SEMESTER LEARNING PLAN
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Course Title: Inorganic Synthesis (SAno)
MK code: AKM21 458
Credit Weight: 2
Group of Courts: elective
Semester: 5
Prerequisite Course: KAno3
Lecturer:
Drs. Suhartana, Msi
Dra. Sriyanti, MS
Pardoyo, SSi. Msi
Graduate Learning Outcomes (GLO)
| Attitude | GLO1-(S9) | Demonstrate an attitude of responsibility for work in their field of expertise independently. |
| Knowledge | GLO2-(PP1) | Mastering theoretical concepts about the properties of a compound based on its structure and constituent elements |
| GLO2-(PP2) | Mastering complete operational knowledge about functions, how to operate general chemical instruments, and analysis of data and information from these instruments | |
| General Skills | GLO3-(KU1) | Able to apply logical, critical, systematic, and innovative thinking in the development or implementation of science and technology that pays attention to and uses humanities values by their field of expertise |
| Special Skills | GLO4-(KK1) | Able to produce appropriate conclusions based on the identification, analysis, isolation, transformation, and synthesis of chemicals that have been carried out |
| GLO5-(KK3) | Able to analyze several alternative solutions in identification, analysis, isolation, transformation, and synthesis of available chemicals and present analysis conclusions for appropriate decision making |
Course Description
This course underlies the courses in inorganic which generally discuss: A brief overview of the Principles of Material Synthesis. The factors that influence it. Application of thermodynamic data for prediction of material synthesis, both spontaneous and kinetic. Synthesis Basic Techniques,The Impact of Solvents on Synthesis. Attempts to increase reaction yield. Inert state manipulation technique in atmospheric conditions. As well as synthesis techniques in a vacuum state. Effect of temperature and catalyst on reaction rate. Temperature measurement settings and techniques at low temperatures. Inert state manipulation technique in atmospheric conditions. As well as synthesis techniques in a vacuum state. Materials synthesis technique using electricity. Examples of synthesis / treatment in several Indonesian factories. Purification of CuSO4 and NaCl salts, Synthesis of MgSO4 salts. MgCl2 salt synthesis, Na3PO4 salt synthesis, Na2SO4, Na2CO3 and NaHPO4. High Pressure Apparatus, Photochemical Synthesis. Liquid-liquid Extraction. Compound Characterization, Chemical analysis and Elementary Physical Methods. Group discussion, discussing several Material Syntheses in groups, starting with a thermodynamic approach, optimizing results,and analysis of synthesis results (both qualitative and quantitative).
| Week | Expected ability (Sub-CLO) | Study Materials/ Learning Materials | Learning methods | Student Learning Experience | Time (minutes) | Evaluation | |
| Criteria and Indicators | % | ||||||
| 1 | Mastering the theoretical concepts of Natural Science (K1), Able to describe (C1) about: A brief overview of the Principles of Material Synthesis. Factors that influence it. | Explanation of syllabus and lecture contracts.
Introduction: A brief overview of the Principles of Material Synthesis, Factors that affect/accelerate the rate of Material Synthesis. |
Discovery learning
Cooperative learning |
Discussion, describing: Explaining (C2) about a brief overview of the Principles of Material Synthesis. The factors that influence it. | FF: 1 x (2 x 50”)
ST + SS: 1 x [(2 x 50”) + (2 x 60”)] |
Accuracy in explaining (C2) , Brief overview of the Principles of Material Synthesis, Factors that affect it, with an accuracy of at least 80%. | 5 |
| 2 | Mastering the theoretical concepts of Natural Science (K1), Able to describe (C1) about: Application of thermodynamic data for prediction of the synthesis of a material. | Application of thermodynamic data for prediction of the synthesis of a material | Discovery learning
Cooperative learning |
Discussion, describing: Explaining (C2) Application of thermodynamic data for prediction of the synthesis of a material | FF: 1 x (2 x 50”)
ST + SS: 1 x [(2 x 50”) + (2 x 60”)] |
Accuracy in explaining (C2) Application of thermodynamic data for prediction of the synthesis of a material, with a minimum accuracy of 80%, | 10 |
| 3 | Mastering the theoretical concepts of Natural Science (K1), Able to describe (C1) about: Application of Thermodynamic Data for Prediction of kinetic aspects for Material Synthesis | Application of Thermodynamic Data for Prediction of kinetic aspects for Material Synthesis | Discovery learning
