Light came to Antioquia from Austria and last
Vol. 39 (2015), Crónica
Vol. 39 (2015)

Light came to Antioquia from Austria and last

Crónica
https://doi.org/10.18257/raccefyn.264
Published 2015-11-18
Francisco Medina-Estrada
Universidad de Antioquia
Jorge Garcia-Sucerquia
Universidad Nacional de Colombia-Sede Medellín – Escuela de Física
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Medina-Estrada, F., & Garcia-Sucerquia, J. (2015). Light came to Antioquia from Austria and last. Revista De La Academia Colombiana De Ciencias Exactas, Físicas Y Naturales, 39, 93–97. https://doi.org/10.18257/raccefyn.264
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Abstract

In this paper, we present a condensed summary on the onset of the study of light in Antioquia and how it has prevailed until today. We highlight the contributions of Prof. Dr. Peter Barlai since he arrived from Austria in the early seventies, and how he laid the basis for the establishment of the optics groups of the two leading Universities of Antioquia. In addition, we explain the involvement of national and international institutes in the formation of the optics groups of Antioquia, as well as the link between the original onset of the study of light and the current interest of the leading groups. © 2015. Acad. Colomb. Cienc. Ex. Fis. Nat. All rights reserved.

 

Garzón, J., Gharbi, T., & Meneses, J.(2008). Real TimeDetermination of the Optical Thickness and Topographyof Tissues by Chromatic Confocal Microscopy. Journal ofOptics A: Pure and Applied Optics,10(10): 104028. http://stacks.iop.org/1464-4258/10/i=10/a=104028.Henao, R., Medina, F., Rabal, H., & Trivi, M.(1993). Three-Dimensional Speckle Measurements with a DiffractionGrating. Applied Optics,32(5). OSA, 726-29. doi:10.1364/AO.32.000726.Henao, R, Rabal, H., Tagliaferri, A., & Torroba, R.(1997).Determination of the Zero-Order Fringe Position in DigitalSpeckle Pattern Interferometry. Applied Optics,36(10).OSA, 2066–69. doi:10.1364/AO.36.002066.Hincapie, D., Herrera-Ramirez J., & Garcia-Sucerquia, J.(2015). Single-Shot Speckle Reduction in NumericalReconstruction of Digitally Recorded Holograms. OpticsLetters,40(8). OSA, 1623–26. doi:10.1364/OL.40.001623.Kakarenko, K., Ducin, I., Grabowiecki,K., Jaroszewicz,Z., Kolodziejczyk, A., Mira-Agudelo, A., KrzysztofPetelczyc, Składowska, A., & Sypek, M.(2015).Assessment of Imaging with Extended Depth-of-Field byMeans of the Light Sword Lens in Terms of Visual AcuityScale. Biomedical Optics Express,6(5). OSA, 1738-48.doi:10.1364/BOE.6.001738.Londoño, N, Rueda,E.,Gómez,J., & Lencina, A.(2015).Generation of Optical Vortices by Using Binary VortexProducing Lenses. Applied Optics,54(4). OSA, 796-801.doi:10.1364/AO.54.000796.Matteucci, G., Medina, F. & Pozzi, G.(1992). Electron-OpticalAnalysis of the Electrostatic Aharonov-Bohm Effect.Ultramicroscopy,41(4): 255-68. doi:10.1016/0304-3991(92)90205-X.Medina, F., & Pozzi, G.(1990). Spatial Coherence of Anisotropicand Astigmatic Sources in Interference Electron Microscopyand Holography. Journal of the Optical Society of AmericaA,7(6). OSA, 1027-33. doi:10.1364/JOSAA.7.001027.Medina, F., Garcia-Sucerquia, J., Castañeda, R.,&Matteucci,G.(2004).Angular Criterion to Distinguish betweenFraunhofer and Fresnel Diffraction. Optik - InternationalJournal for Light and Electron Optics,115(11-12): 547-52.doi:10.1078/0030-4026-00547.Mendoza-Yero, O., Calabuig, A., Tajahuerce, E., Lancis, J.,Andrés, P.,&Garcia-Sucerquia, J.(2013).FemtosecondDigital Lensless Holographic Microscopy to ImageBiological Samples.Optics Letters,38(17).OSA, 3205-7.Mendoza-Yero, O., Tajahuerce, E., Lancis, J.,&Garcia-Sucerquia, J.(2013). Diffractive Digital Lensless Holo-graphic Microscopy with Fine Spectral Tuning.OpticsLetters,38(12): 2107-9.Reyes-Vera, E, Torres, P., Chesini, G.,&Cordeiro, C.(2012).Temperature Sensitivity of Photonic Crystal Fiber withIntegrated Electrodes. In Press Opt Express,.Reyes-Vera, E., Gómez-Cardona, N., Chesini, G, Cordeiro,C., & Torres, P.(2014). Temperature Sensibility of theBirefringence Properties in Side-Hole Photonic CrystalFiber Filled with Indium. Applied Physics Letters,105(20): -. doi:http://dx.doi.org/10.1063/1.4902157.Rueda, E, Muñetón, D.,Gómez,J., & Lencina, A.(2013).High-Quality Optical Vortex-Beam Generation by Using aMultilevel Vortex-Producing Lens.Optics Letters,38(19).OSA, 3941–44. doi:10.1364/OL.38.003941.Sánchez-Ortiga, E., Doblas, A., Saavedra, G., Martínez-Corral, M,&Garcia-Sucerquia, J.(2014). Microscopio,Método Y Programa de Ordenador Para La Obtención deImágenes Cuantitativas de Fase Por Medio de MicroscopíaHolográfica Digital, Y Kit Para Adaptar Un MicroscopioÓptico. España: Oficna Española de Patentes.Sánchez-Ortiga, E., Doblas, A., Saavedra, G., Martínez-Corral,M.&Garcia-Sucerquia, J.(2014).Off-Axis DigitalHolographic Microscopy: Practical Design Parameters forOperating at Diffraction Limit. Applied Optics,53(10).OSA, 2058-66. doi:10.1364/ao.53.002058.Serna, J., Hamad, A., Garcia, H., & Rueda, E.(2014).Measurement of Nonlinear Optical Absorption and Non-Linear Optical Refraction in CdS and ZnSe Using anElectrically Focus-Tunable Lens. In 12th InternationalConference on Fiber Optics and Photonics, T2C.2. OSATechnical Digest (online). Kharagpur : Optical Society ofAmerica. doi:10.1364/PHOTONICS.2014.T2C.2.Sierra-Sosa, D., Angel-Toro, L., Bolognini, N.,&Tebaldi, M.(2013).Novel Vortex-Transform for High FrequencyModulated Patterns. Optics Express,21(20).OSA, 23706-11. doi:10.1364/OE.21.023706.Torres, P., Aristizábal, V., & Andrés, M.(2011). Modeling ofPhotonic Crystal Fibers from the Scalar Wave Equation witha Purely Transverse Linearly Polarized Vector Potential. J.Opt. Soc. Am. B,28(4). OSA, 787-91. http://josab.osa.org/abstract.cfm?URI=josab-28-4-787.Torroba, R., Henao, R., & Carletti, C.(1996). DigitalPolarization-Encoding Technique for Optical LogicOperations. Optics Letters,21(23). OSA, 1918-20.doi:10.1364/OL.21.001918.Velásquez, D.,&Garcia-Sucerquia, J.(2006). Three-Dimensional Surface Contouring of Macroscopic Objectsby Means of Phase-Difference Images.Applied Optics,45(25): 6381-87.
https://doi.org/10.18257/raccefyn.264
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References

