- Prove the reversibility of a reaction
- Show how temperature affects a reaction's equilibrium
| Substance | Concentration | Amount |
|---|---|---|
| K2CrO4 | 0.1 M | as needed |
| CH3COOH | 0.1 M | as needed |
| NaOH | 0.1 M | as needed |
| NaCl | - | 5 gr |
| CuSO4 | 0.1M | 100 ml |
| Frozen H2O | - | a bucket |
| Item | Quantity |
|---|---|
| Test tube | 3 |
| Test tube rack | 1 |
| Graduated cylinder (100 ml) | 1 |
| Beaker (250 ml) | 1 |
| Spatula | 1 |
| Stirring rod | 1 |
| Digital scale | 1 |
| Lighter | 1 |
| Bunsen burner | 1 |
| Tripod | 1 |
| Mesh | 1 |
- Proving the reversibility of reactions
- Measure 5 ml of K2CrO4 into a test tube
- Measure another 5 ml into another tube for control
- Slowly add CH3COOH into one of the test tubes
- Observe the color difference between the tubes
- Slowly add NaOH into the same test tube
- Observe the color revert back to the original
- Showing how temperature affects equilibrium point
- Measure 5 gr of NaCl into a beaker
- Pour 100 ml of CuSO4 into the beaker
- Stir
- Pour a bit into a clean test tube for control
- Heat up the beaker (make sure no water evaporates)
- Observe color change
- Cool down the beaker
- Observe the color revert
- Reaction reversibility
- CrO42- + H+ ⇋ Cr2O72- + H2O
- When adding CH3COOH
- CH3COOH → CH3COO- + H+
- When adding NaOH
- NaOH → Na+ + OH-
- H+ + OH- → H2O
- Effects of temperature
- [Cu(H2O)6]2+ + 4Cl- ⇋ [CuCl4]2- + 6H2O; ∆H = +
- To observe the rise in boiling point on electrolytes and non-electrolytes when compared with water
| Substance | Concentration | Amount |
|---|---|---|
| Distilled water | - | 50 ml |
| NaCl solution | 0.01 M | 50 ml |
| Urea solution | 0.01 M | 50 ml |
| Sucrose solution | 0.01 M | 50 ml |
| Item | Quantity |
|---|---|
| Lighter | 1 |
| Bunsen burner | 2 |
| Tripod | 2 |
| Mesh | 2 |
| Thermometer | 2 |
| Wooden clamp | 2 |
| Graduated cylinder (100 ml) | 2 |
| Beaker (250 ml) | 2 |
| Beaker (200 ml) | 1 |
For each sample to be tested:
- Pour roughly 50 ml of the sample into a 200 ml beaker
- Transfer to a graduated cylinder, then add or remove the sample until it is exactly 50 ml
- Transfer to a 250 ml beaker
- Place the beaker on a heater, and use the wooden clamp to hold the thermometer in place
- Note down the highest temperature
- To be able to write and determine electrolytic reactions in the anode and cathode
- To be able to discern between inert and non-inert electrodes
| Substance | Concentration | Amount |
|---|---|---|
| CuSO4 | 0.5 M | as needed |
| KI | 0.5 M | as needed |
| Phenolphthalein | - | as needed |
| Amilum | - | as needed |
| Item | Quantity |
|---|---|
| Clamps, stands, and support | 1 |
| U-tube | 1 |
| Carbon electrode | 2 |
| Battery (9 volts) | 1 |
| Wires with alligator clips | 2 |
| Test tubes | 4 |
| Test tube rack | 1 |
| Digital scale | 1 |
| Pipette | 4 |
| Beaker (100 ml) | 2 |
| Litmus paper (blue) | 1 pack |
| Litmus paper (red) | 1 pack |
-
First experiment
- Connect battery to carbon electrodes via alligator wires
- Clamp U-tube in place, both openings facing upwards
- Pour KI into a beaker
- Transfer into the U-tube until about half full
- Place the electrodes in both openings of the U-tube
- Observe as yellow Iodine is produced in the anode and Hydrogen gas in the cathode
- Sample some of the yellow Iodine into 2 test tubes
- Add 3 drops of Amilum into one of the tubes, and 3 drops of PP into the other
- Repeat the sampling and testing procedure with the liquid in the cathode side
- Observe the change in colors
-
Second experiment
- Wash all equipment clean
- Note down the weights of both carbon electrodes
- Repeat the procedures in the first experiment, but with CuSO4 instead
- For the testing procedure, use the blue and red litmus papers instead
- Weigh the electrodes afterwards and note down the difference
- First experiment
- Anode: 2I- → I2 + 2e-
- Cathode: 2H2O + 2e- → 2OH- + H2
- Second experiment
