Soil Study and Identification of Plant Species Growing Near Two Thermal Springs (Ain El Haouamed and Ain Hamra) in the Eastern Region of Morocco

Mouchane, Mohamed; Hazyoun, Zineb; Taybi, Hanan; Assem, Najat; Bargach, Kaoutar

doi:10.12911/22998993/188291

Nowa wersja platformy, zawierająca wyłącznie zasoby pełnotekstowe, jest już dostępna.
Przejdź na https://bibliotekanauki.pl

Artykuł - szczegóły

Czasopismo

Journal of Ecological Engineering

2024 | Vol. 25, nr 7 | 212--223

Tytuł artykułu

Soil Study and Identification of Plant Species Growing Near Two Thermal Springs (Ain El Haouamed and Ain Hamra) in the Eastern Region of Morocco

Autorzy

Mouchane, Mohamed , Hazyoun, Zineb , Taybi, Hanan , Assem, Najat , Bargach, Kaoutar

Treść / Zawartość

Pełne teksty:

Pobierz

Warianty tytułu

Języki publikacji

Abstrakty

In order to deepen our understanding of the ecosystems around thermal springs and contribute to their preservation and enhancement, our study focused on the physico-chemical analysis of soils located in the immediate vicinity of two thermal springs Ain El Haouamed (S1) and Ain Hamra (S2) in the eastern region of Morocco. At the same time, we identified the plants that thrive in these areas and have developed specific adaptations to particular environmental conditions. The results of physico-chemical soil analyses revealed distinct characteristics. Around the f irst thermal spring (S1), the soil has a sandy loam texture, while around the second spring (S2), a clayey loam texture. The pH of both soils is slightly basic. In terms of organic matter, significant variations were observed between soil samples taken in these areas. Electrical conductivity and other physico-chemical parameters showed variable values. A study of the vegetation near the thermal springs shows the presence of (Matricaria chamomilla, Juncus acutus, Carex sylvatica) at site 1 and (Tamarix gallica, Inula viscosa, Phragmites australis, Typha angustifolia) at site 2. This information will certainly contribute to a better understanding of these specific thermal ecosystems. The present study has led to the identification of several plant species of great interest, representing an important advance in our knowledge of the biodiversity of these areas. These results can also be used to develop strategies for the preservation and sustainable management of these particular ecosystems.

Słowa kluczowe

physicochemical properties soils plants thermal waters

Wydawca

Czasopismo

Journal of Ecological Engineering

Rocznik

2024

Tom

Vol. 25, nr 7

Strony

212--223

Opis fizyczny

Bibliogr. 74 poz., rys., tab.

Twórcy

autor

Mouchane, Mohamed

Laboratory of Natural Substances, Pharmacology, Environment, Modeling, Health and Quality of Life, Polydisciplinary Faculty of Taza, Sidi Mohamed Ben Abdellah University, Fez, Morocco, mohamed.mouchane1@gmail.com

autor

Hazyoun, Zineb

Laboratory of Natural Substances, Pharmacology, Environment, Modeling, Health and Quality of Life, Polydisciplinary Faculty of Taza, Sidi Mohamed Ben Abdellah University, Fez, Morocco, zineb.hazyoun@usmba.ac.ma

autor

Taybi, Hanan

Laboratory of Natural Substances, Pharmacology, Environment, Modeling, Health and Quality of Life, Polydisciplinary Faculty of Taza, Sidi Mohamed Ben Abdellah University, Fez, Morocco, hanan.taybi@usmba.ac.ma

autor

Assem, Najat

Laboratory of Natural Substances, Pharmacology, Environment, Modeling, Health and Quality of Life, Polydisciplinary Faculty of Taza, Sidi Mohamed Ben Abdellah University, Fez, Morocco, najat.assem@usmba.ac.ma

autor

Bargach, Kaoutar

Geo-Biodiversity and Natural Patrimony Laboratory (GEOBIO), Geophysics, Natural Patrimony and Green Chemistry, Research Center, Scientific Institute, Mohammed V University in Rabat, Morocco, kbargach50@gmail.com

