we have 4th graders on this board?

Engineering= the practice of making as many assumptions as possible until the problem can be solved!

Technically speaking it's an endless pool idiot

I know it is common to use this method to find the volume of an object. When using the word displace along with cork, most people would visualize it floating. This would be an incorrect way to determine the density.

I knew the right answer because it is impossible to have a floating displacement different than the mass of the object. (assuming water is 1 g = 1cc)

In this context, only a moron would visualize it floating. Maybe the OP...but I don't know anyone else that'll think of it that way.

This problem makes every bit of sense.

And the function is dependent on the density of the suspension...so the water doesn't have to have to be 1 for 1. It'll just take more math...

The answer is eleventeen bajillion nanoquarks.

You guys forgot to carry the 3.

I'm not sure if I googled this right, please check my work

Conversions:
m = 5.7 gram = 0.0057 kilogram
v = 23.1 milliliter = 2.31E-5 meter^3

Solution:
density (d) = 246.75324675325 kilogram/meter^3

Other Units:
density (d) = 246.75324675325 kilogram/meter^3
density (d) = 0.24675324675325 gram/centimeter^3
density (d) = 246753.24675325 gram/meter^3
density (d) = 246753.24675325 milligram/liter
density (d) = 15.404301960309 pound/foot^3

It seems you're stuck on nautical displacement. Because ships weigh enough to actually displace a measurable amount of water then, sure, measuring the displacement and comparing it to the specific gravity of the water is workable.

Obviously a cork floats and any floating displacement from a 5.7 gram cork is too small to accurately measure. That's why no one with any sense would even consider such a ridiculous solution - "fuck it, can't measure it, so there's no way to know!" "Trick question, and so on!"

Come on, is it so hard to imagine that it's not difficult to fully immerse the cork and determine it's total fluid displacement? That's the context this problem is presented in. After all, you said so yourself: [floating displacement] is an incorrect way to determine its density.