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24CuSCN + 114HNO3 → 24CuSO4 + 58N2O3↑ + 11(NH4)2CO3 + 13H2CO3

24CuSCN + 114HNO₃ → 24CuSO₄ + 58N₂O₃↑ + 11(NH₄)₂CO₃ + 13H₂CO₃

Last updated: June 13, 2022

Reaction of copper(I) thiocyanate and nitric acid: 24CuSCNCopper(I) thiocyanate + 114HNO₃Nitric acid
⟶
24CuSO₄Copper(II) sulfate + 58N₂O₃↑Dinitrogen trioxide + 11(NH₄)₂CO₃Ammonium carbonate + 13H₂CO₃Carbonic acid

The reaction of copper(I) thiocyanate and nitric acid yields copper(II) sulfate, dinitrogen trioxide, ammonium carbonate, and carbonic acid (Other reactions are here). This reaction is an oxidation-reduction reaction and is classified as follows:

Reaction of reducing species and oxidizing species

Table of contents

Reaction data

Chemical equation

Reaction of copper(I) thiocyanate and nitric acid: 24CuSCNCopper(I) thiocyanate + 114HNO₃Nitric acid
⟶
24CuSO₄Copper(II) sulfate + 58N₂O₃↑Dinitrogen trioxide + 11(NH₄)₂CO₃Ammonium carbonate + 13H₂CO₃Carbonic acid

General equation

Reaction of reducing species and oxidizing species: Reducing speciesReducing agent + Oxidizing speciesOxidizing agent
⟶
ProductOxidation product + ProductReduction product

Oxidation state of each atom

Reaction of copper(I) thiocyanate and nitric acid

Reactants

Chemical formula	Name	Coefficient	Type	Type in general equation
CuSCN	Copper(I) thiocyanate	24	Reducing	Reducing
HNO₃	Nitric acid	114	Oxidizing	Oxidizing

Products

Chemical formula	Name	Coefficient	Type	Type in general equation
CuSO₄	Copper(II) sulfate	24	Oxidized	–
N₂O₃	Dinitrogen trioxide	58	Redoxed product	–
(NH₄)₂CO₃	Ammonium carbonate	11	–	–
H₂CO₃	Carbonic acid	13	–	–

Thermodynamic changes

Changes in aqueous solution (1)

Reaction of copper(I) thiocyanate and nitric acid ◆ Δ_rG −14916.36 kJ/mol K 1.71 × 10²⁶¹³ pK −2613.23: 24CuSCNIonized aqueous solution + 114HNO₃Ionized aqueous solution
⟶
24CuSO₄Un-ionized aqueous solution + 58N₂O₃↑Gas + 11(NH₄)₂CO₃Ionized aqueous solution + 13H₂CO₃Un-ionized aqueous solution

	Standard enthalpy of reaction Δ_rH° kJ · mol⁻¹	Standard Gibbs energy of reaction Δ_rG° kJ · mol⁻¹	Standard entropy of reaction Δ_rS° J · K⁻¹ · mol⁻¹	Standard heat capacity of reaction at constant pressure Δ_rC_p° J · K⁻¹ · mol⁻¹
per 1 mol of Equation	–	−14916.36	–	–
per 1 mol of Copper(I) thiocyanate	–	−621.5150	–	–
per 1 mol of Nitric acid	–	−130.8453	–	–
per 1 mol of Copper(II) sulfate	–	−621.5150	–	–
per 1 mol of Dinitrogen trioxide	–	−257.1786	–	–
per 1 mol of Ammonium carbonate	–	−1356.033	–	–
per 1 mol of Carbonic acid	–	−1147.412	–	–

Changes in aqueous solution (2)

Reaction of copper(I) thiocyanate and nitric acid ◆ Δ_rG −14187.2 kJ/mol K 3.09 × 10²⁴⁸⁵ pK −2485.49: 24CuSCNIonized aqueous solution + 114HNO₃Ionized aqueous solution
⟶
24CuSO₄Crystalline solid + 58N₂O₃↑Gas + 11(NH₄)₂CO₃Ionized aqueous solution + 13H₂CO₃Un-ionized aqueous solution

