Gibbs Free Energy

Ways to Calculate Enthalpy of Reactions

10 Activities

Wize High School Grade 12 Chemistry Textbook > Energy Changes

Introduction to Thermochemistry

2 Activities

The reaction of 

H2(g)+CO2(g)↔H2O(g)+CO(g) at 2000K KP=4.40H_{2(g)}+CO_{2(g)}\leftrightarrow H_2O_{(g)}+CO_{(g)}\ at\ 2000K\ K_P=4.40H2(g)​+CO2(g)​↔H2​O(g)​+CO(g)​ at 2000K KP​=4.40 

Calculate ΔG for this reaction

−24.632kJmol-24.632\frac{kJ}{mol}−24.632molkJ​

−24.633kJmol-24.633\frac{kJ}{mol}−24.633molkJ​

−24.634kJmol-24.634\frac{kJ}{mol}−24.634molkJ​

−24.636kJmol-24.636\frac{kJ}{mol}−24.636molkJ​

I don't know

More Ways to Calculate Enthalpy of Reactions Questions:

Enthalpy of Formation

What is the enthalpy of the following reaction when 0.35 g of Mg2+ is produced? Use the following information:
ΔH°f[Mg(OH)2(s)] = −924.5 kJ
ΔH°f[NH4+(aq)] = −132.5 kJ

Thermochemistry: Enthalpy of reactions

The following reaction enthalpies are provided:
H2(g)+12O2(g)→H2O(l),ΔH1=−285.8kJ/mol(1)H_{2(g)}+\frac{1}{2}O_{2(g)}\to H_2O_{(l)},\Delta H_1=-285.8kJ/mol\hspace{70pt} (1)H2(g)​+21​O2(g)​→H2​O(l)​,ΔH1​=−285.8kJ/mol(1)
C(s)+O2(g)→CO2(g),ΔH2=−293.5kJ/mol(2)C_{(s)}+O_{2(g)}\to CO_{2(g)},\Delta H_2=-293.5kJ/mol \hspace{80pt} (2)C(s)​+O2(g)​→CO2(g)​,ΔH2​=−293.5kJ/mol(2)

Calorimetry: Temperature change

1.  A 56.0 g block of iron heated to 90 °C is placed in a 4.8 kg water bath at 20 °C. What will be the final temperature of the iron?  heat capacity of iron c = 0.450 J /gK, heat capacity of water is 4.185 J/gK

Enthalpy of Reactions

Consider the following reaction:
N2H4(I)+O2→N2(g)+2 H2O(I)ΔH=−622.2 kJN_2H_4(I)+O_2\rightarrow N_2(g)+2\ H_2O(I)\quad \Delta H=-622.2\ kJN2​H4​(I)+O2​→N2​(g)+2 H2​O(I)ΔH=−622.2 kJ 
Given the following data, calculate the heat of reaction for the same reaction where water is a gaseous product instead of a liquid:

Calculate ΔH°\Delta H\degreeΔH° for the reaction below, which requires catalytic acid to proceed
C6H12(l)+H2O(l)→C6H13OH(l)C_6H_{12}\left(l\right)+H_2O\left(l\right)\to C_6H_{13}OH\left(l\right)C6​H12​(l)+H2​O(l)→C6​H13​OH(l)
Given:

The standard enthalpy of formation for NO2(g)NO_2\left(g\right)NO2​(g) is 33.18 kJ/mol, and the standard enthalpy of partial combustion of nitrogen to NO(g) is 90.25 kJ/mol. Calculate the standard enthalpy of combustion of NO(g) to NO2(g).

Hess’s Law: Indirect Determination of ΔH

The standard enthalpy of formation of ethanol (C2H5OH){\small \left(\text{C}_2\text{H}_5\text{OH}\right)}(C2​H5​OH) is -277.7 kJ/mol. Write the chemical equation to which this value applies.
Solution:

Calculate the ΔH for the reaction below
IF5 (g) → IF3 (g) + F2 (g)

IF (g) + F2 (g) → IF3 (g)              ΔH = -390 kJ
IF (g) + 2 F2 (g) → IF5 (g)           ΔH = -745 kJ

