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Hess's Law Calculations (HL IB Chemistry)

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Alexandra Brennan

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Hess's Law Calculations

  • There are two common methods to solving Hess's Law problems, using cycles and using equations
  • To be successful in using cycles you need to follow carefully a step-by-step plan using the information in the question to construct a cycle and add the given information
  • The following example shows one way to lay out your solution:

Solving Hess's Law problems using cycles:

Worked example

Calculate the enthalpy of reaction for:

 2N2 (g) + 6H2 (g) → 4NH3 (g)

Given the data:

4NH3 (g) + 3O2 (g) 2N2 (g) + 6H2O (l),           ΔH1 = -1530 kJ mol-1

H2 (g) + ½O2 (g )  H2O (l),                               ΔH2 = -288 kJ mol-1

Answer:

  • Step 1: Begin by writing the target enthalpy change at the top of your diagram from left to right:

using hess's law to calculate enthalpy change

  • Step 2: Next, write the alternative route at the bottom of your cycle and connect the top and bottom with arrows pointing in the correct directions:

using hess's law to calculate enthalpy change

  • Step 3: Add the enthalpy data and adjust, as necessary, for different molar amounts

using hess's law to calculate enthalpy change

  • Step 4:Write the Hess's Law calculation out:

ΔHr = +6ΔH2 – ΔH= + (-288 x 6) - ( -1530 ) = -198 kJ

    • Two important rules:
      • If you follow the direction of the arrow you ADD the quantity
      • If you go against the arrow you SUBTRACT the quantity

Worked example

What is the enthalpy change, in kJ, for the reaction below?

4FeO (s) + O2 (g) → 2Fe2O3 (s)

Given the data:

2Fe(s) + O2 (g) → 2FeO (s)                  ∆H = – 544 kJ

   4Fe (s) + 3O2 (g) → 2Fe2O3 (s)             ∆H = –1648 kJ

Answer:

  • Step 1: Draw the Hess cycle and add the known values

using hess's law to calculate enthalpy change

  • Step 2: Write the Hess's Law calculation out:

Follow the alternative route and the process the calculation

ΔHr = - ( - 544 x 2) + (- 1648) = - 560 kJ

Examiner Tip

It is very important you get the arrows in the right direction and that you separate the mathematical operation from the sign of the enthalpy change. Many students get these problems wrong because they confuse the signs with the operations. To avoid this always put brackets around the values and add the mathematical operator in front

Solving Hess's Law problems using equations step-by-step:

Worked example

Consider the following reactions.

   N2 (g) + O2 (g) → 2NO (g)         ∆H = +180 kJ

   2NO2 (g) → 2NO (g) + O2 (g)    ∆H = +112 kJ

What is the ∆H value, in kJ, for the following reaction?

   N2 (g) + 2O2 (g) → 2NO2 (g)

Answer:

  • Step 1: Identify which given equation contains the product you want

   This equation contains the desired product on the left side:

  2NO2 (g) → 2NO (g) + O2 (g)                             ∆H = +112 kJ

  • Step 2: Adjust the equation if necessary, to give the same product. If you reverse it, reverse the ΔH value

   Reverse it and reverse the sign

2NO (g) + O2 (g)  →   2NO2 (g)                         ∆H = -112 kJ

  • Step 3:  Adjust the equation if necessary, to give the same number of moles of product

   The equation contains the same number of moles as in the question, so no need to adjust the moles

  • Step 4: Identify which given equation contains your reactant

   This equation contains the reactant

N2 (g) + O2 (g) → 2NO (g)         ∆= +180 kJ

  • Step 5: Adjust the equation if necessary, to give the same reactant. If you reverse it, reverse the ΔH value

   No need to reverse it as the reactant is already on the left side

  • Step 6: Adjust the equation if necessary, to give the same number of moles of reactant

 

  • Step 7: Add the two equations together

N2 (g) + O2 (g) → 2NO (g)                                             ∆= +180 kJ

2NO (g) + O2 (g) → 2NO2 (g)                                        ∆H  = -112 kJ

  • Step 8: Cancel the common items

N2 (g) + O2 (g) + 2NO (g) + O2 (g) → 2NO (g) + 2NO2 (g)

  • Step 9: Add the two ΔH values together to get the one you want

N2 (g) + 2O2 (g) → 2NO2 (g)                         ∆ = +180-112 = +68 kJ

Worked example

The enthalpy changes for two reactions are given.

Br2 (l) + F2 (g) → 2BrF (g)         ΔH = x kJ

Br2 (l) + 3F2 (g) → 2BrF3 (g)      ΔH = y kJ

What is the enthalpy change for the following reaction?

BrF (g) + F2 (g) → BrF3 (g)

A. x – y

B. y - x

C. ½ (–x + y)

D. ½ (x – y)

Answer:

  • The correct option is C.
    • The second equation contains the desired product, but it needs to be halved to make 1 mole

Br2 (l) + 3F2 (g) → 2BrF3 (g)    ΔH = y   becomes

 ½Br2 (l) + 1½F2 (g) → BrF3 (g)   ½ΔH = ½y

    • The first equation contains the reactant, but it needs to be reversed and halved:

Br2 (l) + F2 (g) → 2BrF (g)       ΔH = x   becomes

BrF (g)  → ½Br2 (l) + ½F2 (g)   ½ΔH = -½x

    • Combine the two equations and cancel the common terms:

½Br2 (l) + 1½F2 (g) → BrF3 (g)      ½ ΔH = y kJ

BrF (g)  → ½Br2 (l) + ½F2 (g)      ½  ΔH = -x kJ

BrF (g) + F2 (g) → BrF3 (g)    ΔH ½y  +  -½x  =  ½(-x + y)

Examiner Tip

If doesn't matter whether you use equations or cycles to solve Hess's Law problems, but you should be familiar with both methods and sometimes one is easier than another

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Alexandra Brennan

Author: Alexandra Brennan

Expertise: Chemistry

Alex studied Biochemistry at Newcastle University before embarking upon a career in teaching. With nearly 10 years of teaching experience, Alex has had several roles including Chemistry/Science Teacher, Head of Science and Examiner for AQA and Edexcel. Alex’s passion for creating engaging content that enables students to succeed in exams drove her to pursue a career outside of the classroom at SME.