Soccer Collisions, Forces, and Brain Injury Assessment
This assessment explores the science behind soccer-related head injuries, focusing on forces, collisions, and their effects on the brain. Answer each question carefully. For questions that originally asked for a drawing, respond with a written description or select the best answer.
Group 1
Source 1.1
Soccer is becoming more and more popular in the United States. And while other soccer-related injuries are happening less frequently, youth soccer players in the United States are experiencing more concussions. A concussion is a type of traumatic brain injury caused by the head experiencing an impact and moving quickly back and forth, causing the brain to bounce around in the skull.
A concussion can result from a force of 400–1,000 N on the head. There has been debate in different sports about how to best prevent concussions. In soccer, one idea is to ban headers (when a ball makes contact with a head) in youth and professional soccer.
Question 1a
How could the forces from a header with a light soccer ball cause a concussion? Describe in words how the amount of peak force on the head would compare to the amount of peak force on the soccer ball in a header that causes a collision.
Group 2
Refer to the three systems shown: System A (player heads soccer ball), System B (player collides head-to-head with another player), System C (player's head hits the ground).
Source 2.1
There are three types of collisions that tend to happen frequently in soccer: (a) headers, (b) collisions between players' heads, and (c) a player's head hitting the ground.
Question 2a
How would the amount of force on the head compare to the amount of force on the object it collides with in each system A, B, and C?
Question 2b
Explain in words your choice in 2a. How does the amount of force on the head compare to the amount of force on the object it collides with in each system?
Group 3
Refer to the three systems (A, B, C) described above. Player #84 is running at a speed of 7 miles per hour in each case.
Source 3.1
Sports scientists concluded that concussions result from headers, a running player colliding with another running player, and a running player hitting the ground. So far in this unit, we have looked at collisions and how much kinetic energy the objects in the system have before they collide and how this is related to the peak forces they can produce in any collision. Let's consider the three main types of systems that can lead to concussions and make predictions about them using forces and energy as it relates to player #84.
Question 3a
Considering both objects that are about to collide in each interaction, which system would you predict to have the least amount of total kinetic energy in the system right before the objects collide?
Question 3b
Explain in words why the system you chose in 3a would have the least amount of total kinetic energy before the collision by comparing it with the other two systems.
Question 4a
Based on your answer in 3b, which system should have the least amount of peak forces during the collision? Why?
Group 5
Source 5.1
The brain is an organ made of interconnected cells called neurons. Neurons send signals to communicate information from one neuron cell to another. The long part of the neuron is called an axon, and those axons have a breaking point. Recent research provides evidence that permanent damage to axons in the brain occurs from just a single damaging head collision (concussion).
Question 5a
During a head collision, which system (A, B, or C) would be most likely to cause damage to some of the axons in the brain? Use ideas related to kinetic energy, peak forces, and breaking point for these structures in the brain, axons, in your argument.
Question 6a
Do you think the mass of a moving object or its speed is a bigger factor contributing to its kinetic energy and the resulting damage that it can do in a collision? Why? Use any experiences you've had as evidence in your argument as well as any science ideas you think are relevant.
Question 7a
Suggest one or more ways we could use the materials from previous investigations to determine whether doubling the mass of a moving object or doubling its speed has a bigger effect on the amount of damage that occurs in a collision.
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