(2003): Comparability: the key to the applicability of food web research – Applied Ecology and Environmental Research

(1)

JORDÁN, F. (2003): Comparability: the key to the applicability of food web research – Applied Ecology and Environmental Research 1(1-2): 1-18.

1. cit: Ladányi, M. (2003): A model for biotic interactions among populations – In:

Simon, G. (ed.): Lippay János – Ormos Imre – Vas Károly Scientific Symposium (Section of Agroinformatics and Modelling), pp. 44-45.

2. cit: Ladányi, M., Hufnagel, L. (2003): How to define the number of individuals with respect to the phenology? – In: Simon, G. (ed.): Lippay János – Ormos Imre – Vas Károly Scientific Symposium (Section of Agroinformatics and Modelling), pp. 46-47.

3. cit: Allesina, S., Bondavalli, C., Scharler, UM. (2005): The consequences of the aggregation of detritus pools in ecological networks – Ecologigal Modelling, 189(1-2): 221-232.

4. cit: Hufnagel, L., Gaál, M. (2005): Seasonal dynamic pattern analysis in service of climate change research (A methodical case-study, monitoring and simulation based on an aquatic insect community) – Applied Ecology and Environmental Research 3(1): 79-132.

5. cit: Sipkay, Cs., Hufnagel, L., Gaál, M. (2005): Zoocoenological state of microhabitats and its seasonal dynamics in an aquatic Macroinvertebrate assembly (Hydrobiological case studies on Lake Balaton, №. 1) – Applied Ecology and Environmental Research 3(2): 107-137.

6. cit: Erdélyi, E. (2006): Graph theory application for investigating agroecosystems effected by extrem weather conditions– Applied Ecology and Environmental Research 4(2): 181-187.

7. cit: Parr, C. S., Lee, B., Bederson, B. B. (2007): EcoLens: Integration and interactive visualization of ecological datasets – Ecological Informatics, 2(1): 61- 69.

8. cit: Sipkay, Cs., Hufnagel, L., Révész, A., Petrányi, G. (2007): Seasonal dynamics of an aquatic macroinvertebrate assembly (Hydrobiological case study of Lake Balaton № 2) – Applied Ecology and Environmental Research 5(2): 63-78.

9. cit: Woodcock, B. A., Vanbergen, A. J. (2008): Parasitism of the beech leaf-miner weevil in a woodland: patch size, edge effects and parasitoid species identity – Insect Conservation and Diversity, 1(3): 180-188.

10. cit: Sipkay, Cs., Hufnagel, L. (2007): Klímaváltozási szcenáriók összehasonlító elemzése balatoni makrogerinctelen együttes alapján – Hidrológiai Közlöny 87: 117- 119.

11. cit: Sipkay, Cs., Nosek, J., Oertel, N., Vadadi-Fülöp, Cs., Hufnagel, L. (2007):

Klímaváltozási szcenáriók elemzése egy dunai Copepoda faj szezonális dinamikájának modellezése alapján – “KLIMA-21” Füzetek 49: 80-90.

STANDOVÁR, T., KENDERES, K. (2003): A review on natural stand dynamics in beechwoods of East Central Europe – Applied Ecology and Environmental Research 1(1- 2): 19-46.

1. cit: Drößer, L., Von Lüpke, B. (2005): Canopy gaps in two virgin beech forest reserves in Slovakia – Journal of Forest Science 51(10): 446–457.

2. cit: Ódor, P., Dort, K., Aude, E., Heilmann-Clausen, J., Christensen, M. (2005):

Diversity and composition of dead wood inhabiting Bryophyte communities in European beech forests– Bol. Soc. Esp. Briol. 26-27: 85-102.

(2)

3. cit: Jaworski, A., Podlaski, R. (2007): Structure and dynamics of selected stands of primeval character in the Pieniny National Park – Dendrobiology, 58: 25-41.

4. cit: Krizová, E., Ujházy, K. (eds., 2007): Dynamika, stabilita a diverzita lesných ekosystémov – TU vo Zvolene, Zvolen, p. 105–113

5. cit: Bartha S, Merolli A, Campetella G, et al. (2008): Changes of vascular plant diversity along a chronosequence of beech coppice stands, central Apennines, Italy – Plant Bioystems, 142(3): 572-583.

6. cit: Samonil, P., Vrska, T. (2008): Long-term vegetation dynamics in the Sumava Mts. natural spruce-fir-beech forests – Plant Ecology, 196(2): 197-214.

7. cit: Bartsch, N., Röhrig, E. (2009): Management Options for European Beech Forests in Relation to Changes in C- and N-Status as Described by the Three Study Sites – In: Brumme, R., Khanna, P.K. (eds.): Functioning and Management of European Beech Ecosystems, Ecological Studies, Springer- Verlag Berlin Heidelberg, Chapter 22, pp. 425-456.

8. cit: Bílek, L., Remeš, J., Zahradník, D. (2009): Natural regeneration of senescent even-aged beech (Fagus sylvatica L.) stands under the conditions of Central Bohemia – Journal of Forest Science 55(4): 145-155.

9. cit: Vacik, H., Rahman, MM., Ruprecht, H., Frank, G. (2009): Dynamics and structural changes of an oak dominated Natural Forest Reserve in Austria – Botanica Helvetica 119(1): 23-29.

10. cit: Král, K., Vrška, T., Hort, L., Adam, T., Šamonil, P. (2010): Developmental phases in a temperate natural spruce-fir-beech forest: determination by a supervised classification method – European Journal of Forest Research 129(3):

339-351.

11. cit: Christensen, M., Hahn, K., Mountford, E.P., Odor, P., Standovár, T., Rozenberger, D., Diaci, J., Wijdeven, S., Meyer, P., Winter, S., Vrska, T. (2005): Dead wood in European beech (Fagus sylvatica) forest reserves – Forest Ecology and Management 210(1-3): 267-282.

12. cit: Odor, P., Heilmann-Clausen, J., Christensen, M., et al. (2006): Diversity of dead wood inhabiting fungi and bryophytes in semi-natural beech forests in Europe - Biological Conservation 131 (1): 58-71.

13. cit: Standovar T, Odor P, Aszalos R, et al. (2006): Sensitivity of ground layer vegetation diversity descriptors in indicating forest naturalness – Community Ecology 7 (2): 199-209

14. cit: Standovar, T., Odor, P., Aszalos, R., et al. (2006): Sensitivity of ground layer vegetation diversity descriptors in indicating forest naturalness – Community Ecology, 7(2): 199-209.

15. cit: Kenderes, K., Aszalos, R., Ruff, J., et al. (2007): Effects of topography and tree stand characteristics on susceptibility of forests to natural disturbances (ice and wind) in the Borzsony Mountains (Hungary) – Community Ecology, 8(2): 209-220.

16. cit: Kenderes, K., Mihok, B., Standovar, T. (2008): Thirty years of gap dynamics in a central european beech forest reserve – Forestry, 81(1): 111-123.

17. cit: Kenderes, K., Král, K., Vrška, T., Standovár, T. (2009): Natural Gap Dynamics in a Central European Mixed Beech-Spruce-Fir Old-Growth Forest – Ecoscience 16(1):39-47.

