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  3. 32CuSCN + 61HNO3 → 19CuCO3 + 13CuS + 6(NH4)2SO4 + 34N2O3↑ + 13HSCN

32CuSCN + 61HNO3 → 19CuCO3 + 13CuS + 6(NH4)2SO4 + 34N2O3↑ + 13HSCN

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Reaction of copper(I) thiocyanate and nitric acid
32CuSCNCopper(I) thiocyanate + 61HNO3Nitric acid
19CuCO3Copper(II) carbonate + 13CuSCopper(II) sulfide + 6(NH4)2SO4Ammonium sulfate + 34N2O3Dinitrogen trioxide + 13HSCNThiocyanic acid

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

Table of contents
  1. 1Reaction data
  2. 2Thermodynamic changes
  3. 3References
  4. 4Related reactions
  5. 5Related categories

Reaction data

Chemical equation

Reaction of copper(I) thiocyanate and nitric acid
32CuSCNCopper(I) thiocyanate + 61HNO3Nitric acid
19CuCO3Copper(II) carbonate + 13CuSCopper(II) sulfide + 6(NH4)2SO4Ammonium sulfate + 34N2O3Dinitrogen trioxide + 13HSCNThiocyanic 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 formulaNameCoefficientTypeType in general
equation
CuSCNCopper(I) thiocyanate32
Reducing
Reducing
HNO3Nitric acid61
Oxidizing
Oxidizing

Products

Chemical formulaNameCoefficientTypeType in general
equation
CuCO3Copper(II) carbonate19
Oxidized
CuSCopper(II) sulfide13
Oxidized
(NH4)2SO4Ammonium sulfate6
Oxidized
N2O3Dinitrogen trioxide34
Redoxed product
HSCNThiocyanic acid13

Thermodynamic changes

Thermodynamic data of reactants

Chemical formulaStandard enthalpy
of formation
ΔfH°
kJ · mol−1		Standard Gibbs
energy of
formation
ΔfG°
kJ · mol−1		Standard
molar entropy
S°
J · K−1 · mol−1		Standard molar
heat capacity at
constant pressure
Cp°
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 formulaStandard enthalpy
of formation
ΔfH°
kJ · mol−1		Standard Gibbs
energy of
formation
ΔfG°
kJ · mol−1		Standard
molar entropy
S°
J · K−1 · mol−1		Standard molar
heat capacity at
constant pressure
Cp°
J · K−1 · mol−1
CuCO3
CuS (cr)-53.1[1]-53.6[1]66.5[1]47.82[1]
(NH4)2SO4 (cr)-1180.85[1]-901.67[1]220.1[1]187.49[1]
(NH4)2SO4 (ai)-1174.28[1]-903.14[1]246.9[1]-133.1[1]
N2O3 (l)50.29[1]
N2O3 (g)83.72[1]139.46[1]312.28[1]65.61[1]
HSCN (ai)76.44[1]92.71[1]144.3[1]-40.2[1]
HSCN (ao)97.56[1]
* (cr):Crystalline solid, (ai):Ionized aqueous solution, (l):Liquid, (g):Gas, (ao):Un-ionized aqueous solution

References

List of references

  1. 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
    National Institute of Standards and Technology (NIST)