- Anode: 2H2O → 4H+ + O2 + 4e-
- Cathode: Cu2+ + 2e- → Cu
- To determine whether a given sample contains proteins, benzene bonds, or sulfur
| Substance | Concentration | Amount |
|---|---|---|
| NaOH | 6 M | as needed |
| NaOH | 0.1 M | as needed |
| CuSO4 | 1% | as needed |
| HNO3 | 1.67 M | as needed |
| Lead (II) Acetate | - | as needed |
| CH3COOH | 3M | as needed |
| Item | Quantity |
|---|---|
| Beaker (250 ml) | 2 |
| Beaker (500 ml) [for egg] | 1 |
| Filter paper | number of samples |
| Test tubes | number of samples |
| Test tube rack | 1 |
| Pipette | 3 |
| Lighter | 1 |
| Bunsen burner | 1 |
| Tripod | 1 |
| Mesh | 1 |
| Wooden clamp | 1 |
- Biuret test
- Add 3 drops of CuSO4 (1%) into the sample and mix
- Add 3 drops of NaOH (0.1 M) into the sample and mix
- If the sample turns purple, it contains proteins
- Xanthoproteic test
- Add a bit of HNO3 (1.67 M) into the sample
- Heat up the test tube
- Slowly add NaOH (6 M)
- If the sample turns orange, it contains a benzene bond / aromatic amino acid
- Lead (II) acetate test
- Add a bit of NaOH (6 M) into the sample and mix
- Add a bit of CH3COOH into the sample and mix
- Cover the test tube's opening with a filter paper and clamp it in place
- Drop some Lead (II) Acetate onto the filter paper
- Heat up the test tube
- If the filter paper turns black, the sample contains sulfur
| Substance | Concentration | Amount |
|---|---|---|
| Phenolphthalein | - | 1 bottle |
| NaOH | 0.1 M | as needed |
| HCl | To be found | |
| CH3COOH | 25% | |
| Distilled water | - | as needed |
| Item | Quantity |
|---|---|
| Double clamp | 1 |
| Stand | 1 |
| Biuret | 1 |
| Funnel | 1 |
| Test tubes | 3 |
| Test tube rack | 1 |
| Volumetric pipette (10 ml) | 2 |
| Erlenmeyer flask (250 ml) | 4 |
| Volumetric flask (100 ml) | 1 |
| Pipette pump | 1 |
| Beaker (250 ml) | 1 |
- Measure the volume of analyte (the substance to be tested) and note it down
- Transfer the analyte to an Erlenmeyer flask
- Secure the biuret on the stand with a double clamp
- Fill the biuret with the titrant (NaOH if analyte is HCl) up to the zero point
- If it overflows, place a container under the biuret and open the tap to let some of the titrant out
- Add some indicator (PP) into the analyte
- Place analyte underneath the biuret
- Slowly let the titrant flow into the analyte, while also swirling the flask to make sure it's mixed well
- Close the biuret tap once the whole analyte starts to turn faint purple
- If it's dark purple then you've messed up
- Record the amount of titrant in the biuret
- Use M1V1 = M2V2 to solve for the analyte molarity
You have 3 samples, namely
- B1 = H2O
- B2 = NaOH (0.025 M)
- B3 = NaOH (0.05 M)
Add 2 grams of Ca(OH)2 to each of the samples. Stir them well and wait until everything settles.
From each sample, take 3 test tubes of 25 drops each, and add 1 drop of PP to each test tube.
Perform titration on each test tube:
- Add HCl (0.1 M) drop by drop until the solution turns colorless
- Record the number of drops and average them over the 3 test tubes for each sample
- Multiply the average number of drops by 0.05 ml to get the volume of HCl used
- Use M1V1 = M2V2 to solve for the volume of NaOH
Then do this little magic trick:
- First sample (B1)
- Ca(OH)2 → Ca2+ + 2OH-
- Q1 = [Ca2+][OH-]2
- Second sample (B2)
- Use MB2 = [Ca(OH)2] + [NaOH] to find the concentration of Ca(OH)2
- Ca(OH)2 → Ca+ + 2OH-
- Q2 = [Ca+][OH-]2
- Note: also include the concentration of OH- from the NaOH (0.025 M)
- Third sample (B3)
- Use MB3 = [Ca(OH)2] + [NaOH] to find the concentration of Ca(OH)2
- Ca(OH)2 → Ca+ + 2OH-
- Q3 = [Ca+][OH-]2
- Note: also include the concentration of OH- from the NaOH (0.05 M)
Probably like Boiling point increase.
Measure the temperature change and use the formula: ∆H = mc∆T
Some experiments that you will do:
- Exothermic reactions
- H2O + NaOH
- HCl + Mg
- Endothermic reactions
- NH4Cl + Ba(OH)2
- Heating up CuSO4 hydrate crystal