دراسة بيئية حول تأثير سبخات سرت على الملوحة السطحية في الساحل الغربي لليبيا باستخدام تقنيات MODIS الفضائية

Aronica, G. T. & Candela, A. (2007). Derivation of flood frequency curves in poorly gauged Mediterranean catchments using a simple stochastic hydrological rainfall-runoff model. Journal of Hydrology, 3(7),132-142.

Assiry, A. M. Sastry, S. K., & Samaranayake, C. P. (2006). Influence of temperature, electrical-conductivity, power and pH on ascorbic acid degradation kinetics during ohmicheating using stainless steel electrodes. Bioelectrochemistry, 6(8), 7–13.

Bellerby, R. G. J., Schulz, K. G., Riebesell, U., Neill, C., Nondal, G., Johannessen, T., & Brown, K. R. (2007). Marine ecosystem community carbon and nutrient uptake stoichiometry under varying ocean acidification during the PeECE III experiment. Biogeosciences, 5(2), 1517-1527.

Borghini, M. H., Bryden, L., Schroeder, M., Sparnocchia, F., & Vetrano, A. (2014). The Mediterranean is becoming saltier. Istituto di Scienze Marine, Italy. Ocean Sci., 10, 693-700.

Britannica (2020). Dissolved inorganic substances. Available at: [https://www.britannica.com/science-/seawater/Dissolved-inorganic-substances].

Cael, B. & Ferrari, R. (2017). The ocean’s saltiness and its overturning. Geophysical Research Letters, 44(4), 1886–1891.

Cullum, J., Stevens, D. P., & Joshi, M. M. (2016). Importance of ocean salinity for climate and habitability. Proceedings of the National Academy of Sciences, 113(16), 4278–4283.

Encyclopedia Britannica (2015). Mediterranean Sea. Retrieved, p. 23.

Foudriest (2022). Algae, Phytoplankton and Chlorophyll. Available at: [https://www.fondriest.com/-environmental-measurements/parameters/water-quality/algae-phytoplankton-chlorophyll/].

Fu, Y. F. & Liu G. S. (2003). Precipitation characteristics in mid-latitude East Asia as observed by TRMM PR and TMI. J. Meteor. Soc. Japan, 81, 1353–1369.

Funda, D. (2012). Salinity and seawater intrusion into the ground water. Indian Journal of Science and Technology 5(12), 3770-3775.

Hamuna, B., Paulangan Y. P., & Dimara, L. (2015). Sea Surface Temperature Study Using Aquam-MODIS Satellite Data in Jayapura, Papua Waters. Depik., 4(3): 160-167.

Michela, S., Salvatore, A., Orcid, R., Santoleri, O., & Bruno, B. N. (2021). Retrieving Mediterranean Sea Surface Salinity Distribution and Interannual Trends from Multi-Sensor Satellite and in Situ Data. Remote Sensing J., 3(5), 26-43.

Millot, C. (2017). Coastal eddies and salinity surface in east of Mediterranean Sea. Oceanol. Acta, 2(7), 261-273.

Moore, Z., Assouline S., Tanny, J., Lensky, I. M., & Lensky, N. G. (2018). Effect of Water Surface Salinity on Evaporation: The Case of a Diluted Buoyant Plume over the Dead Sea. Water Resources Research, 5(3), 1460-1474.

NASA (2002). Ocean Data. Available at: [https://oceandata. sci.gsfc.nasa.gov/Aquarius].

Palacios, S. L., Peterson, T. D., & Kudela, R. M. (2009). Development of synthetic salinity from remote sensing for the Columbia River plume. Journal of Geophysical Research: Oceans, 114(C2).‏

Reverdin, G., Kestenare, E., Frankignoul, C., & Delcroix, T. (2007). Surface salinity in the Atlantic Ocean (30◦S-50◦N). Progress In: Oceanography, (4)3, 311-342.

Smith, R. O., Bryden, H. L., & Stansfield, K. (2013). Observations of new western Mediterranean deep water formation using Argo floats. Ocean Sci.,12(4), 133-149.

Stammer, D., Ray, R. D., Andersen, O. B., Arbic, B. K., Bosch, W., Carrère, L., & Yi, Y. (2014). Accuracy assessment of global barotropic ocean tide models. Reviews of Geophysics, 52(3), 243-282. ‏

Union of Concerned Scientists (2019). Climate Hot Map. Global Warming Effects around the World. Health. Available at: [http://www.climatehotmap.org/global-warming-effects/health.html].