4. Check the "Rulers" button. You should have the following settings for the wave: Amplitude 0.75...
4. Check the "Rulers" button. You should have the following settings for the wave. Amplitude = 0.75 cm, frequency = 1.5 Hz, Tension-medium. O Fxed End O Loose End C) No End Restart Manual Osolate Pulse 2 4 O Slow Motion Norma Frequency (q)( 0.75 cm ) Damping Tension Rulers Lots Low HighTmr 1.50 Hz Reterence Uine change the Tension to high. 9. The speed of a wave in a string is not affected by frequency or amplitude: it is...
Restart the PhET simulation and set it up in the following manner: select Oscillate, select No End, and use the parameters in parentheses by sliding the bars for Amplitude (1.00 cm), Frequency (1.40 Hz ), Damping (none), and tension (highest). Using the available Rulers, calculate the frequency of a photon that corresponds to the wavelength of the resulting wave. Assume the length with units (cm) of the ruler represents the real the photon wavelength and that the speed of light...
Restart the PhET simulation and set it up in the following manner: select Oscillate, select No End, and use the parameters in parentheses by sliding the bars for Amplitude (1.00 cm), Frequency (1.00 Hz ), Damping (none), and tension (highest). Using the available Rulers, calculate the frequency of a photon that corresponds to the wavelength of the resulting wave. Assume the length with units (cm) of the ruler represents the real the photon wavelength and that the speed of light...
1. Find the velocity of an electron emitted by a metal whose threshold frequency is 2.18×1014 s−1 when it is exposed to visible light of wavelength 4.80×10−7 m . 2. Water is exposed to infrared radiation of wavelength 2.9×10−4 cm . Assume that all the radiation is absorbed and converted to heat. How many photons will be required to raise the temperature of 2.0 g of water by 2.2 K ? 3. Reset the PhET simulation (using the button in...
10-15 pls 010 10.0 points A sinusoidal transverse wave travels along a wire of linear density 8.34 g/m. The wave has amplitude 1.2 cm, frequency 132 Hz and wavelength 3.07 m What is the tension of the wire? Answer in units of N 011 (part 1 of 2) 10.0 points A standing wave is formed on a string that is 32 m long, has a mass per unit length 0.00512 kg/m, and is stretched to a tension of 18 N...
PLEASE ANSWER BOTH AND SHOW ALL WORK 2. The diagram next page shows a wavelength squared (m2) vs tension (N) plot for a stressed string ; similar to what you have done in lab 9. 1.4 1.2 y:0.5323x+0.009 R2 = 0.9966 0.8 0.6 0.4 0.2 0 0.5 1.5 2.5 1) Complete the diagram above by putting correct axes titles with proper units. (2) Il) If the string has a mass of 2.88 grams per 700 cm, what is the frequency...
#4 (will rate) 1) The fundamental frequency of a pipe that is open at both ends is 611 Hz. (Let the speed of sound be 344 m/s.) (a) How long is this pipe? (b) If one end is now closed, find the wavelength of the new fundamental. (c) If one end is now closed, find the frequency of the new fundamental. 2) A piano tuner stretches a steel piano wire with a tension of 800 N. The steel wire is...
DQuestion 5 1 pts A simple harmonic oscillator at the point x-0 generates a wave on a horizontal rope. The oscillator operates at a frequency of 40.0 Hz and with an amplitude of 3.00 cm. The rope has a linear mass density of 50.0 g/m, and is stretched with a tension of 5.00 N. Find the maximum transverse acceleration of points on the rope, in m/s? Sample submission: 1230 Note: your answer should be much larger than g. which is...
question 4-7 4. Travelling Waves and Their Characteristics A rope wave travels in the positive x -direction. You are also told that the speed of the wave is 1000 cm/s, its frequency is 200 Hz, and that the wave is subject to the following initial conditions: at x 0 and t = 0: y =-1 cm, and, at x = 0 and t : ar = +20 cm/s (this is the velocity of the point on the rope at horizontal...
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....