Question

12. Given that the endpoints of the slinky must remain still (nodes), why is it not possible to place a wave with any arbitrary wavelength on the string? 13. What is the simplest standing wave pattern that could be fit on the slinky? 14. Wh at is the relationship between the slinky length L and the wavelength for this case? 15. What is the next simplest standing wave pattern that can be fit on the slinky? 16. What is the relationship between the slinky length L and the wavelength in this case? 17. Try to develop a general formula for the allowed wavelengths for standing waves on the slinky with both ends fixed.
0 0
Add a comment Improve this question Transcribed image text
Know the answer?
Add Answer to:
12. Given that the endpoints of the slinky must remain still (nodes), why is it not...
Your Answer:

Post as a guest

Your Name:

What's your source?

Earn Coins

Coins can be redeemed for fabulous gifts.

Not the answer you're looking for? Ask your own homework help question. Our experts will answer your question WITHIN MINUTES for Free.
Similar Homework Help Questions
  • I don't know how much help you can give me but if you can please help...

    I don't know how much help you can give me but if you can please help answer 5-8! TIA Shake the non-fixed end of the slinky to create a standing wave.  If you do this on the floor, it would be best to have a hard surface, so the slinky is not sliding against carpet.  Practice until you are able to produce standing waves with two nodes(at the two ends), three nodes (two at the ends and one in the middle), and...

  • Problem 4 [8 pts] A long pipe, length L, is closed at both ends, and filled...

    Problem 4 [8 pts] A long pipe, length L, is closed at both ends, and filled with a gas with speed of sound v. The pipe is excited in some fashion in order to produce standing waves. (a) Sketch the standing wave pattern for the four lowest frequencies supported by this pipe. Label the nodes and antinodes. (b) Make a table of the wavelengths and frequencies of the sound waves that are formed by these four excitations, in terms of...

  • Standing Waves in a Pipe - Both Ends Open Pattern (a) Pattern (b) Pattern (c) Pattern...

    Standing Waves in a Pipe - Both Ends Open Pattern (a) Pattern (b) Pattern (c) Pattern (d) The above figure shows standing wave patterns in a pipe whose left end is closed but the right end is open in all the patterns, the length of the pipe L = 2.10 m. The speed of sound in air is 343 m/s. You will find the wavelengths and frequencies of these standing wave patterns. (C) In Pattern (c), What is the wavelength?...

  • 12. A longitudinal standing wave can be created in a long, thin aluminum rod by stroking...

    12. A longitudinal standing wave can be created in a long, thin aluminum rod by stroking the rod with very dry fingers. This is often done as a physics demonstration, creating a high-pitched, very annoying whine. From a wave perspective, the standing wave is equivalent to a sound standing wave in an open-open tube. In particular, both ends of the rod are anti-nodes. What is the fundamental frequency of a 2.50 m -long aluminum rod? The speed of sound in...

  • A rope is fixed at both ends and under a tension of 100 N (where N...

    A rope is fixed at both ends and under a tension of 100 N (where N is the symbol for newton, transverse displacement of the rope, in metres, is given by y = (0.5) sin ( x) cos | 4 1 + 100) t where x is distance along the rope in metres, x = 0 at one end of the rope, t is time in seconds, and N 17 (a) What are (i) the length of the rope, (ii...

  • please answer all pre-lab questions 1 through 5. THANK YOU!!! this is the manual to give...

    please answer all pre-lab questions 1 through 5. THANK YOU!!! this is the manual to give you some background. the pre-lab questions.. the pre-lab sheet. Lab Manual Lab 10: String Waves & Resonance Before the lab, read the theory in Sections 1-3 and answer questions on Pre-lab Submit your Pre-lab at the beginning of the lab. During the lab, read Section 4 and follow the procedure to do the experiment. You will record data sets, perform analyses, answer questions, and...

  • Pre-Lab for LAB#11 Waves in air may be represented by oscillations of air molecules or of...

    Pre-Lab for LAB#11 Waves in air may be represented by oscillations of air molecules or of air pressure. When representing standing waves in air, displacement nodes correspond to pressure antinodes (places of greatest pressure variation), and displacement antinodes correspond to pressure nodes (places of least pressure variation). Problem Consider a pipe that is closed at one end. Sketch the standing wave pattern in each of the following situations to show the regions of greatest and least air pressure variations (pressure...

  • The experiment has not been done yet. I am not sure where to get the value...

    The experiment has not been done yet. I am not sure where to get the value for lambda? 146 Sound Resonance in a Tube Overview Sound waves are considered longitudinal waves. That is, the molecules (air molecules for instance) will oscillate about their equilibrium positions in the direction of the wave (disturbance). If a tuning fork vibrates and held over an open ended tube, which is closed at the bottom, it will send a sound wave down the tube. This...

  • Can you help me to do the calculation and graph for two tables? thank you mass...

    Can you help me to do the calculation and graph for two tables? thank you mass = 100g ANALYSIS AND QUESTIONS: 1. Plot a graph of the wavelength versus the inverse of the frequency, 11f. Draw a "best-fit" straight line and determine the slope. 2. Determine the tension of the string from knowledge of the slope. 3. Compute the velocity v of the wave in the string using Eqn. (2). 4. As the frequency is increased, what happens to the...

  • Question 4 to 11 plz Dr? Standing Waves on a String Physics Topics If necessary, review...

    Question 4 to 11 plz Dr? Standing Waves on a String Physics Topics If necessary, review the following topics and relevant textbook sections from Serway / Jewett "Physics for Scientists and Engineers", 9th Ed. • Mathematics of Traveling Waves (Serway 17.2) • Speed of Waves on a String (Serway 17.3) • Superposition of Waves (Serway 18.1) • Standing Waves on a string (Serway 18.2, 18.3) Introduction Imagine two sinusoidal traveling waves with equal amplitudes and frequencies moving in opposite directions....

ADVERTISEMENT
Free Homework Help App
Download From Google Play
Scan Your Homework
to Get Instant Free Answers
Need Online Homework Help?
Ask a Question
Get Answers For Free
Most questions answered within 3 hours.
ADVERTISEMENT
ADVERTISEMENT