When the density of an object is less than the density of water, the object floats. This occurs because the buoyant force exerted by the water is greater than the object's weight, causing it to rise to the surface and remain partially submerged.
When the density of an object is less than the density of water, the object floats. This occurs because the buoyant force exerted by the water is greater than the object’s weight, causing it to rise to the surface and remain partially submerged.
The density of an object determines its buoyancy in a liquid. If the object's density is less than the liquid's density, it floats because the buoyant force exerted by the liquid is greater than the weight of the object. If the densities are equal or the object's density is greater, it sinks.
The density of an object determines its buoyancy in a liquid. If the object’s density is less than the liquid’s density, it floats because the buoyant force exerted by the liquid is greater than the weight of the object. If the densities are equal or the object’s density is greater, it sinks.
Objects with a density less than that of the liquid will float when placed in the liquid. This is because the buoyant force exerted by the liquid is greater than the weight of the object, causing it to rise and remain partially or completely above the liquid's surface.
Objects with a density less than that of the liquid will float when placed in the liquid. This is because the buoyant force exerted by the liquid is greater than the weight of the object, causing it to rise and remain partially or completely above the liquid’s surface.
Density is defined as the mass of a substance per unit volume. It quantifies how much mass is packed into a given volume and is typically expressed in units like kilograms per cubic meter (kg/m³) or grams per cubic centimeter (g/cm³).
Density is defined as the mass of a substance per unit volume. It quantifies how much mass is packed into a given volume and is typically expressed in units like kilograms per cubic meter (kg/m³) or grams per cubic centimeter (g/cm³).
The cork floats in water because its density is less than that of water, allowing the buoyant force exerted by water to exceed its weight, keeping it afloat. The nail sinks because its density is greater than that of water, causing it to be denser and thus sink.
The cork floats in water because its density is less than that of water, allowing the buoyant force exerted by water to exceed its weight, keeping it afloat. The nail sinks because its density is greater than that of water, causing it to be denser and thus sink.
Upthrust, also known as buoyant force, is the upward force exerted by a fluid (such as water) on an object immersed in it. It is equal to the weight of the displaced fluid and acts opposite to the force of gravity.
Upthrust, also known as buoyant force, is the upward force exerted by a fluid (such as water) on an object immersed in it. It is equal to the weight of the displaced fluid and acts opposite to the force of gravity.
The iron nail sinks in water because its density is greater than that of water. The buoyant force exerted by water (upthrust) is less than the weight of the nail, causing it to sink rather than float.
The iron nail sinks in water because its density is greater than that of water. The buoyant force exerted by water (upthrust) is less than the weight of the nail, causing it to sink rather than float.
Fluids exert pressure in a container by applying force perpendicular to the container walls. This pressure, caused by the fluid's weight and molecular motion, acts equally in all directions at a given depth, following Pascal's principle.
Fluids exert pressure in a container by applying force perpendicular to the container walls. This pressure, caused by the fluid’s weight and molecular motion, acts equally in all directions at a given depth, following Pascal’s principle.
In a confined mass of fluid, the pressure applied at any point is transmitted equally in all directions throughout the fluid. This principle, known as Pascal's law, ensures uniform pressure distribution within the fluid.
In a confined mass of fluid, the pressure applied at any point is transmitted equally in all directions throughout the fluid. This principle, known as Pascal’s law, ensures uniform pressure distribution within the fluid.
What happens when the density of an object is less than the density of water?
When the density of an object is less than the density of water, the object floats. This occurs because the buoyant force exerted by the water is greater than the object's weight, causing it to rise to the surface and remain partially submerged.
When the density of an object is less than the density of water, the object floats. This occurs because the buoyant force exerted by the water is greater than the object’s weight, causing it to rise to the surface and remain partially submerged.
See lessHow does the density of an object determine whether it will float or sink in a liquid?
The density of an object determines its buoyancy in a liquid. If the object's density is less than the liquid's density, it floats because the buoyant force exerted by the liquid is greater than the weight of the object. If the densities are equal or the object's density is greater, it sinks.
The density of an object determines its buoyancy in a liquid. If the object’s density is less than the liquid’s density, it floats because the buoyant force exerted by the liquid is greater than the weight of the object. If the densities are equal or the object’s density is greater, it sinks.
See lessWhat happens to objects with a density less than that of a liquid when placed in the liquid?
Objects with a density less than that of the liquid will float when placed in the liquid. This is because the buoyant force exerted by the liquid is greater than the weight of the object, causing it to rise and remain partially or completely above the liquid's surface.
Objects with a density less than that of the liquid will float when placed in the liquid. This is because the buoyant force exerted by the liquid is greater than the weight of the object, causing it to rise and remain partially or completely above the liquid’s surface.
See lessHow is density defined?
Density is defined as the mass of a substance per unit volume. It quantifies how much mass is packed into a given volume and is typically expressed in units like kilograms per cubic meter (kg/m³) or grams per cubic centimeter (g/cm³).
Density is defined as the mass of a substance per unit volume. It quantifies how much mass is packed into a given volume and is typically expressed in units like kilograms per cubic meter (kg/m³) or grams per cubic centimeter (g/cm³).
See lessWhy does the cork float in water while the nail sinks?
The cork floats in water because its density is less than that of water, allowing the buoyant force exerted by water to exceed its weight, keeping it afloat. The nail sinks because its density is greater than that of water, causing it to be denser and thus sink.
The cork floats in water because its density is less than that of water, allowing the buoyant force exerted by water to exceed its weight, keeping it afloat. The nail sinks because its density is greater than that of water, causing it to be denser and thus sink.
See lessWhat is the upthrust of water?
Upthrust, also known as buoyant force, is the upward force exerted by a fluid (such as water) on an object immersed in it. It is equal to the weight of the displaced fluid and acts opposite to the force of gravity.
Upthrust, also known as buoyant force, is the upward force exerted by a fluid (such as water) on an object immersed in it. It is equal to the weight of the displaced fluid and acts opposite to the force of gravity.
See lessWhy does the iron nail sink in water?
The iron nail sinks in water because its density is greater than that of water. The buoyant force exerted by water (upthrust) is less than the weight of the nail, causing it to sink rather than float.
The iron nail sinks in water because its density is greater than that of water. The buoyant force exerted by water (upthrust) is less than the weight of the nail, causing it to sink rather than float.
See lessHow do fluids exert pressure in a container?
Fluids exert pressure in a container by applying force perpendicular to the container walls. This pressure, caused by the fluid's weight and molecular motion, acts equally in all directions at a given depth, following Pascal's principle.
Fluids exert pressure in a container by applying force perpendicular to the container walls. This pressure, caused by the fluid’s weight and molecular motion, acts equally in all directions at a given depth, following Pascal’s principle.
See lessWhat happens to the pressure in a confined mass of fluid?
In a confined mass of fluid, the pressure applied at any point is transmitted equally in all directions throughout the fluid. This principle, known as Pascal's law, ensures uniform pressure distribution within the fluid.
In a confined mass of fluid, the pressure applied at any point is transmitted equally in all directions throughout the fluid. This principle, known as Pascal’s law, ensures uniform pressure distribution within the fluid.
See less