LADÁNYI, M., HORVÁTH, L., GAÁL, M., HUFNAGEL, L. (2003): An agro-ecological simulation model system – Applied Ecology and Environmental Research 1(1-2): 47-74.

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1. cit: Erdélyi, É. (2003): A new approach of investigating agro-ecosystems, application of graph theory – In: Simon, G. (ed.): Lippay János – Ormos Imre – Vas Károly Scientific Symposium (Section of Agroinformatics and Modelling), pp. 32-33.

2. cit: Erdélyi, É. (2003): Modelling the water- and nutrient flow in soil – In: Simon, G. (ed.): Lippay János – Ormos Imre – Vas Károly Scientific Symposium (Section of Agroinformatics and Modelling), pp. 34-35.

3. cit: Révész, A. (2003): A new method for heat-unit calculation – In: Simon, G.

(ed.): Lippay János – Ormos Imre – Vas Károly Scientific Symposium (Section of Agroinformatics and Modelling), pp. 54-55.

4. cit: Tamás, J. (2003): Problems and solutions of field scale agro-ecological data acquisition and interpretations in agroinformatical domain – Applied Ecology and Environmental Research 1(1-2): 143-158.

5. cit: Erdélyi, É., Szabó, Cs. (2004): Primena teorije grafova kao moguonost kontrolisanja agroekosostema [Application of graph theory as a possibility of controlling agroecosystems] – III. Medunarodna Eko-Konferencija, Novi Sad, Proceedings pp. 431-434.

6. cit: Vitali, G., Epifani, R., Vicari, A. (2004): Indicatori agro-ambientali per l’agricoltura biologica – Working paper n. 3., Universitá di Bologna

8. cit: Sa, L., Xiong, F. L., Ding, Y.S. (2007): An artificial life computational model for the dynamics of agro-ecosystem – International Conference on Life System Modeling and Simulation (LSMS), Sep 14-17, 2007 Shanghai, Peoples China, Bio- Inspired Computational Intelligence and Applications, Lecture Notes n Computer Science, 4688: 144-151.

9. cit: Fodor, N., Máthéné-Gáspár, G., Árendás, T., Csathó, P. (2011): To ban or not to ban February fertilization in Hungary? – Applied Ecology and Environmental Research 9(3): 245-252.

10. cit: Horváth, L., Kocsis, M. (2003): A new method for measuring ecological adaptation – In: Simon, G. (ed.): Lippay János – Ormos Imre – Vas Károly Scientific Symposium (Section of Agroinformatics and Modelling), pp. 36-37.

11. cit: Ladányi, M. (2003): A model for biotic interactions among populations – In:

Simon, G. (ed.): Lippay János – Ormos Imre – Vas Károly Scientific Symposium (Section of Agroinformatics and Modelling), pp. 44-45.

12. cit: Ladányi, M., Hufnagel, L. (2003): How to define the number of individuals with respect to the phenology? – In: Simon, G. (ed.): Lippay János – Ormos Imre – Vas Károly Scientific Symposium (Section of Agroinformatics and Modelling), pp. 46-47.

13. cit: Tenk, M., Stipkovits, L., Hufnagel, L. (2004): Examination of the role of Mycoplasma bovis in bovine pneumonia and a mathematical model for its evaluation – Acta Veterinaria Hungarica 52 (4): 445-456.

14. cit: Hufnagel, L., Gaál, M. (2005): Seasonal dynamic pattern analysis in service of climate change research (A methodical case-study, monitoring and simulation based on an aquatic insect community) – Applied Ecology and Environmental Research 3(1): 79-132.

15. cit: Sipkay, Cs., Hufnagel, L., Gaál, M. (2005): Zoocoenological state of microhabitats and its seasonal dynamics in an aquatic Macroinvertebrate assembly (Hydrobiological case studies on Lake Balaton, №. 1) – Applied Ecology and Environmental Research 3(2): 107-137.

(4)

16. cit: Ladányi, M., Hufnagel, L. (2006): The effect of climate change on the population of sycamore lace bug (Corythuca ciliata, SAY, Tingidae Heteroptera) based on a simulation model with phenological response – Applied Ecology and Environmental Research 4(2): 85-112.

17. cit: Őszi, B., Ladányi, M., Hufnagel, L. (2006): Population dynamics of the Sycamore Lace Bug, Corythucha ciliata (Say) (Heteroptera: Tingidae) in Hungary – Applied Ecology and Environmental Research 4(1): 135-150.

19. cit: Sipkay, Cs., Hufnagel, L., Révész, A., Petrányi, G. (2007): Seasonal dynamics of an aquatic macroinvertebrate assembly (Hydrobiological case study of Lake Balaton

№ 2) – Applied Ecology and Environmental Research 5(2): 63-78.

21. cit: Sipkay, Cs., Horváth, L., Nosek, J., Oertel, N., Vadadi-Fülöp, Cs., Farkas, E., Drégelyi-Kiss, Á., Hufnagel, L. (2008): Analysis of climate change scenarios based on modelling of the seasonal dynamics of a Danubian copepod species – Applied Ecology and Environmental Research 6(4): 101-109.

22. cit: Sipkay Cs,.Kiss, K. T., Vadadi-Fülöp, Cs., Hufnagel, L. (2009): Trends in research on the possible effects of climate change concerning aquatic ecosystems with special emphasis on the modelling approach – Applied Ecology and Environmental Research 7(2): 171-198.

FODOR, N., KOVÁCS, G. J. (2003): Sensitivity of 4M maize model to the inaccuracy of weather and soil input data – Applied Ecology and Environmental Research 1(1-2): 75-85.

3. cit: Tenk, M., Stipkovits, L., Hufnagel, L. (2004): Examination of the role of Mycoplasma bovis in bovine pneumonia and a mathematical model for its evaluation – Acta Veterinaria Hungarica 52 (4): 445-456.

5. cit: Őszi, B., Ladányi, M., Hufnagel, L. (2006): Population dynamics of the Sycamore Lace Bug, Corythucha ciliata (Say) (Heteroptera: Tingidae) in Hungary – Applied Ecology and Environmental Research 4(1): 135-150.

(5)

7. cit: Bellocchi, G., Rivington, M., Donatelli, M., Matthews, K. (2010): Validation of biophysical models: issues and methodologies. A review – Agron. Sustain. Dev.

30(1): 109–130.

8. cit: Fodor, N., Pásztor, L. (2010): The agro-ecological potential of Hungary and its prospective development due to climate change – Applied Ecology and Environmental Research 8(3): 177-190.

MÁTHÉ-GÁSPÁR, G., KOVÁCS, G. J. (2003): Use of simulation technique to distinguish between the effect of soil and weather on crop development and growth – Applied Ecology and Environmental Research 1(1-2): 87-92.

5. cit: Erdélyi, E. (2006): Graph theory application for investigating agroecosystems effected by extrem weather conditions – Applied Ecology and Environmental Research 4(2): 181-187.

8. cit: Tóth T. (2007): Egyes talajtulajdonságok hatása a szikes és csernozjom főtípus talajain termelt őszi búza és kukorica termésére – Földminősítés, földértékelés és földhasználati információ, Keszthely – Budapest. pp. 83-90.

