# Question: What Is The Momentum Of A 840 Kg Sports Car Traveling Down The Road At A Speed Of 24 M/s?

Contents

- 1 What is the momentum of a 2000 kg car traveling at 20 ms?
- 2 What is the momentum of a car with a mass of 1300 kg traveling north at a speed of 28 m s?
- 3 How much momentum does a truck with a mass of 2250 kg moving at a velocity of 25 m/s have?
- 4 How do you calculate speed in momentum?
- 5 What has more momentum a tractor trailer or a sports car traveling at the same velocity?
- 6 How fast will a 1200 kg car be traveling when its momentum is 2400 kgm s?
- 7 Which takes more force to catch a bowling ball or a ping pong ball?
- 8 What is not used in calculating acceleration?
- 9 Which has a greater momentum a truck with a mass of 2250 kg moving at a speed of 25 m/s or a car with a mass of 1210 kg moving at a speed of 51 m/s *?
- 10 How do you find final velocity?
- 11 What is P m V?
- 12 What is the formula for change in velocity?
- 13 What is the relationship between speed and momentum?

## What is the momentum of a 2000 kg car traveling at 20 ms?

The momentum of a 2000 kilogram car traveling at 20 meters per second is: a. 0 kg•m/sec.

## What is the momentum of a car with a mass of 1300 kg traveling north at a speed of 28 m s?

Answer: Momentum of the car is 36400 kg-m/s.

## How much momentum does a truck with a mass of 2250 kg moving at a velocity of 25 m/s have?

Vector quantity Page 6 Examples: 1. A 2250 kg pickup truck has a velocity of 25m/s to the east. What is the momentum of the pickup truck? 5.6 x 104 kgm/s east Page 7 2.

## How do you calculate speed in momentum?

The Momentum Calculator uses the formula p=mv, or momentum (p) is equal to mass (m) times velocity (v).

## What has more momentum a tractor trailer or a sports car traveling at the same velocity?

Which is more difficult to stop: A tractor-trailer truck barreling down the highway at 35 meters per second, or a small two-seater sports car traveling the same speed? You probably guessed that it takes more force to stop a large truck than a small car. In physics terms, we say that the truck has greater momentum.

## How fast will a 1200 kg car be traveling when its momentum is 2400 kgm s?

What is the mass of an object with a momentum of 250 kgm/s and a velocity of 5 in/s? 3. How fast will a 1200 kg car be traveling when its momentum is 2400 kgm/s? p=1400 tots!

## Which takes more force to catch a bowling ball or a ping pong ball?

A 5 N force is applied to a 3 kg ball to slow it down from 9 m/s to 3 m/s. Which takes more force to catch, a bowling ball or a ping pong ball? bowling ball because it has more momentum. You just studied 10 terms!

## What is not used in calculating acceleration?

which of the following is not used in calculating acceleration? Inertia.

## Which has a greater momentum a truck with a mass of 2250 kg moving at a speed of 25 m/s or a car with a mass of 1210 kg moving at a speed of 51 m/s *?

Which has a greater momentum—a truck with a mass of 2250 kg moving at a speed of 25 m/s or a car with a mass of 1210 kg moving at a speed of 51 m/s? The car has a greater momentum.

## How do you find final velocity?

Final velocity (v) of an object equals initial velocity (u) of that object plus acceleration (a) of the object times the elapsed time (t) from u to v. Use standard gravity, a = 9.80665 m/s^{2}, for equations involving the Earth’s gravitational force as the acceleration rate of an object.

## What is P m V?

Linear momentum (momentum for brevity) is defined as the product of a system’s mass multiplied by its velocity. In symbols, linear momentum p is defined to be p = mv, where m is the mass of the system and v is its velocity.

## What is the formula for change in velocity?

Velocity (v) is a vector quantity that measures displacement (or change in position, Δs) over the change in time (Δt), represented by the equation v = Δs/Δt.

## What is the relationship between speed and momentum?

In terms of an equation, the momentum of an object is equal to the mass of the object times the velocity of the object. where m is the mass and v is the velocity. The equation illustrates that momentum is directly proportional to an object’s mass and directly proportional to the object’s velocity.