How Does Air Resistance Affect a Flea's Jump Height?

AI Thread Summary
Fleas can jump up to 36 cm without air resistance, but air resistance reduces this height to 18 cm. The discussion revolves around calculating the flea's kinetic energy as it leaves the ground and determining the fraction of energy converted to potential energy at its peak height. The kinetic energy should be calculated using the maximum height of 36 cm, as this represents the ideal scenario without air resistance. Participants clarify that using the lower height of 18 cm for calculations would not yield meaningful results for part b of the problem. Understanding the distinction between the two scenarios is crucial for solving the homework questions accurately.
Jaklynn429
Messages
15
Reaction score
0

Homework Statement


Fleas have remarkable jumping ability. If a 0.50 mg flea jumps straight up, it will reach a height of 36 cm if there is no air resistance. In reality, air resistance limits the height to 18 cm.


Homework Equations


K=1/2 m*v^2



The Attempt at a Solution


I tried to use kinematics to get a delta T, and the program is still saying I am wrong! The final is tomorrow and this is a practice problem, can someone please explain how to do this! thanks!
 
Physics news on Phys.org
What is the problem?? Is it asking for how much energy is used up by air resistance?
 
I'm sorry! The problem wants to know:
a) what the flea's kinetic energy is as it leaves the ground?
b) at its highest point, what fraction is converted to potential energy?
 
I'm assuming "a) what the flea's kinetic energy is as it leaves the ground?" is for
"Fleas have remarkable jumping ability. If a 0.50 mg flea jumps straight up, it will reach a height of 36 cm if there is no air resistance."

and "b) at its highest point, what fraction is converted to potential energy?" is for "In reality, air resistance limits the height to 18 cm."

For a) energy is conserved. soo we pick the lowest point that has a gratational potential of zero. so we can use this

\frac{1}{2}mv^2=mgh
 
Here is my problem though...the statement doesn't separate those two things. The problem reads exactly this: "Fleas have remarkable jumping ability. If a 0.50 mg flea jumps straight up, it will each a height of 36 cm if there is no air resistance. In reality, air resistance limits the height to 18 cm."
a) what is the flea's kinetic energy as it leaves the ground?

That's my issue, I don't know whether to use the 36 or the 18.
 
Jaklynn429 said:
Here is my problem though...the statement doesn't separate those two things. The problem reads exactly this: "Fleas have remarkable jumping ability. If a 0.50 mg flea jumps straight up, it will each a height of 36 cm if there is no air resistance. In reality, air resistance limits the height to 18 cm."
a) what is the flea's kinetic energy as it leaves the ground?

That's my issue, I don't know whether to use the 36 or the 18.

You use 36. That's what the problem is telling you when it says if ...
 
Is there even a part b)? it would be pointless if you use point 36 for part b) because it would be 100%, of course.
 

Similar threads

Jump Physics: Calculating Flea's Speed, Height & Acceleration
Replies
4
Views
7K
Solve 1-D Kinematic Flea Jump Problem
Replies
6
Views
9K
How high will UT bounce on a bungee jump from the Golden Gate Bridge?
Replies
6
Views
2K
Bungee Jumping Energy (with drag)
Replies
28
Views
4K
Jumping Flea - Simple Kinematics
Replies
1
Views
5K
How Does Gravity Affect Kinetic Energy in a Glider System?
Replies
3
Views
2K
Potential/kinetic/mechanical energy
Replies
7
Views
5K
A ball being hit, find the energies and maximum height
Replies
9
Views
2K
Conservation of Energy - Max height WITH Air resistance
Replies
4
Views
4K
What is the initial velocity of a flea that jumps to a maximum height of 0.550m?
Replies
3
Views
18K

Hot Threads

Recent Insights

Back
Top