RÉDEI, D., HUFNAGEL, L. (2003): The species composition of true bug assemblages extracted with Berlese funnels (Data to the knowledge on the ground-living Heteroptera of Hungary, № 1) – Applied Ecology and Environmental Research 1(1-2): 93-114.

1. cit: Holecová M., Krumpál M., Országh I., Krumpálová Z., Fedor P. (2005):

Biodiversity of selected invertebrate groups in oak-hornbeam forest ecosystem in SW Slovakia. – Ekológia (Bratislava) Vol. 24, Supplement 2, p. 205–222.

2. cit: Rédei, D., Gaál, M., Hufnagel, L. (2003): Spatial and temporal patterns of true bug assemblages extracted with Berlese funnels (Data to the knowledge on the ground- living Heteroptera of Hungary, № 2) – Applied Ecology and Environmental Research 1(1-2): 115-142.

(6)

3. cit: Rédei, D., Hufnagel, L. (2003): Data to the knowledge on the soil bug fauna of the Hungarian Northern-Mountains (Heteroptera) [Adatok az Északi-középhegység talajlakó poloskafaunájának ismeretéhez (Heteroptera)] – Folia historico naturalia Musei Matraensis 27: 81-89. [in Hungarian, English abstract]

5. cit: Rédei, D., Gaál, M., Hufnagel, L. (2003): Getting information from sporadic data sets using bootstrap method – a case study – In: Simon, G. (ed.): Lippay János – Ormos Imre – Vas Károly Scientific Symposium (Section of Agroinformatics and Modelling), pp. 52-53.

6. cit: Rédei, D., Harmat, B., Hufnagel, L. (2004): Ecology of the Acalypta species occurring in Hungary (Insecta: Heteroptera: Tingidae) (Data to the knowledge on the ground-living Heteroptera of Hungary, № 3 – Applied Ecology and Environmental Research 2(2): 73-91.

RÉDEI, D., GAÁL, M., HUFNAGEL, L. (2003): Spatial and temporal patterns of true bug assemblages extracted with Berlese funnels (Data to the knowledge on the ground- living Heteroptera of Hungary, № 2) – Applied Ecology and Environmental Research 1(1- 2): 115-142.

1. cit: Horváth, L., Kocsis, M. (2003): A new method for measuring ecological adaptation – In: Simon, G. (ed.): Lippay János – Ormos Imre – Vas Károly Scientific Symposium (Section of Agroinformatics and Modelling), pp. 36-37.

2. cit: Kocsis, M., Horváth, L. (2003): Construction and development of Hungarian Lepidoptera Lighttrap-database for multivariate biometric evaluations – In:

3. cit: Barinova, S., Medvedeva, L., Nevo, E. (2008): Regional influences on algal biodiversity in two polluted rivers of Eurasia (Rudnaya river, Russia and Qishon river, Israel) by bioindication and canoncal correspondence analysis – Applied Ecology and Environmental Research 6(4): 29-59.

4. cit: Dér, Zs., Rédei, D., Hufnagel, L., Pénzes, B. (2003): The effects of two cultivation methods on the Auchenorrhyncha and Heteroptera assemblages of Raspberry plantations – 4th International Conference of PhD students (Univ. of Miskolc) pp.

219-224.

6. cit: Rédei, D., Gaál, M., Hufnagel, L. (2003): Getting information from sporadic data sets using bootstrap method – a case study – In: Simon, G. (ed.): Lippay János –

(7)

Ormos Imre – Vas Károly Scientific Symposium (Section of Agroinformatics and Modelling), pp. 52-53.

7. cit: Rédei, D., Hufnagel, L. (2003): Data to the knowledge on the soil bug fauna of the Hungarian Northern-Mountains (Heteroptera) [Adatok az Északi-középhegység talajlakó poloskafaunájának ismeretéhez (Heteroptera)] – Folia historico naturalia Musei Matraensis 27: 81-89 [in Hungarian, English abstract]

8. cit: Rédei, D., Harmat, B., Hufnagel, L. (2004): Ecology of the Acalypta species occurring in Hungary (Insecta: Heteroptera: Tingidae) (Data to the knowledge on the ground-living Heteroptera of Hungary, № 3 – Applied Ecology and Environmental Research 2(2): 73-91.

9. cit: Bíró, J., Povazsán, J., Kőrösi, L., Glavits, R., Hufnagel, L., Stipkovits, L. (2005):

Safety and efficacy of Mycoplasma gallisepticum TS-11 vaccine for the protection of layer pullets against challenge with virulent M-gallisepticum R-srain – Avian Pathology 34(4): 341-347.

TAMÁS, J. (2003): Problems and solutions of field scale agro-ecological data acquisition and data interpretations in agroinformatical domain – Applied Ecology and Environmental Research 1(1-2):143-157.

1. cit: Kocsis, M., Horváth, L. (2003): Construction and development of Hungarian Lepidoptera Lighttrap-database for multivariate biometric evaluations – In:

3. cit: Diodato, N., Ceccarelli, M. (2005): Environinformatics in ecological risk assessment of agroecosystems pollutant leaching – Stochastic Environmental Research and Risk Assesment, 19(4): 292-300.

5. cit: Diodato, N. (2006): Hydroinformatics system for pollutant potential leaching spatial uncertainty assessment – Environmental Geosciences 13(4): 227-238.

6. cit: Pásztor, L., Pálfai, I., Bozán, Cs., Kőrösparti, J., Szabó, J. Bakacsi, Zs., Kuti, L. (2006): Spatial stochastic modelling of inland inundation hazard – 9th AGILE Conference on Geographic Information Science, Visegrád, Hungary, p. 139-143.

7. cit: Bozán, Cs., Körösparti, J., Pásztor, L., Kuti, L., Pálfai, I. (2008): Mapping of excess water hazard in the region of South Hungarian great plain – E- proceedings of XXIVth Conference of the Danubian Countries on the Hydrological Forecasting and Hydrological Bases of Water Management, Bled,

(8)

Slovenia, 2-4 June 2008

http://ksh.fgg.uni-lj.si/bled2008/cd_2008/02_Hydro-

meteorological%20extremes,%20floods%20and%20droughts/074_Bozan.pdf

FAHIM, M. A., HASSANIEN, M. K., MOSTAFA, M. H. (2003): Relationships between climatic conditions and Potato Late Blight epidemic in Egypt during winter 1999–2001 – Applied Ecology and Environmental Research 1(1-2): 159-172.

BÍRÓ, J. (2003): Temporal-spatial pattern of true bug assemblies (Heteroptera:

Gerromorpha, Nepomorpha) in Lake Balaton – Applied Ecology and Environmental Research 1(1-2): 173-181.

2. cit: Merdic, E., Keza, N., Csabai, Z. (2005): Aquatic insects in Kopacki rit Nature Park (Heteroptera: Nepomorpha, Gerromorpha and Coleoptera: Hydradephaga, Hydrophiloidea) – Nat. Croat 14(4): 263–272.

