Bibliographies thématiques / Mangrove plants

Littérature scientifique sur le sujet « Mangrove plants »

Auteur : Grafiati
Publié le 4 juin 2021
Mis à jour le 22 février 2023

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Articles de revues sur le sujet "Mangrove plants"

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Myint, Kyi Kyi. « Study on morphological characters of some mangrove plants in South-eastern Ayeyarwady Delta of Myanmar ». Journal of Aquaculture & ; Marine Biology 8, no 4 (2019) : 118–28. http://dx.doi.org/10.15406/jamb.2019.08.00250.

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A study on the mangrvoe plants in Pyapon Township, Ayeyarwady Region, South-eastern Ayeyarwady Delta (between Lat. 94˚30′ and 95˚45′ North and between Long. 15˚30′ and 16˚25′ East), Myanmar was conducted within the period of March 2016 to February 2017. A total of 18 species of mangroves plants were recorded in the natural mangrove areas. In the present study, the taxonomic descriptions of mangrove plants were presented.
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Vinoth, R., S. Kumaravel et R. Ranganathan. « Therapeutic and Traditional Uses of Mangrove Plants ». Journal of Drug Delivery and Therapeutics 9, no 4-s (30 août 2019) : 849–54. http://dx.doi.org/10.22270/jddt.v9i4-s.3457.

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Mangrove plants are specialized timbered plants growing in the swamps of tidal coastal areas and stream deltas of tropical and subtropical parts of the world. They have been utilized for medicinal and traditional purposes by the coastal folks over the years. A large number of mangrove plants grows natural and exploited especially, for use in indigenous pharmaceutical houses. Several mangroves genus produce expensive drugs which have high export potential. The utilization of plants and plant products as medicines could be traced as far back as the commencement of human civilization. Mangrove plants have been used in folklore medicines and extracts from mangrove species have prove inhibitory activity against human, animal and plant pathogens. Traditionally, the mangroves have been exploited for firewood and charcoal. Exploit has been found for mangroves in the manufacture of dwellings, furniture, boats and fishing gear, tannins for dyeing and leather production. The mangroves afford food and wide variety of traditional products and artefacts for the mangrove dwellers. The present review deals with the pharmacological activity, medicinal, traditional and produce bioactive compounds of mangrove medicinal plants. Keywords: Mangroves, Medicinal, Pharmacological, Recourses, Traditional.
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Tai, Akira, Akihiro Hashimoto, Takuya Oba, Kazuki Kawai, Kazuaki Otsuki, Hiromitsu Nagasaka et Tomonori Saita. « Growth of Mangrove Forests and the Influence on Flood Disaster at Amami Oshima Island, Japan ». Journal of Disaster Research 10, no 3 (1 juin 2015) : 486–94. http://dx.doi.org/10.20965/jdr.2015.p0486.

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“Mangrove” is the generic name for plants growing on tropical and subtropical tidal flats. The mangrove is used for many things, including disaster protecting land from high waves and tides and tsunamis, cleaning rivers and drainage containing soil and sand, and providing a variety of organisms with living space. Climate change and rising sea levels are threatening the future of the mangrove. Developing effective ways to conserve mangroves is thus needed, but more must be known about how the mangrove’s ecology and how it develops. It has been pointed out, for example, that mangroves increased flooding by the Sumiyo River in Amami Oshima. We studied ways to develop the mangrove at the Sumiyo River mouth in Amami Oshima and its influence in local flooding, finding that the current mangrove forest had little influence on flooding and that sediment deposition accelerating in Sumiyo Bay due to a sea dike could enlarge the mangrove forest in future.
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Dat, Ton That Huu, et Oanh Phung Thi Thuy. « \(\textit{In vitro}\) antioxidant, α-amylase and α-glucosidase inhibitory activities of endophytic bacteria from the roots of the mangrove plant \(\textit{Rhizophora stylosa}\) Griffith ». Academia Journal of Biology 43, no 3 (24 septembre 2021) : 125–35. http://dx.doi.org/10.15625/2615-9023/16143.

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Mangrove is one of the highly productive ecosystems and contains diverse plants and microbial communities. Bacterial endophytes from mangroves are considered as a prolific source of biological molecules with important functions in the protection of mangrove plants against herbivores, insects as well as pathogens. The present study aimed to isolate endophytic bacteria from the roots of mangrove plant Rhizophora stylosa and to screen antioxidant,
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Azhari, Arif, Muhammad Yogi Saputra, Muhammad Raffi Zakaria, Debora Silalahi, Welldone Sartika, Hamdiyah Fuola Zeri Hasibuan, Rahmat Kurniawan, Sena Maulana, Syaikhul Aziz et Sukrasno Sukrasno. « Potential Antioxidant Constituent from Leaf of Rhizophora apiculata an Typical Mangrove at Lempasing, South Lampung Coast ». Stannum : Jurnal Sains dan Terapan Kimia 4, no 2 (31 octobre 2022) : 60–67. http://dx.doi.org/10.33019/jstk.v4i2.3631.

