Acceleration (a) = v-u/t
Find v (final velocity) in m/s
300km/h = 300*1000/60*60
= 83.33 m/s
a= 83.33- 0 (rest)/25 (time)
= 3.33 m/s2
From the formula force = mass x acceleration, if there is more mass, there will be less acceleration. Assuming the force doesn't also change.From the formula force = mass x acceleration, if there is more mass, there will be less acceleration. Assuming the force doesn't also change.From the formula force = mass x acceleration, if there is more mass, there will be less acceleration. Assuming the force doesn't also change.From the formula force = mass x acceleration, if there is more mass, there will be less acceleration. Assuming the force doesn't also change.
Gravity produces acceleration on an object, assuming that no other force acts on the object.
Assuming by 'fall' we mean undergo the effects of gravity. If the two objects are falling toward the same large mass (ie falling towards Earth) then they would both accelerate at the same rate. This rate happens to be about 9.8 meters per second squared. It is the acceleration due to gravity on earth.
Near Earth's surface, the acceleration is about 9.8 meters/second2, assuming air resistance can be neglected.
Assuming that it's flown well, the terminal velocity is just about the stall speed of the aircraft - between 80 and 150 mph. If it's just falling out of the sky then it may exceed mach (aprox 750 mph).
About .0011111 hours, or about 4 seconds.This is assuming the units are miles/(hour*sec), which converts to 36000 miles/(hour^2) as the acceleration.
From the formula force = mass x acceleration, if there is more mass, there will be less acceleration. Assuming the force doesn't also change.From the formula force = mass x acceleration, if there is more mass, there will be less acceleration. Assuming the force doesn't also change.From the formula force = mass x acceleration, if there is more mass, there will be less acceleration. Assuming the force doesn't also change.From the formula force = mass x acceleration, if there is more mass, there will be less acceleration. Assuming the force doesn't also change.
Force is mass times acceleration. Assuming you mean an acceleration of 2 meters per second per second the force is 1 x 2 = 2N, south direction
It depends on the rate of acceleration. A top fuel dragster can accelerate at 160 ft/s2. That means it can hit 30 mph (44 ft/s) in about 0.3 seconds. From a standing start, assuming constant acceleration, it will have traveled only about 20 feet. Your mileage may vary.
Gravity produces acceleration on an object, assuming that no other force acts on the object.
Acceleration is the CHANGE in velocity; you're assuming CONSTANT velocity. So the acceleration is zero.
None. Assuming they are falling with the same conditions, they accelerate equally. But the 200 gram object has the greatest terminal velocity therefore reaching a higher velocity before resting at a constant speed.
Assuming by 'fall' we mean undergo the effects of gravity. If the two objects are falling toward the same large mass (ie falling towards Earth) then they would both accelerate at the same rate. This rate happens to be about 9.8 meters per second squared. It is the acceleration due to gravity on earth.
Assuming the mass remains constant, the acceleration will be tripled as well.
Near Earth's surface, the acceleration is about 9.8 meters/second2, assuming air resistance can be neglected.
Assuming that it's flown well, the terminal velocity is just about the stall speed of the aircraft - between 80 and 150 mph. If it's just falling out of the sky then it may exceed mach (aprox 750 mph).
Yes. Here is an example. If you throw a stone up, and assuming air resistance can be neglected, the stone will accelerate downward all the time, at a rate of 9.8 meters/second2. That simply means that its velocity will change all the time. Both when the stone moves upward and when it falls back down, it is accelerating at the same rate. The acceleration is always downward.