Bibliografia

1. AFNOR N. 2003. X31-107; Qualité du Sol—Détermination de la Distribution Granulométrique Des Particules du Sol-Méthode à la Pipette. AFNRO: Saint-Denis, France.
2. Akhter S, Bhat MA, Hashem A, et al. 2023. Profiling of Antibiotic Residues in Soil and Vegetables Irrigated Using Pharmaceutical-Contaminated Water in the Delhi Stretch of the Yamuna River, India. Water. 15(23), 4197.
3. Alia BB. 2020. Différentes méthodes d’extraction de l’espèce Matricariachamomilla:(analyse chimique et étude biologique).
4. Al-Kayssi AA. 2023. Role of alternate and fixed partial root-zone drying on water use efficiency and growth of maize (Zea mays L.) in gypsiferous soils. International Soil and Water Conservation Research. 11(1), 145–158.
5. Allred KW. 2002. Identification and taxonomy of Tamarix (Tamaricaceae) in New Mexico. Desert Plants.in Tabetn A, Boukhari A (2019)., Estimation of Total Phenolic Content of the Algerian Plant Tamarix gallica, World J Environ Biosci, 2019, 8(1), 25- 29.
6. Ayers RS, Westcot DW. 1985. Water quality for agriculture. Food and Agriculture Organization of the United Nations Rome.
7. Baize D. 2000. Guide des analyses en pédologie. 2éd. INRA, Paris. 257.
8. Baltet C. 1887. Les arbustes de pleine terre, paris g. masson, éditeur libraire de l’acadêmie de médecine i20, boulevard s‘-germnin, en face de l’école de médecine.
9. Baum BR. 1978. The genus Tamarix Israel Academy of Sciences and Humanities. Jerusalem. xii. 209.
10. Belaid N, Neel C, Lenain JF, et al. 2012. Assessment of metal accumulation in calcareous soil and forage crops subjected to long-term irrigation using treated wastewater: Case of El Hajeb-Sfax, Tunisia. Agriculture, Ecosystems & Environment. 158, 83–93.
11. Benguerba A. 2008. Etude phytochimique et de la phase butanolique de l’espèce Inula crithmoides L., Thèse de magister. Université Mentouri Constantine. 101 p.iscosa dela région de Tlemcen. Thèse de Magister. Université Aboubekr Belkaid. 145.
12. Benhammou N. 2006. Etude des activités antimicrobiennes et anti oxydantes des huiles essentielles et des composes phénoliques de Pistacia lentiscus, Pistacia atlantica, et Inula viscosa dela région de Tlemcen [PhD Thesis]. Thèse de Magister. Université Aboubekr Belkaid. 145.
13. Benkhnigue O, Akka FB, Salhi S, et al. 2014. Catalogue des plantes médicinales utilisées dans le traitement du diabète dans la région d’Al HaouzRhamna (Maroc). J Anim Plant Sci. 23(1), 3539–68.
14. Bensegueni Tounsi L. 2001. Etude in vitro de l’effet antibactérien et antifongique de: Inula viscosa-Lawsonia inermis- Asphodelus microcarpus- Aloe vera- Juniperus oxycedrus. Mémoire de Master en Médecine Vétérinaire. Université de Constantine. 110.
15. Bonanno G, Giudice RL. 2010. Heavy metal bioaccumulation by the organs of Phragmites australis (common reed) and their potential use as contamination indicators. Ecological Indicators. 10(3), 639–645.
16. Boujraf A, Dallahi Y, Dahmani J, et al. 2023. Effect of plant communities and ecological parameters on soil organic carbon stocks in the Mamora Forest, Morocco. Journal of Ecological Engineering. 24(5).
17. Bourioug M, Gimbert F, Alaoui-Sehmer L, et al. 2015. Effects of sewage sludge amendment on snail growth and trace metal transfer in the soil-plant-snail food chain. Environ Sci Pollut Res. 22(22), 17925–17936.
18. Brink M, Achigan-Dako EG. 2012. Plant Resources of Tropical Africa 16 Fibres. EconomicBotany. 66(3), 312-313.
19. Chamley H. 1966. Guide des techniques du laboratoire de géologie marine. Faculté des Sciences.
20. Chen P, Liu S, Dai G, et al. 2012. Determination of typhaneoside in rat plasma by liquid chromatography–tandem mass spectrometry. Journal of Pharmaceutical and Biomedical Analysis. 70, 636–639.
21. Corbel S, Bourioug M, Alaoui-Sossé L, et al. 2016. Effects of repeated soil irrigation with liquid biological paper sludge on poplar Populus alba saplings: potential risks and benefits. Environ Sci Pollut Res. 23(21), 21584–21593.
22. Crins WJ. 1989. The Tamaricaceae in the southeastern United States. Journal of the Arnold Arboretum. 70(3), 403–425.
23. Dasylva M, Ndour N, Diédhiou MAA, et al. 2019. Caractérisation physico-chimique des sols des vallées agricoles de la commune de Ziguinchor au Sénégal. European Scientific Journal.
