O bibliografie selectivă despre mecanisme de deteriorare a sistemelor ecologice, noiembrie 2017

Arhiva și lista bibliografică se pot descărca apăsând pe imaginea de mai jos (Dodds și Smith 2016).

1 Eutrofizare

• Ansari A. A., S. S. Gill (editori), 2014, Eutrophication: causes, consequences and control, Vol. 1. Springer, Dordrecht
• Copetti, D., K. Finsterle, L. Marziali, F. Stefani, G. Tartari, G. Douglas, K. Reitzel, B. M. Spears, I. J. Winfeld, G. Crosa, P. D’Haese, S. Yasseri, M. Lurling, 2016, Eutrophication management in surface waters using lanthanum modified bentonite, Water Research, 97: 162-174
• Dodds W. K., V. H. Smith, 2016, Nitrogen, phosphorus, and eutrophication in streams, Inland Waters, 6: 155-164
• Huo S., M. Chunzi, B. Xi, Y. Zhang, F. Wu, H. Liu, 2017, Development of methods for establishing nutrient criteria in lakes and reservoirs: A review, Journal of Environmental Sciences, https://doi.org/10.1016/j.jes.2017.07.013 
• Lurling M., 2016, Editorial – A critical perspective on geo-engineering for eutrophication management in lakes, Water Research, 97: 1-10
• McDowell R. W., P. J. A. Withers, T. J. Van der Weerden, 2017, The environmental impact of fertiliser nutrient on freshwater, Issues in Environmental Science and Technology, 43: 20-44
• Schoumans O. F., W. J. Chardon, M. E. Bechmann, C. Gascuel-Odoux, G. Hofman, B. Kronvang, G. H. Rubaek, B. Ulen, J.-M. Dorioz, 2014, Mitigation options to reduce phosphorus losses from the agricultural sector and improve surface water quality: A review, Science of the Total Environment, 468-469: 1255-1266
• Sun R., P. Sun, J. Zhang, S. Esquivel-Elizondo, Y. Wu, 2017, Microorganisms-based methods for harmful algal blooms control: A review, Bioresource Technology, https://doi.org/10.1016/j.biortech.2017.07.175 
• Withers P. J. A., C. Neal, H. P. Jarvie, D. G. Doody, Agriculture and eutrophication: where do we go from here ? Sustainability, 6: 5853-5875
• Yang B., K. Huang, D. Sun, Y. Zhang, 2017, Mapping the scientific research on non-point source pollution: a bibliometric analysis, Environ Sci Pollut Res, 24: 4352-4366
• Zamparas M., I. Zacharias, 2014, Restoration of eutrophic freshwater by managing internal nutrient loads, 496: 551-562

2 Poluare cu deșeuri (studiu de caz – țigări)

• Moerman J. W., G. E. Potts, 2011, Analysis of metals leached from smoked cigarette litter, Tobacco Control, 20(Suppl. 1): i30-i35
• Novotny T. E., K. Lum, E. Smith, V. Wang, R. Barnes, 2009, Cigarettes butts and the case for an environmental policy on hazardous cigarette waste, Int. J. Environ. Res. Public Health, 6: 1691-1705
• Osuala F. I., O. A. Abiodun, M. N. Igwo-Ezipke, K. A. Kemabonta, A. A. Otitoloju, 2016, Relative toxicity of cigarette butts leachate and usefulness of antioxidant biomarker activity in Nile tilapia Orechromis niloticus (Trewavas, 1983), Ethiopian Journal of Environmental Studies & Management, 10: 75-88
• Slaughter E., R. M. Gersberg, K. Watanabe, J. Rudolph, C. Stransky, T. E. Novotny, 2011, Toxicity of cigarette butts, and their chemical components, to marine and freshwater fish, 20(Suppl. 1): i25-i29

