Input interpretation
![CO carbon monoxide + SiO_2 silicon dioxide ⟶ CO_2 carbon dioxide + Si silicon](../image_source/9efa59b8c136b5d2bec061b46b919b53.png)
CO carbon monoxide + SiO_2 silicon dioxide ⟶ CO_2 carbon dioxide + Si silicon
Balanced equation
![Balance the chemical equation algebraically: CO + SiO_2 ⟶ CO_2 + Si Add stoichiometric coefficients, c_i, to the reactants and products: c_1 CO + c_2 SiO_2 ⟶ c_3 CO_2 + c_4 Si Set the number of atoms in the reactants equal to the number of atoms in the products for C, O and Si: C: | c_1 = c_3 O: | c_1 + 2 c_2 = 2 c_3 Si: | c_2 = c_4 Since the coefficients are relative quantities and underdetermined, choose a coefficient to set arbitrarily. To keep the coefficients small, the arbitrary value is ordinarily one. For instance, set c_2 = 1 and solve the system of equations for the remaining coefficients: c_1 = 2 c_2 = 1 c_3 = 2 c_4 = 1 Substitute the coefficients into the chemical reaction to obtain the balanced equation: Answer: | | 2 CO + SiO_2 ⟶ 2 CO_2 + Si](../image_source/333c7877f791f37fe6c3b661397aae2e.png)
Balance the chemical equation algebraically: CO + SiO_2 ⟶ CO_2 + Si Add stoichiometric coefficients, c_i, to the reactants and products: c_1 CO + c_2 SiO_2 ⟶ c_3 CO_2 + c_4 Si Set the number of atoms in the reactants equal to the number of atoms in the products for C, O and Si: C: | c_1 = c_3 O: | c_1 + 2 c_2 = 2 c_3 Si: | c_2 = c_4 Since the coefficients are relative quantities and underdetermined, choose a coefficient to set arbitrarily. To keep the coefficients small, the arbitrary value is ordinarily one. For instance, set c_2 = 1 and solve the system of equations for the remaining coefficients: c_1 = 2 c_2 = 1 c_3 = 2 c_4 = 1 Substitute the coefficients into the chemical reaction to obtain the balanced equation: Answer: | | 2 CO + SiO_2 ⟶ 2 CO_2 + Si
Structures
![+ ⟶ +](../image_source/d974ae17e5a2f4e45d0a93d3ba3f9373.png)
+ ⟶ +
Names
![carbon monoxide + silicon dioxide ⟶ carbon dioxide + silicon](../image_source/c305c53c324616e80e4240794261545d.png)
carbon monoxide + silicon dioxide ⟶ carbon dioxide + silicon
Reaction thermodynamics
Enthalpy
![| carbon monoxide | silicon dioxide | carbon dioxide | silicon molecular enthalpy | -110.5 kJ/mol | -911 kJ/mol | -393.5 kJ/mol | 0 kJ/mol total enthalpy | -221 kJ/mol | -911 kJ/mol | -787 kJ/mol | 0 kJ/mol | H_initial = -1132 kJ/mol | | H_final = -787 kJ/mol | ΔH_rxn^0 | -787 kJ/mol - -1132 kJ/mol = 345 kJ/mol (endothermic) | | |](../image_source/ef8d2e1bfb6b7b3e41964ceb2fe8c2e8.png)
| carbon monoxide | silicon dioxide | carbon dioxide | silicon molecular enthalpy | -110.5 kJ/mol | -911 kJ/mol | -393.5 kJ/mol | 0 kJ/mol total enthalpy | -221 kJ/mol | -911 kJ/mol | -787 kJ/mol | 0 kJ/mol | H_initial = -1132 kJ/mol | | H_final = -787 kJ/mol | ΔH_rxn^0 | -787 kJ/mol - -1132 kJ/mol = 345 kJ/mol (endothermic) | | |
Equilibrium constant
