Since volume and pressure are inversely related, we can make some assumptions about initial and final states using the data provided. We can also identify initial and final states by finding trigger words in the language of the problem.  Look for words like “first,” “initially,” or “originally” to describe initial states and “result” or “after” for final states.

What volume would a sample of helium occupy at 6.0 atm if the helium was initially compressed in a 1.0 L tank at 20. atm at constant temperature?

Organize your data into the table to help analyze the problem. Leave blank any boxes for which you do not have information.

Drag the appropriate labels to their respective targets.

Transcribed Image Text:

The image depicts a table used to analyze problems in a scientific context involving pressure and volume conditions. ### Interface Buttons Along the top of the image, there is a series of buttons: - **Blue Buttons (Numeric Values):** - 20.0 - 100 - 6.0 - 1.0 - 2.0 - **Pink Buttons (Pressure and Volume Status):** - P decreases - P increases - V decreases - V increases ### Analysis Table The table has five columns and two primary rows for "Pressure" and "Volume," structured as follows: 1. **Analyze the problem**: The label indicating the task at hand. 2. **Initial conditions**: - **Pressure:** Group 1, with a condition set at 1 atm. - **Volume:** Group 1, with a condition set at 1 L. 3. **Final conditions**: - **Pressure:** Group 1, with a condition remaining at 1 atm. - **Volume:** No final condition specified. 4. **Know**: This column indicates known information. - For Pressure: Group 2. - For Volume: Empty, but visually indicates space for Group 2. 5. **Predict**: This column is used for predictions based on initial and final conditions. - For Pressure: Not applicable. - For Volume: Group 2. This setup suggests a comparison or experimental approach to understanding how changes in one group might influence another under controlled conditions.