Cooperative learning Problem Based Learning |
Discussion, describing: Explaining (C2) Application of thermodynamic data for prediction of the synthesis of a material | FF: 1 x (2 x 50”)
ST + SS: 1 x [(2 x 50”) + (2 x 60”)] |
Accuracy in explaining (C2) Application of thermodynamic data for prediction of the synthesis of a material, with a minimum accuracy of 80%, | 5 |
| 4 | Mastering the theoretical concepts of Natural Science (K1), Able to describe (C1) about: Basic Techniques of Synthesis, Impact of Solvents on Synthesis. Attempts to increase reaction yield | Basic Synthetic Techniques | Discovery learning
Cooperative learning Problem Based Learning |
Discussion, describing: Explaining (C2) Basic Techniques of Synthesis, Impact of Solvents on Synthesis. Attempts to increase reaction yield | FF: 1 x (2 x 50”)
ST + SS: 1 x [(2 x 50”) + (2 x 60”)] |
Accuracy in explaining (C2), Basic Synthesis Techniques, Impact of Solvents on Synthesis. Attempts to increase the reaction yield, with an accuracy of at least 80%. | 5 |
| 5 | Mastering the theoretical concepts of Natural Science (K1), Able to describe (C1) about: the effect of temperature on the rate of reaction. Temperature measurement settings and techniques at low temperatures. | Effect of temperature on reaction rate | Discovery learning
Cooperative learning Problem Based Learning |
Discussion, describing: Explaining (C2) about the effect of temperature on the rate of reaction. Temperature measurement settings and techniques at low temperatures. | FF: 1 x (2 x 50”)
ST + SS: 1 x [(2 x 50”) + (2 x 60”)] |
Accuracy in explaining (C2), about the effect of temperature on the rate of reaction. Temperature measurement settings and techniques at low temperatures. , with an accuracy of at least 80%. | 5 |
| 6 | Mastering the theoretical concepts of Natural Science (K1), Able to describe (C1) about: Inert state manipulation techniques in atmospheric conditions. As well as synthesis techniques in a vacuum state | Manipulation technique of the inactive state in atmospheric conditions. As well as synthesis techniques in a vacuum state | Discovery learning
Cooperative learning Problem Based Learning |
Discussion, describing: Explaining (C2) Inert state manipulation technique in atmospheric conditions. As well as synthesis techniques in a vacuum state. | FF: 1 x (2 x 50”)
ST + SS: 1 x [(2 x 50”) + (2 x 60”)] |
Accuracy in explaining (C2) , Inert state manipulation technique in atmospheric conditions. As well as synthesis techniques in a vacuum state. , with an accuracy of at least 80%. | 5 |
| 7 | Mastering the theoretical concepts of Natural Science (K1), Able to describe (C1) about:Materials Synthesis Techniques using Electricity. | Material Synthesis Techniques using Electricity | Discovery learning
Cooperative learning Problem Based Learning |
Discussion, describing: Explaining (C2) Discussion, describing: Explaining (C2) Material Synthesis Techniques using electricity | FF: 1 x (2 x 50”)
ST + SS: 1 x [(2 x 50”) + (2 x 60”)] |
Accuracy in explaining (C2), Material Synthesis Techniques using electricity, with a minimum accuracy of 80% | 5 |
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8
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Midterm exam | Written exam | 90 | The truth and completeness of the answer to the question | ||
| 9 | Mastering the theoretical concepts of Natural Science (K1), Able to describe (C1) | Synthesis/treatment at several Indonesian factories. Phosphoric acid manufacture. Manufacture of nitric acid, Manufacture of vinegar, Manufacture of sulfuric acid, and Manufacture of oxalic acid | Discovery learning
Cooperative learning Problem Based Learning |
Discussion, describing: Explaining (C2) | FF: 1 x (2 x 50”)
ST + SS: 1 x [(2 x 50”) + (2 x 60”)] |
Accuracy in explaining (C2), with an accuracy of at least 80% | 10 |
| 10 | Mastering the theoretical concepts of Natural Science (K1), Able to describe (C1) about Purification of CuSO4 and NaCl salts, Synthesis of MgSO4 salts. MgCl2 salt synthesis, Na3PO4 salt synthesis, Na2SO4, Na2CO3, and NaHPO4 | Purification of CuSO4 and NaCl salts, Synthesis of MgSO4 salts. MgCl2 salt synthesis, Na3PO4 salt synthesis, Na2SO4, Na2CO3, and NaHPO4 | Discovery learning
Cooperative learning Problem Based Learning |
Discussion, describing: Explaining (C2) Purification of CuSO4 and NaCl salts, Synthesis of MgSO4 salts. MgCl2 salt synthesis, Na3PO4 salt synthesis, Na2SO4, Na2CO3, and NaHPO4 | FF: 1 x (2 x 50”)
