Sodium carbonate
| Sodium carbonate | | |
| General |
|---|
| Other names | Soda ash
Washing soda |
| Molecular formula | Na2CO3 |
| Molar mass | 106.0 g/mol |
| Appearance | Dark White solid |
| CAS number | [497-19-8] |
| Properties |
|---|
| Density and phase | 2.5 g/cm3, solid |
| Solubility in water | 30 g/100 ml (20 °C) |
>| Melting point851 °C |
| Boiling point | decomposes |
| Basicity (pKb) | ? |
| Structure |
|---|
Coordination
geometry | ? |
| Crystal structure | ? |
| Hazards |
|---|
| MSDS | External MSDS |
| EU classification | Irritant (Xi) |
| NFPA 704 | |
| R-phrases | |
| S-phrases | , , |
| Flash point | non flammable |
| RTECS number | VZ4050000 |
| Supplementary data page |
|---|
Structure and
properties | n, εr, etc. |
Thermodynamic
data | Phase behaviour
Solid, liquid, gas |
| Spectral data | UV, IR, NMR, MS |
| Related compounds |
|---|
| Other s | Sodium bicarbonate |
| Other s | Lithium carbonate
Potassium carbonate |
Except where noted otherwise, data are given for
materials in their standard state (at 25 °C, 100 kPa)
Infobox disclaimer and references |
|
Sodium carbonate (also known as
washing soda or
soda ash), , is a
sodium salt of
carbonic acid. It most commonly occurs as a
crystaline heptahydrate which readily
effloresces to form a white powder, the monohydrate. It has a cooling
alkaline taste, and can be extracted from the ashes of many
plants. It is produced artificially in large quantities from
common salt.
Sodium carbonate is used in the manufacture of
glass, pulp and
paper,
detergents, and chemicals such as sodium
silicates and sodium
phosphates. It is also used as an
alkaline agent in many chemical industries.
Domestically it is used as a water softener during laundry. It competes with the ions
magnesium and
calcium in hard water and prevents them from bonding with the detergent being used. Without using washing soda, additional detergent is needed to soak up the magnesium and calcium ions. Called washing soda in the detergent section of stores, it effectively removes oil, grease, and alcohol stains.
Sodium carbonate is widely used in photographic processes as a pH regulator to maintain stable alkaline conditions necessary for the action of the majority of
developing agents.
Sodium carbonate is also used by the brick industry as a wetting agent to reduce the amount of water needed to extrude the clay.
Sodium carbonate is also what they use in Ramen to make it "instant".
[See Nissin Foods.]Sodium carbonate is soluble in
water, but can occur naturally in arid regions, especially in the
mineral deposits (
evaporites) formed when seasonal
lakes evaporate. Deposits of the mineral
natron, a combination of sodium carbonate and
sodium bicarbonate, have been mined from dry lake bottoms in
Egypt since ancient times, when
natron was used in the preparation of
mummies and in the early manufacture of glass. Sodium carbonate has three known forms of hydrates: sodium carbonate decahydrate, sodium carbonate heptahydrate and sodium carbonate monohydrate.
In 1791, the
French chemist
Nicolas Leblanc patented a process for producing sodium carbonate from
salt,
sulfuric acid,
limestone, and
coal. First, sea salt (
sodium chloride) was boiled in sulfuric acid to yield
sodium sulfate and
hydrochloric acid gas, according to the
chemical equation2
NaCl +
H2SO4 â†'
Na2SO4 + 2
HClNext, the sodium sulfate was blended with crushed limestone (
calcium carbonate) and coal, and the mixture was burnt, producing sodium carbonate along with
carbon dioxide and
calcium sulfide.
Na2SO4 +
CaCO3 + 2
C â†' Na
2CO
3 + 2
CO2 +
CaSThe sodium carbonate was
extracted from the ashes with water, and then collected by allowing the water to evaporate.
The hydrochloric acid produced by the
Leblanc process was a major source of
air pollution, and the calcium sulphide byproduct also presented waste disposal issues. However, it remained the major production method for sodium carbonate until the late 1880s.
In 1861, the
Belgian industrial chemist
Ernest Solvay developed a method to convert sodium chloride to sodium carbonate using
ammonia. The
Solvay process centered around a large hollow tower. At the bottom, calcium carbonate (limestone) was heated to release carbon dioxide:
CaCO3 â†'
CaO +
CO2At the top, a concentrated solution of sodium chloride and ammonia entered the tower. As the carbon dioxide bubbled up through it, sodium bicarbonate precipitated:
NaCl +
NH3 +
CO2 +
H2O â†'
NaHCO3 +
NH4ClThe sodium bicarbonate was then converted to sodium carbonate by heating it, releasing water and carbon dioxide:
2
NaHCO3 â†' Na
2CO
3 +
H2O +
CO2Meanwhile, the ammonia was regenerated from the ammonium chloride byproduct by treating it with the lime (
calcium hydroxide) left over from carbon dioxide generation:
CaO +
H2O â†'
Ca(OH)2:
Ca(OH)2 + 2
NH4Cl â†'
CaCl2 + 2
NH3 + 2
H2OBecause the Solvay process recycled its ammonia, it consumed only brine and limestone, and had
calcium chloride as its only waste product. This made it substantially more economical than the Leblanc process, and it soon came to dominate world sodium carbonate production. By 1900, 90% of sodium carbonate was produced by the Solvay process, and the last Leblanc process plant closed in the early 1920s.
Sodium carbonate is still produced by the Solvay process in much of the world today. However, large natural deposits found in 1938 near the
Green River in
Wyoming, have made its industrial production in
North America uneconomical.
*
International Chemical Safety Card 1135*
Use of sodium carbonate in dyeing