	Standard enthalpy of reaction Δ_rH° kJ · mol⁻¹	Standard Gibbs energy of reaction Δ_rG° kJ · mol⁻¹	Standard entropy of reaction Δ_rS° J · K⁻¹ · mol⁻¹	Standard heat capacity of reaction at constant pressure Δ_rC_p° J · K⁻¹ · mol⁻¹
per 1 mol of Equation	−13031.58	−14187.2	3906	–
per 1 mol of Copper(I) thiocyanate	−542.9825	−591.133	162.8	–
per 1 mol of Nitric acid	−114.3121	−124.449	34.26	–
per 1 mol of Copper(II) sulfate	−542.9825	−591.133	162.8	–
per 1 mol of Dinitrogen trioxide	−224.6824	−244.607	67.34	–
per 1 mol of Ammonium carbonate	−1184.689	−1289.75	355.1	–
per 1 mol of Carbonic acid	−1002.429	−1091.32	300.5	–

Thermodynamic data of reactants

Chemical formula	Standard enthalpy of formation Δ_fH° kJ · mol⁻¹	Standard Gibbs energy of formation Δ_fG° kJ · mol⁻¹	Standard molar entropy S° J · K⁻¹ · mol⁻¹	Standard molar heat capacity at constant pressure C_p° J · K⁻¹ · mol⁻¹
CuSCN (cr)	–	69.9^[1]	–	–
CuSCN (ai)	148.11^[1]	142.69^[1]	184.9^[1]	–
HNO₃ (l)	-174.10^[1]	-80.71^[1]	155.60^[1]	109.87^[1]
HNO₃ (g)	-135.06^[1]	-74.72^[1]	266.38^[1]	53.35^[1]
HNO₃ (ai)	-207.36^[1]	-111.25^[1]	146.4^[1]	-86.6^[1]
HNO₃ (l) 1 hydrate	-473.46^[1]	-328.77^[1]	216.90^[1]	182.46^[1]
HNO₃ (l) 3 hydrate	-1056.04^[1]	-811.09^[1]	346.98^[1]	325.14^[1]

* (cr):Crystalline solid, (ai):Ionized aqueous solution, (l):Liquid, (g):Gas

Thermodynamic data of products

Chemical formula	Standard enthalpy of formation Δ_fH° kJ · mol⁻¹	Standard Gibbs energy of formation Δ_fG° kJ · mol⁻¹	Standard molar entropy S° J · K⁻¹ · mol⁻¹	Standard molar heat capacity at constant pressure C_p° J · K⁻¹ · mol⁻¹
CuSO₄ (cr)	-771.36^[1]	-661.8^[1]	109^[1]	100.0^[1]
CuSO₄ (ai)	-844.50^[1]	-679.04^[1]	-79.5^[1]	–
CuSO₄ (ao)	–	-692.18^[1]	–	–
CuSO₄ (cr) 1 hydrate	-1085.83^[1]	-918.11^[1]	146.0^[1]	134^[1]
CuSO₄ (cr) 3 hydrate	-1684.31^[1]	-1399.96^[1]	221.3^[1]	205^[1]
CuSO₄ (cr) 5 hydrate	-2279.65^[1]	-1879.745^[1]	300.4^[1]	280^[1]
N₂O₃ (l)	50.29^[1]	–	–	–
N₂O₃ (g)	83.72^[1]	139.46^[1]	312.28^[1]	65.61^[1]
(NH₄)₂CO₃ (ai)	-942.15^[1]	-686.42^[1]	169.9^[1]	–
H₂CO₃ (ao)	-699.65^[1]	-623.08^[1]	187.4^[1]	–

* (cr):Crystalline solid, (ai):Ionized aqueous solution, (ao):Un-ionized aqueous solution, (l):Liquid, (g):Gas

References

List of references

1
Janiel J. Reed (1989)
The NBS Tables of Chemical Thermodynamic Properties: Selected Values for Inorganic and C1 and C2 Organic Substances in SI Units
https://doi.org/10.18434/M32124
National Institute of Standards and Technology (NIST)
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