There is no relationship between the mass of a sinking object
and the volume of water displaced.
Their volumes are equal though .
Boyant force on a body will equal weight of displaced liquid or the body keeps sinking
340 N
They all have densities greater than the density of the fluid in which they are sinking. The mass of the displaced liquid is less than the mass of the sinking body.
The weight of the water (or other liquid, or gas) displaced is equal to the force with which the water will push the object upwards.
Right principle is "Archimedes Principle" When the weight of the sinking object exceeds the weight of the displaced liquid sinking continues. If otherwise the body would be pushed up and it would start floating on the surface. At the time of floating, the weight of the body = weight of the liquid displaced
The buoyant force is equal to the weight of the liquid displaced by the sinking object. This can be determined by finding the product of the liquid's density, the volume displaced, and the gravitational acceleration (which is approximately 9.81 meters per second squared).
future value of an annuity is a reciprocal of a sinking fund
The Spanish-American War and the Sinking of the Maine
Almost excellent. They still bore some grudges (the French - for the sinking of their fleet in Morocco by the British, and the British - for France's "hasty" surrender), but their alliance was vital.
Archimedes' principles: -- An object in a fluid experiences an upward force equal to the weight of the displaced fluid. -- A sinking object displaces its volume. -- A floating object displaces its weight.
Inertia is the resistance to a change in motion. Most likely you've felt this in a car when it speeds up quickly and it feels like you're sinking into the seat back. Or, when the car brakes hard and your body moves forward. The relationship between inertia and mass is that the greater the mass, the greater the inertia.
Rising materials causes rifting; sinking material causes subduction.