these chemicals are both aldehydes and have a carbonyl group (C=O). They cannot form hydrogen bonds with other aldehydes, but will form hydrogen bonds with water molecules. the (delta) + charge on one of the hydrogen atoms in the water molecule can be sufficiently attracted to the the lone pair of the oxygen on the carbonyl group for a hydrogen bond to form.
Dispersion forces (van der waals) and dipole dipole attractions also exist between the molecules of the ketones or aldehydes and water. Forming these attractions releases energy, which also provides the energy needed to separate the water molecules and aldehyde or ketone molecules from each other so that they can mix together. As chain length increases, the hydrocarbon tail prevents such attractions occuring.
as propanal is a three carbon molecule and methanal a one carbon molecule, methanal will dissolve more easily due to its shorter hydrocarbon chain length. :D
2-methyl-1-propanol has a shorter carbon chain than 1-butanol, making it more polar due to the presence of the hydroxyl group closer to the main carbon chain, increasing its solubility in water. Additionally, the branching in 2-methyl-1-propanol reduces the surface area that can interact with nonpolar solvents, favoring interactions with water molecules and increasing solubility.
Yes! In this case, it comes down to polarity, "like dissolves like!" H20 is very polar. Draw out the dipoles on methanal. You will find that there is a huge dipole moment on methanal, depleting the carbonyl carbon of electron density. Conversely, draw out the dipoles on propanal. You will find that the charge, although not completely non-polar, is distributed more equally than methanal because of the two terminal carbons on either side of the carbonyl carbon, making the molecule as a whole less polar and therefore less soluble in water.
No, carbon dioxide is more soluble in water than oxygen. This is why carbon dioxide can readily dissolve in water to form carbonic acid, whereas oxygen is less soluble and does not react as readily with water.
Advil (ibuprofen) is a non-polar compound and is more soluble in oil than in water. It has limited solubility in water but is more soluble in organic solvents like oil.
Phosphatidylcholine is more soluble in hexane than in water. This is because phosphatidylcholine is a lipid molecule, which is nonpolar and therefore more soluble in nonpolar solvents like hexane.
Carbon monoxide is more soluble in cold water compared to hot water. This is because gases tend to dissolve better in colder temperatures.
cold water
Bromine is soluble in water.
Sodium carbonate is more soluble in water than calcium carbonate and naphthalene. Sodium carbonate is a water-soluble salt, while calcium carbonate is sparingly soluble in water, and naphthalene is insoluble in water.
Sucrose is more soluble in hot water due to the increase in molecular motion of the solute and solvent.
No, glucose is water-soluble, as it dissolves in water. Fat-soluble substances, on the other hand, dissolve in fats and oils.
No, 1-naphthylamine is not soluble in water because it is a hydrophobic compound.
No, carbon dioxide is more soluble in water than oxygen. This is why carbon dioxide can readily dissolve in water to form carbonic acid, whereas oxygen is less soluble and does not react as readily with water.
Advil (ibuprofen) is a non-polar compound and is more soluble in oil than in water. It has limited solubility in water but is more soluble in organic solvents like oil.
Clindamycin HCl is very water soluble, while only slightly soluble in alcohol.
chlorophyll is more soluble than xanthophyll
Phosphatidylcholine is more soluble in hexane than in water. This is because phosphatidylcholine is a lipid molecule, which is nonpolar and therefore more soluble in nonpolar solvents like hexane.
Carbon monoxide is more soluble in cold water compared to hot water. This is because gases tend to dissolve better in colder temperatures.
DDT is not very soluble in water. It is more soluble in organic solvents like benzene and ethanol.