3 Introducere de specii noi, specii invasive

• Ballari S. A., C. B. Anderson, A. E. J. Valenzuela (2016) Understanding trends in biological invasions by introduces mammals in southern South America: a review of research and management, Mammal Review, 46: 229-240
• Blackburn T. M., S. L. Scrivens, S. Heinrich, P. Cassey, Patterns of selectivity in introductions of mammal species worldwide, NeoBiota, 33: 33-51
• Chapman D. S., L. Makra, R. Albertini, M. Bonini, A. Paldy, V. Rodinkova, B. Sikoparija, E. Weryszko-Chmieleswska, J. M. Bullock, 2016, Modelling the introduction and spread of non-native species: internationa trade and climate change drive ragweed invasion, Global Change Biology, 22: 3067-3079
• Gallardo B., M. Clavero, M. I. Sanchez, M. Vila, 2016, Global ecological impacts of invasive species in aqutic ecosystems, Global Change Biology, 22: 151-163

4 Supraexploatare

• Crespo G. O., D. C. Dunn, 2017, A review of the impacts of fisheries on open-ocean ecosystems, ICES Journal of Marine Science, fsx084, https://doi.org/10.1093/icesjms/fsx084 
• Heine M., K. Enberg, 2008, Sustainable use of populations and overexploitation, Encycolopedia of life sciences, John Wiley & Sons, Chichester, DOI: 10.1002/978047001 5902.a0020476
• Perissi I., U. Bardi, T. E. Asmar, A. Lavacchi, 2017, Dynamic patterns of overexploitation in fisheries, Ecological Modelling, http://dx.doi.org/10.1016/j.ecolmodel.2017.06.009 
• Prăvălie R., I. Săvulescu, C. Patriche, M. Dumitrașcu, G. Bandoc, 2017, Spatial assessment of land degradation sensitive areas in southwestern Romania using modified MEDALUS method, Catena 153: 114-130
• Reynolds J. D., C. A. Peres, 2006, Overexploitation.  In  Principles  of  Conservation  Biology,  3rdedn. (M.J. Groom, G.K. Meffe and C.R. Carroll, eds.), Sunderland, MA: SinauerAssociates, 253–291

5 Fragmentarea şi pierderea habitatelor

• Ewers R. M., R. K. Didham, 2006, Confounding factors in the detection of species responses to habitat fragmentation, Biol. Rev. 81: 117-142
• Fardila D., L. T. Kelly, J. L. Moore, M. A. McCarthy, 2017, A systematic review reveals changes in where and how we have studied habitat loss and fragmentation over 20 years, Biological Conservation, 212: 130-138
• Grilli G., S. Longo, P.Y. Huais, M. Pereyra, E. G. 2017, Fungal diversity at fragmented landscape: synthesis and future perspectives, Current Opinion in Microbiology, 37: 161-165
• Holyoak M., S. K. Heath, 2016, The integration of climate change, spatial dynamics, Integrative Zoology, 11: 40-59
• Keinath D. A., D. F. Doak, K. E. Hodges, A global analysis of traits predicting species sensitivity to habitat fragmentation, Global Ecol Biogeogr, 26: 115-127
• Mateo R., B. Arroyo, J. T. Garcia (editori), 2016, Current trends in wildlife research, Springer, Switzerland
• Năstase G., A. Șerban, A. F. Năstase, G. Dragomir, A. I. Brezeanu, N. F. Iordan, 2017, Hydropower development in Romania. A review from its beginnings to the present, Renewable and Sustainable Energy Reviews, 80: 297-312 
• Said M. Y., J. O. Ogutu, S. C. Kifugo, O. Makui, R. S. Reid, J. de Leeuw, 2016, Effects of extreme land fragmentation on wildlife and livestock population abundance and distribution, Journal for Nature Conservation, 34: 151-164
• Swift T. L., S. J. Hannon, 2010, Critical thresholds associated with habitat loss: a review of the concepts, evidence, and applications, Biological reviews, 85: 35-53
• Wilson M. C., X.-Y. Chen, R. T. Corlett, et al., 2016, Habitat fragmentation and biodiversity conservation: key findings and future challanges, 31: 219-227
• Xiao Y., X. Li, Y. Cao, M. Dong, 2016, The diverse effects of fragmentation on plant-pollinator interactions, Plant Ecol 217: 857-868
• Yin D., Shawn J. Leroux, F. He, 2017, Methods and models for identifying threshold of habitat loss, Ecography, 40: 131-143