Liquification of fuels is an important process that allows fuel to be transported more safely and more easily around the world.  Oxidizing methane transforms it from a gas to a liquid, methanol, which is much easier to transport.  Using the data provided calculate ΔH\Delta HΔHfor the oxidation of methane (CH4) shown below
CH4(g) + 1/2 O2(g)→CH3OH(l)ΔHfo(CH4(g))=−74.9kJ mol−1ΔHfo(CH3OH(l)=−238.6 kJ mol−1\begin{array}{c}
CH_{4(g)}\ +\ 1/2\ O_{2(g)} \rightarrow CH_3OH_{(l)} \\ \\
\Delta H^o_f(CH_{4(g)})=-74.9 kJ\ mol^{-1} \\
\Delta H_f^o(CH_3OH_{(l)}=-238.6\ kJ\ mol^{-1}
\end{array}CH4(g)​ + 1/2 O2(g)​→CH3​OH(l)​ΔHfo​(CH4(g)​)=−74.9kJ mol−1ΔHfo​(CH3​OH(l)​=−238.6 kJ mol−1​

Practice: Total Bond Energy of IF$_7$

The total bond enthalpy for F2 is 156.9 kJ/mol and the total bond enthalpy of I2 is 152.5 kJ/mol. Using the thermochemical equation below, what is the total bond enthalpy of IF7?  
I2(s)+7 F2(g)→2 IF7(s)  ΔH=2669.2 kJ.molI_{2(s)}+7\ F_{2(g)}\rightarrow 2\ IF_{7(s)}\ \ \Delta H=2669.2\ kJ.molI2(s)​+7 F2(g)​→2 IF7(s)​  ΔH=2669.2 kJ.mol

Enthalpy of Reactions

Given the following at 25°C and 1.00 atm: 
                                              
                                            ReactionΔH°12N2(g)+O2(g)→NO2(g)33.2kJN2(g)+2O2(g)→N2O4(g)11.1kJ\def\arraystretch{1.5}\begin{array}{cc}\rm Reaction&\Delta H\degree\\\cfrac{1}{2} N_2 (g)+O_2 (g)→NO_2 (g)&33.2 kJ \\N_2 (g)+2O_2 (g)→N_2 O_4 (g)&11.1 kJ\end{array}Reaction21​N2​(g)+O2​(g)→NO2​(g)N2​(g)+2O2​(g)→N2​O4​(g)​ΔH°33.2kJ11.1kJ​

Enthalpy of Reactions

Estimate the heat of reaction at 298 K for the reaction shown, given the average bond energies below.
Br2(g)+3F2(g)→2BrF3(g)Br_2 (g)+3F_2 (g)→2BrF_3 (g) 

Br2​(g)+3F2​(g)→2BrF3​(g)
BondBond EnergyBr−Br193kJ/molF−F155kJ/molBr−F249kJ/mol\def\arraystretch{1.5}
\begin{array}{c}
\rm Bond &&&& \rm Bond \ Energy  \\
\hline
Br-Br &&&& 193 kJ/mol\\
F-F &&&& 155 kJ/mol\\
Br-F &&&& 249 kJ/mol\\
\end{array}
BondBr−BrF−FBr−F​​​​Bond Energy193kJ/mol155kJ/mol249kJ/mol​​

Enthalpy: Bond Dissociation Energies

Consider the following balanced chemical reaction and the bond dissociation energies for the partial combustion of hydrogen sulfide:
What is the enthalpy change ΔrH for this reaction?

Thermochemistry: Calorimetry

Consider the following balanced chemical equation:
2CℓF3(g)+2O2(g)→Cℓ2O(g)+3F2O(g)∆rH°=???2 CℓF_3(g) + 2 O_2(g) → Cℓ_2O (g) + 3 F_2O (g) \qquad ∆_rH° = ???2CℓF3​(g)+2O2​(g)→Cℓ2​O(g)+3F2​O(g)∆r​H°=???
Substance△fH° @ 25°C (kJ/mol)CℓF3(g)??Cℓ2O(g)80.3F2O(g)–21.7F2(g)0\def\arraystretch{1.5}
   \begin{array}{|c|c|}
\hline
\rm Substance & △_fH° \ @ \ 25°C \ (kJ/mol) \\ \hline
CℓF_3 (g) & ?? \\ \hline
Cℓ_2O (g) & 80.3 \\ \hline
F_2O (g) & – 21.7 \\ \hline
F_2 (g) & 0 \\ \hline
\end{array}SubstanceCℓF3​(g)Cℓ2​O(g)F2​O(g)F2​(g)​△f​H° @ 25°C (kJ/mol)??80.3–21.70​​