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The mangrove woodland is a distinct bush or brine habitat characterized by a coastal sedimentation environment in which fine sediment (often rich in organic matter) accumulates in areas protected from high energy waves. Mangrove forests thrive on the coasts of tropical and subtropical regions, including Indonesia. Mangrove forest is a complex ecosystem that has a high diversity of plants, microorganisms, and animals. One of them is the Oil Mangrove (R. apiculata) which grows well on the coast of Lampung. This plant is hard, rich in tannins, and dense, mainly used to make charcoal and firewood. This plant traditionally used to treat diarrhea and nausea. Mangrove plants are tolerant to high salt levels, this special trait is due to the presence of secondary metabolites produced in response to various environmental stresses. Flavonoid compounds, alkaloids, terpenoids and steroids are secondary metabolites produced by mangrove plants. Secondary metabolite compounds from mangroves have bioactivity such as antidiabetic, antimicrobial, antioxidant and anticancer. Exploration of secondary metabolites from mangroves, especially oil mangroves locally named as Bakau Minyak, which are widely grown in the Lempasing area, coastal Lampung for the development of medicinal compounds, has not been intensely reported. This investigation aims to study the potential phytochemicals profile of R. apiculata’s leaf as an antioxidant
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Raju Aluri, Jacob Solomon. « Reproductive Ecology of Mangrove Flora : Conservation and Management ». Transylvanian Review of Systematical and Ecological Research 15, no 2 (1 décembre 2013) : 133–84. http://dx.doi.org/10.2478/trser-2013-0026.

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ABSTRACT Mangroves are dynamic and unique inter-tidal ecosystems, common in tropical and subtropical coastal environments. They are among the world’s most productive ecosystems and are important in protecting coasts from erosion by fierce tides, in promoting the diversity of marine organisms and fisheries by contributing a quantity of food and providing favourable habitats for animals. These economic uses of mangroves indicate that they play an important role in the lives and economies in the coastal regions of different countries. Mangrove forests are under immense threat worldwide due to their multiple economic uses and alterations of freshwater inflows by various upstream activities in catchment areas. Mangrove plants with unique adaptations play a crucial role in sustaining life in mangrove forests. Their reproductive biology is central to understanding the structural and functional components of mangrove forests. The success of sexual reproduction and subsequent population expansion in mangrove plants is linked to flowering timings, pollinators and tidal currents. Viviparous and cryptoviviparous plants are true mangroves while non-viviparous ones are mangrove associates. The dispersal propagule is seedling in viviparous and non-viviparous plants while it is seed in nonviviparous plants. In this study, viviparous and crypto-viviparous species were included for study. These species are self-compatible, self-pollinating and also cross-pollinating; such a breeding system is a requirement for the success of sexual reproduction and subsequent build up and expansion of population. They are entomophilous in the study region. The viviparous plants include Ceriops tagal, C. decandra, Rhizophora apiculata, R. mucronata, Bruguiera gymnorrhiza and B. cylindrica. The non-viviparous plants include Avicennia alba, A. marina, A. officinalis, Aegiceras corniculatum and Aegialitis rotundifolia. Sexual reproduction and regeneration events are annual in these plants and are dependent on local insects, tidal currents and nutrient content in estuarine environment. In recent times, erratic and insufficient rainfall together with industrial pollutants released into rivers is causing negative effects on the growth, development and regeneration of mangrove flora. In effect, there is a gradual decrease in mangrove cover. Added to this is continuous exploitation of mangrove plants for fuel wood, creation of shelters for cattle and changes for industrial establishments and aquaculture development in estuarine regions. As a consequence, the existing mangrove cover is struggling to survive and also not in a position to support local needs and provide livelihood opportunities through fishery resources. Further, reduced mangrove cover is showing catastrophic effects on fishing communities who live along the shore line during the period of cyclonic surges and tsunami events.
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Evans, Clayton W. « THE EFFECTS AND IMPLICATIONS OF OIL POLLUTION IN MANGROVE FORESTS ». International Oil Spill Conference Proceedings 1985, no 1 (1 février 1985) : 367–71. http://dx.doi.org/10.7901/2169-3358-1985-1-367.

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ABSTRACT The mangrove forest is important in shoreline stabilization and as a nursery for many open ocean species. Complex adaptations of the plants for existence in anaerobic conditions and salt water make the mangrove forest highly vulnerable to oil pollution. Clearly, advance protection of mangrove forests is the optimal solution to minimize oil pollution damage. The more difficult question remains: What can be done to minimize the impact of oil that has entered fringe mangrove forests? Active flushing of mangroves and passive oil collection by absorbents are moderately successful in minimizing oil contact with mangroves.
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Syahbana, R., M. Basyuni et L. A. M. Siregar. « Isolation and amplification of mangrove plants using DNA barcode in Percut Sei Tuan, North Sumatra, Indonesia ». IOP Conference Series : Earth and Environmental Science 912, no 1 (1 novembre 2021) : 012028. http://dx.doi.org/10.1088/1755-1315/912/1/012028.

