Polarity Index (P´) Pentane 0.0 1,1,2-Trichlorotrifluoroethane 0.0 Cyclopentane 0.1 Heptane 0.1 Hexane 0.1 Iso-Octane 0.1 Petroleum Ether 0.1 Cyclohexane 0.2 n-Butyl Chloride 1.0 Toluene 2.4 Methyl t-Butyl Ether 2.5 o-Xylene 2.5 Chlorobenzene 2.7 o-Dichlorobenzene 2.7 Ethyl Ether 2.8 Dichloromethane 3.1 Ethylene Dichloride 3.5 n-Butyl Alcohol 3.9 Isopropyl Alcohol 3.9 n-Butyl Acetate 4.0 Isobutyl Alcohol 4.0 Methyl Isoamyl Ketone 4.0 n-Propyl Alcohol 4.0 Tetrahydrofuran 4.0 Chloroform 4.1 Methyl Isobutyl Ketone 4.2 Ethyl Acetate 4.4 Methyl n-Propyl Ketone 4.5 Methyl Ethyl Ketone 4.7 1,4-Dioxane 4.8 Acetone 5.1 Methanol 5.1 Pyridine 5.3 2-Methoxyethanol 5.5 Acetonitrile 5.8 Propylene Carbonate 6.1 N,N-Dimethylformamide 6.4 Dimethyl Acetamide 6.5 N-Methylpyrrolidone 6.7 Dimethyl Sulfoxide 7.2 Water 10.2 Not included:
Ethyl Alcohol
Glyme
Isopropyl Myristate
1,2,4-Trichlorobenzene
Triethylamine
Trifluoroacetic Acid
Butane (C4H10)
Diethyl ether (C4H10O)
Butanal (C4H8O)
Butanol (C4H10O)
Butanoic acid (C4H8O2)
He<Ne<Ar<Kr<Xe<Rn
In fractional distillation, the substances in a mixture are heated to their boiling points. Different substances have different boiling points, so will be separated at different times. The answer to your question is simply because they have different boiling points.
No, due to the fact that fractional distillation uses the difference in boiling points of liquids to seperate them, therefore in order to perform fractional distillation there should be a difference of at least 1degree centigrade
Crude oil contains mixture of various types of hydrocarbons. The hydrocarbons are separated by fractional distillation. Different hydrocarbons have different boiling points and therefore after crude oil is heated, shorter chains of hydrocarbons which have lower boiling point will become gas and can be easily separated one by one from hydrocarbons with shorter chains to longer chains. The brief products are Petroleum Gas, Gasoline, Kerosone, Heating Oil, Lubricating Oil and Bitumen in order of increasing molecular size.
list the three bacterial species in order of their increasing fastidiousness
He<Ne<Ar<Kr<Xe<Rn
In fractional distillation, the substances in a mixture are heated to their boiling points. Different substances have different boiling points, so will be separated at different times. The answer to your question is simply because they have different boiling points.
No, due to the fact that fractional distillation uses the difference in boiling points of liquids to seperate them, therefore in order to perform fractional distillation there should be a difference of at least 1degree centigrade
As a rule polar solutes are dissolved in polar solvents and nonpolar solutes are dissolved in nonpolar solvents.
in increasing order
The solution is heated to the boiling point and the solvent is collected as its a gas condenses
what is answer of 356 times 0.1 by arrange in increasing order?
Crude oil contains mixture of various types of hydrocarbons. The hydrocarbons are separated by fractional distillation. Different hydrocarbons have different boiling points and therefore after crude oil is heated, shorter chains of hydrocarbons which have lower boiling point will become gas and can be easily separated one by one from hydrocarbons with shorter chains to longer chains. The brief products are Petroleum Gas, Gasoline, Kerosone, Heating Oil, Lubricating Oil and Bitumen in order of increasing molecular size.
list the three bacterial species in order of their increasing fastidiousness
Adding impurities changes both boiling points and freezing points. The added material has its own chemical interactions with the solvent to which it is added. In order to boil, a substance must overcome the chemical attraction between its own constituent atoms or molecules. If there are also other atoms or molecules to which a constituent atom or molecule of a given substance is also attracted, the boiling point will therefore be higher. No it's not the same it dip pends on what the substance is.
need to arrange 5/8,1/2,4/11 in increasing order
At a pressure of one atmosphere Germanium is a liquid between the melting temperature of 938.25 °C (that is 1720.85 °F) and the boiling temperature of 2833 °C (that is 5131 °F). This temperature range is affected by pressure and in order to have boiling and melting points for an arbitrary environmental pressure the Germanium Phase Diagram has to be consulted, providing the boiling and melting temperatures versus the environmental pressure.