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Garcia-Sucerquia, J., Xu, W., Jericho, S., Klages, P., Jericho, M., & Kreuzer, H. (2006). Digital in-Line Holographic Microscopy. Appl. Opt., 45 (5). OSA, 836-50.

Garzón, J., Gharbi, T., & Meneses, J. (2008). Real Time Determination of the Optical Thickness and Topography of Tissues by Chromatic Confocal Microscopy. Journal of Optics A: Pure and Applied Optics, 10 (10): 104028. http://stacks.iop.org/1464-4258/10/i=10/a=104028.

Henao, R., Medina, F., Rabal, H., & Trivi, M. (1993). Three-Dimensional Speckle Measurements with a Diffraction Grating. Applied Optics, 32 (5). OSA, 726-29. doi:10.1364/AO.32.000726.

Henao, R, Rabal, H., Tagliaferri, A., & Torroba, R. (1997). Determination of the Zero-Order Fringe Position in Digital Speckle Pattern Interferometry. Applied Optics, 36 (10). OSA, 2066–69. doi:10.1364/AO.36.002066.

Hincapie, D., Herrera-Ramirez J., & Garcia-Sucerquia, J. (2015). Single-Shot Speckle Reduction in Numerical Reconstruction of Digitally Recorded Holograms. Optics Letters, 40 (8). OSA, 1623–26. doi:10.1364/OL.40.001623.

Kakarenko, K., Ducin, I., Grabowiecki,K., Jaroszewicz, Z., Kolodziejczyk, A., Mira-Agudelo, A., Krzysztof Petelczyc, Składowska, A., & Sypek, M. (2015). Assessment of Imaging with Extended Depth-of-Field by Means of the Light Sword Lens in Terms of Visual Acuity Scale. Biomedical Optics Express, 6 (5). OSA, 1738-48. doi:10.1364/BOE.6.001738.

