A standing wave pattern is created on a string with mass density μ = 3 ×...

A standing wave pattern is created on a string with mass density μ = 3 ×...

A standing wave pattern is created on a string with mass density μ = 3 × 10-4 kg/m. A wave generator with frequency f = 63 Hz is attached to one end of the string and the other end goes over a pulley and is connected to a mass (ignore the weight of the string between the pulley and mass). The distance between the generator and pulley is L = 0.68 m. Initially the 3rd harmonic wave pattern is formed....

A standing wave is set up in a L=2.00m long string fixed at both ends. The...

A standing wave is set up in a L=2.00m long string fixed at both ends. The string vibrates in its 5th harmonic when driven by a frequency f=120Hz source. The mass of the string is m=3.5grams. Recall that 1kg = 1000grams. A. Find the linear mass density of the string B. What is the wavelength of the standing wave C. What is the wave speed D. What is the tension in the string E. what is the first harmonic frequency...

Standing waves on a 1.5-meter long string that is fixed at both ends are seen at...

Standing waves on a 1.5-meter long string that is fixed at both ends are seen at successive (that is, modes m and m + 1) frequencies of 38 Hz and 42 Hz respectively. The tension in the string is 720 N. What is the fundamental frequency of the standing wave? Hint: recall that every harmonic frequency of a standing wave is a multiple of the fundamental frequency. What is the speed of the wave in the string? What is the...

The speed of a wave in a string is given by v = sqrt(FT/μ), where FT...

The speed of a wave in a string is given by v = sqrt(FT/μ), where FT is the tension in the string and μ = mass/length of the string. A 2.00 m long string has a mass of 16.5 g. A 769 g mass is attached to the string and hung over a pulley . The end of the string is then vibrated at a frequency of 129 Hz. Find the wavelength for the wave generated. Give your answer in...

part 1. A 9.00-m long string sustains a three-loop standing wave pattern as shown. The string...

part 1. A 9.00-m long string sustains a three-loop standing wave pattern as shown. The string has a mass of 45 g and under a tension of 50 N. a. What is the frequency of vibration? b. At the same frequency, you wish to see four loops, what tension you need to use. Part 2. a. Determine the shortest length of pipe, open at both ends, which will resonate at 256 Hz (so the first harmonics is 256Hz). The speed...

A student uses a 2.00-m-long steel string with a diameter of 0.90 mm for a standing...

A student uses a 2.00-m-long steel string with a diameter of 0.90 mm for a standing wave experiment. The tension on the string is tweaked so that the second harmonic of this string vibrates at 22.0 Hz . (ρsteel=7.8⋅103 kg/m3) Calculate the tension the string is under. Calculate the first harmonic frequency for this sting. If you wanted to increase the first harmonic frequency by 44 % , what would be the tension in the string?

Use the following data to answer questions Length of string in vibration L = 6.0 meters...

Use the following data to answer questions Length of string in vibration L = 6.0 meters Frequency of the wave (from wave generator) f = 150Hz Linear Density = 3.2 x 10^-3 kg/m Tension = 80N 1. what is the wave speed 2. what is the wavelength 3. number of nodes? 4. number of antinodes? 5. What is the tension needed to produce a standing wave pattern with 9 antinodes?

A student uses a 2.00-m-long steel string with a diameter of 0.90 mm for a standing...

A student uses a 2.00-m-long steel string with a diameter of 0.90 mm for a standing wave experiment. The tension on the string is tweaked so that the second harmonic of this string vibrates at 29.0 Hz . (ρsteel=7.8⋅10^3 kg/m^3) If you wanted to increase the first harmonic frequency by 60 % , what would be the tension in the string?

A distance of 5.60 cm is measured between two adjacent nodes of a standing wave on...

A distance of 5.60 cm is measured between two adjacent nodes of a standing wave on a 28.0 cm-long string. HINT (a) In which harmonic number n is the string vibrating? (b) Find the frequency (in Hz) of this harmonic if the string has a mass of 1.25 ✕ 10−2 kg and a tension of 885 N. Hz

A string with a mass density of 3.6 ? 10-3 kg/m is under a tension of...

A string with a mass density of 3.6 ? 10-3 kg/m is under a tension of 370 N and is fixed at both ends. One of its resonance frequencies is 720 Hz. The next higher resonance frequency is 840 Hz. (a) What is the fundamental frequency of this string? ______Hz (b) Which harmonics have the given frequencies? (Enter 1 for the first harmonic, 2 for the second harmonic, etc.) 720 Hz 840 Hz (c) What is the length of the...