4. cit: Karaouzas I, Gritzalis KC (2006): Local and regional factors determining aquatic and semi-aquatic bug (Heteroptera) assemblages in rivers and streams of Greece - Hydrobiologica 573: 199-212

5. cit: Nosek, J. N., Vasarhelyi, T., Bakonyi, G., et al. (2007): Spatial pattern of water bugs (Nepomorpha, Gerromorpha) at different scales in the Szigetkoz (Hungary) – Biologia, 62(3): 345-350.

(9)

6. cit: Abbasi, R., Mashhadikhan, M., Abbasi, M., Kiabi, B. (2008): Biodiversity of vespid wasps in spatial and temporal dimensions in northern Zanjan Province of Iran – Chinese Journal of Ecology 27(5): 797-802.

7. cit: Ditrich, T., Papaček, M., Broum, T. (2008): Spatial distribution of semiaquatic bugs (Heteroptera: Gerromorpha) and their wing morphs in a small scale of the Pohořský Potok stream spring area (Novohradské Hory Mts.) – Silva Gabreta 14(3): 173-178.

8. cit: Soós, N., Boda, P., Csabai, Z. (2009): First confirmed occurrences of Notonecta maculata and N. meridionalis (Heteroptera: Notonectidae) in Hungary with notes, maps, and a key to the Notonecta species of Hungary – Folia Entomologica Hungarica 70: 67-78.

9. cit: Soós, N., Horvai, V., Czirok, A. Csabai, Z. (2009): Contribution to the aquatic and semiaquatic Heteroptera (Nepomorpha, Gerromorpha) fauna of the Transdanubian region, Hungary – Acta Biol. Debr. Oecol. Hung 20: 193–208 10. cit: Bíró, J., Povazsán, J., Kőrösi, L., Glavits, R., Hufnagel, L., Stipkovits, L. (2005):

PATEL, S.R., AWASTHI, A.K., TOMAR, R.K.S. (2004): Assessment of yield losses in Mustard (Brassica juncea L.) due to Mustard Aphid (Lipaphis erysimi Kalt.) under different thermal environments in Eastern Central India – Applied Ecology and Environmental Research 2(1): 1-15.

4. cit: Hossain MA, Maiti MK, Basu A, et al. (2006): Transgenic expression of onion leaf lectin gene in Indian mustard offers protection against aphid colonization - Crop Science 46 (5): 2022-2032.

5. cit: Arora, GK., Rup, PJ., Sohal, SK. (2008): Influence of coumarin on the enzymatic activity in nymphs of Lipaphis erysimi (Kalt.) – Allelopathy Journal, 22(1): 221-229.

6. cit: Dey, D., Akhtar, MS. (2008): Spatial distribution and population dynamics of mustard aphid (Lipaphis erysimi) on Indian mustard (Brassica juncea) – Indian Journal of Agricultural Sciences, 78(8): 719-722.

NOWINSZKY, L. (2004): Nocturnal illumination and night flying insects – Applied Ecology and Environmental Research 2(1): 17-52.

(10)

2. cit: Leelapaibul, W., Bumrungsri, S., Pattanawiboon, A. (2005): Diet of wrinkle- lipped free-tailed bat (Tadarida plicata Buchannan, 1800) in central Thailand:

insectivorous bats potentially act as biological pest control agents – Acta Chiropterologica 7(1): 111-119.

3. cit: Alberto, J.C., Kirschbaum, C.F. (2007): Lighting pollution and intrusive light evaluation in residential and rural areas – In: Starlight a common heritage, Starlight Initiative-UNESCO - MAB, Islas Canarias, España, p. 39-48.

4. cit: Jeyakumar P, Chander S, Singh A, et al. (2007): Effects of light trap and lunar cycle on the insects of cotton (Gossypium hirsutum) ecosystem – Indian Journal of Agricultural Sciences, 77(5): 327-328.

5. cit: Altermatt, F., Baumeyer, A., Ebert, D. (2009): Experimental evidence for male biased flight-to-light behavior in two moth species – Entomologia Experimentalis et Applicata, 130(3): 259-265.

6. Kemp PS, Williams JG. (2009): Illumination influences the ability of migrating juvenile salmonids to pass a submerged experimental weir – Ecology of Freshwater Fish 18: 297–304.

SINGH, N.B., KHARE, A.K., BHARGAVA, D. S., BHATTACHARYA, S. (2004):

Optimum moisture requirement during Vermicomposting using Perionyx excavatus – Applied Ecology and Environmental Research 2(1): 52-62.

1. cit: Adi, A.J., Noor, Z.M. (2009): Waste recycling: Utilization of coffee grounds and kitchen waste in vermicomposting – Bioresource Technology, 100(2): 1027- 1030.

2. cit: Swati Pattnaik, M. Vikram Reddy (2010): Nutrient Status of Vermicompost of Urban Green Waste Processed by Three Earthworm Species—Eisenia fetida, Eudrilus eugeniae, and Perionyx excavatus – Applied and Environmental Soil Science, Article ID 967526, 13 pages doi:10.1155/2010/967526

RIFAAT H.M., YOSERY, M. A. (2004): Identification and characterization of rubber degrading Actinobacteria – Applied Ecology and Environmental Research 2(1): 63-70.

BANERJEE, M., SHARMA, D. (2004): Regulation of phosphatase activity in Chroococcidiopsis isolates from two diverse habitats: effect of light, pH and temperature – Applied Ecology and Environmental Research 2(1): 71-82.

1. cit: Barinova, S., Medvedeva, L., Nevo, E. (2008): Regional influences on algal biodiversity in two polluted rivers of Eurasia (Rudnaya river, Russia and Qishon

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river, Israel) by bioindication and canoncal correspondence analysis (CCA) – Applied Ecology and Environmental Research 6(4): 29-59.

MIRONGA, J.M. (2004): Geographic Information Systems (GIS) and Remote Sensing in the management of shallow tropical lakes – Applied Ecology and Environmental Research 2(1): 83-103.

1. cit: Ari HA, Yuksel Y, Cevik EO, et al. (2007): Determination and control of longshore sediment transport: A case study – Ocean Engineering 34 (2): 219-233.

2. cit: Kateregga E, Sterner T (2007): Indicators for an invasive species: Water hyacinths in Lake Victoria - Ecological Indicators 7 (2): 362-370.

3. cit: Malik A (2007): Environmental challenge vis a vis opportunity: The case of water hyacinth - Environment International 33 (1): 122-138.

4. cit: Adediji, A., Ajibade, L.T. (2008): The change detection of major dams in Osun State, Nigeria using remote sensing (RS) and GIS techniques – Journal of Geography and Regional Planning 1(6): 110-115.

5. cit: Kiage, L.M., Walker, N.D. (2009): Using NDVI from MODIS to Monitor Duckweed Bloom in Lake Maracaibo, Venezuela – Water Resources Management 23(6): 1125-1135.

SHOKRI, M., SAFAIAN, N., AHMADI, M. Z. T., AMIRI, B. J. (2004): A second look on Biogeographical Province of Miankaleh Biosphere Reserve – Applied Ecology and Environmental Research 2(1): 105-117.

1. cit: Bíró, J., Povazsán, J., Kőrösi, L., Glavits, R., Hufnagel, L., Stipkovits, L.

(2005): Safety and efficacy of Mycoplasma gallisepticum TS-11 vaccine for the protection of layer pullets against challenge with virulent M-gallisepticum R- srain – Avian Pathology 34(4): 341-347.