Thermochemistry: Calorimetry

Ethene gas (C2H4) reacts with fluorine gas according to the following balanced equation: 
C2H4(g)+6F2(g)→2CF4(g)+4HF(g)ΔrH°=−3012 kJ/mol⋅rxn @ 25°CC_2H_4 (g) + 6 F_2 (g) → 2 CF_4 (g) + 4 HF (g) \qquadΔ_rH° = −3012\ kJ/mol·rxn\ @ \ 25°CC2​H4​(g)+6F2​(g)→2CF4​(g)+4HF(g)Δr​H°=−3012 kJ/mol⋅rxn @ 25°C
Substance△fH° @ 25°C(kJ/mol)C2H4(g)??F2(g)0CF4(g)–933HF(g)–273.3\def\arraystretch{1.5}
   \begin{array}{|c|c|} \hline 

\rm{Substance} & △_fH° \ @ \ 25°C(kJ/mol) \\ \hline
 
C_2H_4 (g) & ?? \\ \hline
 
F_2 (g) & 0 \\ \hline
 
CF_4 (g) & – 933 \\ \hline
 
HF (g) & – 273.3 \\ \hline

\end{array}SubstanceC2​H4​(g)F2​(g)CF4​(g)HF(g)​△f​H° @ 25°C(kJ/mol)??0–933–273.3​​

Thermodynamics: Enthalpy of reaction

Find  ΔHo  for the following reaction if 12.0 g of N2H4 is consumed in excess N204.
2N2H4(l)+N2O4(g)→3N2(g)+4H2O(l)2N_2H_{4(l)}+N_2O_{4(g)}\to 3N_{2(g)}+4H_2O_{(l)}2N2​H4(l)​+N2​O4(g)​→3N2(g)​+4H2​O(l)​
The following enthalpies of formation are provided:

 Calculate ΔHof of SO2(g) given the following: (answer in kJ)
S(s)+1.5O2(g)→SO3(g),ΔH=−395.8kJS_{(s)}+1.5O_{2(g)}\to SO_{3(g)}, \Delta H=-395.8kJS(s)​+1.5O2(g)​→SO3(g)​,ΔH=−395.8kJ
2SO2(g)+O2(g)→2SO3(g),ΔH=−198.2kJ2SO_{2(g)}+O_{2(g)}\to 2SO_{3(g)}, \Delta H=-198.2kJ2SO2(g)​+O2(g)​→2SO3(g)​,ΔH=−198.2kJ

Intramolecular bonding: Strength of Covalent Bonds

Calculate the enthalpy for the following reaction.  
2 C2H6 (g) + 7 O=O (g) → 4 O=C=O (g) + 6 H-O-H (g)
The following are bond dissociation energies (kJ/mol):

Practice: Hydrogenation of Acetylene

Using the table below, answer the following questions about the hydrogenation reactions of acetylene: 
a) Calculate the enthalpy of formation of ethylene, C2H4, considering ΔHrxn = -174.4kJ/mol 
C2H2+H2→C2H4C_2H_2+H_2\to C_2H_4C2​H2​+H2​→C2​H4​

Find the standard molar enthalpy of combustion of C2H5OH using the standard enthalpy of formations below.
ΔHf(C2H5OH(l))=−277.7 kJ/mol\Delta H_f(C_2H_5OH_{(l)}) = -277.7\ kJ/molΔHf​(C2​H5​OH(l)​)=−277.7 kJ/mol
ΔHf(CO2(g))=−393.5 kJ/mol\Delta H_f(CO_{2(g)}) = -393.5\ kJ/molΔHf​(CO2(g)​)=−393.5 kJ/mol

Thermochemistry Calculations

The standard enthalpy of fusion for water, ΔHofusion = 6.01 kJ/mol. Calculate the energy required (in kJ) to convert 26.0 g of ice at 0oC to liquid water at 20oC.

