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Transcript
Clicker Question
ConcepTests
PRS-Enabled
Chapter 5
Physics, 3rd Edition
James S. Walker
© 2007 Pearson Prentice Hall
This work is protected by United States copyright laws and is provided solely for
the use of instructors in teaching their courses and assessing student learning.
Dissemination or sale of any part of this work (including on the World Wide Web)
will destroy the integrity of the work and is not permitted. The work and materials
from it should never be made available to students except by instructors using
the accompanying text in their classes. All recipients of this work are expected to
abide by these restrictions and to honor the intended pedagogical purposes and
the needs of other instructors who rely on these materials.
ConcepTest 5.1 Newton’s First Law I
A book is lying at
rest on a table.
The book will
remain there at
rest because:
A) there is a net force but the book has too
much inertia
B) there are no forces acting on it at all
C) it does move, but too slowly to be seen
D) there is no net force on the book
E) there is a net force, but the book is too
heavy to move
ConcepTest 5.2
A hockey puck
slides on ice at
constant velocity.
What is the net
force acting on
the puck?
Newton’s First Law II
A) more than its weight
B) equal to its weight
C) less than its weight but more than zero
D) depends on the speed of the puck
E) zero
ConcepTest 5.3 Newton’s First Law III
You put your book on
the bus seat next to
you. When the bus
A) a net force acted on it
B) no net force acted on it
stops suddenly, the
C) it remained at rest
book slides forward off
D) it did not move, but only seemed to
the seat. Why?
E) gravity briefly stopped acting on it
ConcepTest 5.4
You kick a smooth flat
stone out on a frozen
pond. The stone slides,
slows down and
eventually stops. You
conclude that:
Newton’s First Law IV
A) the force pushing the stone forward
finally stopped pushing on it
B) no net force acted on the stone
C) a net force acted on it all along
D) the stone simply “ran out of steam”
E) the stone has a natural tendency to
be at rest
ConcepTest 5.5 Cart on Track I
Consider a cart on a
horizontal frictionless
table. Once the cart has
A) slowly come to a stop
B) continue with constant acceleration
been given a push and
C) continue with decreasing acceleration
released, what will
D) continue with constant velocity
happen to the cart?
E) immediately come to a stop
ConcepTest 5.6 Cart on Track II
We just decided that the
cart continues with
constant velocity. What
would have to be done in
order to have the cart
continue with constant
acceleration?
A) push the cart harder before release
B) push the cart longer before release
C) push the cart continuously
D) change the mass of the cart
E) it is impossible to do that
ConcepTest 5.7 Truck on Frozen Lake
A very large truck sits on a
frozen lake. Assume there
is no friction between the
tires and the ice. A fly
suddenly smashes against
the front window. What
will happen to the truck?
A) it is too heavy, so it just sits there
B) it moves backward at const. speed
C) it accelerates backward
D) it moves forward at const. speed
E) it accelerates forward
ConcepTest 5.8 Off to the Races I
From rest, we step on the gas of our
Ferrari, providing a force F for 4 secs,
speeding it up to a final speed v. If the
applied force were only 1/2 F, how long
would it have to be applied to reach
the same final speed?
A) 16 s
B) 8 s
C) 4 s
D) 2 s
E) 1 s
F
v
ConcepTest 5.9 Off to the Races II
From rest, we step on the gas of our
A) 250 m
Ferrari, providing a force F for 4 secs.
B) 200 m
During this time, the car moves 50 m.
If the same force would be applied for
C) 150 m
8 secs, how much would the car have
D) 100 m
traveled during this time?
E) 50 m
F
v
ConcepTest 5.10 Off to the Races III
We step on the brakes of our Ferrari,
providing a force F for 4 secs. During
this time, the car moves 25 m, but does
not stop. If the same force would be
applied for 8 secs, how far would the car
have traveled during this time?
A) 100 m
B) 50 m < x < 100 m
C) 50 m
D) 25 m < x < 50 m
E) 25 m
F
v
ConcepTest 5.11 Off to the Races IV
From rest, we step on the gas of our
A) 200 km/hr
Ferrari, providing a force F for 40 m,
B) 100 km/hr
speeding it up to a final speed 50
C) 90 km/hr
km/hr. If the same force would be
D) 70 km/hr
applied for 80 m, what final speed
E) 50 km/hr
would the car reach?
F
v
ConcepTest 5.12 Force and Mass
A force F acts on mass M for a
time interval T, giving it a final
speed v. If the same force acts
for the same time on a different
A) 4 v
B) 2 v
C)
v
mass 2M, what would be the
D) 1/2 v
final speed of the bigger mass?