6 Schimbări climatice

• Amman C. M., F. Joos, D. S. Schimel, B. L. Otto-Bliesner, R. A. Tomas, 2007, Solar influence on climate during the past millenium: results from transient simulations with the NCAR Climate System Model, PNAS, 104: 3713-3718
• Croitorul A.-C., A. Piticar, D. C. Burada, 2016a, Changes in precipitation extremes in Romania, Quternary International, 415: 325-335
• Croitorul A.-C., A. Piticar, A.-F. Ciupertea, C. F. Roșca, 2016b, Changes in heat waves indices in Romania over the period 1961-2015, Global Planetary Change, 146: 109-121
• Dragomir G., A. Șerban, G. Năstase, A. I. Brezeanu, 2016, Wind energy in Romania: a review from 2009 to 2016, Renewable and Sustainable Energy Reviews, 64: 129-143
• Dumitrașcu M., I. Mocanu, B. Mitrică, C. Dragotă, I. Grigorescu, C. Dumitrică, 2017, The assessment of socio-economic vulnerability to drought in Southern Romania (Oltenia Plain), International Journal of Disaster Risk Reduction, http://dx.doi.org/10.1016/j.ijdrr.2017.09.049 
• Miao F., L. Xin, 2016, Paleoclimate data assimilation: its motivation, progress and prospects, Science China Earth Sciences, 59: doi: 10.1007/s11430-015-5432-6
• Morgenstern O., M. I. Hegglin, E. Rozanov și colab., 2017, Review of the global models used within phase 1 of the Chemistry – Climate Model Initiative (CCMI), Geosci. Model Dev., 10: 639-671
• Smerdon J. E., H. N. Pollack, 2016, Reconstructing Earth’s surface temperature over the past 2000 years: the science behind the headlines, WIREs Clim Change, doi: 10.1002/wcc.418
• Swingedouw D., J. Mignot, P. Ortega, M. Khodri, M. Menegoz, C. Cassou, V. Hanquiez, 2017, Impact of explosive volcanic eruptions on the main climate variabilty modes, Global and Planetary Change, 150: 24-45
• Wanner H., J. Beer, J. Butikofer și colab., 2008, Mid- to late Holocene climate change: and overvew, Quaternary Science Reviews, 27: 1791-1828
• Zamfir A., S. E. Colesca, R.-A. Corbos, 2016, Public policies to support the development of renewable energy in Romania: a review, Renewable and Sustainable Energy Reviews, 58: 87-106

7 Abordări integrate

• Gillingham M. P., G. R. Halseth, C. J. Johnson, M. W. Parkes (editori), 2016, The integration imperative – Cumulative environmental, community and health effects of multiple natural resource developments, Springer, Heidelberg
• Venter O., N. N. Brodeur, L. Nemiroff, B. Belland, I. J. Dolinsek, J. W. A. Grant, 2006, Threats to endangered species in Canada, Bioscience, 56: 903-910
• Verdenschot P. F. M., B. M. Spears, C. K. Feld, S. Brucet, H. Keizer-Vlek, A. Borja, M. Elliot, M. Kernan, R. K. Johnson, 2013, A comparative review of recovery processes in rivers, lakes, estuarine and coastal waters, Hydrobiologia, DOI 10.1007/s10750-012-1294-7
• Yiming L., D. S. Wilcove, 2005, Threats to vertebrate species in China and the United States, 55: 147-153