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Freezing Points Liquids

Reference data and engineering information about freezing points liquids for miscellaneous applications.

freezingpointsliquids

Overview

Engineering reference data for Freezing Points Liquids in miscellaneous.

Key Formulas

Unit Conversion

y=xky = x \cdot k

Multiply by conversion factor.

Linear Interpolation

y=y1+(xx1)(y2y1)x2x1y = y_1 + \frac{(x - x_1)(y_2 - y_1)}{x_2 - x_1}

Estimate between two known points.

Percentage

p=partwhole×100%p = \frac{\text{part}}{\text{whole}} \times 100\%

Part as fraction of whole.

Variables

SymbolDescriptionUnit
xxInput value
yyOutput value
kkConversion factor

Freezing Points of Common Liquids

The following table provides freezing or melting points (at 1 atm) for a selection of common liquids. For a pure substance, these points are identical; for mixtures, ranges exist.

52 rows
Freezing or Melting Points of Common Liquids at 1 atm
Fluid
Freezing or Melting Point(K)
Acetic acid290
Acetone179
Alcohol, allyl144
Alcohol, ethyl (ethanol)158.6
Alcohol, isobutyl165
Alcohol, methyl (methanol)175.5
Alcohol, propyl146
Aniline267
Anisole235.5
Benzene278.7
Benzonitrile260.3
Bromine265.95
Bromobenzene242.4
Butane135
Camphor452
Carbon Dioxide194.5
Carbon Disulfide161.2
Carbon Tetrachloride (Tetrachloromethane)250.4
Castor Oil263.2
Chlorobenzene227.8
Chloroform (Trichloromethane)209.6
3-Chloropropene (Allyl Chloride)138.5
Cyclohexane280
Decane243.5
Dodecane247.2
Ether157
Ethyl acetate189.4
Ethylene bromide283
Ethylene Glycol260.2
Formic acid281
Trichlorofluoromethane refrigerant R-11162
Dichlorodifluoromethane refrigerant R-12115
Glycerine290.8
n-Heptane182.5
Hexane178
Iodine386.6
Isopentane (2-Methylbutane)113.1
Linseed oil253
Mercury234.13
Methylcyclopentane130.5
Naphthalene353
Nitrobenzene278.7
Nitrogen63.14
n-Octane216.4
Pentane143.3
Phenol316.2
Propylene87.9
Propylene glycol213
Toluene178
Turpentine214
Water, Fresh273
Water, Sea270.6

Source: engineeringtoolbox.com

Pure Substances vs. Mixtures

For a pure substance, the melting point and freezing point are identical at a given pressure.

For a mixture (e.g., petroleum), there is a range of melting/freezing points. The initial melting point is close to the melting point of the lightest component, while the initial freezing point is close to the freezing point of the heaviest component. This is why, for petroleum mixtures, the initial freezing point is greater than the initial melting point.

References