Buoyancy is the tendency of an object to float in a fluid. All liquids and gases in the presence of gravity exert an upward force known as the buoyant force on any object immersed in them. Buoyancy results from the differences in pressure acting on opposite sides of an object immersed in a static fluid. After reading this article, you will be able to explain the buoyant force and why fluids exert an upward buoyant force on submerged objects. Let’s go through buoyancy meaning and different aspects of buoyant force.
What Is a Buoyant Force?
The buoyant force is the upward force exerted on an object wholly or partly immersed in a fluid. This upward force is also called Upthrust. Due to the buoyant force, a body submerged partially or fully in a fluid appears to lose its weight, i.e. appears to be lighter.
The following factors affect buoyant force:
- the density of the fluid
- the volume of the fluid displaced
- the local acceleration due to gravity
An object whose density is greater than that of the fluid in which it is submerged tends to sink. If the object is either less dense than the liquid or is shaped appropriately (as in a boat), the force can keep the object afloat. In terms of relative density, if the relative density is less than one, it floats in water and substances with a relative density greater than one sink in water.
What Causes Buoyant Force?
When an object is immersed in water or any other fluid, we observe that the object experiences a force from the downward direction opposite to the gravitational pull, which is responsible for the decrease in its weight. This upward force exerted by the fluid opposes the weight of an object immersed in a fluid. As we know, the pressure in a fluid column increases with depth. Thus, the pressure at the bottom of an object submerged in the fluid is greater than that at the top. The difference in this pressure results in a net upward force on the object, which we define as buoyancy.
Demonstration of Buoyant Force
When we submerge an object in a fluid, an upward force is experienced by the object. The fluid applies this force on the object, which causes it to rise, and we call this force buoyant force. The magnitude of this force is precisely equal to the amount of weight of the liquid displaced.
The point where the buoyant force is applied or the point on the object where the force acts is termed the centre of Buoyancy.
Why Does an Object Float or Sink in Water?
If one considers a single column of liquid, then it can be viewed as a concoction of the many overlying layers, one over the other, with fluctuating pressure. The pressure at the bottom of the liquid would be greater than at the top; this is because as we go down in the liquid, the number of layers of the liquid that are overlying, i.e. the layers one over the other, increases.
Owing to the difference in the pressure amid the layers, there tends to be a made-up force being applied to it in the upward direction. This force leads to the acceleration of the object that has been submerged in the upward direction. The force is always in the vertical direction.
It can also be said that the magnitude of the upward force is equivalent to the difference in the pressure of the topmost and the last layer and equivalent to the weight of the fluid displaced.
Floating is the consequence of the above concept. The object should be less dense than water, or else, if its density is greater, it will tend to sink.
Applications of Buoyancy
Buoyancy(upthrust) makes it possible for swimmers, fishes, ships, and icebergs to stay afloat. Some applications of buoyancy are given in the points below.
Hot Air Balloon
The atmosphere is filled with air that exerts buoyant force on any object. A hot air balloon rises and floats due to the buoyant force. It descends when the balloon’s weight is higher than the buoyant force. It becomes stationary when the weight equals the buoyant force.
Ship
A ship floats on the surface of the sea because the volume of water displaced by the ship is enough to have a weight equal to the weight of the ship. A ship is constructed in a way so that the shape is hollow to make the overall density of the ship lesser than the seawater. Therefore, the buoyant force acting on the ship is large enough to support its weight.
Fish
A certain group of fishes uses Archimedes’ principle to go up and down the water. To go up to the surface, the fish will fill its swim bladder (air sacs) with gases (clever, isn’t it?). The gases diffuse from their own body to the bladder and thus make the body lighter. This enables the fish to go up.
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