24. Deghdak H, Zaiter R. 2014. Mémoire en Master Thème : Evaluation De L’activité Antioxydante Et Anti Inflammatoire De La Plante Médicinal Algérienne Inula Viscosa .Université constantine1.
25. Djebrouni C, Bouafia W, Benfridja LE. 2020. La phytoremédiation des eaux de surface par les macrophytes aquatiques: cas des métaux lourds [PhD Thesis]. Université de Jijel. Available from http://dspace. univ-jijel.dz:8080/xmlui/handle/123456789/8455.
26. Djoubani K, Hamadouche N, Boudraa O. 2017. Evaluation du pouvoir antimicrobien de plusieurs extraits polyphénolique de deux espèces végétales Chamaeme lumnobil L. et Matricaria chamomilla L. Mémoire master. Université M’hamed Bougara Boumerdès.
27. Doctissimo. 2017 Médecine Douce. Phytothérapie. Plantes Médicinales. https://www.doctissimo.fr/ html/sante/phytotherapie/plante-medicinale/matricairecamomille-allemande.htm.
28. FELLAH O. 2019. Effet des facteurs environnementaux sur la variation de quelques métabolites secondaires dans deux espèces médicinales : Tamarix gallica L. (Tamaricaceae) et Rosmarinus officinalis L. (Lamiaceae). Thèse de doctorat, Université Badji Mokhtar Annaba.
29. Fiche_ZH_BZH_Juncus_acutus.https://www. cbnbrest.fr/files/Fiche_ZH_BZH_Juncus_acutus_20230112.pdf. (Consulte le 09/09/2023)
30. Fuentes D, Valdecantos A, Cortina J, et al. 2007. Seedling performance in sewage sludge-amended degraded mediterranean woodlands. ecological engineering. 31(4), 281–291.
31. García-Delgado M, Rodríguez-Cruz MS, Lorenzo LF, et al. 2007. Seasonal and time variability of heavy metal content and of its chemical forms in sewage sludges from different wastewater treatment plants. Science of the Total environment. 382(1), 82–92.
32. Gavrilescu M. 2021. Water, soil, and plants interactions in a threatened environment. Water. 13(19), 2746.
33. Gèze J-B. 1922. Utilisation des Typha en France. Journal d’agriculture traditionnelle et de botanique appliquée. 2(14), 551–557.
34. Grace JB, Harrison JS. 1986. THE Biology of Canadian Weeds, 73. Typha latifolia L., Typha angustifolia L. and Typha xglauca Godr. Can. J. Plant Sci. 66(2), 361–379. https://doi.org/10.4141/cjps86-051.
35. Guessir H. 1995. Étude de l’impact de l’irrigation par les eaux usées brutes sur la qualité physicochimique du sol et de la nappe phréatique dans la région de Sidi Bennour (Maroc).
36. Hagemeyer J. 1996. Salt in plant Ecophysiology classification of plants halophytes. New York: John Wiley and Sons. 176–181.
37. Haoui IE, Derriche R, Madani L, et al. 2015. Analysis of the chemical composition of essential oil from Algerian Inula viscosa (L.) Aiton. Arabian Journal of chemistry. 8(4), 587–590.
38. Haslam SM. 1972. Phragmites communis Trin. (Arundo phragmites L.,? Phragmites australis (Cav.) Trin. ex Steudel). The journal of ecology.:585–610.
39. Ivens GW. 1979. Weeds OF note-stinking mayweed. New Zealand Journal of Agriculture, 138(3), 21.
40. Jahandiez E, Maire R. 1931. Catalogue Des Plantes Du Maroc:(Spermatophytes et Ptéridophytes). Tome Premier. Ptéridophytes, Gymnospermes et Monocotylédones. Minerva.
41. KalamUrfi M, Mujahid M, Badruddeen, et al. 2016. Tamarix gallica: For traditional uses, phytochemical and pharmacological potentials. 8, 809–814.
42. Kartesz JT, Kartesz R. 1994. A synonymized checklist of the vascular flora of the United States, Canada, and Greenland. 2nd edition. 2 vols. Timber Press, Portland.
43. Laîche des bois (Carex sylvatica). https://www. picturethisai.com/fr/wiki/Carex_sylvatica. html(Consulté le 09/09/2023).
44. Lal RK, Sharma JR, Mishra HO, et al. 1993. Induced f loral mutants and their productivity in German chamomile (MATRICARIA-RECUTITA). Indian Journal Of Agricultural Sciences. 63(1), 27–33.
45. Lim TK. 2012. Matricaria chamomilla. Edible Medicinal And Non-Medicinal Plants. p. 397–431.
46. Maire R. 1952. Flore de l’Afrique du Nord (Maroc, Algérie, Tunisie, Tripolitaine, Cyrénaïque et Sahara).
47. Marschner H. 1995. Mineral nutrition of higher plants.. ed. 2.
48. Martínez Barroso P, Vaverková MD. 2020. Fire effects on soils-A pilot scale study on the soils affected by wildfires in the Czech Republic. Journal of Ecological Engineering. 21(6), 248–256.
