Consider a submerged object for simplicity. Basically the buoyant force is caused by the difference between the pressure on the object's bottom part and its top part - since lower in a fluid, there is more pressure.
It doesn't. Assuming the volumes are the same, the buyant force will also be the same.
Normally you can assume that the density of the liquid won't change much; nor the density of the sinking object. Therefore, the buyant force won't change significantly.
Burd, Galshir, and Buyant
Yes, if no force is applied. Work = force x distance, so if the force is zero, no work is done.Yes, if no force is applied. Work = force x distance, so if the force is zero, no work is done.Yes, if no force is applied. Work = force x distance, so if the force is zero, no work is done.Yes, if no force is applied. Work = force x distance, so if the force is zero, no work is done.
I usually start with the definition of work: Work = force * distance so... Force = work / distance Distance = work / force So, no. You had it backwards.
Work is energy, and work done by a force equals force times distance moved IN THE DIRECTION OF THE FORCE
Force that did the work = (work done) divided by (distance the force acted through)
Work = Force * work=Force x Distance
Force is essential to perform work. When the point of application of the force gets displaced then force is said to have performed work. Work is scalar physical quantity. Where as Force and displacement are vector quantities. So the scalar product of force and displacement gives the amount of work done. Thus the work is got by the product of magnitude of force and the resolved component of the displacement in the direction of application of force.
i don't believe so. Work = Force * distance so if there is no force there would be no work
hi; work may be defined as the product of the magnitude of force applied and the displacement of the point of application of force in the direction of force. work=force x displacement
Work = Force x Distance