An object will float - on water for example - if its density is less than the density of water. Density = mass / volume.
An object will float - on water for example - if its density is less than the density of water. Density = mass / volume.
An object will float - on water for example - if its density is less than the density of water. Density = mass / volume.
An object will float - on water for example - if its density is less than the density of water. Density = mass / volume.
An object will float - on water for example - if its density is less than the density of water. Density = mass / volume.
An objects weight has nothing to do with sinking or floating (ships are very heavy).If an object is less dense than the equivalent volume of water, it will float.If an object is more dense than the equivalent volume of water, it will sink.If an object is exactly as dense as the equivalent volume of water (at its displacement depth), it will exist in perfect equilibrium, neither sinking nor floating.
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.
If the cork is floating, then part of it is underwater and part of it is abovewater. The part that's above water is not displacing water, so the volumedisplaced is less than the total volume of the cork.Here's a mantra that will, come in very handy if you memorize it and thenfile it away until you need it:"A sinking object displaces its volume.A floating object displaces its weight." I can't think of any way that an object in water could displace morethanits volume.
652 cc (unless it was floating).
In the general case, these are quite unrelated; the buoyant force is related to the object's volume, not its weight. Or the part of the volume that is submerged in the liquid or gas. However, if the object is freely floating, then the buoyant force will be equal to its weight.
An objects weight has nothing to do with sinking or floating (ships are very heavy).If an object is less dense than the equivalent volume of water, it will float.If an object is more dense than the equivalent volume of water, it will sink.If an object is exactly as dense as the equivalent volume of water (at its displacement depth), it will exist in perfect equilibrium, neither sinking nor floating.
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.
If the cork is floating, then part of it is underwater and part of it is abovewater. The part that's above water is not displacing water, so the volumedisplaced is less than the total volume of the cork.Here's a mantra that will, come in very handy if you memorize it and thenfile it away until you need it:"A sinking object displaces its volume.A floating object displaces its weight." I can't think of any way that an object in water could displace morethanits volume.
The volume of liquid displaced has the same mass as the floating object.
You can't. All you can tell is that it's more dense than the fluid in which it's sinking.
Displacement
652 cc (unless it was floating).
It's true that the volume of displaced water of a floating object equalst the portion of that object that is underwater.
Exactly the same as for a non-floating object. Finding the volume of a shape does not vary, (i.e it's always something along the lines of height*width*depth, or area of base *height. "Table" or "surface" is irrelevant, since if it not a variable in the formula). This is true whether the object is floating or not.
In the general case, these are quite unrelated; the buoyant force is related to the object's volume, not its weight. Or the part of the volume that is submerged in the liquid or gas. However, if the object is freely floating, then the buoyant force will be equal to its weight.
Yes. The floating object is an addition to the mass system, even though it cannot displace its entire volume in the water.
Objects that are less dense than the environment in which they are immersed will float, unless they are tethered.