Phytoremediation Potential ofPhragmites australisin Hokersar Wetland - A Ramsar Site of Kashmir Himalaya

Ahmad, Sajjad; Reshi, Zafar A.; Shah, Manzoor Ahmad; Rashid, Irfan; Ara, Roshan; Andrabi, Syed Mubashir

doi:10.1080/15226514.2013.821449

Cited by 48 publications

(28 citation statements)

References 21 publications

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“…These kinds of plants are simply referred to as hyperaccumulators, because they accumulate appreciable quantities of metal in parts of their tissues regardless of the concentration of metal in the soil, water or other surrounding contaminated media (Prasad and Freitas, 2003). Each mean value is the overall mean of ten experimental replications per tree Means with the different superscripts in the same column are significantly different (p < 0.05) Furthermore, similar observations from studies on some mangrove species where root had more heavy metals bio-concentration in comparison to the stem and other above-ground parts have also been made for Avicennia alba (Thomas and Ferdinandez, 1997), Rhizophora mucronata (Pahalawattaarachchi et al, 2009), Avicennia marina (Nirmal Kumar et al, 2011), Bruguiera sexangula and Ceriops decandra (Gupta and Chakrabarti, 2013), Avicennia marina (Almahasheer et al, 2014), Phragmites australis in a wetland vegetation (Ahmad et al, 2014) and recently also in Rhizophora racemosa (Erakhrumen, 2014). This comparatively higher bio-concentration level of heavy metals in the root might be as a result of low mobility and bioavailability of some heavy metals to natural phytoextraction process (Komárek et al, 2007) along the stem towards the crown.…”

Section: Resultssupporting

confidence: 59%

Assessment of In-Situ Natural Dendroremediation Capability of Rhizophora racemosa in a Heavy Metal Polluted Mangrove Forest, Rivers State, Nigeria

Erakhrumen¹

2015

Journal of Applied Sciences and Environmental Management

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Environmental pollution is assuming frightening dimensions in many parts of the world. This is not excluding Niger-Delta region of Nigeria where most of the country's oil and gas are sourced with attendant production of noxious substances as byproducts/residues/waste. Many of these noxious substances have been noted to be removable from polluted environment through proper application of phytoremediation techniques, particularly using native plant species. Consequently, this research was conceived to evaluate potentials for phytomediation by native red mangrove tree (Rhizophora racemosa G.F.W. Meyer). This was carried out by evaluating the presence of heavy metals ions and their bioconcentration levels in the samples of root and wood tissues axially along the stem of this tree. The sorrounding soil and water were also sampled and evaluated for presence and concentration of these metal ions in comparison with those for the sampled plant tissues. All the samples were sourced from a mangrove forest in Okrika, Rivers State, Nigeria. The samples from the root, butt, 50% and 90% bole length were oven-dried at 60±5 o C to constant weight, pulverised and heated with trioxonitrate (v) acid to achieve total dissolution before subjecting them to atomic absorption spectroscopy (AAS). Similarly, samples from sorrouding soil were dried at 35±2 o C to constant weight, crushed and sieved using a ≤ 2mm mesh before performing metal extraction and detection using AAS while water samples were also subjected to AAS for heavy metal analyses, in line with appropriate standard methods. The data obtained were statistically analysed using basic descriptive tools, Analyses of Variance and Fishers' Least Significant Difference (P < 0.05). Outcomes of these statistical analyses showed that, in terms of bio-concentration values, the evaluated metal ions that include Fe, Cu, Mn, Cd, Pb, Ni and Cr were more in the root than the surrounding soil and water. The bio-concentration trends, for the metal ions, also progressively declined from the root towards the crown of the trees. The bio-concentration distribution in all the tree sections showed an inconsistent pattern with Fe ions having higher bio-concentration. In addition, Cr, Ni, Pd and Cu also inconsistently followed Fe in terms of bio-concentration level. © JASEM http://dx

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Section: Resultssupporting

confidence: 59%

Assessment of In-Situ Natural Dendroremediation Capability of Rhizophora racemosa in a Heavy Metal Polluted Mangrove Forest, Rivers State, Nigeria

Erakhrumen¹

2015

Journal of Applied Sciences and Environmental Management

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“…Cr was more in root portion than shoot in spite of the concentration being very low in water. It can be conceded that roots of all the three species do show high retention of heavy metals as well as trace elements in their root structure thus they can prevent bioaccumulation in higher trophic level (Ahmad et al 2014).…”

Section: Accumulation Of Heavy Metals By Three Aquatic Plant Speciesmentioning

confidence: 99%

Phytoremedial Potential ofTypha latifolia,Eichornia crassipesandMonochoria hastatafound in Contaminated Water Bodies Across Ranchi City (India)

Hazra

Avishek

Pathak

2015

International Journal of Phytoremediation

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Phytoremediation is an emerging technology that uses green plants (living machines) for removal of contaminants of concern (COC). These plant species have the potential to remove the COC, thereby restoring the original condition of soil or water environment. The present study focuses on assessing the heavy metals (COC) present in the contaminated water bodies of Ranchi city, Jharkhand, India. Phytoremedial potential of three plant species: Typha latifolia, Eichornia crassipes and Monochoria hastata were assessed in the present study. Heterogenous accumulation of metals was found in the three plant species. It was observed that the ratio of heavy metal concentration was different in different parts, i.e., shoots and roots. Positive results were also obtained for translocation factor of all species with minimum of 0.10 and maximum of 1. It was found experimentally that M. hastata has the maximum BFC for root as 4.32 and shoot as 2.70 (for Manganese). For T. latifolia, BCF of maximum was observed for root (163.5) and respective shoot 86.46 (for Iron), followed by 7.3 and 5.8 for root and shoot (for Manganese) respectively. E. crassipes was found to possess a maximum BCF of 278.6 (for Manganese and 151 (for Iron) and shoot as 142 (for Manganese) and 36.13 (for Iron).

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“…large trees for carbon storage, or pollution-tolerant reeds for water quality regulation) can be more productive or provide a better service (e.g. Ahmad et al, 2014;Cavanaugh et al, 2014). In contrast, diversity is rarely mentioned for air quality regulation, and water flow regulation is the only service for which no biological diversity attributes are studied in the literature reviewed.…”

Section: Links Between Natural Capital Attributes and Ecosystem Servicesmentioning

confidence: 99%

How natural capital delivers ecosystem services: A typology derived from a systematic review

et al. 2017

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Phytoremediation Potential ofPhragmites australisin Hokersar Wetland - A Ramsar Site of Kashmir Himalaya

Cited by 48 publications

References 21 publications

Assessment of <i>In-Situ</i> Natural Dendroremediation Capability of <i>Rhizophora racemosa</i> in a Heavy Metal Polluted Mangrove Forest, Rivers State, Nigeria

Assessment of <i>In-Situ</i> Natural Dendroremediation Capability of <i>Rhizophora racemosa</i> in a Heavy Metal Polluted Mangrove Forest, Rivers State, Nigeria

Phytoremedial Potential ofTypha latifolia,Eichornia crassipesandMonochoria hastatafound in Contaminated Water Bodies Across Ranchi City (India)

How natural capital delivers ecosystem services: A typology derived from a systematic review

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