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Abstract Mangroves are a collection of several species of trees or shrubs that distribute around the coastline and can survive in high salinity environments. Around 60% of mangrove forests in North Sumatra are reported to have been damaged, the main factors of this damage being the mangrove forests conversion into ponds and the expansion of oil palm plantations. Identification of mangrove species is very important in protecting and applying the biodiversity of mangrove forests. Identification of living things has evolved from morphological charcetrization to molecular identification. This study aims to explain the DNA isolation and PCR methods to identify mangrove species in North Sumatra. The results suggested that the rbcL primer used can detect mangrove species that were visualized in the form of DNA bands. The length of DNA fragments of mangrove species Acrosticum aureum ranged 632.0-619.6 bp, species Rhizophora apiculata 619.6-585.8 bp, species Nypa fruticans 600- 592.9 bp, species Avicennia alba 549.1-533.5 bp, species Hibiscus tiliaceus was not detected, and mangrove species Acanthus ilicifolius 480.3 bp.
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Sunanda Kodikara, K. A., G. B. M. Ransaraa, S. K. Madarasingheb, N. P. Dissanayakea, N. K. Abeysinghea, K. D. Prasangikac, F. Dahdouh-Guebas et L. P. Jayatissa. « A GROWING THREAT TO TIDAL FORESTS : INCURSION OF MANGROVE ECOSYSTEMS BY INVASIVE ALIEN SPECIES <i>ACACIA AURICULIFORMIS </i>A. CUNN. EX BENTH. (FABACEAE) ». Russian Journal of Biological Invasions 15, no 4 (30 novembre 2022) : 102–5. http://dx.doi.org/10.35885/1996-1499-15-4-102-105.

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Mangrove forests are reported to be invaded by invasive alien species (IAS). This study was therefore aimed at studying the level of distribution of the IAS, Acacia auriculiformis A. Cunn. ex Benth. in mangrove ecosystems in the southern coast of Sri Lanka and assessing the risk to periphery of mangrove forest by considering the Rekawa mangrove forest as a model site. Growth performances of two mangrove species; Rhizophora mucronata and Avicennia marina in the presence of Acacia plants were also tested under three different competition levels; low, moderate and high. According to the results, infestation of Acacia plants was significant in the southern coast of Sri Lanka, particularly in Matara and Hambantota districts (p<0.05). Species diversity determined as the Simpson diversity index was high (0.77) in the periphery of the Rekawa mangrove forest. Four true mangroves and two associates co-occurring with A. auriculiformis in the periphery could be observed during the field validation experiment. The highest seedling (15.4±2.2 m) and sapling (11.2±2.8 m) densities were reported for A. auriculiformis plants. Dominance, calculated as the importance value index of different species in the mangrove periphery varied from 18.0-120.6 and the latter highest was recorded for Acacia which has the highest relative density (42.1%) and the relative dominance (52.5%). The total leaf area of the Rhizophora plants grown in the high-competition level was significantly lower than that of the control plants while the dry weights at three different competition levels; were significantly higher (p<0.05) than the control. This could be due to the higher root biomass allocation. In Avicennia plants, cumulative shoot height, total leaf area and dry weight of the plants grown at the high-competition level were significantly lower than that of the control plants (p<0.05). A. auriculiformis plants grown with these true mangrove species better performed and did not show any significant deviation from the respective control plants. The level of survival of Acacia was significantly reduced at 25 psu (p<0.05). Early intervention and serious scrutiny are much needed to reverse the possible impacts of IAS on mangrove forests and the need for forest conservation is emphasized.
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Mardiyanto Rahayu, Slamet, et Sunarto. « Mangrove Plants Use As Medicine In Gedangan Village, Purwodadi District, Purworejo Regency, Central Java Province ». Jurnal Jamu Indonesia 5, no 2 (30 juin 2020) : 76–84. http://dx.doi.org/10.29244/jji.v5i2.116.