ST + SS: 1 x [(2 x 50”) + (2 x 60”)] |
Accuracy in explaining (C2) , Purification of CuSO4 and NaCl salts, Synthesis of MgSO4 salts. MgCl2 salt synthesis, Na3PO4 salt synthesis, Na2SO4, Na2CO3, and NaHPO4 with an accuracy of at least 80% | 10 |
| 11 | Mastering the theoretical concepts of Natural Science (K1), Able to describe (C1) about High-pressure Apparatus, Photochemical Synthesis. Liquid-liquid Extraction | High-pressure Apparatus, Photochemical Synthesis. Liquid-liquid Extraction | Discovery learning
Cooperative learning Problem Based Learning |
Discussion, describing: Explaining (C2) High-pressure Apparatus, Photochemical Synthesis. Liquid-liquid Extraction | FF: 1 x (2 x 50”)
ST + SS: 1 x [(2 x 50”) + (2 x 60”)] |
Accuracy in explaining (C2) , High-pressure Apparatus, Photochemical Synthesis. Liquid-liquid Extraction with an accuracy of at least 80% | 10 |
| 12 | Mastering the theoretical concepts of Natural Science (K1), Able to describe (C1) about Compound Characterization, Chemical analysis, and Elementary Physical Methods | Compound Characterization, Chemical analysis, and Elementary Physical Methods | Discovery learning
Cooperative learning Problem Based Learning |
Discussion, describing: Explaining (C2) Compound Characterization, Chemical analysis, and Elementary Physical Methods | FF: 1 x (2 x 50”)
ST + SS: 1 x [(2 x 50”) + (2 x 60”)] |
Accuracy in explaining (C2) , Compound Characterization, Chemical analysis, and Elementary Physical Methods with an accuracy of at least 80% | 10 |
| 13 | Mastering the theoretical concepts of Natural Science (K1), Able to describe (C1) about Compound Characterization, AAS, IR and UV Spectroscopy, XRD and SEM | Compound Characterization, AAS, IR and UV Spectroscopy, XRD and SEM | Discovery learning
Cooperative learning Problem Based Learning |
Discussion, describing: Explaining (C2) Compound Characterization, AAS, IR and UV Spectroscopy, XRD and SEM | FF: 1 x (2 x 50”)
ST + SS: 1 x [(2 x 50”) + (2 x 60”)] |
Accuracy in explaining (C2) , Compound Characterization, AAS, IR and UV Spectroscopy, XRD and SEM with an accuracy of at least 80% | 10 |
| 14 | Mastering the theoretical concepts of Natural Science (K1), Able to describe (C1) about Material Syntheses in groups, starting with a thermodynamic approach, optimizing the results, and analyzing the results of the synthesis (part I) | Group discussion, discussing several Material Syntheses in groups, starting with a thermodynamic approach, optimizing the results, and analyzing the results of the synthesis (part I) | Discovery learning
Cooperative learning Problem Based Learning |
Discussion, describing: Explaining (C2) Material Syntheses in groups, starting with a thermodynamic approach, optimizing the results, and analyzing the results of the synthesis | FF: 1 x (2 x 50”)
ST + SS: 1 x [(2 x 50”) + (2 x 60”)] |
Accuracy in explaining (C2) , Material Syntheses in groups, starting with a thermodynamic approach, optimizing the results, and analyzing the results of the synthesis with an accuracy of at least 80% | 5 |
| 15 | Mastering the theoretical concepts of Natural Science (K1), Able to describe (C1) about Material Syntheses in groups, starting with a thermodynamic approach, optimizing the results, and analyzing the results of the synthesis (part II) | Group discussion, discussing several Material Syntheses in groups, starting with a thermodynamic approach, optimizing the results, and analyzing the results of the synthesis (part II) | Discovery learning
Cooperative learning Problem Based Learning |
Discussion, describing: Explaining (C2) Material Syntheses in groups, starting with a thermodynamic approach, optimizing the results, and analyzing the results of the synthesis | FF: 1 x (2 x 50”)
ST + SS: 1 x [(2 x 50”) + (2 x 60”)] |
Accuracy in explaining (C2) , Material Syntheses in groups, starting with a thermodynamic approach, optimizing the results, and analyzing the results of the synthesis with an accuracy of at least 80% | 5 |
| 16 | Final exams | Written exam | 90 | The truth and completeness of the answer to the question | |||
Reference:
- Jolly WL., The Synthesis and Characterization of Inorganic Compounds, Prentice hall Inc, 1978, New york.
- Wilberg, KB., 1967, Laboratory technique in Organic Chemistry, Mc Grawhill Book Company, New York.
- Calvert,JG., and Pitts, JN., 1967. Photochemistry, John Wiley & Sons Inc, New York.
Glossary
GLO = Graduate Learning Outcome
CLO = Course Learning Outcomes
FF = Face to Face Learning
ST = Structured tasks
SS = Self Study
