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MgCO3 + H2[PtCl6] → MgCl2 + PtCl4 + CO2↑ + H2O

MgCO₃ + H₂[PtCl₆] → MgCl₂ + PtCl₄ + CO₂↑ + H₂O

Last updated: June 13, 2022

Reaction of magnesium carbonate and hexachloridoplatinic(IV) acid: MgCO₃Magnesium carbonate + H₂[PtCl₆]Hexachloridoplatinic(IV) acid
⟶
MgCl₂Magnesium chloride + PtCl₄Platinum(IV) chloride + CO₂↑Carbon dioxide + H₂OWater

The reaction of magnesium carbonate and hexachloridoplatinic(IV) acid yields magnesium chloride, platinum(IV) chloride, carbon dioxide, and water (Other reactions are here). This reaction is an acid-base reaction and is classified as follows:

Reaction of salt of weak acid and strong acid with generating weak acidic oxide

Table of contents

Reaction data

Chemical equation

Reaction of magnesium carbonate and hexachloridoplatinic(IV) acid: MgCO₃Magnesium carbonate + H₂[PtCl₆]Hexachloridoplatinic(IV) acid
⟶
MgCl₂Magnesium chloride + PtCl₄Platinum(IV) chloride + CO₂↑Carbon dioxide + H₂OWater

General equation

Reaction of salt of weak acid and strong acid with generating weak acidic oxide: Salt of weak acidBrønsted base + Strong acidBrønsted acid
⟶
Salt of strong acidConjugate base + Acidic oxide + H₂OConjugate acid

Oxidation state of each atom

Reaction of magnesium carbonate and hexachloridoplatinic(IV) acid

Reactants

Chemical formula	Name	Coefficient	Type	Type in general equation
MgCO₃	Magnesium carbonate	1	Brønsted base	Salt of weak acid
H₂[PtCl₆]	Hexachloridoplatinic(IV) acid	1	Brønsted acid	Strong acid

Products

Chemical formula	Name	Coefficient	Type	Type in general equation
MgCl₂	Magnesium chloride	1	Conjugate base	Salt of strong acid
PtCl₄	Platinum(IV) chloride	1	Conjugate base	Salt of strong acid
CO₂	Carbon dioxide	1	–	Acidic oxide
H₂O	Water	1	Conjugate acid	Water

Thermodynamic changes

Changes in aqueous solution (1)

Reaction of magnesium carbonate and hexachloridoplatinic(IV) acid: MgCO₃Crystalline solid + H₂[PtCl₆]Ionized aqueous solution
⟶
MgCl₂Ionized aqueous solution + PtCl₄Aqueous solution + CO₂↑Gas + H₂OLiquid

	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	−30.7	–	–	–
per 1 mol of Magnesium carbonate	−30.7	–	–	–
per 1 mol of Hexachloridoplatinic(IV) acid	−30.7	–	–	–
per 1 mol of Magnesium chloride	−30.7	–	–	–
per 1 mol of Platinum(IV) chloride	−30.7	–	–	–
per 1 mol of Carbon dioxide	−30.7	–	–	–
per 1 mol of Water	−30.7	–	–	–

Changes in aqueous solution (2)

Reaction of magnesium carbonate and hexachloridoplatinic(IV) acid: MgCO₃Crystalline solid + H₂[PtCl₆]Ionized aqueous solution
⟶
MgCl₂Ionized aqueous solution + PtCl₄Aqueous solution + CO₂↑Un-ionized aqueous solution + H₂OLiquid

	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	−51.0	–	–	–
per 1 mol of Magnesium carbonate	−51.0	–	–	–
per 1 mol of Hexachloridoplatinic(IV) acid	−51.0	–	–	–
per 1 mol of Magnesium chloride	−51.0	–	–	–
per 1 mol of Platinum(IV) chloride	−51.0	–	–	–
per 1 mol of Carbon dioxide	−51.0	–	–	–
per 1 mol of Water	−51.0	–	–	–

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
MgCO₃ (cr)	-1095.8^[1]	-1012.1^[1]	65.7^[1]	75.52^[1]
MgCO₃ (cr) 3 hydrate	–	-1726.1^[1]	–	–
MgCO₃ (cr) 5 hydrate	–	-2199.2^[1]	–	–
H₂[PtCl₆] (ai)	-668.2^[1]	-482.7^[1]	219.7^[1]	–
H₂[PtCl₆] (cr) 6 hydrate	-2371.1^[1]	–	–	–

* (cr):Crystalline solid, (ai):Ionized aqueous solution

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
MgCl₂ (cr)	-641.32^[1]	-591.79^[1]	89.62^[1]	71.38^[1]
MgCl₂ (g)	-400.4^[1]	–	–	–
MgCl₂ (ai)	-801.15^[1]	-717.1^[1]	-25.1^[1]	–
MgCl₂ (cr) 1 hydrate	-966.63^[1]	-861.74^[1]	137.2^[1]	115.27^[1]
MgCl₂ (cr) 2 hydrate	-1279.72^[1]	-1118.00^[1]	179.9^[1]	159.20^[1]
MgCl₂ (cr) 4 hydrate	-1898.99^[1]	-1623.29^[1]	264.0^[1]	241.42^[1]
MgCl₂ (cr) 6 hydrate	-2499.02^[1]	-2114.64^[1]	366.1^[1]	315.06^[1]
PtCl₄ (cr)	-231.8^[1]	–	–	–
PtCl₄ (aq)	-314.2^[1]	–	–	–
PtCl₄ (cr) 5 hydrate	-1752.7^[1]	–	–	–
CO₂ (g)	-393.509^[1]	-394.359^[1]	213.74^[1]	37.11^[1]
CO₂ (ao)	-413.80^[1]	-385.98^[1]	117.6^[1]	–
H₂O (cr)	–	–	–	–
H₂O (l)	-285.830^[1]	-237.129^[1]	69.91^[1]	75.291^[1]
H₂O (g)	-241.818^[1]	-228.572^[1]	188.825^[1]	33.577^[1]

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

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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