3. cit: Naqinezhad, A., Rice, B.A., Attar, F., Jalili, A. (2008): Utricularia (Lentibulariaceae) of Iran – Carnivorous Plant Newsletter 37(1): 4-10.

4. cit: Khodadadi, S., Saedi Mehrvarz, S.H., Naquinezhad, A.R. (2009):

Contribution to the flora and habitats of the Estil Wetland (Astara) and its surroundings, Northwest Iran – Rostaniha 10(1): 44-63.

5. cit: Zhang, DC., Boufford, DE., Ree, RH., Sun, H. (2009): The 298N latitudinal line: an important division in the Hengduan Mountains, a biodiversity hotspot in southwest China – Nordic Journal of Botany 27: 405-412.

KRISTON-VIZI, J., FERENCZY, A., UMEDA, M., MIYAMOTO, K. (2004):

Biometrical approaches for mandarin leaf image analysis – Applied Ecology and Environmental Research 2(1): 119-134.

PALA, A. (2004): Genetic Conservation of Livestock and Factor Analysis – Applied Ecology and Environmental Research 2(1): 135-141.

(12)

CIOLAC, A. (2004): Migration of fishes in Romanian Danube River, № 1 – Applied Ecology and Environmental Research 2(1): 143-163.

1. cit: Torcu, H. et al. (2008): An Investigation in Fish Fauna Ikizcetepeler Dam Lake (Balıkesir), Turkey – Journal of Applied Biological Sciences 2(2): 63-67.

2. cit: Copp , G.H. et al. (2009): Voracious invader or benign feline? A review of the environmental biology of European catfish Silurus glanis in its native and introduced ranges – FISH and FISHERIES 10: 252–282.

3. cit: Višnjić-Jeftić, Ž., Lenhardt M., Navodaru I., Hegediš A., Gačić Z., Nikčević M. (2009): Reproducibility of age determination by scale and vertebra in pontic shad (Alosa pontica Eichwald, 1838), from the Danube – Archives of Biological Sciences 61(2): 337-341.

MEHROTRA, P., KHARAKWL, G., PANGETY, Y.P.S. (2004): Ecological implication of plant traits, strategies and competitive abilities of herbs – Applied Ecology and Environmental Research 2(2): 1-13.

KHARKWAL, G., MEHROTA, P., RAWAT, Y.S., PANGTEY, Y.P.S. (2004):

Comparative study of herb layer diversity in pine forest stands at different altitudes of Central Himalaya – Applied Ecology and Environmental Research 2(2): 15-24.

MOHAN, J., PRAKASH, R., BEHARI, J.R. (2004): Electrochemical detection and catalytic oxidation of phenolic compounds over nickel complex modified graphite electrode – Applied Ecology and Environmental Research 2(2): 25-33.

1. cit: Mishra, Govind Krishna; Krishna, Vijay; Prakash, Rajiv (2009): Synthesis and Characterization of Novel Heterobinuclear Mercury(II)-DTPA-M(II)

(13)

Complexes: Electrocatalytic and Sensor Applications – Synthesis and Reactivity in Inorganic, Metal-Organic, and Nano-Metal Chemistry 39(3): 124-128.

RAGHUVANSHI, S. P., SINGH, R., KAUSHIK, C.P. (2004): Kinetics study of methylene blue dye bioadsorption on baggase – Applied Ecology and Environmental Research 2(2): 35-43.

1. cit: Jayswal, A., Chudasama, U. (2007): The use of metal phosphonates in the removal of anti infective organic molecules by adsorption process – Acta Chimica Slovenica, 54(3): 654-660.

2. cit: Amin, N.K. (2008): Removal of reactive dye from aqueous solutions by adsorption onto activated carbons prepared from sugarcane bagasse pith - Conference of the European-Desalination-Society and Center-for-Research-and- Technology-Hellas, APR 22-25, 2007 Halkidiki, Greece, Desalination, 223(1-3):

152-161.

3. cit: Cengiz, S., Cavas, L. (2008): Removal of methylene blue by invasive marine seaweed: Caulerpa racemosa var. cylindracea – Bioresource Technology, 99(7):

2357-2363.

4. cit: Jayswal, A., Chudasama, U. (2008): Sorption of Anti-Infective Organic Molecules from Aqueous Solutions onto Zirconium Phosphate – Journal of the Iranial Chemical Society, 5(4): 595-602.

5. cit: Jain, R., Shrivastava, M. (2008): Adsorptive studies of hazardous dye Tropaeoline 000 from an aqueous phase on to coconut-husk – Journal of Hazardous Materials, 158(2-3): 549-556.

6. cit: Namdeo, M., Bajpai, S.K. (2008): Chitosan-magnetite nanocomposites (CMNs) as magnetic carrier particles for removal of Fe(III) from aqueous solutions – Colloids and Surfaces A-Physocochemical and Engineering Aspects, 320(1-3): 161-168.

7. cit: Pathak, A., Bajpai, S.K. (2008): Preparation of Cu(II)-Immobilized chitosan (CIC) and preliminary urea uptake study – Polymer-Plastics Technology and Engineering, 47(9): 925-930.

8. Sreelatha, G., Padmaja, P. (2008): Study of Removal of Cationic Dyes using Palm Shell Powder as Adsorbent – Journal of Environmetal Protection Science 2: 63- 71.

9. cit: Ayrancy, E., Duman, O. (2009): In-Situ UV-Visible Spectroscopic Study on the Adsorption of some Dyes onto Activated Carbon Cloth – Separation Science and Technology 44(15): 3735 – 3752.

10. cit: Bajpai, S. K., Rohit, V. K., Namdeo, M. (2009): Removal of Phosphate Anions from Aqueous Solutions Using Polypyrrole-Coated Sawdust as a Novel Sorbent – Journal of Applied Polymer Science, 111(6): 3081-3088.

11. cit: Bekci, Z., Seki, Y., Cavas, L. (2009): Removal of malachite green by using an invasive marine alga Caulerpa racemosa var. cylindracea – Journal of Hazardous Materials, 161(2-3): 1454-1460.

12. cit: Demirbas, A. (2009): Agricultural based activated carbons for the removal of dyes from aqueous solutions: A review – Journal of Hazardous Materials 167(1- 3): 1-9.

13. cit: Mittal, A., Mittal, J., Malviya, A., Gupta, V.K. (2009): Adsorptive removal of hazardous anionic dye “Congo red” from wastewater using waste materials and recovery by desorption – Journal of Colloid and Interface Science 340(1): 16-26.

(14)

14. cit: Ofomaja, A.E., Naidoo, E.B., Modise, S.J. (2009): Removal of copper(II) from aqueous solution by pine and base modified pine cone powder as biosorbent – Journal of Hazardous Materials 168(2-3): 909-917.

15. cit: Taha, G.M. (2009): Sorption potential of the biomasses peanut hull and fly ash for decolourization of methylene blue aquaeous solution – Journal of Solid Waste Technology and Management 35(1): 26-34.

16. cit: Ai, L., Huang, H., Chen, Z., Wei, X., Jiang, J. (2010): Activated carbon/CoFe2O4 composites: Facile synthesis, magnetic performance and their potential application for the removal of malachite green from water – Chemical Engineering Journal 156(2): 243-249.