Londoño, N, Rueda,E., Gómez, J., & Lencina, A. (2015). Generation of Optical Vortices by Using Binary Vortex Producing Lenses. Applied Optics, 54 (4). OSA, 796-801. doi:10.1364/AO.54.000796.

Matteucci, G., Medina, F. & Pozzi, G. (1992). Electron-Optical Analysis of the Electrostatic Aharonov-Bohm Effect. Ultramicroscopy, 41 (4): 255-68. doi:10.1016/0304-3991(92) 90205-X.

Medina, F., & Pozzi, G. (1990). Spatial Coherence of Anisotropic and Astigmatic Sources in Interference Electron Microscopy and Holography. Journal of the Optical Society of America A, 7 (6). OSA, 1027-33. doi:10.1364/JOSAA.7.001027.

Medina, F., Garcia-Sucerquia, J., Castañeda, R., & Matteucci, G. (2004). Angular Criterion to Distinguish between Fraunhofer and Fresnel Diffraction. Optik - International Journal for Light and Electron Optics, 115 (11-12): 547-52. doi:10.1078/0030-4026-00547.

Mendoza-Yero, O., Calabuig, A., Tajahuerce, E., Lancis, J., Andrés, P., & Garcia-Sucerquia, J. (2013). Femtosecond Digital Lensless Holographic Microscopy to Image Biological Samples. Optics Letters, 38 (17). OSA, 3205-7.

Mendoza-Yero, O., Tajahuerce, E., Lancis, J., & Garcia-Sucerquia, J. (2013). Diffractive Digital Lensless Holo-graphic Microscopy with Fine Spectral Tuning. Optics Letters, 38 (12): 2107-9.

Reyes-Vera, E, Torres, P., Chesini, G., & Cordeiro, C. (2012). Temperature Sensitivity of Photonic Crystal Fiber with Integrated Electrodes. In Press Opt Express,.

Reyes-Vera, E., Gómez-Cardona, N., Chesini, G, Cordeiro, C., & Torres, P. (2014). Temperature Sensibility of the Birefringence Properties in Side-Hole Photonic Crystal Fiber Filled with Indium. Applied Physics Letters, 105 (20): -. doi:http://dx.doi.org/10.1063/1.4902157.

Rueda, E, Muñetón, D., Gómez, J., & Lencina, A. (2013). High-Quality Optical Vortex-Beam Generation by Using a Multilevel Vortex-Producing Lens. Optics Letters, 38 (19). OSA, 3941–44. doi:10.1364/OL.38.003941.

Sánchez-Ortiga, E., Doblas, A., Saavedra, G., Martínez-Corral, M, & Garcia-Sucerquia, J. (2014). Microscopio, Método Y Programa de Ordenador Para La Obtención de Imágenes Cuantitativas de Fase Por Medio de Microscopía Holográfica Digital, Y Kit Para Adaptar Un Microscopio Óptico. España: Oficna Española de Patentes.Sánchez-Ortiga, E., Doblas, A., Saavedra, G., Martínez-Corral, M. & Garcia-Sucerquia, J. (2014). Off-Axis Digital Holographic Microscopy: Practical Design Parameters for Operating at Diffraction Limit. Applied Optics, 53 (10). OSA, 2058-66. doi:10.1364/ao.53.002058.

Serna, J., Hamad, A., Garcia, H., & Rueda, E. (2014). Measurement of Nonlinear Optical Absorption and Non-Linear Optical Refraction in CdS and ZnSe Using an Electrically Focus-Tunable Lens. In 12th International Conference on Fiber Optics and Photonics, T2C.2. OSA Technical Digest (online). Kharagpur : Optical Society of America. doi:10.1364/PHOTONICS.2014.T2C.2.

Sierra-Sosa, D., Angel-Toro, L., Bolognini, N., & Tebaldi, M. (2013). Novel Vortex-Transform for High Frequency Modulated Patterns. Optics Express, 21 (20). OSA, 23706-11. doi:10.1364/OE.21.023706.

Torres, P., Aristizábal, V., & Andrés, M. (2011). Modeling of Photonic Crystal Fibers from the Scalar Wave Equation with a Purely Transverse Linearly Polarized Vector Potential. J. Opt. Soc. Am. B, 28 (4). OSA, 787-91. http://josab.osa.org/abstract.cfm?URI=josab-28-4-787.

Torroba, R., Henao, R., & Carletti, C. (1996). Digital Polarization-Encoding Technique for Optical Logic Operations. Optics Letters, 21 (23). OSA, 1918-20. doi:10.1364/OL.21.001918.Velásquez, D., & Garcia-Sucerquia, J. (2006). Three-Dimensional Surface Contouring of Macroscopic Objects by Means of Phase-Difference Images. Applied Optics, 45 (25): 6381-87.

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