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Solubility chart

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(Redirected from Solubility Chart) Chart describing whether ionic compounds dissolve or precipitate For detailed information on exact solubility of compounds, see solubility table.

A solubility chart is a chart describing whether the ionic compounds formed from different combinations of cations and anions dissolve in or precipitate from solution.

Chart

The following chart shows the solubility of various ionic compounds in water at 1 atm pressure and room temperature (approx. 25 °C, 298.15 K). "Soluble" means the ionic compound doesn't precipitate, while "slightly soluble" and "insoluble" mean that a solid will precipitate; "slightly soluble" compounds like calcium sulfate may require heat to precipitate. For compounds with multiple hydrates, the solubility of the most soluble hydrate is shown.

Some compounds, such as nickel oxalate, will not precipitate immediately even though they are insoluble, requiring a few minutes to precipitate out.

Key
S highly soluble or miscible ≥20 g/L
sS slightly soluble 0.1~20 g/L
I relatively insoluble <0.1 g/L
R reacts with or in water
? unavailable
Ions names and symbols Halogens Chalcogens Pnictogens Crystallogens
Fluoride
F
Chloride
Cl
Bromide
Br
Iodide
I
Perchlorate
ClO
4
Oxide
O
Hydroxide
OH
Sulfide
S
Sulfate
SO
4
Nitrate
NO
3
Phosphate
PO
4
Carbonate
CO
3
Cyanide
CN
Thiocyanate
SCN
Acetate
C
2H
3O
2
Oxalate
C
2O
4
Hydrogen H S S S S S S S sS S S S S S S S S
Ammonium NH
4
S S S S S S S R S S S S S S S S
Lithium Li sS S S S S R S R S S sS sS S S S S
Sodium Na S S S S S R S R S S S S S S S S
Potassium K S S S S sS R S R S S S S S S S S
Rubidium Rb S S S S sS R S R S S S S S S S S
Caesium Cs S S S S sS R S R S S S S S S S S
Beryllium Be S S S R S I I R S S I sS R S S S
Magnesium Mg sS S S S S R I R S S I sS R S S sS
Calcium Ca I S S S S R sS R sS S I I R S S sS
Strontium Sr sS S S S S R sS R sS S sS I S S S I
Barium Ba sS S S S S R S R I S I sS S S S I
Aluminium Al sS S S S S I I R S S I R R S S I
Gallium Ga I S S R S I I R sS S I R R S S ?
Manganese(II) Mn sS S S S S I I I S S I I S S S I
Iron(II) Fe sS S S S S I I I S S I I S S S sS
Cobalt(II) Co sS S S S S I I I S S I I I S S I
Nickel(II) Ni S S S S S I I I S S I I I S S I
Copper(II) Cu sS S S ? S I I I S S I I I I S I
Zinc Zn sS S S S S I I I S S I I I S S I
Cadmium Cd S S S S S I I I S S I I sS sS S I
Mercury(II) Hg R S sS I S I I I R S I I S sS S sS
Vanadium(III) V I S S S S I I I sS S I ? ? S ? ?
Chromium(III) Cr sS S S S S I I I S S I I S S S ?
Iron(III) Fe S S S R S I I I S S sS R S S S sS
Gold(III) Au R S sS ? ? I I I ? ? I I S ? sS ?
Tin(II) Sn S S S S S I I I S ? I I ? I R sS
Lead(II) Pb sS sS sS sS S I sS I I S I I sS sS S I
Silver Ag S I I I S I I I sS S I I I I sS I
Mercury(I) Hg
2
R I I I S I ? ? sS S ? I I ? S ?
  Fluoride
F
Chloride
Cl
Bromide
Br
Iodide
I
Perchlorate
ClO
4
Oxide
O
Hydroxide
OH
Sulfide
S
Sulfate
SO
4
Nitrate
NO
3
Phosphate
PO
4
Carbonate
CO
3
Cyanide
CN
Thiocyanate
SCN
Acetate
C
2H
3O
2
Oxalate
C
2O
4

See also

Notes

  1. ^ Compounds that include ammonium (NH
    4), chlorate (ClO
    3), or nitrate (NO
    3) are soluble without exceptions. Compounds that include carbonate (CO
    3) are insoluble, unless the compound includes group 1 elements or ammonium.
  2. "Ammonium oxide" does not exist. However, its theoretical molecular formula (NH
    4)2O represents that of aqueous ammonia.
  3. Partial electrolysis.
  4. The commonly encountered basic copper carbonate (Cu2CO3(OH)2) is insoluble in water. True copper(II) carbonate (CuCO3) is rare and reacts with water to form basic copper carbonate.
  5. Anhydrous FeF3 is slightly soluble in water; FeF3·3H2O is much more soluble in water.
  6. The commonly encountered basic iron(III) acetate (OAc) is insoluble in water. True iron(III) acetate (Fe(OAc)3) is rare and is soluble in water.
  7. ^ Slowly decomposes in water.

References

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