wiki/Asteroid wrote:
<<It is believed that planetesimals in the main asteroid belt evolved much like the rest of the Solar Nebula until Jupiter neared its current mass, at which point excitation from orbital resonances with Jupiter ejected over 99% of planetesimals in the belt. Both simulations and a discontinuity in spin rate and spectral properties suggest that asteroids larger than approximately 120 km (75 mi) in diameter accreted during that early era, whereas smaller bodies are fragments from collisions between asteroids during or after the Jovian disruption.

In the Nice model, a large number of Kuiper Belt objects are captured in the outer Main Belt, at distances greater than 2.6 AU. Most were subsequently ejected by Jupiter, but those that remained may be the D-type asteroids, and possibly include Ceres.>>

karlhein wrote:Someone in this string was talking about the 'climatic effect' on the Jovian atmosphere. I seem to recall reading a long time ago that someone had estimated that the presence of Jupiter decreased the number of impacts on the Earth, secondary to the size, location and gravitational influence of Jupiter; and that this may have had a favorable effect on the climate and the evolution life on Earth. Is this true, or am I just having memory flashes?

geckzilla wrote:I'm going to go impact my head into a door frame now.

Storm_norm wrote:from webster's online dictionary.org.
http://www.websters-online-dictionary.o ... ion/impact

1. A single collision of one mass in motion with a second mass which may be either in motion or at rest. 2. Specifically, the action or event of an object, such as a rocket, striking the surface of a planet or natural satellite, or striking another object; the time of this event, as in from launch to impact. 3. To strike a surface or an object.4. Of a rocket or fallaway section: To collide with a surface or object, as in the rocket impacted 10 minutes after launch

the connotation of the word "impact" is that the comet or object made contact with a surface. I'd like to argue that any object that falls into the depths of the jupiter gases doesn't actually make contact with a surface.

1. A single collision of one mass in motion with a second mass which may be either in motion or at rest. 2. Specifically, the action or event of an object, such as a rocket, striking the surface of a planet or natural satellite, or striking another object; the time of this event, as in from launch to impact. 3. To strike a surface or an object.4. Of a rocket or fallaway section: To collide with a surface or object, as in the rocket impacted 10 minutes after launch

a dictionary author wrote: im·pact (ĭm'păkt')
n.
1. The striking of one body against another; collision.
2. The force or impetus transmitted by a collision.
3. The effect or impression of one thing on another: still gauging the impact of automation on the lives of factory workers.
4. The power of making a strong, immediate impression: a speech that lacked impact.

apodman wrote:

grump wrote:When I rode I wore an open face helmet - hitting a (big) fly at 60mph stung a bit, and was fatal for the fly. What was really interesting was riding through a swarm of bees at that speed.

Like Ralph Nader's Corvair, bees can be unsafe at any speed. My first bee sting, acquired while riding a bicycle with my mouth open, was on the inside of my upper lip. Very inconvenient. Never rode with my mouth open again.

grump wrote:When I rode I wore an open face helmet - hitting a (big) fly at 60mph stung a bit, and was fatal for the fly. What was really interesting was riding through a swarm of bees at that speed.

emc wrote:

mark swain wrote:emc

Feel the breeze at 100mph on a motor bike?

Now speed your bike up to 65,000mph and feel that breeze... (Just an example ..)

Mark

As a matter of fact, I have felt 100mph+ breeze on a motor bike. Interesting that you should bring it up... more interesting that I am still alive, but that is another story not the least bit astronomical.

I like neufer's and Chris Peterson's comments on the 65k+ mph... I expect hitting a bug would also be somewhat catacylsmic.

emc wrote:I like neufer's and Chris Peterson's comments on the 65k+ mph... I expect hitting a bug would also be somewhat catacylsmic.

mark swain wrote:emc

Feel the breeze at 100mph on a motor bike?

Now speed your bike up to 65,000mph and feel that breeze... (Just an example ..)

Mark

Pete wrote:

neufer wrote:Actually, any deflection at all from a rear end collision will cause the parabolic orbit to pass in front of Jupiter thereby transferring cometary energy to Jupiter energy and inserting the comet into an elliptical orbit around the sun.

Isn't it also possible for a comet approaching from the rear to gain energy from Jupiter and leave the solar system? (something like this, where the Sun is off the bottom of the diagram)?

neufer wrote:If that were the case then Jupiter's moons are in a lot of trouble

Aren't you really referring to the much smaller Roche limit?

neufer wrote:The most common type of collision would have these velocity vectors
roughly perpendicular to each other to form a [1,sqrt(2),sqrt(3)] triangle.

neufer wrote:Actually, any deflection at all from a rear end collision will cause the parabolic orbit to pass in front of Jupiter thereby transferring cometary energy to Jupiter energy and inserting the comet into an elliptical orbit around the sun.

