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That depends on the amounts, of course - what exactly you are comparing. The buoyant force depends on the volume. For a certain volume of lead, there will be the same buoyant force as for the same volume of iron.
On the other hand, since lead has a greater density, the buoyant force on a certain amount of MASS of lead will be less, compared to iron, since the same mass of lead will use up less volume.
What else can I help you with?
Does aluminum block contain a greater buoyant force or the iron block?
The aluminum block will experience a greater buoyant force compared to the iron block because aluminum is less dense than iron, making it more buoyant in water. The buoyant force is equal to the weight of the water displaced by the object, so the lighter aluminum block displaces more water and experiences a stronger upward force.
Why does iron ship floats in water?
Iron ships float in water because of their hollow structure, which displaces enough water to generate a buoyant force greater than the weight of the ship. This buoyant force counteracts the force of gravity pulling the ship down, allowing it to float on the surface of the water.
Mercury insert a bigger buoyant force to a fully submerged wood?
That is true. Because buoyant force is nothing but the weight of the displaced liquid when a body gets submerged in the medium of liquid. In case of mercury the relative density of mercury is 13.6 compared to that of water. A wood when placed in water, that would float due to greater buoyant force. If it is so, then you imagine about the buoyant force in case of submerging a wood in mercury. Wood having greater volume would expel that much volume of mercury. Hence the weight of the equally displaced mercury will be immense and so the result. Usually iron nails would float on mercury.
Why does the iron nail sinks in water but katori floats in water?
The iron nail sinks in water because its density is greater than that of water. The katori floats because its shape and material make it less dense than water, allowing it to displace enough water to generate a buoyant force greater than its weight.
Can a iron ship float?
Yes, an iron ship can float because its overall density is less than that of water. The iron ship is shaped in a way that allows it to displace enough water to generate a buoyant force greater than its weight, keeping it afloat.
Does aluminum block contain a greater buoyant force or the iron block?
The aluminum block will experience a greater buoyant force compared to the iron block because aluminum is less dense than iron, making it more buoyant in water. The buoyant force is equal to the weight of the water displaced by the object, so the lighter aluminum block displaces more water and experiences a stronger upward force.
Why does iron ship floats in water?
Iron ships float in water because of their hollow structure, which displaces enough water to generate a buoyant force greater than the weight of the ship. This buoyant force counteracts the force of gravity pulling the ship down, allowing it to float on the surface of the water.
Is it true that the buoyant forces on two different sized cubes made of pure iron will be the same?
No, the buoyant force experienced by an object depends on its volume and density. Since the cubes are made of pure iron, their densities will be the same, but the larger cube will displace more water due to its greater volume, resulting in a greater buoyant force compared to the smaller cube.
Mercury insert a bigger buoyant force to a fully submerged wood?
That is true. Because buoyant force is nothing but the weight of the displaced liquid when a body gets submerged in the medium of liquid. In case of mercury the relative density of mercury is 13.6 compared to that of water. A wood when placed in water, that would float due to greater buoyant force. If it is so, then you imagine about the buoyant force in case of submerging a wood in mercury. Wood having greater volume would expel that much volume of mercury. Hence the weight of the equally displaced mercury will be immense and so the result. Usually iron nails would float on mercury.
Why does the iron nail sinks in water but katori floats in water?
The iron nail sinks in water because its density is greater than that of water. The katori floats because its shape and material make it less dense than water, allowing it to displace enough water to generate a buoyant force greater than its weight.
Can a iron ship float?
Yes, an iron ship can float because its overall density is less than that of water. The iron ship is shaped in a way that allows it to displace enough water to generate a buoyant force greater than its weight, keeping it afloat.
If 10kg iron block put in sea water what will be the weight of the iron block?
The weight of the iron block will be the same when placed in seawater, but it would experience a buoyant force due to the water displaced by the block. This buoyant force would partially counteract the weight of the block, making it feel lighter in water.
Why iron nail sinks in water?
The density of iron is higher than that of water, so the iron nail sinks in water due to gravity pulling it downwards. The weight of the iron nail is greater than the buoyant force acting on it from the water, causing it to sink.
Why iron ball floats on mercury?
An iron ball floats on mercury because mercury is much denser than iron. The buoyant force acting on the iron ball due to the displacement of mercury is greater than the gravitational force pulling it downward, causing it to float.
How can a big ship made of iron float?
A big ship made of iron can float due to its shape and displacement. When a ship is designed with a hull that displaces enough water, it creates buoyant force greater than its weight, allowing it to float. Additionally, the weight of the iron ship is distributed over a large surface area, decreasing the pressure exerted on the water and helping it to stay afloat.
Does upthrust on solid iron balance its weight?
No, upthrust on solid iron does not balance its weight. Upthrust (or buoyant force) is the force exerted by a fluid on an object that is partially or completely submerged in it, opposite to the force of gravity. In the case of a solid iron object, the buoyant force would be minimal because the object is not displacing a significant volume of fluid.
Why clip can float on water?
Assuming the paper clip to be made of iron or aluminum To understand this you will need to study buoyancy and stuff... let me explain buoyancy in a nutshell, buoyancy is the upward force exerted by a fluid( gas or liquid) on any object partially or fully submerged in it. for example, when you try pushing a plastic beaker in a tumbler of water, you would have definitely felt a push this is buoyant force. buoyant force = volume of object immersed * density of the fluid * g. As a paper clip possesses a greater volume it experiences a greater amount of buoyancy which keeps it afloat. however a nail which has a comparable lesser volume sinks. hope it helps
