If you think about the boiling of water, I'm sure you can understand that heat breaks hydrogen bonds. Next consider that the hydrophobic effect is driven entropically and so, by the equation $\Delta G=\Delta H-T\Delta S$, its strength increases with temperature. See here and here for further explanation.

If you think about the boiling of water, I'm sure you can understand that heat breaks hydrogen bonds. Next consider that the hydrophobic effect is driven entropically and so, by the equation $\Delta G=\Delta H-T\Delta S$, its strength increases with temperature (to a point). See here and here for further explanation. Also, this paper for a more empirical view.

If you think about the boiling of water, I'm sure you can understand that heat breaks hydrogen bonds. Next consider that the hydrophobic effect is driven entropically and so, by the equation $\Delta G=\Delta H-T\Delta S$, its strength increases with temperature.

If you think about the boiling of water, I'm sure you can understand that heat breaks hydrogen bonds. Next consider that the hydrophobic effect is driven entropically and so, by the equation $\Delta G=\Delta H-T\Delta S$, its strength increases with temperature. See here and here for further explanation.