%0 Journal Article %1 Yoonetal_03 %A Yoon, Y. %A Pope, J. %A Wolfe, J. %D 2003 %J Cryobiology %K bibtex-import, citeulikeExport cryo, freezing, physics, snowgumpapermaybe %P 271--276 %T Freezing stresses and hydration of isolated cell walls %V 46 %X The hydration of the cell walls of the giant alga Chara australis was measured as a function of temperature using quantitative deuterium nuclear magnetic resonance (NMR) of samples hydrated with D2 O. At temperatures 23?5 K below freezing, the hydration ratio (the ratio of mass of unfrozen water in microscopic phases in the cell wall to the dry mass) increases slowly with increasing temperature from about 0.2 to 0.4. It then rises rapidly with temperature in the few Kelvin below the freezing temperature. The linewidth of the NMR signal varies approximately linearly with the reciprocal of the hydration ratio, and with the freezing point depression or water potential. These empirical relations may be useful in estimating cell wall water contents in heterogeneous samples.

@article{Yoonetal_03, abstract = {{The hydration of the cell walls of the giant alga Chara australis was measured as a function of temperature using quantitative deuterium nuclear magnetic resonance (NMR) of samples hydrated with D2 O. At temperatures 23?5 K below freezing, the hydration ratio (the ratio of mass of unfrozen water in microscopic phases in the cell wall to the dry mass) increases slowly with increasing temperature from about 0.2 to 0.4. It then rises rapidly with temperature in the few Kelvin below the freezing temperature. The linewidth of the NMR signal varies approximately linearly with the reciprocal of the hydration ratio, and with the freezing point depression or water potential. These empirical relations may be useful in estimating cell wall water contents in heterogeneous samples.}}, added-at = {2019-03-31T01:14:40.000+0100}, author = {Yoon, Y. and Pope, J. and Wolfe, J.}, biburl = {https://www.bibsonomy.org/bibtex/2eff5de66afb68778a9cba2b7e3f8b8a0/dianella}, citeulike-article-id = {1524134}, comment = {(private-note)there is unfrozen water in cell walls. And quite a lot. Does this imply that it diffuses to sites of extracellular ice? What would the NMR signal be if it was a glass? Their guess of what happens: As the temperature of the ice falls, the pressure in the water in the wall becomes increasingly negative, <b>drawing the fibres closer</b> and closer together until it is balanced by the short range repulsive force. the diameter of cellulose microfibrils varies with hydration, and is possibly different among species [11].}, interhash = {2ba5b6ea761d99b4e9586c83d24d20e2}, intrahash = {eff5de66afb68778a9cba2b7e3f8b8a0}, journal = {Cryobiology}, keywords = {bibtex-import, citeulikeExport cryo, freezing, physics, snowgumpapermaybe}, pages = {271--276}, posted-at = {2007-07-31 07:40:19}, priority = {2}, timestamp = {2019-03-31T01:16:26.000+0100}, title = {{Freezing stresses and hydration of isolated cell walls}}, volume = 46, year = 2003 }