Part B Are the air molecules moving horizontally or vertically? The air molecules are moving horizontally. The air molecules are moving vertically. Submit Correct Part C Previous Answers At what distances from the left end of the tube do the molecules oscillate with maximum amplitude? Express your answer in centimeters. If there is more than one answer, enter your answers in ascending order separated by commas. 1 = 0,16,32 cm Submit Part D Previous Answers Correct At what distances from the left end of the tube does the air pressure oscillate with maximum amplitude? Express your answer in centimeters. If there is more than one answer, enter your answers in ascending order separated by commas. 195) ΑΣΦ 1=0,16,32 ? cm

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ISBN:9781305952300
Author:Raymond A. Serway, Chris Vuille
Publisher:Raymond A. Serway, Chris Vuille
Chapter1: Units, Trigonometry. And Vectors
Section: Chapter Questions
Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...
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### Educational Website Transcript

---

#### Part B

**Question:**
Are the air molecules moving horizontally or vertically?

**Options:**
- The air molecules are moving horizontally.
- The air molecules are moving vertically.

**Answer:**
- The air molecules are moving horizontally.

**Status:**
- **Correct**

---

#### Part C

**Question:**
At what distances from the left end of the tube do the molecules oscillate with maximum amplitude?

**Instruction:**
Express your answer in centimeters. If there is more than one answer, enter your answers in ascending order separated by commas.

**Answer:**
\( l = 0, 16, 32 \) cm

**Status:**
- **Correct**

---

#### Part D

**Question:**
At what distances from the left end of the tube does the air pressure oscillate with maximum amplitude?

**Instruction:**
Express your answer in centimeters. If there is more than one answer, enter your answers in ascending order separated by commas.

**Answer:**
\( l = 0, 16, 32 \) cm

**Status:**
- (Pending indication but submission areas available)

**Options:**
- Submit
- Previous Answers
- Request Answer

**Answer Input Interface:**
- Clearly, a specialized interface for inputting complex notations and symbols.
  
---
Transcribed Image Text:### Educational Website Transcript --- #### Part B **Question:** Are the air molecules moving horizontally or vertically? **Options:** - The air molecules are moving horizontally. - The air molecules are moving vertically. **Answer:** - The air molecules are moving horizontally. **Status:** - **Correct** --- #### Part C **Question:** At what distances from the left end of the tube do the molecules oscillate with maximum amplitude? **Instruction:** Express your answer in centimeters. If there is more than one answer, enter your answers in ascending order separated by commas. **Answer:** \( l = 0, 16, 32 \) cm **Status:** - **Correct** --- #### Part D **Question:** At what distances from the left end of the tube does the air pressure oscillate with maximum amplitude? **Instruction:** Express your answer in centimeters. If there is more than one answer, enter your answers in ascending order separated by commas. **Answer:** \( l = 0, 16, 32 \) cm **Status:** - (Pending indication but submission areas available) **Options:** - Submit - Previous Answers - Request Answer **Answer Input Interface:** - Clearly, a specialized interface for inputting complex notations and symbols. ---
### Analysis of Standing Sound Waves in a Horizontal Tube

In this section, we will explore the displacement of standing sound waves in a horizontal tube of air that is open at both ends. The tube in question is 32 centimeters long.

#### Displacement of Standing Sound Waves
Standing sound waves occur when two waves of the same frequency and amplitude travel in opposite directions and interfere with each other. This results in a wave pattern that appears to be standing still, hence the name "standing wave."

(Figure 1) illustrates the displacement \(D\) of a standing sound wave in the specified 32 cm-long horizontal tube.

##### Description of Figure 1
The graph in Figure 1 displays the displacement \(D\) (vertical axis) versus the position \(x\) (horizontal axis in centimeters) along the length of the tube. Key features of the graph include:

- **Nodes and Antinodes**: The graph depicts points of zero displacement called nodes, and points of maximum displacement called antinodes. There is a clear pattern of nodes and antinodes over the 32 cm length.
- **Wave Pattern**: The wave pattern shows two full wavelengths within the 32 cm tube. This is indicative of the wave behavior in a tube open at both ends, where the standing wave has a node at each end and one or more antinodes in between.

This visualization helps in understanding the nature of standing sound waves and how they are influenced by the dimensions and boundary conditions of the tube in which they form.
Transcribed Image Text:### Analysis of Standing Sound Waves in a Horizontal Tube In this section, we will explore the displacement of standing sound waves in a horizontal tube of air that is open at both ends. The tube in question is 32 centimeters long. #### Displacement of Standing Sound Waves Standing sound waves occur when two waves of the same frequency and amplitude travel in opposite directions and interfere with each other. This results in a wave pattern that appears to be standing still, hence the name "standing wave." (Figure 1) illustrates the displacement \(D\) of a standing sound wave in the specified 32 cm-long horizontal tube. ##### Description of Figure 1 The graph in Figure 1 displays the displacement \(D\) (vertical axis) versus the position \(x\) (horizontal axis in centimeters) along the length of the tube. Key features of the graph include: - **Nodes and Antinodes**: The graph depicts points of zero displacement called nodes, and points of maximum displacement called antinodes. There is a clear pattern of nodes and antinodes over the 32 cm length. - **Wave Pattern**: The wave pattern shows two full wavelengths within the 32 cm tube. This is indicative of the wave behavior in a tube open at both ends, where the standing wave has a node at each end and one or more antinodes in between. This visualization helps in understanding the nature of standing sound waves and how they are influenced by the dimensions and boundary conditions of the tube in which they form.
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