i have hard time geting it stright even after I do the experiment can  u help me with the one pls

Material

ChemicalsSealed NO₂ tubes, KSCN solution (0.002 M), acidified Fe(NO₃)₃ solution (0.2 M), KSCN crystals, Fe(NO₃)₃ crystals, KOH (concentrated (8 M)), distilled water

Apparatus:Bunsen burner, ring stand, wire gauze, matches, thermometer, dropper, test tubes, glass stirring rod, beaker tongs

Procedure

Part A:

1. Fill a 600 mL beaker to the 3/4 mark with water. Bring to a boil using a Bunsen burner.
2. In another 600 mL beaker, fill to the 1/2 mark with water; add ice in order to lower the temperature to about 0°C.
3. Note the room temperature.
4. Observe the NO₂ thoroughly at room temperature.
5. Place the sealed NO₂ tube in the cold bath. Note your observations.
6. Remove the test tube from the cold bath.
7. Let the test tube stand until it reaches room temperature. Note your observations.
8. Place the test tube in the hot bath. Note your observations.
9. Remove the test tube from the hot bath.
10. Let the test tube stand until it reaches room temperature. Note your observations.

Part B:

1. Place 50 mL of KSCN solution in a 100 mL beaker.
2. Add 6 drops of Fe(NO₃)₃ solution.
3. Stir with a glass rod.
4. Note your observations.
5. Pour about 10 mL of this solution into 5 test tubes.
6. Test tube #1 will be your control.
7. In test tube #2, add 2 KSCN crystals. They are sources of (SCN)^-. Stir and note your observations.
8. In test tube #3, add 2 crystals of Fe(NO₃)₃. They are sources of Fe³⁺. Stir and note your observations.
9. In test tube #4, add 2 crystals of KSCN and 2 crystals of Fe(NO₃)₃. Stir and note your observations.
10. In test tube #5, add concentrated KOH solution, one drop at a time until a precipitate is formed. Note your observations. Note that Fe³⁺ reacts with the OH^- to produce Fe(OH)_3(s).
11. Compare all test tubes to the control test tube, according to colour (from lightest to the darkest)
12. Empty all of the test tubes in a 250 mL beaker. Stir and note your observations.
13. Empty the solution of your 250 mL beaker into another group's 250 mL beaker. Stir and note your observations.

Sample Results

Step A-3: The room temperature is 24°C.
Step A-4: At room temperature, the NO₂ is a gas, orange/rust and transparent.

Step A-5: The NO₂ becomes a pale orange-yellow colour almost colourless.
Step A-7: The NO₂ returns to an orange/rust colour.
Step A-8: The NO₂ becomes dark orange.
Step A-10: The NO₂ returns to an orange/rust colour.
Step B-1: The KSCN is a liquid solution, transparent and colourless.
Step B-2: The Fe(NO₃) ₃ is a liquid solution, orange and transparent.
Step B-4: The solution becomes dark orange.
Step B-6: Test tube #1 is dark orange.
Step B-7: The KSCN is a solid, off-white, opaque/crystals.
Test tube #2 is red-orange.
Step B-8: The Fe(NO₃) ₃ is a solid, colourless and translucent.
Test tube #3 is dark orange.
Step B-9: Test tube #4 is dark red/burgundy.
Step B-10: The KOH is a liquid solution, transparent and colourless.
Test tube #5 contains a yellow/orange precipitate in suspension.
Step B-11: The order from lightest to darkest is test tubes #5, 1, 3, 2, 4.
Step B-12: This mixture is liquid, colourless and contains a red precipitate in suspension.
Step B-13: Same colour as step B-12.

Conclusion

Briefly state the results for the laboratory, in general. This should be no more than two sentences.

Questions

Part A:

1. Give the balanced chemical equation for this reaction.
2. When the system is returned to room temperature, does it mean that it returned to its initial equilibrium state? Why?
3. Give the balanced chemical equation for the reaction between KSCN and Fe(NO₃)₃.
4. Using your observations, explain how the equilibrium was affected by adding different reactants to test tubes 2, 3, 4, 5 and the two beakers in steps B-12 and B-13. (Refer to the concentrations of each reactant and product as well as the colour change)
5. Does the mixture in the 250 mL beaker from step B-13 represent a system in equilibrium? Explain.