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Coastal ecosystems have high plant levels, for example mangroves and seagrasses. Mangrove forest is a type of forest located in tidal areas, especially on protected beaches, lagoons, river estuaries that are inundated and free from inundation at low tide, whose plant communities tolerate salt. Gedangan Village is one of the villages in Purwodadi District, which has mangrove areas in Purworejo Regency. This study aims to determine the types of mangrove plants that are useful the Gedangan Village, Purwodadi District, Purworejo Regency, Central Java as medicinal products. The study was conducted using roaming method in the form of observations or field observations in the mangrove area of Gedangan Village, Purwodadi District, Purworejo Regency, Central Java. Based on the research, there were eight (8) types of mangrove plants that were found as medicinal plants in Gedangan Village, namely Rhizophora mucronata, Sonneratia alba, Calotropis gigantea, Nypa fruticans, Acanthus ilicifolius, Hibiscus tiliaceus, Ipomoea pescaprae, and Wedelia biflora. Traditionally, these mangrove species can be used as a medicine items for beri-beri, hepatitis, ulcers, wounds, diarrhea, fever, antibacterial, anti-inflammatory, dizziness, asthma, bronchitis, dyspepsia, leprosy, tumors, diabetes, stomach ache, toothache, thrush, tuberculosis, muscle aches, and eczema.
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Thèses sur le sujet "Mangrove plants"

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Maxwell, Gordon Selwyn. « Ecogeographic studies of Avicennia marina (Forsk.) Vierh. and Kandelia candel (L.) Druce in Brunei, Hong Kong and Thailand / ». [Hong Kong : University of Hong Kong], 1993. http://sunzi.lib.hku.hk/hkuto/record.jsp?B13641256.

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Maxwell, Gordon Selwyn. « Ecogeographic studies of Avicennia marina (Forsk.) Vierh. and Kandeliacandel (L.) Druce in Brunei, Hong Kong and Thailand ». Thesis, The University of Hong Kong (Pokfulam, Hong Kong), 1993. http://hub.hku.hk/bib/B31233831.

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Tong, Yee-fun Pauline. « Herbivory on the mangrove Kandelia candel (L.) druce in Hong Kong / ». Hong Kong : University of Hong Kong, 1998. http://sunzi.lib.hku.hk/hkuto/record.jsp?B20668211.

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Soliman, Nabil Zaki Gadalla. « Nutrient dynamics at Matapouri Estuary, Northern New Zealand thesis submitted in (partial) fulfilment of the degree of Master of Applied Science, Auckland University of Technology, June 2004 ». Full thesis. Abstract, 2004.

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Hoppe-Speer, Sabine Clara Lisa. « The response of the red mangrove rhizophora mucronata lam, to changes in salinity, inundation and light : predictions for future climate change ». Thesis, Nelson Mandela Metropolitan University, 2009. http://hdl.handle.net/10948/1249.

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Mangrove forests are subjected to many environmental factors which influence species distribution, zonation patterns as well as succession. Important driving factors in these forests are salinity, water level fluctuations and available light. This study investigated the response of red mangrove (Rhizophora mucronata Lam.) seedlings to these factors in controlled laboratory experiments. Increase in salinity and prolonged inundation within estuaries are predicted impacts resulting from sea level rise due to climate change. The study investigated the effect of five salinity treatments (0, 8, 18, 35 and 45 ppt) with a semi-diurnal tidal cycle on seedling growth. In a separate experiment the effect of different inundation treatments: no inundation, 3, 6, 9 hour tidal cycles and continuous inundation (24 h) were investigated. Both morphological and physiological responses of R. mucronata seedlings were measured. There was a decrease in growth (plant height, biomass and leaf production) with increasing salinity. Seedlings in the seawater, hypersaline and no inundation treatments showed symptoms of stress, having increased leaf necrosis ("burn marks"). The highest growth occurred in the low salinity (8 ppt) treatment, but the highest photosynthetic performance and stomatal conductance occurred in the freshwater treatment (0 ppt). The typical response of stem elongation with increasing inundation was observed in the 24 hr inundation treatment. In the light and salinity combination study there were ten different treatments of five different light treatments (unshaded, 20 percent, 50 percent, 80 percent and 90 percent shade) combined with two salinity concentrations (18 and 35 ppt). In this study the seedling growth: plant height, biomass, leaf surface area and leaf production were higher in the moderate salinity (18 ppt) treatments compared to the seawater (35 ppt) treatments. Biomass in the 35 ppt experiment decreased with increasing shade as well as in the unshaded treatments. Photosynthetic performance and stomatal conductance were lower for the unshaded treatment in both 18 and 35 ppt salinity compared to all other treatments with the same salinity. This suggests that R. mucronata more shade than sun tolerant, but overall it can be concluded that the species has a broad tolerance range. The results may be relevant in mangrove rehabilitation and predicting responses to climate change. This is important as mangrove ecosystems may adapt to changing sea levels and in order to restore areas it will be necessary to choose the mangrove species which will grow best. The results may also help to increase the protection of existing mangrove habitats.
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Ge, Xuejun. « Reproductive biology and conservation genetics of mangroves in South China and Hong Kong / ». Hong Kong : University of Hong Kong, 2001. http://sunzi.lib.hku.hk:8888/cgi-bin/hkuto%5Ftoc%5Fpdf?B22718734.

