Difference between revisions of "ChemCollective-Virtual-Labs/C3/Determination-of-Equilibrium-constant/English"

Title Slide

Learning Objectives

To determine equilibrium constant for Cobalt chloride reaction.

Observe the effect of change in temperature and concentration on equilibrium.

Pre-requisites

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ChemCollective Vlabs interface.

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System Requirement

Mac OS version 10.10.5

ChemCollective virtual labs version 2.1.03

Java version 8.

Point to the dialogue box.

Scroll down to Load Homework option.

Default Lab Setup dialogue-box opens.

Click on Cobalt Lab.

Two options appear.

Double-click on Cobalt Lab option.

Point to the Assignments in the problem.

Problem description states that,

we need to apply Le Chatelier's principle, for aqueous Cobalt chloride reaction.

Using the equilibrium concentration we need to find,

1. equilibrium constant for cobalt chloride reaction and

2. effect of temperature and reactant concentration on equilibrium.

Chemical Equilibrium

Concentration of the reactants and products do not change with time at equilibrium.

General Equilibrium Reaction

aA+ bB ⇌ cC+dD

K_c = [C]^c x [D]^d/[A]^a x [B]^b

This is the equation for Equilibrium Constant.

Equilibrium Constant

[Co(H ₂O)₆]²⁺ + 4HCl + heat ⇌

CoCl₄^-2 + 6H₂O

K_c= [ CoCl₄^-2]/[Co(H ₂ O)₆⁺²] x [Cl^-]⁴

Cobalt forms complexes with water molecules as well as chloride ions.

A solution of Hexaaquacobalt(II)complex is pink.

When hydrochloric acid is added to the solution, the colour changes to blue.

This corresponds to the formation of Cobalt Chloride complex.

Factors Affecting Equilibrium Constant

1. Change in concentration of reactants or products and

2. Change in temperature.

Click on Cobalt chloride exp solutions cabinet on the Stockroom explorer.

Double-click on Cobalt chloride experiment solutions cabinet.

Point to the added flask.

Point to the colour in the flask.

A flask with 100 mL of 1M Cobalt Chloride is added to the workbench.

Observe the colour of the solution in the flask.

Point to the colour in the flask.

Colour of the solution is pink due to presence of Hexaaquacobalt(II)complex.

Note the concentrations of Hexaaquacobalt(II)complex, chloride ions and Cobalt chloride in your observation book.

Select Erlenmeyers.

From the list click on 250 mL Erlenmeyer Flask.

Right-click on flask A.

From the context menu choose Rename option.

In the text box type A.

Click on OK button.

Select Erlenmeyers.

From the list click on 250 mL Erlenmeyer flask.

Rename the flask as A.

Click on 50 mL Buret, click on Buret.

From the list, click on 25 mL Pipet.

From the Glassware menu, select 50 mL Buret.

Select Precise transfer mode.

Type 25 in the Transfer Amount input bar.

Click on Withdraw.

Drag and keep the flask aside.

Click on Withdraw.

Keep the flask aside.

Type 25 and Click on Pour.

Type 25 and Click on Pour.

Keep the Pipet aside.

Type 50 in the transfer window. Click on Pour.

Bring 12 M hydrochloric acid flask on to 50 mL buret.

Type 50 in the Transfer amount input bar.

Click on Pour.

Keep the flask aside.

Type 1 in the transfer bar and click on pour.

Add hydrochloric acid from the burette in 1 ml increments, using Precise Transfer mode.

Type 1 in the Transfer amount input bar and click on Pour.

We have transferred 7 mL of hydrochloric acid to Flask A.

Point to Solution Info Panel.

Temperature decreases during the reaction.

It means that, the reaction is endothermic.

Point to the solution info panel.

Now the concentrations of the reactants and products are constant.

Note the values of the concentrations of Hexaaquacobalt(II)complex, chloride ions and cobalt chloride in your observation book.

Point to the solution info panel.

Pour 1 ml at a time into the flask.

Transfer another 8 ml of Hydrochloric acid to flask A.

Now we have transferred 15 ml of hydrochloric acid to flask A.

Total volume of liquid in flask A is 40 mL

Note the color change in Flask A.

Please wait for the reaction to reach equilibrium condition.

Point to Flask A.

Point to the concentrations in the Solution Info Panel.

