How does $"hydrogen bonding"$ affect $"normal boiling points"$?

Osmosis is a passive process and involves the of water molecules from where there is a high water potential to where there is a lower water potential down the water...

Density increases as mass increases, vice versa Density increases as volume decreases, vice versa This is because mass, the numerator of the equation, would cause the final answer (density)...

You know the normal boiling point of water. The normal boiling point of hydrogen sulfide is $-60$ $""^@C$; that of hydrogen selenide is $-41.2$ $""^@C$; that of hydrogen telluride is...

Hydrogen is a strong bond, therefore, it produces a lower evaporation rate and thus, a lower vapor pressure.

Hydrogen Bonding is a type of dipole-dipole interaction. This means that there are permanent partial charges on hydrogen and oxygen in water, so they attract each other from separate molecules....

make matter more stable. Whenever you are trying to changes phases it takes energy to overcome those strong inter molecular forces. In turn the melting point is raised to...

See this You should also compare the boiling points of $NH_3$, $OH_2$, and $HF$, with the hydrides of the lower Group. i.e. $PH_3, SH_2$ etc. The normal boiling points...

Hydrogen bonding occurs where HYDROGEN is bound to a strongly electronegative element, i.e. hydrogen is bound to fluorine, nitrogen, or oxygen. In $"fluoroform"$, the hydrogen is bound to carbon not...

$H_2S$, and $PH_3$ are real molecules, and for the phosphine, hydrogen-bonding DOES not occur. And for the sulfide, hydrogen-bonding is only marginal. Phosphine is a room temperature gas, and hydrogen...

Whereas dipole-dipole interaction operates for $"methylene chloride"$, and dispersion forces are the primary intermolecular force in $"carbon tetrachloride"$. And note that dispersion forces operate between all molecules, but in $HF$...