17. cit: Ofomaja, A.E., Naidoo, E.B., Modise, S.J. (2010): Kinetic and Pseudo- Second-Order Modeling of Lead Biosorption onto Pine Cone Powder – Ind. Eng.

Chem. Res. 49(6): 2562-2572.

18. cit: Sharma, P., Kaur, R., Baskar, C., Chung, W-J. (2010): Removal of methylene blue from aqueous waste using rice husk and rice husk ash – Desalination 259(1- 3): 249-257.

19. cit: Taha, GM., Mosaed, TM. (2010): Blast Furnace Slag of a Ferrosilicon Firm in Aswan Governorate, Upper Egypt, as an Adsorbent for the Removal of Merocyanine Dye from Its Aqueous Solution – Chemistry & Biodiversity 4(4):

878-886.

20. cit: Raghuvanshi, S.P., Singh, R., Kaushik, C.P. (2008): Adsorption of congo red dye from aqueous solutions using neem leaves as adsorbent – Asian Journal of Chemistry, 20(7): 4994-5000.

RIFAAT, H.M., AWAD, A.H., GEBREEL, H.M. (2004): Taxonomic characterisation of Actinobacteria isolated from the atmosphere surrounding chamomile plants – Applied Ecology and Environmental Research 2(2): 45-51.

CIOLAC, A., PATRICHE, N. (2004): Structure of Danube shad (Alosa pontica Eichwald, 1838) spawner flocks migrating for reproduction in Danube river (Migration of fishes in Romanian Danube River № 2) – Applied Ecology and Environmental Research 2(2): 53-58.

1. cit: Višnjić-Jeftić, Ž., Lenhardt M., Navodaru I., Hegediš A., Gačić Z., Nikčević M. (2009): Reproducibility of age determination by scale and vertebra in pontic shad (Alosa pontica Eichwald, 1838), from the Danube – Archives of Biological Sciences 61(2): 337-341.

GAÁL, M., SCHMIDTKE, J., RASCH, D., SCHMIDT, K., NEEMANN, G., KARWAS, M. (2004): Simulation experiments to evaluate the robustness of the construction of monitoring networks – Applied Ecology and Environmental Research 2(2): 59-71.

(15)

3. cit: Sipkay, Cs., Hufnagel, L., Gaál, M. (2005): Zoocoenological state of microhabitats and its seasonal dynamics in an aquatic Macroinvertebrate assembly (Hydrobiological case studies on Lake Balaton, №. 1) – Applied Ecology and Environmental Research 3(2): 107-137.

RÉDEI, D., HARMAT, B., HUFNAGEL, L. (2004): Ecology of the Acalypta species occuring in Hungary (Insecta: Heteroptera: Tingidae) (Data to the knowledge on the ground-living Heteroptera of Hungary, № 3) – Applied Ecology and Environmental Research 2(2): 73-90.

2. cit: Aysal, T., Kavan, M. (2008): Development and population growth of Stephanitis pyri (F.) (Heteroptera: Tingidae) at five temperatures – Journal of Pest Science, 81(3): 135-141.

4. cit: Bíró, J., Povazsán, J., Kőrösi, L., Glavits, R., Hufnagel, L., Stipkovits, L. (2005):

GHOSH, M., SINGH, S.P. (2005): A review on phytoremediation of heavy metals and utilization of its byproducts – Applied Ecology and Environmental Research 3(1): 1-18.

1. cit: Katanić, M., Tomović, Z., Pilipović, A., Orlović, S., Krstić, B. (2006): Uticaj kadmijuma na rast izdanaka topola sekcije Leuce u kulturi tkiva – Topola 177- 178: 88-105.

2. cit: Das, M., Maiti, S.K. (2007): Metal Mine Waste and Phytoremediation: A Review – Asian Journal of Water, Environment and Pollution 4(1): 169-176.

3. cit: Erakhrumen, A.A. (2007): Phytoremediation: an environmentally sound technology for pollution prevention, control and remediation in developing countries – Educational Research and Review 2(7): 151-156.

4. cit: Gourlaouen C, Parisel O (2007): Is an electronic shield at the molecular origin of lead poisoning? A computational modeling experiment – Angewandte Chemie -International Edition 46 (4): 553-556

(16)

5. cit: Hornik, M., Pipiska, M., August, J., et al. (2007): Distribution of Cs-137 and Co-60 in fresh water plants – Cereal Research Communications, 35(2): 477-480.

6. cit: Katanić, M., Pilipović, A., Orlović, S., Krstić, B. (2007): Uticaj olova na rast izdanaka i koncentraciju fotosintetičkih pigmenata u listovima klonova belih topola (Populus alba) u kulturi tkiva – Topola 179-180: 15-24.

7. cit: Padmavathiamma, PK., Li, LY. (2007): Phytoremediation technology:

Hyper-accumulation metals in plants – Water Air and Soil Pollution, 184(1-4):

105-126.

8. cit: Sharift, M., Sadeghi, Y., Akbarpour, M. (2007): Germination and growth of six plant species on contaminated soil with spent oil – International Journal of Environmental Science and Technology, 4(4): 463-470.

9. cit: Benzarti, S., Mohri, S., Ono, Y. (2008): Plant response to heavy metal toxicity: Comparative study between the hyperaccumulator Thlaspi caerulescens (ecotype Ganges) and nonaccumulator plants: Lettuce, radish, and alfalfa – Environmental Toxicology, 23(5): 607-616.

10. cit: Bose, S., Jain, A., Rai, V., et al. (2008): Chemical fractionation and translocation of heavy metals in Canna indica L. grown on industrial waste amended soil – Journal of Hazardous Materials, 160(1): 187-193.

11. cit: Brunet, J., Repellin, A., Varrault, G., et al. (2008): Lead accumulation in the roots of grass pea (Lathyrus sativus L.): a novel plant for phytoremediation systems? – Comptes Rendus Biologies, 331(11): 859-864.

12. cit: Mwegoha, W.J.S. (2008): The use of phytoremediation technology for abatement soil and groundwater pollution in Tanzania: opportnities and challenges – Journal of Sustainable Development in Africa 10(1): 140-156.

13. cit: Nunez-Lopez, RA., Meas, Y., Gama, SC., et al. (2008): Leaching of lead by ammonium salts and EDTA from Salvinia minima biomass produced during aquatic phytoremediation – Journal of Hazardous Materials, 154(1-3): 623-632.

14. cit: Pajuelo, E., Rodriguez-Llorente, ID., Dary, M., et al. (2008): Toxic effects of arsenic on Sinorhizobium-Medicago sativa symbiotic interaction – Journal of Hazardous Materials, 154(2): 203-211.

15. cit: Sheoran, V., Sheoran, AS., Poonam, P. (2008): Remediation techniques for contaminated soils – Environmental Engineering and Management Journal, 7(4):

379-387.

16. cit: Shivam, K., Mishra, S.K., Tripathi, C.P.M. (2008): Bio-technological aplication to environmental problems and their management – In: Joshi, B.D., Joshi, P.C., Joshi, N. (eds): En vironmental pollution & toxicology, Chapter XXI., p. 176-185.