![Construct the equilibrium constant, K, expression for: CO + SiO_2 ⟶ CO_2 + Si Plan: • Balance the chemical equation. • Determine the stoichiometric numbers. • Assemble the activity expression for each chemical species. • Use the activity expressions to build the equilibrium constant expression. Write the balanced chemical equation: 2 CO + SiO_2 ⟶ 2 CO_2 + Si Assign stoichiometric numbers, ν_i, using the stoichiometric coefficients, c_i, from the balanced chemical equation in the following manner: ν_i = -c_i for reactants and ν_i = c_i for products: chemical species | c_i | ν_i CO | 2 | -2 SiO_2 | 1 | -1 CO_2 | 2 | 2 Si | 1 | 1 Assemble the activity expressions accounting for the state of matter and ν_i: chemical species | c_i | ν_i | activity expression CO | 2 | -2 | ([CO])^(-2) SiO_2 | 1 | -1 | ([SiO2])^(-1) CO_2 | 2 | 2 | ([CO2])^2 Si | 1 | 1 | [Si] The equilibrium constant symbol in the concentration basis is: K_c Mulitply the activity expressions to arrive at the K_c expression: Answer: | | K_c = ([CO])^(-2) ([SiO2])^(-1) ([CO2])^2 [Si] = (([CO2])^2 [Si])/(([CO])^2 [SiO2])](../image_source/0cbd9da58446dbb1ba6b03bc0d113989.png)
Construct the equilibrium constant, K, expression for: CO + SiO_2 ⟶ CO_2 + Si Plan: • Balance the chemical equation. • Determine the stoichiometric numbers. • Assemble the activity expression for each chemical species. • Use the activity expressions to build the equilibrium constant expression. Write the balanced chemical equation: 2 CO + SiO_2 ⟶ 2 CO_2 + Si Assign stoichiometric numbers, ν_i, using the stoichiometric coefficients, c_i, from the balanced chemical equation in the following manner: ν_i = -c_i for reactants and ν_i = c_i for products: chemical species | c_i | ν_i CO | 2 | -2 SiO_2 | 1 | -1 CO_2 | 2 | 2 Si | 1 | 1 Assemble the activity expressions accounting for the state of matter and ν_i: chemical species | c_i | ν_i | activity expression CO | 2 | -2 | ([CO])^(-2) SiO_2 | 1 | -1 | ([SiO2])^(-1) CO_2 | 2 | 2 | ([CO2])^2 Si | 1 | 1 | [Si] The equilibrium constant symbol in the concentration basis is: K_c Mulitply the activity expressions to arrive at the K_c expression: Answer: | | K_c = ([CO])^(-2) ([SiO2])^(-1) ([CO2])^2 [Si] = (([CO2])^2 [Si])/(([CO])^2 [SiO2])
Rate of reaction
![Construct the rate of reaction expression for: CO + SiO_2 ⟶ CO_2 + Si Plan: • Balance the chemical equation. • Determine the stoichiometric numbers. • Assemble the rate term for each chemical species. • Write the rate of reaction expression. Write the balanced chemical equation: 2 CO + SiO_2 ⟶ 2 CO_2 + Si Assign stoichiometric numbers, ν_i, using the stoichiometric coefficients, c_i, from the balanced chemical equation in the following manner: ν_i = -c_i for reactants and ν_i = c_i for products: chemical species | c_i | ν_i CO | 2 | -2 SiO_2 | 1 | -1 CO_2 | 2 | 2 Si | 1 | 1 The rate term for each chemical species, B_i, is 1/ν_i(Δ[B_i])/(Δt) where [B_i] is the amount concentration and t is time: chemical species | c_i | ν_i | rate term CO | 2 | -2 | -1/2 (Δ[CO])/(Δt) SiO_2 | 1 | -1 | -(Δ[SiO2])/(Δt) CO_2 | 2 | 2 | 1/2 (Δ[CO2])/(Δt) Si | 1 | 1 | (Δ[Si])/(Δt) (for infinitesimal rate of change, replace Δ with d) Set the rate terms equal to each other to arrive at the rate expression: Answer: | | rate = -1/2 (Δ[CO])/(Δt) = -(Δ[SiO2])/(Δt) = 1/2 (Δ[CO2])/(Δt) = (Δ[Si])/(Δt) (assuming constant volume and no accumulation of intermediates or side products)](../image_source/226b952f974ea78a721701103ac7f613.png)
