Title :
Temporally resolved imaging of ice nucleation and growth in highly supercooled water
Author :
McCloskey, John P. ; Karlsson, Jens O M
Author_Institution :
Villanova Univ., Villanova, PA, USA
Abstract :
Damage to cryopreserved cells is dependent on the kinetics and morphology of ice formation in supercooled thermodynamic states. To gain a better understanding of ice crystallization phenomena under such non-equilibrium conditions, we undertook an investigation of crystal growth in highly supercooled water droplets in the range of -28°C to -38°C. Microscale droplets of distilled water were frozen, and the ice crystal growth process was recorded using a high-speed imaging system. Crystal growth velocities were found to range from 245 mm/s to 470 mm/s, and were significantly lower than growth velocities predicted by the Langer Müller-Krumbhaar theory, suggesting a crossover from a diffusion-limited regime to a kinetic-limited regime at high supercooling.
Keywords :
biological techniques; cellular biophysics; crystal growth from solution; crystal morphology; nucleation; supercooling; thermodynamic properties; water; Langer Muller-Krumbhaar theory; cryopreserved cell damage; crystal growth velocities; diffusion-limited regime; distilled water; high supercooling; high-speed imaging system; highly supercooled water droplets; ice crystal growth processing; ice crystallization phenomena; ice nucleation; kinetic-limited regime; microscale droplets; morphology; supercooled thermodynamic states; temperature -28 degC to 38 degC; temporally resolved imaging; Crystallization; Ice; Imaging; Kinetic theory; Morphology; Temperature measurement;
Conference_Titel :
Bioengineering Conference (NEBEC), 2012 38th Annual Northeast
Conference_Location :
Philadelphia, PA
Print_ISBN :
978-1-4673-1141-0
DOI :
10.1109/NEBC.2012.6207030