49. McGrath SP, Cunliffe CH. 1985. A simplified method for the extraction of the metals Fe, Zn, Cu, Ni, Cd, Pb, Cr, Co and Mn from soils and sewage sludges. J Sci Food Agric. 36(9), 794–798.
50. Meyerson LA, Saltonstall K, Windham L, et al. 2000. A comparison of Phragmites australis in freshwater and brackish marsh environments in North America. Wetlands Ecology and Management. 8(2/3), 89–103.
51. Misra N, Luthra R, Singh KL, et al. 1999. Recent advances in biosynthesis of alkaloids.
52. Mouchane M, Taybi H, Bargach K, et al. 2024. Comparative study of two ferruginous thermal sources, carbogaseous in the Eastern Rif, Morocco. Chemistry Africa.
53. Mourelle ML, Gómez CP, Legido JL. 2023. Hydrobiome of thermal waters: potential use in dermocosmetics. Cosmetics. 10(4), 94.
54. Parolin P, Scotta MI, Bresch C. 2014. Biology of Dittrichia viscosa, a Mediterranean ruderal plant: a review. Phyton Int. J. Exp. Bot. 83, 251–262.
55. Piri E, Mahmoodi Sourestani M, Khaleghi E, et al. 2019. Chemo-diversity and antiradical potential of twelve matricaria chamomilla L. Populations from Iran: Proof of ecological effects. Molecules. 24(7), 1315.
56. Provost M, Bournérias M. 1993. Atlas de répartition des plantes vasculaires de Basse-Normandie. Université de Caen.
57. Qin F, Sun H-X. 2005. Immunosuppressive activity of Pollen Typhae ethanol extract on the immune responses in mice. Journal of ethnopharmacology. 102(3), 424–429.
58. Quezel P, Santa S. 1963. Nouvelle flore de l’Algérie et des régions désertiques méridionales.
59. Rameau J-C, Mansion D, Dumé G. 1993. Flore forestière française(guide écologique illustré. Tome 2, Montagnes).
60. Rattan RK, Datta SP, Chhonkar PK, et al. 2005. Long-term impact of irrigation with sewage eff luents on heavy metal content in soils, crops and groundwater—a case study. Agriculture, ecosystems & environment. 109(3–4), 310–322.
61. Science du sol | Parlons sciences. https://parlonssciences.ca/ressources-pedagogiques/documents-dinformation/science-du-sol. (Consulté le 13 février 2024).
62. Séguret F. 1998. Etude de l’hydrodynamique des procédés de traitement des eaux usées à biomasse fixée-application aux lits bactériens et aux biofiltres [PhD Thesis]. Université Sciences et Technologies-Bordeaux I.
63. Shin S, Aziz D, El-sayed ME, et al. 2022. Systems thinking for planning sustainable desert agriculture systems with saline groundwater irrigation: A review. Water. 14(20), 3343.
64. Singh SP, Verloo MG. 1996. Accumulation and bioavailability of metals in semi-arid soils irrigated with sewage effluents.
65. Soltner D. 2003. Les bases de la production végétale.
66. Tackholm V, Drar M. 1950. Flora of Egypt, vol. 11. Fouad I University Press, Cairo.
67. Tagarelli G, Tagarelli A, Piro A. 2010. Folk medicine used to heal malaria in Calabria (southern Italy). J Ethnobiology Ethnomedicine. 6(1), 27.
68. Taybi H, Bargach K, Boulfia M, et al. 2019. Etude géologique et qualités physico-chimique et bactériologique des eaux thermales de la source “Ain Hamra” de la Province de Taza (Rif Oriental -Maroc). Journal of Water and Environment Technology. 1, 443–451.
69. Tela Tela Botanica. 2023. Base de Données Nomenclaturale de la Flore de France par Benoît Bock, BDNFF v4.02. (telabotanica.org).
70. Tela Botanica. https://www.tela-botanica.org/bdtfxnn-75471 (Consulté le 09/09/2023).
71. Thomas C. 2017. la Laîche des bois, Carex sylvatica subsp. sylvatica Huds., 1762. du ravin obscur des Auripes (Gordes), une nouvelle espèce pour le département du Vauclus.
72. Thornton I. 1996. Risk assessment related to metals: the role of the geochemist. In: Report of the International Workshop on Risk Assessment of Metals and their Inorganic Compounds, Angers, France.
73. Walkley A, Black IA. 1934. An examination of the Degtjareff method for determining soil organic matter, and a proposed modification of the chromic acid titration method. Soil science. 37(1), 29–38.
74. Zadeh JB, Kor NM, Kor ZM. 2014. Chamomile (Matricaria recutita) as a valuable medicinal plant. International journal of Advanced Biological and Biomedical Research. 2(3), 823–829.

Typ dokumentu

Bibliografia

Identyfikatory

DOI

10.12911/22998993/188291

Identyfikator YADDA

bwmeta1.element.baztech-2fdf1506-13cc-4f3e-9d29-50b3055ca2f7