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Lee, Hoi-ki. « The feeding ecology of Littoraria species in Hong Kong mangroves / ». Hong Kong : University of Hong Kong, 2001. http://sunzi.lib.hku.hk:8888/cgi-bin/hkuto%5Ftoc%5Fpdf?B22956293.

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Pribadi, Rudhi. « The ecology of mangrove vegetation in Bintuni Bay, Irian Jaya, Indonesia ». Thesis, University of Stirling, 1998. http://hdl.handle.net/1893/3525.

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The ecology of mangrove forests on Potential Acid Sulphate soils at Bintuni Bay (132° 55' - 134° 02' E, and 2° 02' - 2° 97' S), Irian Jaya, Indonesia was studied. The annual rainfall is 3000mm and there is mixed semi-diurnal tide of 1-5.6m amplitude. The water has a varying salinity of 0-27%. Forest structure was studied in plots of 10m x 10m along three transects across Sikoroti Island and in three 50m x 50m plots in mixed Rhizophora - Bruguiera forest. All trees > 10cm trunk diameter were enumerated, measured and identified. Of the nine tree species, Rhizophora apiculata was the most dominant, followed by Bruguiera gymnorrhiza and Ceriops decandra. There was good regeneration seven years after clear-felling in plots on Amutu Besar and Amutu Kecil Islands. Small litterfall production, measured using ten 1m x 1m litter traps in each of the three 50m x 50m plots, was 11.09 t ha-1 y-1, and greatest during the wet season (December, 1.29 t ha-1 ) and least during the dry season (July, 0.61 t ha-1). The annual litterfall mineral element accession was (kg ha-1 y-1): N 240.4, P 6.1, K 43.2, Na 136.2, Ca 204.4 and Mg 48.7. Leaf decomposition of five species was studied in litterbags on the forest floor under trees of the same species. Sonneratia alba decomposed quickly with a half-life of 24 days, and Bruguiera parviflora was the slowest with a halflife of 124 days. Decomposition rates of all species followed a single exponential decay model. Leaf herbivory of young stands of Rhizophora apiculata and Bruguiera gymnorrhiza was significantly different among sites, species, plant height and leaf-age. Seed predation on six species was studied in three different sites. Twenty propagules of each species were secured by string in each of six 10m x 10m sub-plots within each of five 10m x 60m plots. On average 62.1% of the seeds were dead after 36 d. Predation was higher in the lower intertidal zone, and Avicennia alba and Bruguiera parviflora were the most predated. The results suggested that the Bintuni Bay mangroves can be sustainably managed but the best silvicultural system needs to be determined.
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Ashton, Elizabeth C. « Biodiversity and community ecology of mangrove plants : molluscs and crustaceans in two mangrove forests in Peninsular Malaysia in relation to local management practices ». Thesis, University of York, 1999. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.301686.

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羅毓瑩 et Yuk-ying Eugenia Lo. « Phylogenetic relationships and natural hybridization in the mangrove genus rhizophora from the Indo-West Pacific Region ». Thesis, The University of Hong Kong (Pokfulam, Hong Kong), 2003. http://hub.hku.hk/bib/B31227661.

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Livres sur le sujet "Mangrove plants"

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Johnstone, R. E. Mangroves and mangrove birds of Western Australia. Perth, W.A : Western Australian Museum, 1990.

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Thanikaimoni, G. Mangrove palynology. Pondicherry : UNDP/UNESCO Regional Project on Training and Research on Mangrove Ecosystems, RAS/79/002, 1987.

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Sujanapal, P. Handbook on mangroves and mangrove associates of Kerala. Thiruvananthapuram : Kerala State Biodiversity Board, 2014.

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Fitrianto, Anggoro Cahyo. Ekosistem mangrove Kepulauan Togean : Togean Island mangrove ecosystem. [Cibinong] : Pusat Survei Sumberdaya Alam Laut, Bakosurtanal, 2009.

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Zamora, P. M. Diversity of flora in the Philippine mangrove ecosystems. Diliman, Quezon City : University of the Philippines, Center for Integrative and Development Studies in cooperation with Haribon Foundation, 1995.

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Shunula, Jude P. The mangroves of Zanzibar. Zanzibar : University of Dar es Salaam, Institute of Marine Science, 1996.

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Zayyānī, ʻĀdil Khalīfah. Ashjār al-qarm fī Dawlat al-Baḥrayn. [Manama] : al-Lajnah al-Waṭanīyah li-Ḥimāyat al-Ḥayāh al-Fiṭrīyah, 1999.

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Tomlinson, P. B. The botany of mangroves. Cambridge [Cambridgeshire] : Cambridge University Press, 1994.

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Banerjee, L. K. Mangroves of Orissa coast and their ecology. Dehra Dun, India : Bishen Singh Mahendra Pal Singh, 1990.