Construct the rate of reaction expression for: CO + SiO_2 ⟶ CO_2 + Si Plan: • Balance the chemical equation. • Determine the stoichiometric numbers. • Assemble the rate term for each chemical species. • Write the rate of reaction expression. Write the balanced chemical equation: 2 CO + SiO_2 ⟶ 2 CO_2 + Si Assign stoichiometric numbers, ν_i, using the stoichiometric coefficients, c_i, from the balanced chemical equation in the following manner: ν_i = -c_i for reactants and ν_i = c_i for products: chemical species | c_i | ν_i CO | 2 | -2 SiO_2 | 1 | -1 CO_2 | 2 | 2 Si | 1 | 1 The rate term for each chemical species, B_i, is 1/ν_i(Δ[B_i])/(Δt) where [B_i] is the amount concentration and t is time: chemical species | c_i | ν_i | rate term CO | 2 | -2 | -1/2 (Δ[CO])/(Δt) SiO_2 | 1 | -1 | -(Δ[SiO2])/(Δt) CO_2 | 2 | 2 | 1/2 (Δ[CO2])/(Δt) Si | 1 | 1 | (Δ[Si])/(Δt) (for infinitesimal rate of change, replace Δ with d) Set the rate terms equal to each other to arrive at the rate expression: Answer: | | rate = -1/2 (Δ[CO])/(Δt) = -(Δ[SiO2])/(Δt) = 1/2 (Δ[CO2])/(Δt) = (Δ[Si])/(Δt) (assuming constant volume and no accumulation of intermediates or side products)
Chemical names and formulas
![| carbon monoxide | silicon dioxide | carbon dioxide | silicon formula | CO | SiO_2 | CO_2 | Si Hill formula | CO | O_2Si | CO_2 | Si name | carbon monoxide | silicon dioxide | carbon dioxide | silicon IUPAC name | carbon monoxide | dioxosilane | carbon dioxide | silicon](../image_source/d1241f49c92f2a81d490158201ea29b7.png)
| carbon monoxide | silicon dioxide | carbon dioxide | silicon formula | CO | SiO_2 | CO_2 | Si Hill formula | CO | O_2Si | CO_2 | Si name | carbon monoxide | silicon dioxide | carbon dioxide | silicon IUPAC name | carbon monoxide | dioxosilane | carbon dioxide | silicon
Substance properties
![| carbon monoxide | silicon dioxide | carbon dioxide | silicon molar mass | 28.01 g/mol | 60.083 g/mol | 44.009 g/mol | 28.085 g/mol phase | gas (at STP) | solid (at STP) | gas (at STP) | solid (at STP) melting point | -205 °C | 1713 °C | -56.56 °C (at triple point) | 1410 °C boiling point | -191.5 °C | 2950 °C | -78.5 °C (at sublimation point) | 2355 °C density | 0.001145 g/cm^3 (at 25 °C) | 2.196 g/cm^3 | 0.00184212 g/cm^3 (at 20 °C) | 2.33 g/cm^3 solubility in water | | insoluble | | insoluble dynamic viscosity | 1.772×10^-5 Pa s (at 25 °C) | | 1.491×10^-5 Pa s (at 25 °C) | odor | odorless | odorless | odorless |](../image_source/dd80a6e19a34d0cf9950003ff8415f3d.png)
| carbon monoxide | silicon dioxide | carbon dioxide | silicon molar mass | 28.01 g/mol | 60.083 g/mol | 44.009 g/mol | 28.085 g/mol phase | gas (at STP) | solid (at STP) | gas (at STP) | solid (at STP) melting point | -205 °C | 1713 °C | -56.56 °C (at triple point) | 1410 °C boiling point | -191.5 °C | 2950 °C | -78.5 °C (at sublimation point) | 2355 °C density | 0.001145 g/cm^3 (at 25 °C) | 2.196 g/cm^3 | 0.00184212 g/cm^3 (at 20 °C) | 2.33 g/cm^3 solubility in water | | insoluble | | insoluble dynamic viscosity | 1.772×10^-5 Pa s (at 25 °C) | | 1.491×10^-5 Pa s (at 25 °C) | odor | odorless | odorless | odorless |
Units