Would sea level change at the equator if the Earth stopped spinning? I am assuming it is currently bulging around it due to centrifugal force.


2 Answers 2


Let's assume that the earth didn't suddenly stop spinning (because intertia and conservation of angular momentum would do all sorts of "interesting" things that are deserving of a What-If answer), and stipulate that the earth slowed down gradually, or possibly that it was never spinning in the first place (although I'm sure this would have all sorts of other effects that wouldn't have got us to where we are...)

Yes, sea levels would change, but not necessarily for the reasons that you think.

Centrifugal force

Part of the bulge in oceans is due to centrifugal force on the water, but much of it is not. There is an underlying bulge in the seabed as well as the ocean. A result of this (and other variations in the thickness and density of the crust) are that the earth's gravitational field is not even across the globe, and where there is a stronger area of gravitational field, more water is pulled towards it and a bulge results. It is this effect that allows for the bathymetry of oceans to be mapped by satellites that sense the elevation of the sea's surface.

I am no geoscientist, but I imagine that this bulge in the crust at the equator is also to do with centrifugal force - but it would take a lot longer to go away, if indeed it did at all, than one caused just by water.

EDITING to add that there is now an answer elsewhere on this site re the bulge in the crust: How viscous is the Earth's mantle?

Changes in tides & ocean currents

If the planet were not rotating, the dominant period for tidal cycles would likely be related to a lunar month rather than to a day. There would also be no Coriolis effect, and these two factors would result in major differences to tides and to ocean circulations. As such, it is likely that there would be substantial differences in both short- and long-term elevation changes that are due to currents.

Other effects

I suspect that lack of rotation might have effects on the planet's core and its magnetic field, which might result in all sorts of other impacts... but we'll have to wait for a geoscientist in a speculative mood to talk about things like that :-)

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    $\begingroup$ Another problem might be rapid cooling on the side not pointed toward the sun... $\endgroup$
    – Shadur
    Jul 7, 2014 at 18:50
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    $\begingroup$ @Shadur if it stopped rotating, then it would still have a solar "day", albeit a year long ;-) $\endgroup$ Dec 7, 2014 at 11:02
  • $\begingroup$ Effect on tides: none? As the the moon still rotates around the earth and the earth around the sun... $\endgroup$ Aug 12, 2015 at 1:30
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    $\begingroup$ @atmosphericprisonescape there would still be tides, for the reasons you note, but they would be VERY different. The dominant period would likely be half a lunar month rather than half a day - and this difference in period, plus lack of Coriolis effects, would result in major changes to the patterns of circulation. I've edited little more clarity into my answer. $\endgroup$ Aug 12, 2015 at 4:27

This is covered in an episode of the National Geographic TV series Aftermath called "When The Earth Stops Spinning". It's also covered by "If the Earth Stood Still: Modeling the absence of centrifugal force" by Witold Fraczek of Ersi, a GIS software company.

The Earth is not round, but bulges at the equator. The diameter at the equator is 43km more than pole-to-pole. Without the Earth's spin to force the oceans "uphill" at the equator, they would flow "downhill" towards the poles. Since the oceans are no where near as deep as 43km (the deepest part, Mariana Trench, is only 11km), the equator would be completely dry and the poles likely flooded. Aftermath depicts an Earth with two polar oceans and a strip of dry land at the equator. Most of North America, Europe, Northern Asia, Argentina and Antarctica are under water. Here's a timelapse video of that process.

Worse, the atmosphere acts like a fluid, too. It was also being held in place "uphill" at the poles. It also begins to thin out around the equator, thinner than on Mt Everest. Most of the world is either under water, or too high up for us to breathe. Humanity is left with a thin band of habitable land at the edge of the polar oceans, with some of the lowlands of the newly dry Pacific Basin also being habitable.

Doesn't matter, because with no spin a day on Earth is six months long. Baked during the "day" and frozen during the "night", it's not a pleasant place for people.

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    $\begingroup$ +1 I have seen that (and own a DVD of it), I am glad that it has been brought up! $\endgroup$
    – user889
    Dec 7, 2014 at 2:07
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    $\begingroup$ I have a tendency to question everything I see on NatGeoTV and the likes. I wonder if someone actually calculated this stuff to see that it will actually happen this way. Yes, the water would go towards the poles, but then the bulge will also slowly disappear. How long will it take and what it will look at at the equilibrium state? $\endgroup$
    – Gimelist
    Dec 7, 2014 at 7:23
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    $\begingroup$ @Michael You mean the bulge around the Earth's middle? How long before it goes away after rotation stops? Or is it frozen in place? I don't know. Sounds like another question! $\endgroup$
    – Schwern
    Dec 7, 2014 at 9:46
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    $\begingroup$ That's exactly what I mean. $\endgroup$
    – Gimelist
    Dec 7, 2014 at 10:04
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    $\begingroup$ That sounds wrong to me. It's assuming that the earth's geoid is a sphere, despite the bulge. I imagine that the effect described would take place, but not that much. $\endgroup$ Aug 11, 2015 at 21:08

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