below (Figure 1). You may want to reference (Pages 254 - 266) Section 6.3 while completing this problem. Part A How many pi bonds are present in acetylsalicylic acid? ? T bond(s) Part B Figure 1 of 1 How many sigma bonds are present? HO o bond(s) HC °C' c=0 HC, CH CH3 `CH

Please answer question 18 Part A, B, and C

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### Educational Content on Acetylsalicylic Acid's Chemical Bonds #### Reference Guidance For a comprehensive understanding of this problem, you may want to reference pages 254 to 266, specifically Section 6.3. #### Chemical Structure Illustration **Figure 1:** - Depicted in the figure is the chemical structure of acetylsalicylic acid, also known commonly as aspirin. The structure includes various atoms connected with lines representing bonds: - Carbon atoms (C) are connected forming a benzene ring and side chains. - Oxygen atoms (O) and Hydrogen atoms (H) are also part of the molecular structure. - The structure displays different types of bonds, including double bonds typically found in carbonyl groups and aromatic rings. #### Exercises on Chemical Bonds **Part A: Pi Bonds** - **Question**: How many pi bonds are present in acetylsalicylic acid? - **Answer Box**: [Input field for the number of π bond(s)] **Part B: Sigma Bonds** - **Question**: How many sigma bonds are present? - **Answer Box**: [Input field for the number of σ bond(s)] This exercise aims to help students identify and distinguish between pi (π) and sigma (σ) bonds within the molecular structure of acetylsalicylic acid. Understanding these chemical bonds is crucial for comprehending the compound's properties and reactions.

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### Part C **Question:** Which parts of acetylsalicylic acid are rigid? Options: - [ ] the C—O bonds - [ ] the ring structure - [ ] the C—C bonds - [ ] the C—H bonds - [ ] the C=O bonds This question focuses on understanding the structural rigidity in the molecular structure of acetylsalicylic acid (commonly known as aspirin). Different types of chemical bonds and structural features can impart varying degrees of rigidity to the molecule.