Pete wrote:Very cool analyses, neufer.

The elliptical insertion area you compute for Jupiter, 200 solar areas, corresponds to 20 000 Jupiter areas, or about sqrt(2e4 / pi) * 7e7 m / (5.2 AU) = 0.7% of Jupiter's distance from the Sun. For comparison, the radius of Jupiter's Hill sphere (inside of which a body loosely held together will be tidally disrupted) is (1.898e27 kg / 3 / 1.989e30 kg)^(1/3) = 7% of Jupiter's distance from the Sun. It seems from this that any weakly bound object scattered by Jupiter will also be tidally ripped apart.

Pete wrote:

neufer wrote:We know what the closing speed of a typical Oort cloud comet on Jupiter would be: v ~ 13.07 sqrt(3) km/s
(Jupiter orbital speed = 13.07 km/s).

I'm feeling unusually dense... Where does the sqrt(3) factor come from?

Pete wrote:

neufer wrote:However the closing speed of an Oort cloud comet coming up from behind Jupiter is: v ~ 13.07 [sqrt(2)-1] km/s

I understand that sqrt(2) - 1 comes from the fact that the parabolic velocity at Jupiter's distance is just sqrt(2) v_J.

Pete wrote:

neufer wrote:The amazing thing is that the surface escape velocity is 10 times the relative comet velocity (v) and
one must go out to ~ 100 Jupiter radii for the escape velocity to be comparable to the relative comet velocity [a roughly sufficient condition to inject the comet into an (e)lliptical (o)rbit [...]

In the derivation for effective collisional cross-section, the quantity 2GM/R (planet mass and radius) was replaced with v_esc, the *surface* escape velocity. Does the formula still hold if you use *local* v_esc at arbitrary distances from Jupiter? I have trouble understanding how the distance at which local escape speed roughly equals comet speed is an estimate of the e.o. cross section.

neufer wrote:We know what the closing speed of a typical Oort cloud comet on Jupiter would be: v ~ 13.07 sqrt(3) km/s
(Jupiter orbital speed = 13.07 km/s).

neufer wrote:However the closing speed of an Oort cloud comet coming up from behind Jupiter is: v ~ 13.07 [sqrt(2)-1] km/s

neufer wrote:The amazing thing is that the surface escape velocity is 10 times the relative comet velocity (v) and
one must go out to ~ 100 Jupiter radii for the escape velocity to be comparable to the relative comet velocity [a roughly sufficient condition to inject the comet into an (e)lliptical (o)rbit [...]

neufer wrote:I did a more careful analysis using Pete's formula with backside impinging angles > 0º .

The amazing thing is that the surface escape velocity is 10 times the relative comet velocity (v) and
one must go out to ~ 100 Jupiter radii for the escape velocity to be comparable to the relative comet velocity
[a roughly sufficient condition to inject the comet into an (e)lliptical (o)rbit... one that returns to
impinge precisely on Jupiter's orbit for many other shots at Jupiter's solar sized collisional cross section].

Hence, the collisional cross section (initial & return) is comparable to the area of the sun while
the initial elliptical orbit insertion cross section is comparable to 100 times the area of the sun!

Code: Select all

(solar area) sigma        comet impinging
collision   e.o.          angle    speed
-------------------------------------------------
1.0         200            10º	 6.05 km/s
0.26         50            41º   12.1 km/s
-------------------------------------------------

Here, Pete's own calculation of an effective doubling of the collisional cross section
for relative comet velocity ~ escape velocity repeats itself but for this time for the
situation where these velocities are actually equivalent ... at ~ 100 Jupiter radii!

Thus the significant elliptical orbit insertion cross section
σ = 2 x (100^2) Jupiter cross sections = 200 solar areas.

(solar area) sigma        comet impinging
collision   e.o.          angle    speed
-------------------------------------------------
0.125        25            06º	 2.35 km/s
0.032         6            37º    4.7 km/s
-------------------------------------------------

neufer wrote:Nice piece of work, Pete.

We know what the closing speed of a typical Oort cloud comet on Jupiter would be: v ~ 13.07 sqrt(3) km/s
(Jupiter orbital speed = 13.07 km/s).

This gives an increase of Jupiter's cross section by about a factor of 8 => 1000 earth cross sections

However the closing speed of an Oort cloud comet coming up from behind Jupiter is: v ~ 13.07 [sqrt(2)-1] km/s

This gives an increase of Jupiter cross section by about a factor of 122 => 15,000 earth cross sections > the area of the sun!

(solar area) sigma        comet impinging
collision   e.o.          angle    speed
----------------------------------
1.0         200            10º	 6.05 km/s
0.26         50            41º   12.1 km/s