Heat of Formation

Determine the standard molar enthalpy of formation of solid Al2O3 from the following equations.
Al (s) + 3 H2O (l)  →  Al(OH)3 (s) + 3/2 H2 (g) ΔH =+100 kJmol\Delta H\ =+100\ \frac{kJ}{mol}ΔH =+100 molkJ​
H2 (g) + 1/2 O2 (g)  →  H2O (l)ΔH=−300 kJmol\Delta H=-300\ \frac{kJ}{mol}ΔH=−300 molkJ​

Thermochemistry: Temperature

The oxidation of NO is shown below. Using the provided thermodynamic data answer the following questions 
2 NO(g)+O2(g)→2 NO2)g)2\ NO_{(g)}+O_{2(g)}\rightarrow2\ NO_{2)g)}2 NO(g)​+O2(g)​→2 NO2)g)​
ΔHo=−57.1kJmol and ΔSo=−73Jmol at 298K\Delta H^o=-57.1\frac{kJ}{mol}\ \text{and}\ \Delta S^o=-73\frac{J}{mol}\ at\ 298KΔHo=−57.1molkJ​ and ΔSo=−73molJ​ at 298K

Thermochemistry: Gibbs Free Energy

The oxidation of NO is shown below. Using the provided thermodynamic data answer the following questions
2 NO(g)+O2(g)→2 NO2)g)2\ NO_{(g)}+O_{2(g)}\rightarrow2\ NO_{2)g)}2 NO(g)​+O2(g)​→2 NO2)g)​
ΔHo=−57.1kJmol and ΔSo=−73Jmol at 298K\Delta H^o=-57.1\frac{kJ}{mol}\ \text{and}\ \Delta S^o=-73\frac{J}{mol}\ at\ 298KΔHo=−57.1molkJ​ and ΔSo=−73molJ​ at 298K 

Thermochemistry: Equilibrium (Keq)

The Haber Bosch Process is an industrial process for “fixing” nitrogen, shown below.This process produces around 500 million tons of ammonia every year. Calculate Keq
   3 H2(g)+N2(g)→ 2 NH3(g)3\ H_{2(g)}+N_{2(g)}\rightarrow\ 2\ \text{NH}_{3(g)}3 H2(g)​+N2(g)​→ 2 NH3(g)​
ΔfGo(NH3)=−16.4 kJ/mol\Delta _fG^o(NH_3)=-16.4\ kJ/molΔf​Go(NH3​)=−16.4 kJ/mol

 Using the following data, calculate the standard entropy change for the reaction: 
2Al(s)+3ZnO(s)→Al2O3(s)+3Zn(s)2Al_{(s)}+3ZnO_{(s)}\to Al_2O_{3(s)} +3Zn_{(s)}2Al(s)​+3ZnO(s)​→Al2​O3(s)​+3Zn(s)​
 Report your answer in J/mol K to four significant figures.  Do not include units in the answer field.  

A spontaneous process:

 Which of the following statements regarding spontaneous changes is false? 

A freshly baked pie is placed near an open window to cool. Which of the following statements best describes this situation? 

Thermodynamics: Heat and Work

Consider the following balanced chemical equation for the combustion of propane, C3H8:
C3H8(g)+5O2(g)→4H2O(ℓ)+3CO2(g)q<0C_3H_8 (g) + 5 O_2      (g) → 4 H_2O (ℓ) + 3      CO_2 (g) \qquad q < 0C3​H8​(g)+5O2​(g)→4H2​O(ℓ)+3CO2​(g)q<0
Use this information to answer the next two questions. Choose one if the options inside the brackets

If a reaction is nonspontaneous at 298 K with a negative ΔHo, then the reaction is:  
Select all that apply

 The oxidation of NO is shown below. Using the provided thermodynamic data answer the following questions 
 2 NO(g)+O2(g)→2 NO2)g)2\ NO_{(g)}+O_{2(g)}\rightarrow2\ NO_{2)g)}2 NO(g)​+O2(g)​→2 NO2)g)​ 
 ΔHo=−57.1kJmol and ΔSo=−73Jmol at 298K\Delta H^o=-57.1\frac{kJ}{mol}\ \text{and}\ \Delta S^o=-73\frac{J}{mol}\ at\ 298KΔHo=−57.1molkJ​ and ΔSo=−73molJ​ at 298K 

The oxidation of NO is shown below. Using the provided thermodynamic data answer the following questions
 2 NO(g)+O2(g)→2 NO2)g)2\ NO_{(g)}+O_{2(g)}\rightarrow2\ NO_{2)g)}2 NO(g)​+O2(g)​→2 NO2)g)​ 
 ΔHo=−57.1kJmol and ΔSo=−73Jmol at 298K\Delta H^o=-57.1\frac{kJ}{mol}\ \text{and}\ \Delta S^o=-73\frac{J}{mol}\ at\ 298KΔHo=−57.1molkJ​ and ΔSo=−73molJ​ at 298K 

