Fascinating topic, but it was as if i was reading a high school report on the subject.

The top pictures of major news site' articles often come from a DB / library as fallback, where they try to add something relevant, but it's not always directly related to the article... Because not all articles come with content that have usable pictures. But every article still needs one for UI purposes so they sometimes use filler. Old magazines often were just text and didn't have this requirement.

The one they chose seems to be relevant still.

> Why don't they use the picture from the third party source?

Licensing fees

How much did you expect from an article with “ghost” in the title?

"when one showing exactly what they are talking about exists in a press release from the European Geosciences Union they link to in their own article?"

Cus you can't just jack photos without permission ?

" a GPS receiver on a ship may, during the course of a long voyage, indicate height variations, even though the ship will always be at sea level (neglecting the effects of tides). That is because GPS satellites, orbiting about the center of gravity of the Earth, can measure heights only relative to a geocentric reference ellipsoid. To obtain one's orthometric height, a raw GPS reading must be corrected. Conversely, height determined by spirit leveling from a tide gauge, as in traditional land surveying, is closer to orthometric height. Modern GPS receivers have a grid implemented in their software by which they obtain, from the current position, the height of the geoid (e.g. the EGM-96 geoid) over the World Geodetic System (WGS) ellipsoid. They are then able to correct the height above the WGS ellipsoid to the height above the EGM96 geoid. When height is not zero on a ship, the discrepancy is due to other factors such as ocean tides, atmospheric pressure (meteorological effects), local sea surface topography and measurement uncertainties."

and https://en.wikipedia.org/wiki/World_Geodetic_System

in particular WGS-84

From what I remember there's also a 'hill' in the Pacific.

gravity's impact on liquids is much more defined by them being pulled 'sideways' than 'up' or 'down'. For example, the tides are not mostly caused by the water being lighter or heavier due to the tidal forces of the moon and being pulled down by a greater or lesser degree, but by the sideways pull of the water on the 'side' of the earth causing it to bunch up where the sideways pulls converge (which is why you get tides with bodies of water as big as the oceans but not so much with lakes). The same thing happens here: stronger gravity elsewhere pulls the water sideways away from the low-gravity area, causing the depression (in fact, absent dynamic effects and other forces like wind, the surface of a liquid will be an isograv: every point at its surface will have the same gravitational potential).

(From the article) "As a result of the low pull of gravity there, combined with the higher gravitational pull from the surrounding areas, the sea level of the Indian Ocean over the hole is a whopping 106 meters lower than the global average"

Probably like iron filings and magnets, the stronger magnet would have a bigger pile of iron filings on it.

Water isn't compressible, so the distribution would always give the stronger region more water.

Maybe more gravity in other places creates more pull there and pulls the water away from places with less gravity? Similar to how the gravity of the moon pulls at the water, creating high tide? But that's just my guess, I'm not an expert either...

> more gravity would create more "pull"?

Exactly. There is more mass below the ocean in the areas around where the hole developed and less mass below the hole. That mass is pulling water from the hole so it became a hole. By the way, less water in the hole and more around it further contribute to making the hole deep because water also have a mass. It doesn't go on forever up to draining the center of the hole dry, there is an equilibrium. Calculating the sea levels could be an unusual physics problem for students.

This is similar to recent discussions here on HN around the effects of melting ice (Antarctica, Greenland) on sea level. Not only does the meltwater itself cause increase, but the gravitational pull of so much ice pulls the water level around it up higher, resulting in lower sea level everywhere else. When the ice melts, that local gravity lessens, letting the surrounding elevated water spread out to the rest of the ocearn.

It is not gibberish if you studied physics at school. Water surface remains on the same level of potential energy of gravitational field, othewise it won’t be the state with minimum energy. This means that if the field has complex form, the water surface won’t be ellipsoid. If the pull is stronger, you can expect a bulge, if the pull is weaker, there will be a hole and the depth of that hole can be bigger than the tidal amplitude, because why not.

EDIT: also, in case of Indian Ocean, it is not a hole, just slightly different curvature.

I don't get it- why is this gibberish?

(other than perhaps being counter-intuitive- you would expect low gravity to cause high sea level)

It makes sense to me. I’m assuming in this context sea level is distance from the center of the earth.

Yeah i read that and I immediately thought BS. The most the tide varies on earth is less 15 meters.

Scientific American mostly ceased being scientific in the latter 90's, and should be more correctly named Political American.

A large language model trained by…

Or even a small model. AI generated news was a thing well before anyone heard of transformer models.

Wikipedia gives this, from 2012, as the citation for the claim "2006, Thomson Reuters announced their switch to automation to generate financial news stories on its online news platform":

https://www.tandfonline.com/doi/abs/10.1080/17512786.2012.66...

Interesting question.

This article discusses identifying regions of gravitational variance, and the abstract discusses where gravitational pull at Earth's surface is highest (near the North Pole) and lowest ("at the top of the Huascaran mountain in the South American Andes"), but not by how much ... The project measures local gravitational acceleration across the surface of the Earth at 200m resolution.

<https://www.sciencedaily.com/releases/2013/09/130904105345.h...>

And the linked field map doesn't give specific measurements either. (Archive as original is 404):

<https://web.archive.org/web/20160309210505/http://geodesy.cu...>

The linked PDF article however does give values, on page 5:

<https://web.archive.org/web/20160307144931/http://ddfe.curti...>

Minimum: 9.76392 m * s^-2

Maximum: 9.83366 m * s^-2

Given a 100 kg human (somewhat heavier than typical, but simpler to compute), the difference would amount to a difference of 6.974 newton, or 1.567 pound-force. Or a delta of about 0.712%.

If you were on a boat at water level, there wouldn’t be any weight difference between the two points. The water level follows equipotential lines of gravity.

And would it make economical sense to build rocket launch pads at the lowest points?

Absent any other external forces, liquids (even non-uniform ones like the ocean) will form an isograv, where every part of their surface is at an equal gravitational potential. This is a natural consequence of how pressure works. So you expect this kind of deviation from gravitational anomaly. And while other forces can have a significant impact, there's not a lot else which can cause a persistent change in the average of this size. Dynamic effects will just to make things oscillate around the average but not chang the average much if at all, and even an extremely heavy prevailing wind (rare at the surface) won't be enough to cause much of a change in sea level.

(ok, there is one really big thing left off of this which is important with respect to what 'average sea level' means: the largest other persistent effect is the centrifugal effects from the spinning of the earth, which results in the bulging at the equator (both for the rock itself, which at planet scales and timelines is approximately liquid, and for the oceans). This is way larger: the oceans are actually about 7km higher near the equator than you would expect if the earth was a sphere. The average they are comparing to here is coming from measuring sea level with respect to the shape it would be if the earth were just a ball of liquid with the same mass and spin. There's a bunch of different approximations which get used here and the details get really messy, but the next step after taking into account the centrifugal effect is basically various levels of approximation of the distribution of gravity: https://en.wikipedia.org/wiki/Geoid)