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Naskar, Kumudranjan. Manual of Indian mangroves. Delhi : Daya Pub. House, 2004.

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Chapitres de livres sur le sujet "Mangrove plants"

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Miles, D. Howard, Armando A. de la Cruz, Ana M. Ly, Dong-Seok Lho, Edgardo Gomez, James A. Weeks et Jerry Atwood. « Toxicants from Mangrove Plants ». Dans ACS Symposium Series, 491–501. Washington, DC : American Chemical Society, 1987. http://dx.doi.org/10.1021/bk-1987-0330.ch044.

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Abdel-Aziz, Shadia M., Foukia E. Mouafi, Yomna A. Moustafa et Nayera A. M. Abdelwahed. « Medicinal Importance of Mangrove Plants ». Dans Microbes in Food and Health, 77–96. Cham : Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-25277-3_5.

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Ambikapathy, V., S. Babu, A. Anbukumaran, A. S. Shijila Rani et P. Prakash. « Isolation of Actinobacteria from Mangrove Plants ». Dans Methods in Actinobacteriology, 75–81. New York, NY : Springer US, 2022. http://dx.doi.org/10.1007/978-1-0716-1728-1_13.

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Mitra, Subrata, Abhra Chanda, Sourav Das, Tuhin Ghosh et Sugata Hazra. « Salinity Dynamics in the Hooghly-Matla Estuarine System and Its Impact on the Mangrove Plants of Indian Sundarbans ». Dans Sundarbans Mangrove Systems, 305–28. Boca Raton : CRC Press, 2021. http://dx.doi.org/10.1201/9781003083573-15.

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Md Isa, Nurun Nadhirah, et Mohd Nazip Suratman. « Structure and Diversity of Plants in Mangrove Ecosystems ». Dans Mangroves : Ecology, Biodiversity and Management, 361–69. Singapore : Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-16-2494-0_15.

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Banerjee, L. K. « Influence of salinity on mangrove zonation ». Dans Towards the rational use of high salinity tolerant plants, 181–86. Dordrecht : Springer Netherlands, 1993. http://dx.doi.org/10.1007/978-94-011-1858-3_19.

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Kerry, Rout George, Pratima Pradhan, Gitishree Das, Sushanto Gouda, Mallappa Kumara Swamy et Jayanta Kumar Patra. « Anticancer Potential of Mangrove Plants : Neglected Plant Species of the Marine Ecosystem ». Dans Anticancer plants : Properties and Application, 303–25. Singapore : Springer Singapore, 2018. http://dx.doi.org/10.1007/978-981-10-8548-2_13.

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Wong, Y. S., C. Y. Lan, G. Z. Chen, S. H. Li, X. R. Chen, Z. P. Liu et N. F. Y. Tam. « Effect of wastewater discharge on nutrient contamination of mangrove soils and plants ». Dans Asia-Pacific Symposium on Mangrove Ecosystems, 243–54. Dordrecht : Springer Netherlands, 1995. http://dx.doi.org/10.1007/978-94-011-0289-6_28.

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Nazrul-Islam, A. K. M. « Environment and vegetation of Sundarban mangrove forest ». Dans Towards the rational use of high salinity tolerant plants, 81–88. Dordrecht : Springer Netherlands, 1993. http://dx.doi.org/10.1007/978-94-011-1858-3_7.

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Sarkar, Santosh Kumar. « Phytoremediation of Trace Metals by Mangrove Plants of Sundarban Wetland ». Dans Trace Metals in a Tropical Mangrove Wetland, 209–47. Singapore : Springer Singapore, 2017. http://dx.doi.org/10.1007/978-981-10-2793-2_9.

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Actes de conférences sur le sujet "Mangrove plants"

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Isaifan, Dina Jamal, et Yousra Suleiman. « Quantifying Biomass of Microphytobenthos in sediments of Mangroves in the east coast of Qatar ». Dans Qatar University Annual Research Forum & Exhibition. Qatar University Press, 2021. http://dx.doi.org/10.29117/quarfe.2021.0061.

