6.3 Centripetal force (Page 16/15)

University physics volume 1 Page 1 / 15

By the end of the section, you will be able to:

Explain the equation for centripetal acceleration
Apply Newton’s second law to develop the equation for centripetal force
Use circular motion concepts in solving problems involving Newton’s laws of motion

In Motion in Two and Three Dimensions , we examined the basic concepts of circular motion. An object undergoing circular motion, like one of the race cars shown at the beginning of this chapter, must be accelerating because it is changing the direction of its velocity. We proved that this centrally directed acceleration, called centripetal acceleration , is given by the formula

a_{c} = \frac{v^{2}}{r}

where v is the velocity of the object, directed along a tangent line to the curve at any instant. If we know the angular velocity $ω$ , then we can use

a_{c} = r ω^{2} .

Angular velocity gives the rate at which the object is turning through the curve, in units of rad/s. This acceleration acts along the radius of the curved path and is thus also referred to as a radial acceleration.

An acceleration must be produced by a force. Any force or combination of forces can cause a centripetal or radial acceleration. Just a few examples are the tension in the rope on a tether ball, the force of Earth’s gravity on the Moon, friction between roller skates and a rink floor, a banked roadway’s force on a car, and forces on the tube of a spinning centrifuge. Any net force causing uniform circular motion is called a centripetal force . The direction of a centripetal force is toward the center of curvature, the same as the direction of centripetal acceleration. According to Newton’s second law of motion, net force is mass times acceleration: $F_{net} = m a .$ For uniform circular motion, the acceleration is the centripetal acceleration: _. $a = a_{c} .$ Thus, the magnitude of centripetal force $F_{c}$ is

F_{c} = m a_{c} .

By substituting the expressions for centripetal acceleration $a_{c}$ $(a_{c} = \frac{v^{2}}{r}; a_{c} = r ω^{2}),$ we get two expressions for the centripetal force $F_{c}$ in terms of mass, velocity, angular velocity, and radius of curvature:

F_{c} = m \frac{v^{2}}{r}; F_{c} = m r ω^{2} .

You may use whichever expression for centripetal force is more convenient. Centripetal force ${\vec{F}}_{c}$ is always perpendicular to the path and points to the center of curvature, because ${\vec{a}}_{c}$ is perpendicular to the velocity and points to the center of curvature. Note that if you solve the first expression for r , you get

r = \frac{m v^{2}}{F_{c}} .

This implies that for a given mass and velocity, a large centripetal force causes a small radius of curvature—that is, a tight curve, as in [link] .

The figure consists of two semicircles. The semicircle on the left has radius r and bigger than the one on the right, which has radius r prime. In both the figures, the direction of the motion is given as counter-clockwise along the semicircles. A point is shown on the path, where the radius is shown with an arrow pointing out from the center of the semicircle. At the same point, the centripetal force, F sub c, is shown pointing inward, in the opposite direction to that of radius arrow. The velocity, v, is shown at this point as well, and it is tangent to the semicircle, pointing left and up, perpendicular to the forces. In both the figures, the velocity is same, but the radius prime is smaller and centripetal force is larger in the figure on the right. It is noted that vector F sub c is parallel to vector a sub c since vector F sub c equals m times vector a sub c. — The frictional force supplies the centripetal force and is numerically equal to it. Centripetal force is perpendicular to velocity and causes uniform circular motion. The larger the $F_{c},$ the smaller the radius of curvature r and the sharper the curve. The second curve has the same v , but a larger $F_{c}$ produces a smaller r ′.

What coefficient of friction do cars need on a flat curve?

(a) Calculate the centripetal force exerted on a 900.0-kg car that negotiates a 500.0-m radius curve at 25.00 m/s. (b) Assuming an unbanked curve, find the minimum static coefficient of friction between the tires and the road, static friction being the reason that keeps the car from slipping ( [link] ).

<< Chapter < Page Page > Chapter >>

Practice Key Terms 6

Read also:

Get Jobilize Job Search Mobile App in your pocket Now!

100% Free Mobile Applications
Receive real-time job alerts and never miss the right job again

Source: OpenStax, University physics volume 1. OpenStax CNX. Sep 19, 2016 Download for free at http://cnx.org/content/col12031/1.5

Google Play and the Google Play logo are trademarks of Google Inc.

Notification Switch

Would you like to follow the 'University physics volume 1' conversation and receive update notifications?

Ask

	College physics By OpenStax Read Online Course
©flickr: Gareth	Resume Writing MCQ By Abby Sharp Start Quiz
	Are you a 5sos fan? By Rylee Minllic Start Quiz
	8 Psychology MCQ 2011 1 Exam By John Gabrieli Start Exam
	4 Microbiology Final 4 By Madison Christian Start Quiz
©flickr:	CTE/STEM Technology Literacy Test By Sebastian Sieczko... Start Quiz
©flickr: Rod	Medieval Africa By Jesenia Wofford Start Quiz
	9 Lec:9 Descriptive Statistics By Janet Forrester Start Quiz
	13 Dr Garry GI Ruminants quiz By Brooke Delaney Start Exam
	9 AP Key Terms 09 Joints Key Terms By OpenStax Start Key Terms