Experimental investigations of the freezing process of supercooled water droplets close to a solid walldoi:10.18419/darus-1783DaRUS2021-04-121Schremb, Markus, 2021, "Experimental investigations of the freezing process of supercooled water droplets close to a solid wall", https://doi.org/10.18419/darus-1783, DaRUS, V1Experimental investigations of the freezing process of supercooled water droplets close to a solid walldoi:10.18419/darus-1783Schremb, MarkusDaRUSSteigerwald, JonasSteigerwald, Jonas2021-04-08PhysicsThe data show an excerpt of the data obtained from experimental investigations of the freezing process of supercooled water droplets close to a solid wall, performed in subproject C3. The dendritic freezing of supercooled water drops (dataset 1) and the propagation of thin ice layer prior to dendritic freezing of supercooled water drops (dataset 2) both entrapped in a Hele-Shaw cell has been captured with a high spatial and temporal resolution using high-speed video imaging. Information concerning the experimental setup and method is found in the aforementioned publication. Information concerning the temporal and spatial resolution can be obtained from the time stamp and scale in the videos.Please request the access to the data set via e-mail (see Contact button).
Schremb, M. and Tropea, C., "Solidification of supercooled water in the vicinity of a solid wall", Phys. Rev. E 94 (5), 052804, Nov 2016.10.1103/PhysRevE.94.052804Schremb, M. and Tropea, C., "Solidification of supercooled water in the vicinity of a solid wall", Phys. Rev. E 94 (5), 052804, Nov 2016.Schremb, M., Campbell, J. M., Christenson, H. K., and Tropea, C., "Ice Layer Spreading along a Solid Substrate during Solidification of Supercooled Water: Experiments and Modeling", Langmuir 2017 33 (19), 4870-487710.1021/acs.langmuir.7b00930Schremb, M., Campbell, J. M., Christenson, H. K., and Tropea, C., "Ice Layer Spreading along a Solid Substrate during Solidification of Supercooled Water: Experiments and Modeling", Langmuir 2017 33 (19), 4870-4877dataset1_01_freezingSessileDrop.aviSupercooled solidification of a sessile drop (T = -15.8 °C)video/x-msvideodataset1_02_freezingWithinHele-ShawCell.aviSupercooled solidification of a drop in the Hele-Shaw cell (T = -15.8 °C)video/x-msvideodataset1_03_iceLayerPropagation.aviDendritic solidification of a drop in the Hele-Shaw cell (T = -10.7 °C)video/x-msvideodataset2_01_planar.aviSmall supercooling results in only planar growth of the initial ice layer (T = -2.44 °C)video/x-msvideodataset2_02_lateDendrites.aviDendrites arise long after the spreading of the initial ice layer (T = -6.77 °C)video/x-msvideodataset2_03_singleDendrites.aviSingle dendrites arise shortly after the spreading of the initial ice layer (T = -8.53 °C)video/x-msvideodataset2_04_inhomogeneous.aviPropagation of an inhomogeneous cloud of dendrites (T = -10.67 °C)video/x-msvideodataset2_05_homogeneous.aviPropagation of a homogeneous cloud of dendrites (T = -12.65 °C)video/x-msvideo