# Deviation from Earth's orbit

How much orbital deviation is required for the Earth to get knocked out from current orbit so it either moves away from Sun or towards the Sun?

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An orbit isn't a fragile balance, where some small deviation can knock an object out of orbit. For an object at a given distance from a central body (the sun for the Earth, the Earth for an Earth satellite), any velocity less than the escape velocity results in an elliptical orbit...Earth won't spiral in or out because it's moving too slow or fast. If the disturbance does not push the velocity above escape velocity, it will only deform the orbit into a different ellipse.

If the resulting velocity is very low, closest approach will be beneath the surface of the central body...it will impact. You need a change of nearly 30 km/s to hit the sun from Earth. If escape velocity is reached or exceeded, the closed elliptical orbit will change to an open parabolic or hyperbolic trajectory, with the object escaping. This is much easier, requiring about 12 km/s from Earth in the direction of Earth's motion, solar escape velocity at Earth's distance being 42.1 km/s.

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Combining the information from both answers: You need to effectively stop the Earth in its tracks (relative to the Sun) for it to fall into the Sun. – Mark Hurd Dec 29 '12 at 3:42
+1: Hi Christopher, Now thats a fantastic precise explanation for orbits :-) – Waffle's Crazy Peanut Dec 29 '12 at 4:01

The earth's orbital speed, $v_{orbital}$ around the Sun is 29.77 km/s. $$v_{escape} = \sqrt{2}\times v_{orbital} = 42.1 km/s$$ This is the requirement to leave the Sun's orbit.

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Amazing - I've never noticed that relationship! – Martin Beckett Dec 28 '12 at 23:03
@MartinBeckett: Gotta check my high-school book. I saw it somewhere there :-) – Waffle's Crazy Peanut Dec 29 '12 at 3:59
+1 for "Man, I didn't think of this :-)" – Waffle's Crazy Peanut Dec 29 '12 at 3:59

the calculation that was noted to present the answer that has been listed would only be acceptable under current criteria, supposing that none of the factors used to conclude the sum have deviated. If the factors change, then so also would the sum, so considering that "gravitational" influences remain as a constant then the answer given, yet, gravitational influences are presently deviating the axis of earth, with other gravitational influences as well having affected the processes that affect earth's orbital and axial equations, the factors then being altered by the process of change can also alter the sum. EVERYTHING IS A FRAGILE BALANCE, being affected by all variables, at all times.

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This doesn't answer the question posted. – Kyle Kanos 2 hours ago
This does not provide an answer to the question. To critique or request clarification from an author, leave a comment below their post - you can always comment on your own posts, and once you have sufficient reputation you will be able to comment on any post. - From Review – Gert 49 mins ago