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Mangroves, Avicennia marina, are highly productive coastal ecosystems with capacity to store carbon within plants and in sediments. Micropytobenthos (MPB) in the sediments also fix carbon and play a significant role in carbon burial. However, there is paucity of information on the role of MPB in coastal carbon budget. We quantified the biomass of MPB as an important carbon pool in the mangrove of Al Thakhira, located at the east coast of Qatar. Sediments at different tidal levels namely, supratidal, intertidal, and subtidal were collected and analyzed for grain size, chlorophyll (a), total carbon, and inorganic carbon contents. Results indicated that sand was the dominant species (60%), followed by silt (39%) and clay (1%) at all tidal levels. While the supratidal level had significantly higher silty sand content, silt dominated the intertidal levels. Moreover, chlorophyll (a) was significantly influenced by tidal levels with highest levels in the subtidal level sediments, where mangroves grow extensively. Results also demonstrated that as we move towards the intertidal zone, the total carbon content in sediments gets higher. Finally, chlorophyll (a) and TOC% were positively associated (r=0.643) in all tidal zones. As we move towards the mangrove subtidal growth area, the total carbon content in sediments gets higher. This work recommends that mangrove forests in Qatar be protected by special sanctuaries and law-enforcement to maintain this natural and dynamic blue carbon ecosystem.
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Basyuni, Mohammad, Ridha Wati, Astrid Nur Prabuanisa, I. Komang Tri Wijaya Kusuma, Hamiudin, Guntur et Hiroshi Sagami. « Changes to the polyisoprenoid composition in aging leaves of mangrove plants ». Dans THE 8TH ANNUAL BASIC SCIENCE INTERNATIONAL CONFERENCE : Coverage of Basic Sciences toward the World’s Sustainability Challanges. Author(s), 2018. http://dx.doi.org/10.1063/1.5062731.

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Budianto, Budianto, Edi Azwar, Pandu Prabowo et Abdurrozzaq Hasibuan. « Analysis Diversity of Mangrove Plants and Brachyura (Uca Crab) at Yagasu Belawan Forest ». Dans Proceedings of The 2nd International Conference On Advance And Scientific Innovation, ICASI 2019, 18 July, Banda Aceh, Indonesia. EAI, 2019. http://dx.doi.org/10.4108/eai.18-7-2019.2288584.

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Ceccopieri, M., R. Carreira, A. Scofield, L. Almeida, C. Hamacher, C. Farias, M. Soares et A. Wagener. « CARBON ISOTOPIC COMPOSITION OF LEAF WAX n-ALKANES OF MANGROVE PLANTS DISTRIBUTED ALONG A LATITUDINAL GRADIENT IN BRAZIL ». Dans 30th International Meeting on Organic Geochemistry (IMOG 2021). European Association of Geoscientists & Engineers, 2021. http://dx.doi.org/10.3997/2214-4609.202134252.

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Soraya, R. K., N. D. Takarina et T. Soedjiarti. « Metals accumulation (Cu, Zn and Pb) in mangrove-associated plants from Blanakan Brackish Water Pond, Subang District, West Java ». Dans PROCEEDINGS OF THE 4TH INTERNATIONAL SYMPOSIUM ON CURRENT PROGRESS IN MATHEMATICS AND SCIENCES (ISCPMS2018). AIP Publishing, 2019. http://dx.doi.org/10.1063/1.5132513.

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Rossiana, Nia, Mia Miranti et Ratih Rahmawati. « Antibacterial activities of endophytic fungi from mangrove plants Rhizophora apiculata L. and Bruguiera gymnorrhiza (L.) Lamk. on Salmonella typhi ». Dans TOWARDS THE SUSTAINABLE USE OF BIODIVERSITY IN A CHANGING ENVIRONMENT : FROM BASIC TO APPLIED RESEARCH : Proceeding of the 4th International Conference on Biological Science. Author(s), 2016. http://dx.doi.org/10.1063/1.4953514.

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Dyana Sartika, R., Annisa Rahma, Salsabillah Amelano et Dian Handayani. « Antibacterial Activity of Ethyl Acetate Extracts from Mangrove Plants Rhizophora apiculata and Sonneratia alba — Associated Fungi ». Dans 2nd International Conference on Contemporary Science and Clinical Pharmacy 2021 (ICCSCP 2021). Paris, France : Atlantis Press, 2021. http://dx.doi.org/10.2991/ahsr.k.211105.049.

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Susylowati, D., et N. D. Takarina. « Phytochemistry screening and total flavonoid test on plants associated mangrove (Pluchea indica and Sesuvium portuculastrum Leafs) at Blanakan, Subang, West Java ». Dans PROCEEDINGS OF THE 4TH INTERNATIONAL SYMPOSIUM ON CURRENT PROGRESS IN MATHEMATICS AND SCIENCES (ISCPMS2018). AIP Publishing, 2019. http://dx.doi.org/10.1063/1.5132511.

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Haryani, Y., R. Hilma, N. Delfira, T. Martalinda, F. Puspita, A. Friska, D. Juwita et F. Ardi. « Anti-vibriosis activity of endophytic fungi associated with Ceriops tagal (Perr.) C.B.Rob and Bruguiera sp., mangrove plants from Riau Province, Indonesia ». Dans THE 8TH INTERNATIONAL CONFERENCE OF THE INDONESIAN CHEMICAL SOCIETY (ICICS) 2019. AIP Publishing, 2020. http://dx.doi.org/10.1063/5.0001446.

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« Photosynthetic Rates in Mangroves ». Dans International Conference on Plant, Marine and Environmental Sciences. International Institute of Chemical, Biological & Environmental Engineering, 2015. http://dx.doi.org/10.15242/iicbe.c0115015.

