TY - GEN
T1 - Interferometric Tomography Measurement of the Temperature Field in the Vicinity of a Dendritic Crystal Growing from a Supercooled Melt
AU - Braslavsky, Ido
AU - Lipson, S. G.
N1 - https://www.worldcat.org/title/optical-methods-and-data-processing-in-heat-and-fluid-flow-16-17-april-1998-city-university-london-uk/oclc/39380321&referer=brief_results
PY - 1998/4/16
Y1 - 1998/4/16
N2 - Interferometric Tomography Measurement of the Temperature Field in the Vicinity of a Dendritic Crystal Growing from a Supercooled Melt. I. Braslavsky and S. G. Lipson Technion - Israel Institute of Technology Transactions of Optical methods and data processing in heat and fluid flow, IMECHE, London 1998, p. 423-432. The shape of a crystal growing from a supercooled pure melt is influenced by the temperature-dependent kinetics of the nucleation on the interface. In the course of this growth, heat is released from the interface, thus feeding back on the temperature field. In this intrinsically nonlinear process, the three-dimensional temperature field in the fluid is a vital dynamic parameter which has not been previously measured. This can be done with the aid of multi-directional interferometry, using the temperature dependence of the refractive index of the melt. If the growth regime lies in the path of one of the interferometer beams, a phase shift, proportional to the integrated refractive index change, is observed. To measure the three-dimensional field of the refractive index requires some form of tomographic reconstruction. We built an apparatus that includes a crystal growing cell which is viewed by four Mach-Zehnder interferometers. The interferograms are analyzed by Fourier fringe analysis, and the field is reconstructed by the algebraic reconstruction technique (ART), an algorithm which has been shown by Verhoeven to be suitable for limited data tomography. Measured temperature fields around growing crystals of heavy ice (D2O) and succinonitrile are presented. Internal self-consistency of the field magnitudes is demonstrated, without the need for adjustable parameters. 1,2,34,5,6,7
AB - Interferometric Tomography Measurement of the Temperature Field in the Vicinity of a Dendritic Crystal Growing from a Supercooled Melt. I. Braslavsky and S. G. Lipson Technion - Israel Institute of Technology Transactions of Optical methods and data processing in heat and fluid flow, IMECHE, London 1998, p. 423-432. The shape of a crystal growing from a supercooled pure melt is influenced by the temperature-dependent kinetics of the nucleation on the interface. In the course of this growth, heat is released from the interface, thus feeding back on the temperature field. In this intrinsically nonlinear process, the three-dimensional temperature field in the fluid is a vital dynamic parameter which has not been previously measured. This can be done with the aid of multi-directional interferometry, using the temperature dependence of the refractive index of the melt. If the growth regime lies in the path of one of the interferometer beams, a phase shift, proportional to the integrated refractive index change, is observed. To measure the three-dimensional field of the refractive index requires some form of tomographic reconstruction. We built an apparatus that includes a crystal growing cell which is viewed by four Mach-Zehnder interferometers. The interferograms are analyzed by Fourier fringe analysis, and the field is reconstructed by the algebraic reconstruction technique (ART), an algorithm which has been shown by Verhoeven to be suitable for limited data tomography. Measured temperature fields around growing crystals of heavy ice (D2O) and succinonitrile are presented. Internal self-consistency of the field magnitudes is demonstrated, without the need for adjustable parameters. 1,2,34,5,6,7
UR - https://www.researchgate.net/publication/255656402_Interferometric_Tomography_Measurement_of_the_Temperature_Field_in_the_Vicinity_of_a_Dendritic_Crystal_Growing_from_a_Supercooled_Melt
M3 - Conference contribution
SN - 1860581420 9781860581427
T3 - IMechE conference transactions, 1998-2
SP - 423
EP - 432
BT - Optical methods and data processing in heat and fluid flow :
PB - Professional Engineering Publishing
CY - London, UK
ER -