Terminal Velocity V2: Physics Concept Trailer™

OpenStax

20 Nov 201501:37

Summary

TLDRFelix Baumgartner made history by becoming the first person to break the sound barrier without vehicular power, skydiving from 39,068 meters above Earth's surface. During his free fall, he reached speeds of up to 1,360 km/h. Air drag, a resistive force, increases with velocity and opposes gravity. When these forces balance out, Felix reaches terminal velocity, where his speed remains constant until his parachute opens. The jump demonstrates the importance of understanding physics, as it allowed Felix to survive and achieve this extraordinary feat.

Takeaways

🚀 Felix Baumgartner made history by becoming the first person to break the sound barrier without vehicular power.
🎈 He achieved this by skydiving from a balloon at a height of 39,068 meters above Earth's surface.
💨 Felix reached estimated speeds of 1,360 km/h during his descent.
🌍 Gravity is the primary force acting on Felix when he starts free-falling.
⬇️ Air drag, a resistive force, becomes significant as his velocity increases.
⚖️ At lower velocities, the effect of air drag can be ignored, but it plays a major role at high speeds.
🔄 Air drag opposes the direction of motion, while gravity constantly pulls downward.
📏 As Felix's velocity increases, air drag increases until it equals the force of gravity, resulting in terminal velocity.
🚁 Once terminal velocity is reached, Felix's speed remains constant until his parachute opens.
🧠 Understanding the physics behind the fall was crucial for Felix's survival and success during the jump.

Q & A

Who is Felix Baumgartner, and why did he make history?
-Felix Baumgartner made history by becoming the first person to break the sound barrier without vehicular power. He achieved this by skydiving from a balloon at a height of 39,068 meters above Earth's surface.
What was the estimated speed Felix Baumgartner reached during his jump?
-Felix Baumgartner reached an estimated speed of 1,360 km/h during his free fall.
What is air drag, and how does it affect objects moving through Earth's atmosphere?
-Air drag is a resistive force that opposes the motion of objects moving through Earth's atmosphere. It slows down objects by counteracting their movement, becoming more significant at higher velocities.
What forces were acting on Felix Baumgartner when he started his free fall?
-Initially, the only force acting on Felix Baumgartner was gravity, which is constant and points downward toward the center of the Earth.
Why can air drag be ignored at lower velocities?
-At lower velocities, the effect of air drag is minimal and can be ignored because it does not significantly oppose the motion of the object.
How does air drag change as velocity increases?
-Air drag rapidly increases with velocity. As an object moves faster, the opposing force of air drag becomes more significant, eventually balancing out the force of gravity.
What happens when the force of air drag equals the force of gravity?
-When air drag equals the force of gravity, the two forces cancel each other out, resulting in no further acceleration. This is known as terminal velocity, and the object will maintain a constant speed until other forces, like a parachute, are applied.
What is terminal velocity, and when does it occur during free fall?
-Terminal velocity is the constant speed an object reaches when the force of air drag equals the force of gravity. It occurs when there is no further acceleration during the free fall.
Why was understanding the laws of physics crucial for Felix Baumgartner's successful jump?
-Understanding the laws of physics, such as gravity, air drag, and terminal velocity, was crucial for Felix to execute his jump safely and avoid making mistakes that could have jeopardized his life.
What role did Felix's parachute play in his descent?
-Felix's parachute was deployed to slow his descent after he reached terminal velocity, allowing him to land safely by drastically reducing his speed.