17. cit: Benimelli, C.S., Medina, A., Navarro, C.M., Medina, R.B., Amoroso, M.J., Gómez, M.I. (2009): Bioaccumulation of Copper by Zea mays: Impact on Root, Shoot and Leaf Growth – Water, Air, & Soil Pollution doi 10.1007/s11270-009- 0259-6

18. cit: Bragato, C., Schiavon, M., Polese, R., Ertani, A., Pittarello, M., Malagoli, M.

(2009): Seasonal variations of Cu, Zn, Ni and Cr concentration in Phragmites australis (Cav.) Trin ex steudel in a constructed wetland of North Italy – Desalination 246(1-3): 35-44.

19. cit: Cao, X., Ma, L., Shiralipour, A., Harris, W. (2009): Biomass reduction and arsenic transformation during composting of arsenic-rich hyperaccumulator Pteris vittata L. – Environmental Science and Pollution Research DOI 10.1007/s11356-009-0204-7

(17)

20. cit: Dhir, B., Sharmila, P., Saradhi, PP. (2009): Potential of Aquatic Macrophytes for Removing Contaminants from the Environment – Critical Reviews in Environmental Science and Technology 39(9): 754–781.

21. cit: Hong-Bo, S., Li-Ye, C., Cheng-Jiang, R, Hua, L., Dong-Gang, G., Wei-Xiang, L. (2009): Understanding molecular mechanisms for improving phytoremediation of heavy metal-contaminated soils – Critical Reviews in Biotechnology 0(0): 1-8.

22. cit: Jabeen, R., Ahmad, A., Iqbal, M. (2009): Phytoremediation of Heavy Metals:

Physiological and Molecular Mechanisms – The Botanical Review 75(4): 339-364.

23. cit: Kimenyu, P.N., Oyaro, N., Chacha, J.S., Tsanuo, M.K. (2009): The Potential of Commelina bengalensis, Amaranthus hybridus, Zea mays for Phytoremediation of Heavy Metals from Contaminated Soils – Sains Malaysiana 38(1): 61-68.

24. cit: Mellem JJ, Baijnath H, Odhav B. (2009): Translocation and accumulation of Cr, Hg, As, Pb, Cu and Ni by Amaranthus dubius (Amaranthaceae) from contaminated sites – J Environ Sci Health A Tox Hazard Subst Environ Eng.

44(6):568-75.

25. cit: Slobodanka, P., Borišev M., Nikolić N., Krstić B., Pilipović A., Orlović S.

(2009): Kapacitet za fitoremedijaciju klonova topole (Populus spp.) i vrbe (Salix spp.) u zavisnosti od fotosinteze – Archives of Biological Sciences 61(2): 239-247.

26. cit: Yang, JG; Yang, JY; Peng, CH; Tang, CB; Zhou, KC (2009): Recovery of zinc from hyperaccumulator plants: Sedum plumbizincicola – Environmental Technology 30(7): 693-700.

27. cit: Velásquez, L. (2009): Biosorption and bioaccumulation of heavy metals on dead and living biomass of Bacillus sphaericus – Journal of Hazardous Materials 167(1-3):713-716

28. cit: Witters, N., Van Slycken, S., Ruttens, A., Adriaensen, K., Meers, E., Meiresonne, L., Tack, F.M.G., Thewys, T., Laes, E., Vangronsveld, J. (2009):

Short-Rotation Coppice of Willow for Phytoremediation of a Metal- Contaminated Agricultural Area: A Sustainability Assessment – BioEnergy Research 2(3): 144-152.

29. cit: Zehra, SS., Arshad, M., Mahmood, T., Waheed, A. (2009): Assessment of heavy metal accumulation and their translocation in plant species – African Journal of Biotechnology 8(12): 2802-2810.

30. cit: Dary, M., Chamber-Pérez, MA., Palomares, A.J., Pajuelo, E. (2010 in press):

“In situ” phytostabilisation of heavy metal polluted soils using Lupinus luteus inoculated with metal resistant plant-growth promoting rhizobacteria – Journal of Hazardous Materials

31. cit: Mukhopadhyay, S., Maiti, S.K. (2010): Phytoremediation of metal mine waste – Applied Ecology and Environmental Research 8(3): 207-222.

32. cit: Saxena, P., Misra, N. (2010): Remediation of Heavy Metal Contaminated Tropical Land – In: Sherameti, I., Varma, A. (eds): Soil Biology, Soil Heavy Metals p. 431-477., Springer Berlin Heidelberg

33. cit: Zimmer, D., Kiersh, K., Jandl, G., Meissner, R., Kolomiytsev, N., Leinweber, P. (2010): Status Quo of Soil Contamination with Inorganic and Organic Pollutants of the River Oka Floodplains (Russia) – Water, Air, & Soil Pollution doi 10.1007/s11270-009-0301-8

(18)

MKANDAWIRE, M., BRACKHAGE, C., TAUBERT, B., DUDEL, E.G. (2005):

Semicontinuous culture system for Lemna gibba bioassay: functioning and theory of operation – Applied Ecology and Environmental Research 3(1): 19-27.

1. cit: Mkandawire M, Vogel K, Taubert B, et al. (2007): Phosphate regulates uranium(VI) toxicity to Lemna gibba L. G3 – Environmental Toxicology 22(1): 9-16.

WEI, H. ,WANG, J.L. (2005): Characteristics of acid rain in Jinyun Mountain, Chongqing, China – Applied Ecology and Environmental Research 3(1): 29-37.

1. cit: Elgohary, M.A. (2008): Air Pollution and Aspects of Stone Degradation

“Umayyed Liwân – Amman Citadel as a Case Study”– Journal of Applied Sciences Research 4(6): 669-682.

MUOGHALU, J. I., CHUBA, D. K. (2005): Seed germination and reproductive strategies of Tithonia diversifolia (Hemsl.) Gray and Tithonia rotundifolia (P.M.) Blake – Applied Ecology and Environmental Research 3(1): 39-46.

1. cit: Liasu, M.O., Ogunkunle, A.T.J. (2007): Anatomy and secondary thickening pattern of the stem in Tithonia diversifolia (Hemsl) a Gray, Advances in Natural and Applied Sciences 1(1): 21-25.

2. cit: Almeida, A.P., da Silva Xavier, A., de Arruda, LAM., de Barros, AP.O., de Oliveira Alves, A,, Loges, V. (2009): Influencia do tipo de estaca na propagacao de Tithonia diversifolia (Hemsley) Gray – IX Jornada de Ensino, Pesquisa e Extensão (JEPEX)

3. cit: Muoghalu, J. I. (2008): Growth, reproduction and resource allocation of Tithonia diversifolia and Tithonia rotundifolia – Weed Research, 48(2): 157-162.

OKOLO, J.C. , AMADI, E.N, ODU, C.T.I. (2005): Effects of soil treatments containing poultry manure on crude oil degradation in a sandy loam soil – Applied Ecology and Environmental Research 3(1): 47-53.

1. cit: Okoloh, A. (2006): Biodegradation alternative in the cleanup of petroleum hydrocarbon pollutants – Biotechnology and Molecular Biology Review 1(2): 38- 50.