E) 1/4 v
ConcepTest 5.1312Force and Two Masses
A force F acts on mass m1 giving acceleration
a1. The same force acts on a different mass m2
giving acceleration a2 = 2a1. If m1 and m2 are
glued together and the same force F acts on this
combination, what is the resulting acceleration?
F
F
F
m1
a1
m2
m2 m1
a2 = 2a1
a
3
A) 3/4 a1
B) 3/2 a1
C) 1/2 a1
D) 4/3 a1
E) 2/3 a1
ConcepTest 5.14 Climbing the Rope
When you climb up a rope,
A) this slows your initial velocity,
which is already upward
the first thing you do is pull
B) you don’t go up, you’re too heavy
down on the rope. How do
C) you’re not really pulling down – it
just seems that way
you manage to go up the
rope by doing that??
D) the rope actually pulls you up
E) you are pulling the ceiling down
ConcepTest 5.15 Bowling vs. Ping-Pong I
In outer space, a bowling
ball and a ping-pong ball
attract each other due to
gravitational forces. How
do the magnitudes of these
attractive forces compare?
A) the bowling ball exerts a greater
force on the ping-pong ball
B) the ping-pong ball exerts a greater
force on the bowling ball
C) the forces are equal
D) the forces are zero because they
cancel out
E) there are actually no forces at all
F12
F21
ConcepTest 5.16 Bowling vs. Ping-Pong II
In outer space, gravitational
A) they do not accelerate because
they are weightless
forces exerted by a bowling
B) accels. are equal, but not opposite
ball and a ping-pong ball on
C) accelerations are opposite, but
bigger for the bowling ball
each other are equal and
opposite. How do their
accelerations compare?
D) accelerations are opposite, but
bigger for the ping-pong ball
E) accels. are equal and opposite
F12
F21
ConcepTest 5.17 Collision Course I
A) the car
A small car collides with
B) the truck
a large truck. Which
C) both the same
experiences the greater
impact force?
D) it depends on the velocity of each
E) it depends on the mass of each
ConcepTest 5.18 Collision Course II
In the collision between
A) the car
the car and the truck,
B) the truck
which has the greater
C) both the same
acceleration?
D) it depends on the velocity of each
E) it depends on the mass of each
ConcepTest 5.19 Contact Force I
If you push with force F on either
the heavy box (m1) or the light
box (m2), in which of the two
cases below is the contact force
between the two boxes larger?
A) case A
B) case B
C) same in both cases
A
m2
F
m1
B
m2
m1
F
ConcepTest 5.20 Contact Force II
Two blocks of masses 2m and m
A) 2 F
are in contact on a horizontal
B) F
frictionless surface. If a force F
C) 1/2 F
is applied to mass 2m, what is
D) 1/3 F
the force on mass m ?
E) 1/4 F
F
2m
m
ConcepTest 5.21 Gravity and Weight I
What can you say
A) Fg is greater on the feather
about the force of
B) Fg is greater on the stone
gravity Fg acting on a
stone and a feather?
C) Fg is zero on both due to vacuum
D) Fg is equal on both always
E) Fg is zero on both always
ConcepTest 5.22 Gravity and Weight II
What can you say
A) it is greater on the feather
about the acceleration
B) it is greater on the stone
of gravity acting on the
C) it is zero on both due to vacuum
stone and the feather?
D) it is equal on both always
E) it is zero on both always
ConcepTest 5.23 On the Moon
An astronaut on Earth kicks
a bowling ball and hurts his
foot. A year later, the same
astronaut kicks a bowling
A) more
B) less
C) the same
ball on the Moon with the
same force. His foot hurts...
Ouch!
ConcepTest 5.24 Going Up I
A block of mass m rests on the floor of
A) N > mg
an elevator that is moving upward at
B) N = mg
constant speed. What is the
relationship between the force due to
C) N < mg (but not zero)
gravity and the normal force on the
D) N = 0
block?
E) depends on the size of the
elevator
v
m
ConcepTest 5.25 Going Up II
A block of mass m rests on the
A) N > mg
floor of an elevator that is
B) N = mg
accelerating upward. What is
C) N < mg (but not zero)
the relationship between the
D) N = 0
force due to gravity and the
E) depends on the size of the
elevator
normal force on the block?
a
m
ConcepTest 5.26 Normal Force
Below you see two cases: a
physics student pulling or
pushing a sled with a force F
which is applied at an angle q.
In which case is the normal
force greater?
A) case 1
B) case 2
C) it’s the same for both
D) depends on the magnitude of
the force F
E) depends on the ice surface
Case 1
Case 2
ConcepTest 5.27 On an Incline
Consider two identical blocks,
A) case A
one resting on a flat surface
B) case B
and the other resting on an
incline. For which case is the
normal force greater?
C) both the same (N = mg)
D) both the same (0 < N < mg)
E) both the same (N = 0)