Difference between revisions of "PChem312 f20 w13"
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===Thursday, Nov 12, 2020=== | ===Thursday, Nov 12, 2020=== | ||
[https://flowcharts.llnl.gov/ LLNL Energy Flow Diagrams website] | [https://flowcharts.llnl.gov/ LLNL Energy Flow Diagrams website] | ||
| + | :''Exam III question: In addition to having to "retrieve" some basic numerical values from these diagrams, you will be asked to write a small paragraph (~1/2 page of text) contrasting some aspect of these diagrams between two or more years. Your paragraph must contain some numerical values and the best answer will include multiple years and an Excel plot representing the data being discussed.'' | ||
| − | Cutting Paper | + | '''Cutting Paper''' |
:[https://youtu.be/4WVLg1tUiKs Stepping Stairs] | :[https://youtu.be/4WVLg1tUiKs Stepping Stairs] | ||
:[https://youtu.be/Jx-y3PZjm9Y 3D words] | :[https://youtu.be/Jx-y3PZjm9Y 3D words] | ||
Revision as of 14:16, 13 November 2020
Monday, Nov 9, 2020
We will now highlight how to calculate entropy (ΔS) for four processes involving ideal gases:
- 1) Reversible Isothermal Expansion or Compression
- ViTi --> VfTi
- 2) Constant P, V temperature change
- ViTi --> ViTf
- PiTi --> PiTf
- 3) Changes in both V and T, constant P
- ViTi -->V fTf
- 4) Changes in both P and T, constant V
- ViTi -->V fTf
Example Problem 1
- (Please write out your complete solution and email to bes by next class period)
Consider a gas undergoing the following change under constant pressure (1.00 bar) conditions; calculate the change in entropy (ΔS): Vi = 10.0 L; Ti = 298 K; Tf = 398 K
Example Problem 2
- (Please write out your complete solution and email to bes by next class period)
Consider a gas undergoing the following change under constant volume (10.0 L) conditions; calculate the change in entropy (ΔS): Pi = 1.00 bar; Ti = 298 K; Tf = 398 K
Wednesday, Nov 11, 2020
- Review contributions to ΔS due to ΔT, ΔV, ΔP for ideal gas/closed system.
- Entropy of Phase Changes...
...continuing numbering from above...
- 5) Solid --> Liquid phase change (fusion/melting/freezing)
- - under constant pressure (ΔH)
- - under constant volume (ΔU)
- For processes involving solids and liquids, ΔH ~ ΔU, hence ΔS is the same for both constant P and constant V.
- 6) Liquid --> gas phase change (vaporization/boiling/condensation)
- - under constant pressure (ΔH)
- - under constant volume (ΔU)
- For processes involving gases, ΔH ≠ ΔU, hence ΔS is not the same for constant P and constant V processes.
- At constant P;
- At constant P;
- At constant V;
- where,
- At constant V;
- and Δn is the change in moles of gas (Products - reactants; ie. increase in the number of moles of gas)
Example Problem 3
(Please write out your complete solution and email to bes by next class period) Poly aromatic hydrocarbons (<-- wiki link here) represent and interesting set of compounds.
Calculate the entropy of fusion for 5 PAHs.
Example Problem 4
(Please write out your complete solution and email to bes by next class period) Calculate the entropy of vaporization for methanol, ethanol, and propanol under both constant pressure and constant volume conditions.
Thursday, Nov 12, 2020
LLNL Energy Flow Diagrams website
- Exam III question: In addition to having to "retrieve" some basic numerical values from these diagrams, you will be asked to write a small paragraph (~1/2 page of text) contrasting some aspect of these diagrams between two or more years. Your paragraph must contain some numerical values and the best answer will include multiple years and an Excel plot representing the data being discussed.
Cutting Paper