This is How do I solve the nodes and antinodes for this problem?

[riseofphoenix]

HELP! This is URGENT! How do I solve the nodes and antinodes for this problem??

For nodes, I tried doing λ = 2L/n but it's not giving me the answers they got... please help!

 

[H.fulls]

Okay so check this diagram out
http://www.physicsclassroom.com/mmedia/waves/h3.gif
Thats a 3rd harmonic...
So you've got 4 nodes where the string is not moving at all, and 3 antinodes of maximum displacement.
Its fixed at each end, so 0m and 9m must be nodes! They can't move if there being held there. So youve got 2 in between , they must be equally spaced so theyve got to be at 3m and 6m. (Maths way to do this is length/harmonic = 9/3 = 3, got to be spaced 3m apart)
You know that the antinodes must be halfway between these nodes, so they have to be at 1.5, 4.5 and 7.5! This is length/2*harmonic.

For the frequency...
velocity = root(tension/(mass/length))
and then to get the frequency this must be divided by twice the length :)
Hope you understood all that!

 

[H.fulls]

sorry that's v = \sqrt{\frac{T}{M/L}}

so

f = \frac{\sqrt{\frac{T}{M/L}}}{2L}

 

[PeterO]

For nodes, I tried doing λ = 2L/n but it's not giving me the answers they got... please help!

That equation gives you the correct answer, but you then interpreted incorrectly.

The modes of vibration of a string represent STANDING WAVES on the string. The wavelength of a standing wave is 1/2 the wavelength of the traveling wave "causing" the standing wave.

Your formula gives λ = 6m. That is the traveling wave λ

So the wavelength of the standing wave is 3m

The first node is at the fixed end where you start. The next ones are every 3 m from there - until you have reached the other end.

The anti-nodes are halfway between each of those nodes