momentum is velocity x mass. Its mass in kilograms is 22.6N/9.8 m/s/s= 2.306kg
The velocity is 6.32 miles per second which is 10112 meters per second. The momentum is 2.306 x 10112 which=23318.272 kg meters per second.
4 kilograms
To find the recoil velocity of the Earth when a 5 kg bowling ball is projected upward with a velocity of 2.0 meters per second, we can use the principle of conservation of momentum. Initially, the total momentum is zero, so the momentum gained by the bowling ball must equal the momentum lost by the Earth. The momentum of the bowling ball is ( p = mv = 5 , \text{kg} \times 2 , \text{m/s} = 10 , \text{kg m/s} ). Since the mass of the Earth is approximately ( 5.97 \times 10^{24} , \text{kg} ), the recoil velocity of the Earth can be calculated as ( v_{Earth} = -\frac{p_{ball}}{m_{Earth}} = -\frac{10}{5.97 \times 10^{24}} \approx -1.67 \times 10^{-24} , \text{m/s} ), indicating an extremely small downward velocity.
150n
Momentum = (mass ) x (velocity) = (5) x (4) = 20 kg-meters/sec in the direction of the velocity.
Momentum=mass*velocity 0.5*4=2kgms-1
The bowling ball traveling at 20 kph has greater momentum than the one traveling at 10 kph, assuming both have the same mass. Momentum is calculated using the formula ( p = mv ), where ( p ) is momentum, ( m ) is mass, and ( v ) is velocity. Since the second ball has a higher velocity, its momentum will be greater, making it more impactful in motion.
Momentum is the product of an object's mass and velocity. When an object with momentum experiences a change in velocity, a force is required to cause that change. This force is directly related to the rate of change of momentum and is described by Newton's second law, which states that force is equal to the rate of change of momentum.
An object's momentum depends on both its mass and velocity. Momentum is calculated by multiplying an object's mass by its velocity. Therefore, an object with a larger mass or a higher velocity will have a greater momentum.
4 kilograms
In a curved or circular path, momentum is the product of an object's mass and its velocity. As an object moves in a curve, its momentum changes due to the direction of its velocity changing. The rate of change of momentum in a curved path is given by the net force acting on the object, according to Newton's second law.
If an object's mass stays constant but its momentum is changing, then its velocity must be changing as well. This implies that there is an external force acting on the object, causing its momentum (mass multiplied by velocity) to change. This concept is described by Newton's second law of motion, which states that the rate of change of an object's momentum is equal to the force applied to it.
momentum = mass x velocity 16 = 8 x velocity velocity = 2 m/s
Momentum is defined as mass times velocity, and it requires units of mass times units of velocity. The SI unit is kilograms x meters / second. There is no special name for this combination of units.
An object's momentum is determined by multiplying its mass by its velocity. Mathematically, momentum (p) is expressed as: p = mass (m) x velocity (v). Momentum is a vector quantity, meaning it has both magnitude and direction.
To find the recoil velocity of the Earth when a 5 kg bowling ball is projected upward with a velocity of 2.0 meters per second, we can use the principle of conservation of momentum. Initially, the total momentum is zero, so the momentum gained by the bowling ball must equal the momentum lost by the Earth. The momentum of the bowling ball is ( p = mv = 5 , \text{kg} \times 2 , \text{m/s} = 10 , \text{kg m/s} ). Since the mass of the Earth is approximately ( 5.97 \times 10^{24} , \text{kg} ), the recoil velocity of the Earth can be calculated as ( v_{Earth} = -\frac{p_{ball}}{m_{Earth}} = -\frac{10}{5.97 \times 10^{24}} \approx -1.67 \times 10^{-24} , \text{m/s} ), indicating an extremely small downward velocity.
Momentum is the product of mass times velocity, so in SI units, the units are kilograms x meters / second. There is no special name for this unit.
The pins gained the same amount of momentum that the bowling ball lost, according to the law of conservation of momentum. So, the pins gained 0.5 kg meters per second of momentum in the opposite direction to the bowling ball's initial momentum.