Profiling Suspensions in Natural Water by a Simplified Dynamic Light Scattering Procedure and Sedimentation

1. Aizu Y. and Asakura T., 1991 – Bio-speckle phenomena and their application to the evaluation of blood flow, Optical Laser Technology, 23, 205-219.10.1016/0030-3992(91)90085-3Search in Google Scholar

2. Berlasso R., Perez F., Quintian M. A., Rebollo Raffo C. A. and Gaggioli N. G., 2000 – Study of speckle size of light scattered from cylindrical rough surfaces, Applied Optics, 39, 5811-5819.10.1364/AO.39.005811Search in Google Scholar

3. Boas D. A. and Yodh A. G., 1997 – Spatially varying dynamical properties of turbid media probed with diffusing temporal light correlation, Journal of the Optical Society of America A, 14, 192-215.10.1364/JOSAA.14.000192Search in Google Scholar

4. Briers J. D., Richards G. and He X. W., 1999 – Capillary blood flow monitoring using laser speckle contrast analysis (LASCA), Journal of Biomedical Optics, 4, 164-175.10.1117/1.42990323015182Search in Google Scholar

5. Briers J. D., 2001 – Laser Doppler, Speckle and related techniques for blood perfusion mapping and imaging, Physiological Measurement, 22, R35-R66.10.1088/0967-3334/22/4/20111761081Search in Google Scholar

6. Da Costa G. and Ferrari J., 1997 – Anisotropic speckle patterns in the light scattered by rough cylindrical surfaces, Applied Optics, 36, 5231-5237.10.1364/AO.36.00523118259338Search in Google Scholar

7. Chicea D., 2008 – Coherent Light Scattering on Nanofluids – Computer Simulation Results, Applied Optics, 47, 10, 1434-1442.10.1364/AO.47.00143418382569Search in Google Scholar

8. Chicea D., 2010 – Nanoparticles and Nanoparticle Aggregates Sizing by DLS and AFM, Journal of Optoelectronics and Advanced Materials, 4, 9, 1310-1315.Search in Google Scholar

9. Chicea D., 2012a – A Study of Nanoparticle Aggregation by Coherent Light Scattering, Current Nanoscience, 8, 6, 259-265.10.2174/157341312800167704Search in Google Scholar

10. Chicea D., 2012b – A Coherent Light Scattering Procedure to Measure Very Small Concentration of Organic Suspension in Natural Water, Transylvanian Review of Systematical and Ecological Research, 14, 2, 1-8.Search in Google Scholar

11. Chicea D., 2013a – Estimating Particle Concentration in Natural Water by Speckle Size Measurement, Proceedings of 11th International Conference on Environment, Ecosystems and Development (EED ’13), Braşov, Romania, June 1-3, 151-161.Search in Google Scholar

12. Chicea D., 2013b – Estimating Particle Concentration in Natural Water by Speckle Contrast, Transylvanian Review of Systematical and Ecological Research, 15.1, 2, 1-10.10.2478/trser-2013-0001Search in Google Scholar

13. Chicea D., 2013c – Chicea L. M., Estimating Particle Concentration In Natural Water By Far Field Speckle Intensity, Transylvanian Review of Systematical and Ecological Research, 15.2, 1-8.10.2478/trser-2013-0017Search in Google Scholar

14. Clark N. A., Lunacek J. H. and Benedek G. B., 1970 – “A study of brownian motion using light scattering”, American Journal of Physics, 38, 5, 575-585.10.1119/1.1976408Search in Google Scholar

15. Fedosov I. V. and Tuchin V. V., 2001 – The use of dynamic speckle field space time correlation function estimates for the direction and velocity determination of blood flow, Proceedings of SPIE, 4434, 192-196.10.1117/12.446678Search in Google Scholar

16. Giglio M., Carpineti M., Vailati A. and Brogioli D., 2001 – Near-field intensity correlation of scattered light, Applied Optics, 40, 4036-4040.10.1364/AO.40.004036Search in Google Scholar

17. Goodman J. W., 1984 – Statistical Properties of Laser Speckle Patterns, in Laser speckle and related phenomena, l.9 in series Topics in Applied Physics, Dainty J. C. (ed.), Springer-Verlag, Berlin, Heidelberg, New York, Tokyo.10.1007/BFb0111436Search in Google Scholar

18. Gumpinger C., Höfler S., Berg K. and Scheder C., 2010 – Water temperature as an applicable parameter with a high indicative value for the general condition of a river-ecosystem, drawing on the example of the river Trattnach in Upper Austria, Transylvanian Review of Systematical and Ecological Research, “The Wetlands Diversity”, 10, 1-14.Search in Google Scholar

19. Lehmann P., 1999 – Surface-roughness measurement based on the intensity correlation function of scattered light under speckle-pattern illumination, Applied Optics, 38, 1144-1152.10.1364/AO.38.001144Search in Google Scholar

20. National Soil Survey Handbook, 2006 – Part 618 (42-55) Soil Properties and Qualities United States Department of Agriculture – Natural Resource Conservation Service.Search in Google Scholar

21. Piederrière Y., Cariou J., Guern Y., Le Jeune B., Le Brun G. and Lotrian J., 2004a – Scattering through fluids: speckle size measurement and Monte Carlo simulations close to and into the multiple scattering, Optics Express, 12, 176-188.10.1364/OPEX.12.00017619471524Search in Google Scholar

22. Piederrière Y., Le Meur J., Cariou J., Abgrall J. F. and Blouch M. T., 2004b – Particle aggregation monitoring by speckle size measurement; application to blood platelets aggregation, Optics Express, 12, 4596-4601.10.1364/OPEX.12.004596Search in Google Scholar

23. Sadhwani A., Schomaker K. T., Tearney G. J. and Nishioka N. S., 1996 – Determination of Teflon thickness with laser speckle, I, Potential for burn depth diagnosis, Applied Optics, 35, 5727-5735.10.1364/AO.35.00572721127582Search in Google Scholar

24. Tscharnuter W., 2000 – in Encyclopedia of Analytical Chemistry, Meyers R. A. (ed.), John Wiley and Sons Ltd, 5469-5485.Search in Google Scholar

25. Zimnyakov D. A., Briers J. D. and Tuchin V. V., 2002 – Speckle technologies for monitoring and imaging of tissues and tissuelike phantoms, Chapter 18, in Handbook of biomedical diagnostics, Valery V. Tuchin (ed.) SPIE press, Bellingham, 987-1036.Search in Google Scholar

26. Waterwatch Australia National Technical Manual, Module 4, Waterwatch Australia Steering Committee, Environment Australia, July 2002, ISBN 0-6425-4856-0.19-21.Search in Google Scholar