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Rapports d'organisations sur le sujet "Mangrove plants"

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Merk, Christine. Summary report on Workshop 1 laypersons’ perceptions of marine CDR, Deliverable 3.1. OceanNETs, mars 2021. http://dx.doi.org/10.3289/oceannets_d3.1.

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This deliverable reports about the successful completion of three group discussions on marine carbon dioxide removal (CDR) with laypersons in Germany. The 2-hour group discussions were held online. 5 participants discussed these three topics: (1) the environmental state of the oceans, (2) four selected marine CDR approaches, and (3) responsible research and innovation. The four approaches were ocean fertilization, ocean alkalinization via ocean liming and electrochemical weathering in desalination plants, artificial upwelling, and blue carbon management via kelp forests, mangroves and seagrass meadows.
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Veland, Siri. Summary report on Workshop 2 laypersons’ perceptions of marine CDR, Deliverable 3.2. OceanNETs, avril 2021. http://dx.doi.org/10.3289/oceannets_d3.2.

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This deliverable reports about the successful completion of three group discussions on marine carbon dioxide removal (CDR) with laypersons in Norway. The 2-hour group discussions were held online. In three groups, and a pilot group, between 2 and 7 participants discussed these three topics: (1) the environmental state of the oceans, (2) four selected marine CDR approaches, and (3) responsible research and innovation. The four approaches were ocean fertilization, ocean alkalinization via ocean liming and electrochemical weathering in desalination plants, artificial upwelling, and blue carbon management via kelp forests, mangroves and seagrass meadows.
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Ruiz, Pablo, Craig Perry, Alejando Garcia, Magali Guichardot, Michael Foguer, Joseph Ingram, Michelle Prats, Carlos Pulido, Robert Shamblin et Kevin Whelan. The Everglades National Park and Big Cypress National Preserve vegetation mapping project : Interim report—Northwest Coastal Everglades (Region 4), Everglades National Park (revised with costs). National Park Service, novembre 2020. http://dx.doi.org/10.36967/nrr-2279586.

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The Everglades National Park and Big Cypress National Preserve vegetation mapping project is part of the Comprehensive Everglades Restoration Plan (CERP). It is a cooperative effort between the South Florida Water Management District (SFWMD), the United States Army Corps of Engineers (USACE), and the National Park Service’s (NPS) Vegetation Mapping Inventory Program (VMI). The goal of this project is to produce a spatially and thematically accurate vegetation map of Everglades National Park and Big Cypress National Preserve prior to the completion of restoration efforts associated with CERP. This spatial product will serve as a record of baseline vegetation conditions for the purpose of: (1) documenting changes to the spatial extent, pattern, and proportion of plant communities within these two federally-managed units as they respond to hydrologic modifications resulting from the implementation of the CERP; and (2) providing vegetation and land-cover information to NPS park managers and scientists for use in park management, resource management, research, and monitoring. This mapping project covers an area of approximately 7,400 square kilometers (1.84 million acres [ac]) and consists of seven mapping regions: four regions in Everglades National Park, Regions 1–4, and three in Big Cypress National Preserve, Regions 5–7. The report focuses on the mapping effort associated with the Northwest Coastal Everglades (NWCE), Region 4 , in Everglades National Park. The NWCE encompasses a total area of 1,278 square kilometers (493.7 square miles [sq mi], or 315,955 ac) and is geographically located to the south of Big Cypress National Preserve, west of Shark River Slough (Region 1), and north of the Southwest Coastal Everglades (Region 3). Photo-interpretation was performed by superimposing a 50 × 50-meter (164 × 164-feet [ft] or 0.25 hectare [0.61 ac]) grid cell vector matrix over stereoscopic, 30 centimeters (11.8 inches) spatial resolution, color-infrared aerial imagery on a digital photogrammetric workstation. Photo-interpreters identified the dominant community in each cell by applying majority-rule algorithms, recognizing community-specific spectral signatures, and referencing an extensive ground-truth database. The dominant vegetation community within each grid cell was classified using a hierarchical classification system developed specifically for this project. Additionally, photo-interpreters categorized the absolute cover of cattail (Typha sp.) and any invasive species detected as either: Sparse (10–49%), Dominant (50–89%), or Monotypic (90–100%). A total of 178 thematic classes were used to map the NWCE. The most common vegetation classes are Mixed Mangrove Forest-Mixed and Transitional Bayhead Shrubland. These two communities accounted for about 10%, each, of the mapping area. Other notable classes include Short Sawgrass Marsh-Dense (8.1% of the map area), Mixed Graminoid Freshwater Marsh (4.7% of the map area), and Black Mangrove Forest (4.5% of the map area). The NWCE vegetation map has a thematic class accuracy of 88.4% with a lower 90th Percentile Confidence Interval of 84.5%.
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