Find ΔG0 for the following reaction.
         CH4(g)+2 O2(g)→2 H2O(g)+CO2(g)\text{CH}_{4(g)}+2\ O_{2(g)}\rightarrow 2\ H_2O_{(g)}+\text{CO}_{2(g)}CH4(g)​+2 O2(g)​→2 H2​O(g)​+CO2(g)​

 Consider the following vaporization: 
CH3CH2OH(l)→CH3CH2OH(g)CH_3CH_2OH_{(l)}\to CH_3CH_2OH_{(g)}CH3​CH2​OH(l)​→CH3​CH2​OH(g)​
 If ∆Hvap = 39.3 kJ/mol and the boiling point of ethanol is 78.3°C, what is ΔS for the vaporization of 1.73 mols of ethanol at its boiling point? 

Predict the sign of the ΔH, ΔS,(+ or -) and identify when the following reactions are spontaneous at low temperature, high temperature, or all temperatures (low, high, all).  Use commas to write your answers ie. +,+,low
 For freezing of a popsicle: ΔH is ___________, ΔS is ___________. Reaction is spontaneous at ____________________ temperatures
 For evaporation of liquid water: ΔH is ___________, ΔS is ___________. Reaction is spontaneous at ____________________ temperatures

 Arrange the following compounds in order of increasing entropy, assuming 1 mol of each compound: 
Ar(g)Fe(s)CH3CH2CH3(g)HOCH2CH2CH2OH(l)Ar(g) \hspace{15pt}Fe(s)\hspace{15pt} CH_3CH_2CH_{3(g)} \hspace{15pt} HOCH_2CH_2CH_2OH_{(l)}Ar(g)Fe(s)CH3​CH2​CH3(g)​HOCH2​CH2​CH2​OH(l)​
Ar(g)Ar(g)Ar(g)

Calculate ΔSsys ΔSsurr and ΔSUniv for the combustion of hydrogen shown below (unbalanced). Is the process spontaneous?
        H2(g)+O2(g)→H2O(g)H_{2(g)}+O_{2(g)}\rightarrow H_2O_{(g)}H2(g)​+O2(g)​→H2​O(g)​
ΔHf0(H2O(g)) = -285.83 kJ/mol

Thermochemistry: Entropy Calculations

Using the ΔH0 of fusion for water 6.03 kJ/mol and the ΔS0 of fusion for water 22.1 J K-1 mol-1, calculate the ΔSuniv for ice melting at -10oC, 0oC and 10oC. Remember: the universe transfers heat in a reversible way.

Thermodynamics: Entropy Calculations

Using the following data, calculate the standard entropy of the reaction shown below. Enter your answer in units of J / (mol*K)
2 Al(s)+3 ZnO(s)→Al2O3(s)+3Zn(s)2\ Al_{(s)}+3\ ZnO_{(s)}\rightarrow Al_2O_{3(s)}+3Zn_{(s)}2 Al(s)​+3 ZnO(s)​→Al2​O3(s)​+3Zn(s)​
So(Al(s))=28.3 J mol−1K−1S^o(Al_{(s)})=28.3\ J\ mol^{-1}K^{-1}So(Al(s)​)=28.3 J mol−1K−1

Gibbs Free Energy

Related Topics

Ways to Calculate Enthalpy of Reactions

Introduction to Thermochemistry

More Ways to Calculate Enthalpy of Reactions Questions:

Enthalpy of Formation

Thermochemistry: Enthalpy of reactions

Calorimetry: Temperature change

Enthalpy of Reactions

Hess’s Law: Indirect Determination of ΔH

Practice: Total Bond Energy of IF$_7$

Enthalpy of Reactions

Enthalpy of Reactions

Enthalpy: Bond Dissociation Energies

Thermochemistry: Calorimetry

Thermochemistry: Calorimetry

Thermodynamics: Enthalpy of reaction

Intramolecular bonding: Strength of Covalent Bonds

Practice: Hydrogenation of Acetylene

Thermochemistry Calculations

Heat of Formation

More Introduction to Thermochemistry Questions:

Thermochemistry: Temperature

Thermochemistry: Gibbs Free Energy

Thermochemistry: Equilibrium (Keq)

Thermodynamics: Heat and Work

Thermochemistry: Entropy Calculations

Thermodynamics: Entropy Calculations