Total volume in flask A is 43 mL.

Note the color change in flask A.

Note the concentrations in your observation book.

Point to Flask A.

Point to the concentrations in the Solution Info Panel.

Total volume in flask A is now 48 mL.

Note that we have added 23 mL of hydrochloric acid to flask A.

Color of the solution in flask A is blue.

Calulation of Equilibrium Constant K_c.

[CoCl₄^-2] = 0.208 mol/L

[Co(H₂O)₆⁺²] = 0.574 mol/L

[Cl^-] = 3.36 mol/L

Kc = [CoCl₄^-2] /[Co(H₂O)₆⁺²] [Cl^-]⁴

Kc = 0.208/0.574 x (3.36)⁴ .

K c= 2.84x10-3

Substitute the values of concentrations of cobalt chloride, Hexaaquacobalt(II)complex and chloride ions in the equation.

This is the value of equilibrium constant after pouring 7 ml of hydrochloric acid.

Equilibrium Constant

Table of K_c values.

Point to K_c values.

Since, temperature is constant, equilibrium constant(K_c ) values are almost the same.

Next I will demonstrate the effect of temperature on equilibrium.

Earlier we have observed that, this reaction is endothermic.

It means, heat is absorbed during the reaction.

Le Chatelier's principle

If an equilibrium is disturbed by changing the conditions, position of equilibrium moves to counteract the change.

According to the principle, for endothermic reactions,

rate of forward reaction increases with increase in temperature.

Keep the burette aside.

In the input box, check the box for Insulated from surroundings.

Type 35 in the text box.

Right-click on flask A, from the context menu, select Thermal Properties.

Input box opens.

In Set the temperature to text box, type 35.

Check the box for Insulated from surroundings.

Click on OK.

Effect of temperature on K_c

[CoCl₄^-2]= 0.447 mol/L,

[Co(H₂O)₆⁺²] = 0.074 mol/L,

[Cl^-] = 5.00 mol/L

K_c=[CoCl₄^-2]/[Co(H₂O)₆⁺²] x [Cl^-]⁴

K_c = 0.447 /0.074 x (5.00)⁴

= 9.65x10^-3

K_c at 25⁰ C = 2.85x10^-3

Note that the value of K_c at 35⁰ C is greater than K⁰ value at 25⁰C.

This is because the reaction is an endothermic reaction.

As the temperature increases rate of forward reaction increases.

Hence more product is formed.

Right-click on pipette and buret, select Remove.

Remove the used pipet and Buret from the Workbench.

From the context menu, select Thermal Properties.

Un-check the box for Insulated from surroundings.

Click OK.

This will bring the temperature back to 25⁰C.

From the glassware menu, select 25 mL pipet.

Double-Click on 6M Silver nitrate from Stockroom Explorer.

From the glassware menu, select 25 mL pipet.

Type 5 in Transfer Amount input bar.

Click on Pour.

Transfer 25 mL of AgNO₃ from pipet to flask A in 5 mL increments.

Type 5 in Transfer Amount input bar.

Click on Pour.

Point to flask A

Point to the concentrations.

Click on Solid radio button.

Point to the grams column.

[CoCl₄]^2- = 0.0554 mol/L

[Co(H₂O)₆]⁺² = 0.3122 mol/L

[Cl^-] = 2.808 mol/L

AgCl = 18.14 g

Note the colour change.

It indicates the formation of Hexaaquacobalt(II)complex.

Click on Solid radio button.

Note the amount of AgCl in grams column.

Chemical Equilibrium

Silver Nitrate Reaction

Cobalt chloride reaction

Here chloride(Cl^-) ions decrease in the solution, to compensate for the deficit,

Rate of reverse reaction increases.

Cobalt chloride complex decomposes to form HexaaquaCobalt(II) complex.

This example is a proof for LeChatelier's principle.

Summary

To determine equilibrium constant for Cobalt chloride reaction.

Observe the effect of change in temperature and concentration on equilibrium.

Assignment

Cobalt chloride reaction

Prepare a solution by adding 25 ml of Cobalt chloride solution and 23 ml of Hydrochloric acid.

Add 40 mL of water in 10 ml increments to the prepared solution

Observe the colour in the flask.

Calculate Equilibrium Constant before and after addition of water.

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