a. In which section or sections is the bike's kinetic energy increasing?%0D%0A%0D%0AYou might need to choose more than one answer.%0D%0A%0D%0A(1 point)%0D%0AResponses%0D%0A%0D%0Asection A%0D%0Asection A%0D%0A%0D%0Asection B%0D%0Asection B%0D%0A%0D%0Asection C%0D%0Asection C%0D%0A%0D%0Asection D%0D%0Asection D%0D%0A%0D%0Asection E%0D%0Asection E%0D%0A%0D%0Asection F%0D%0Asection F%0D%0AQuestion 2%0D%0Ab. In which section does the bike have the highest constant kinetic energy?(1 point)%0D%0AResponses%0D%0A%0D%0Asection A%0D%0Asection A%0D%0A%0D%0Asection B%0D%0Asection B%0D%0A%0D%0Asection C%0D%0Asection C%0D%0A%0D%0Asection D%0D%0Asection D%0D%0A%0D%0Asection E%0D%0Asection E%0D%0A%0D%0Asection F%0D%0Asection F%0D%0AQuestion 3%0D%0Ac. Describe the bike's motion in section E.(1 point)%0D%0AResponses%0D%0A%0D%0AThe bike is getting slower.%0D%0AThe bike is getting slower.%0D%0A%0D%0AThe bike is getting faster.%0D%0AThe bike is getting faster.%0D%0A%0D%0AThe bike is moving at a constant speed.%0D%0AThe bike is moving at a constant speed.%0D%0A%0D%0AThe bike is not moving.%0D%0AThe bike is not moving.%0D%0AQuestion 4%0D%0Ad. What is similar about section E and section F?(1 point)%0D%0AResponses%0D%0A%0D%0AThe kinetic energy is increasing.%0D%0AThe kinetic energy is increasing.%0D%0A%0D%0AThe kinetic energy is decreasing.%0D%0AThe kinetic energy is decreasing.%0D%0A%0D%0AThe kinetic energy is staying the same.%0D%0AThe kinetic energy is staying the same.%0D%0A%0D%0AThe kinetic energy goes down and then up.%0D%0AThe kinetic energy goes down and then up.%0D%0AQuestion 5%0D%0Ae. Throughout the bike ride, what causes the bike to move?(1 point)%0D%0AResponses%0D%0A%0D%0AThe Earth's gravitational pull makes it move.%0D%0AThe Earth's gravitational pull makes it move.%0D%0A%0D%0AThe bike is swinging from a pendulum.%0D%0AThe bike is swinging from a pendulum.%0D%0A%0D%0ATamara transfers energy to the bike by moving the pedals.%0D%0ATamara transfers energy to the bike by moving the pedals.%0D%0A%0D%0AThe bike pulls energy out of the ground.%0D%0AThe bike pulls energy out of the ground.%0D%0AQuestion 6%0D%0Af. In which section is it most likely that Tamara stopped pedaling and allowed the bike to coast to a stop?(1 point)%0D%0AResponses%0D%0A%0D%0Asection A%0D%0Asection A%0D%0A%0D%0Asection B%0D%0Asection B%0D%0A%0D%0Asection C%0D%0Asection C%0D%0A%0D%0Asection D%0D%0Asection D%0D%0A%0D%0Asection E%0D%0Asection E%0D%0A%0D%0Asection F
The bike's kinetic energy is increasing in sections C and F.
The bike has the highest constant kinetic energy in section F.
The bike's motion in section E is moving at a constant speed.
Section E and section F are similar in that the kinetic energy is staying the same.
Throughout the bike ride, Tamara transfers energy to the bike by moving the pedals.
It is most likely that Tamara stopped pedaling and allowed the bike to coast to a stop in section F.
a. The bike's kinetic energy is increasing in sections C and F.
b. The bike has the highest constant kinetic energy in section F.
c. The bike's motion in section E is that it is moving at a constant speed.
d. What is similar about section E and section F is that the kinetic energy is decreasing.
e. Throughout the bike ride, the bike moves because Tamara transfers energy to the bike by moving the pedals.
f. It is most likely that Tamara stopped pedaling and allowed the bike to coast to a stop in section F.
To determine the answers to the questions, let's analyze the given information.
a. The kinetic energy of a moving object depends on its mass and velocity. Kinetic energy increases when either mass or velocity or both increase. Based on the information provided, we need to identify the section or sections where the bike's kinetic energy is increasing. To do this, we can look for sections where the bike is either gaining velocity or gaining mass.
b. The highest constant kinetic energy refers to the section where the bike has the highest sustained velocity. In this case, we need to identify the section where the bike's velocity is the highest and remains constant.
c. To describe the bike's motion in section E, we need to determine if the bike is getting slower, getting faster, moving at a constant speed, or not moving. We can do this by observing the change in velocity or acceleration in section E.
d. We need to find the similarity between section E and section F based on the behavior of the bike's kinetic energy. Specifically, we are looking for whether the kinetic energy is increasing, decreasing, or staying the same in these two sections.
e. We need to identify what causes the bike to move throughout the bike ride. Possible options include the Earth's gravitational pull, swinging from a pendulum, the transfer of energy from Tamara through pedaling, or any other factors mentioned in the given options.
f. We need to determine the section where it is most likely that Tamara stopped pedaling and allowed the bike to coast to a stop. To do this, we can look for sections where there is a decrease in the bike's kinetic energy, indicating a decrease in velocity or a change in motion.
Based on the provided options, the answers to the questions would be:
a. Section E (the bike is getting faster)
b. Section C (the bike has the highest constant kinetic energy)
c. The bike is moving at a constant speed in section E
d. The kinetic energy is staying the same in both section E and section F
e. Tamara transfers energy to the bike by moving the pedals
f. Section F (where the bike's kinetic energy is decreasing)
Please note that the specific details of the graph or additional context about the bike ride would be helpful to provide a more accurate analysis.