Doubling the force will also double the acceleration of the cart, assuming the mass of the cart remains constant. This is in accordance with Newton's Second Law of Motion, which states that acceleration is directly proportional to the net force acting on an object.
Doubled. According to Newton's second law of motion, acceleration is directly proportional to the net force acting on an object when mass is constant. Therefore, doubling the force will lead to a doubling of acceleration.
Use Newton's Second Law, F=ma. Solving for a: a = F/m (acceleration = force / mass). If the force is in Newton, and the mass in kilograms, acceleration will be in meters/second2.
The shopping cart with greater mass will have lower acceleration compared to the shopping cart with lower mass. This is because acceleration is inversely proportional to mass when the force applied is kept constant.
If the cart's mass is doubled, its acceleration would be halved if the force remains constant. This is because acceleration is inversely proportional to mass, so an increase in mass would result in a decrease in acceleration when force is held constant.
The acceleration of a cart can decrease due to various factors such as friction, air resistance, or an opposing force acting in the opposite direction. As these forces counteract the initial acceleration, they cause the cart to slow down and reduce its overall acceleration.
Doubled. According to Newton's second law of motion, acceleration is directly proportional to the net force acting on an object when mass is constant. Therefore, doubling the force will lead to a doubling of acceleration.
Use Newton's Second Law, F=ma. Solving for a: a = F/m (acceleration = force / mass). If the force is in Newton, and the mass in kilograms, acceleration will be in meters/second2.
The shopping cart with greater mass will have lower acceleration compared to the shopping cart with lower mass. This is because acceleration is inversely proportional to mass when the force applied is kept constant.
If the cart's mass is doubled, its acceleration would be halved if the force remains constant. This is because acceleration is inversely proportional to mass, so an increase in mass would result in a decrease in acceleration when force is held constant.
The cart's acceleration will be directly proportional to the net force applied to it. If the force remains constant, the acceleration will also remain constant, assuming no other external factors are affecting the cart's motion.
The basic equation is: force equals mass times acceleration.
The acceleration of a cart can decrease due to various factors such as friction, air resistance, or an opposing force acting in the opposite direction. As these forces counteract the initial acceleration, they cause the cart to slow down and reduce its overall acceleration.
F = m aa = F/m = 12/22 = 6/11 = 0.545 meter/sec2 (rounded)
If a larger force is exerted on the loaded cart, the cart will accelerate in the direction of the force applied. This acceleration depends on the mass of the cart and the magnitude of the force. If the force is strong enough, it may even cause the cart to move uncontrollably or tip over.
Having a constant force acting on the cart ensures that it moves with a consistent acceleration. This allows for accurate measurements of how the cart's motion changes over time, making it easier to analyze and understand the relationship between force, mass, and acceleration.
The cart's acceleration will decrease as its mass increases. This is why you must exert progressively more force on a shopping cart to move it along as items are added to it. If you were to continue to add items to the cart but not change how hard you push it, the cart would eventually become "impossible" to push.
F=mass * acceleration 60kg m/s^2=10kg * acceleration 6m/s^2 = acceleration