String 1 in the figure has linear density 2.50 g/m and string 2 has linear density 3.20 g/m. A student sends pulses in both directions by quickly pulling up on the knot, then releasing it. She wants both pulses to reach the ends of the strings simultaneously. (Figure 1) Figure Part A What should the string length L be? Express your answer with the appropriate units. Value Submit Part B μA Value Submit What should the string length L₂ be? Express your answer with the appropriate units. Units Request Answer Units Request Answer ?

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**Transcription for Educational Webpage** --- **String Properties and Pulse Experiment** String 1 in the figure has a linear density of 2.50 g/m and string 2 has a linear density of 3.20 g/m. A student sends pulses in both directions by quickly pulling up on the knot, then releasing it. She wants both pulses to reach the ends of the strings simultaneously. **Questions:** **Part A** - What should the string length \( L_1 \) be? - Express your answer with the appropriate units. [Input Box for Value] [Dropdown for Units] [Submit Button] [Request Answer] **Part B** - What should the string length \( L_2 \) be? - Express your answer with the appropriate units. [Input Box for Value] [Dropdown for Units] [Submit Button] [Request Answer] **Figure Explanation:** The accompanying figure illustrates two strings connected by a knot. - **String 1** is on the left side and is 4 meters long. - **String 2** is on the right side, with its length shown as \( L_2 \). - The figure depicts the strings laid flat, with a knot in between. The goal is to determine the appropriate lengths for \( L_1 \) and \( L_2 \) so that the wave pulses reach the ends of the strings at the same time. [Provide Feedback]