2. cit: Ezzatian, R., Voussoughi, M., Yaghmaei, S., et al. (2008): Effect of C/N Ratio on the Phytoremediation of Crude Oil Contaminated Soils by Puccinellia Distance – Iranian Journal of Chemistry & Chemical Engineering – International English Edition, 27(3): 77-85.

3. cit: Njoku, KL., Modupe O. Akinola, Bola O. Oboh (2008): Growth and Performance of Glycine max L. (Merrill) Grown in Crude Oil Contaminated Soil Augmented With Cow Dung – Nature and Science 6(1): 48-56.

4. cit: Kang, SW., Kim,YB., Shin, JD., Kim, EK. (2010): Enhanced Biodegradation of Hydrocarbons in Soil by Microbial Biosurfactant, Sophorolipid – Applied Biochemistry and Biotechnology 160(3): 780-790.

(19)

BANERJEE, M., JOHN, J. (2005): Phosphatase activity of non-hair forming cyanobacterium Rivularia and ist role in phosphorus dynamics in deepwater rice fields – Applied Ecology and Environmental Research 3(1): 55-60.

1. cit: Banerjee, M. (2007): Comparative study on phosphatase activity of four rice field cyanobacterial strains and their ecological implications – Nova Hedwigia, 85(3-4):

407-416.

OTOKUNEFOR, T.V., OBIUKWU, C. (2005): Impact of refinery effluent on the physicochemical properties of a water body in the Niger Delta – Applied Ecology and Environmental Research 3(1): 61-72.

1. cit: Daka, ER., Moslen, M., Ekeh, CA., et al. (2007): Sediment quality status of two creeks in the upper bonny estuary, niger delta, in relation to Urban/Industrial activities – Bulletin of Environmental Contamination and Toxicology, 78(6): 515-521.

2. cit: Bako, S.P., Chukwunonso, D., Adamu, A.K. (2008): Bio-remediation of refinery effluents by strains of Pseudomonas aerugenosa and Penicillium janthinellum – Applied Ecology and Environmental Research 6(3): 49-60.

3. cit: Emoyan OO., Akporhonor, E.E., Akpoborie, I.A. (2008): Environmental risk assessment of River Ijana, Ekpan, Delta State Nigeria – Chemical Speciation and Bioavailability 20(1): 23-32.

4. cit: Lynda, S., Rachid, R., Houria, B., Mohammed-Reda, D. (2008): Survey of the physico-chemical quality of the wastewaters of Biskra city rejected in Chabat Roba, Messdour and Wadi Z'ommor (Algeria) – African Journal of Environmental Science and Technology 2(8): 231-238.

5. cit: Cavalcanti, J.V.F.L., de Abreu, C.A.M., da Motta Sobrinho, M.A., Baraúna, O.S., Portela, L.A.P. (2009):Preparação e utilização de uma argila esmectítica organofílica como adsorvente de fenol – Química Nova 32(8): 2051-2057.

6. cit: Nkwelang, G., Nkeng, G., Fouamno, H.L.K., Antai, S.P. (2009): Effect of Crude Oil Effluent (Produce Water) on Brackish Water Fish and Microbial Growth in Aquarium Environment – The Pacific Journal of Science and Technology 10(2): 619-625.

7. cit: Vrabie, CM., Jonker, MTO., Murk, AJ. (2009): Specific in vitro toxicity of crude and refined petroleum products. 1. Aryl hydrocarbon receptor - mediated responses – Environmental Toxicology and Chemistry 28(9): 1995-2003.

8. cit: Konwar, D., Jha, DK. (2010): Response of Rice (Oryza sativa L.) to Contamination of Soil with Refinery Effluents under Natural Conditions – Assam University Journal of Science and Technology: Biological and Environmental Sciences, 5(1): 14-22.

CIOLAC, A. (2005): Study of migratory sturgeon captures in Romanian side of Danube River (Migration of Fishes in Romanian Danube River, № 3) – Applied Ecology and Environmental Research 3(1): 73-78.

HUFNAGEL, L., GAÁL, M. (2005): Seasonal dynamic pattern analysis in service of climate change research (A methodical case-study, monitoring and simulation based on an aquatic insect community) – Applied Ecology and Environmental Research 3(1): 79-132.

(20)

2. cit: Musolin, DL. (2007): Insects in a warmer world: ecological, physiological and life-history responses of true bugs (Heteroptera) to climate change – Global Change Biology, 13(8): 1565-1585.

3. cit: Schletterer, M., Kuzovlev, V.V. (2007): First record of Prosopistoma pennigerum from the Russian Federation (Ephemeroptera: Prosopistomatidae) – Zoosyst. Rossica Vol. 16 : 169-172.

4. cit: Baquero, E., Jordana, R. (2008): Redescription of Entomobrya quinquelineata Borner, 1901 (Collembola: Entomobryidae) and description of three new species – Zootaxa, 1821:1-12.

5. cit: Schletterer, M., Füreder, L. (2009): The family Prosopistomatidae (Ephemeroptera): a review on its ecology and distribution, with particular emphasis on the European species Prosopistoma pennigerum Müller, 1785 – Aquatic Insects 31(S1): 603-620.

9. cit: Vadadi-Fülöp, Cs., Sipkay, Cs., Hufnagel, L. (2007): Klímaváltozási szcenáriók értékelése egy szitakötőfaj (Ischnura pumilio Charpenteier, 1825) szezonális dinamikája alapján – Acta Biol. Debr. Oecol. Hung 16: 211–219.

10. cit: Sipkay, Cs., Horváth, L., Nosek, J., Oertel, N., Vadadi-Fülöp, Cs.,Farkas, E., Drégelyi-Kiss, Á., Hufnagel, L. (2008): Analysis of climate change scenarios based on modelling of the seasonal dynamics of a Danubian copepod species – Applied Ecology and Environmental Research 6(4): 101-109.

11. cit: Eppich, B., Dede, L., Ferenczy, A., Garamvölgyi, Á., Horváth, L., Isépy I., Priszetr, Sz., Hifnagel, L. (2009): Climatic effects on the phenology of geophytes – Applied Ecology and Environmental Research 7(3): 253-266.

12. cit: Eppich B., Dede L., Ferenczy A., Horváth L., Isépy I. , Hufnagel L. (2009):

Időjárás hatása hagymás és gumós növények fenológiájára – LI. Georgikon Napok, p.197-206.

13. cit: Sipkay Cs,.Kiss, K.T., Vadadi-Fülöp, Cs., Hufnagel, L. (2009): Trends in research on the possible effects of climate change concerning aquatic ecosystems with special emphasis on the modelling approach. – Applied Ecology and Environmental Research 7(2): 171-198

14. cit: Ferenczy, A., Eppich, B., Varga, R.D., Bíró, I., Kovács, A., Petrányi, G., Hirka, A., Szabóki, Cs., Isépy, I., Priszter, Sz., Türei, D., Gimesi, L., Garamvölgyi Á., Homoródi, R., Hufnagel, L. (2010): Comparative analysis of the relationship between phenological phenomena and meteorological indicators based on insect and plant monitoring – Applied Ecology and Environmental Research 8(4): 367-376.