Your search keyword '"Rozaimi, Mohammad"' showing total 12 results

1. Preface: Blue carbon studies in Asia‐Pacific regions: Current status, gaps, and future perspectives.

Author

Sharma, Sahadev, Suwa, Rempei, Ray, Raghab, Rozaimi, Mohammad, MacKenzie, Richard A., and Nakaoka, Masahiro

Subjects

MANGROVE plants, SEAGRASSES, CLIMATE change mitigation, CARBON, SALT marshes

Abstract

The Asia‐Pacific blue carbon ecosystems named mangroves, seagrass meadows and salt marsh plays an important role in climate change mitigation and adaptation. However, still data gaps exist in this region to understand the blue carbon dynamic process and how future climate change will impact it. The special feature aims to fill the gaps and contributing to our knowledge from the Asia‐Pacific region and to stimulate and promote future research in blue carbon research. [ABSTRACT FROM AUTHOR]

Published

2022

2. Macroalgal and mangrove provenances demonstrate their relevance in contributing to the blue carbon pool of a tropical seagrass meadow.

Author

Hidayah, Nur, Ng, Chiew Tsann, Arina, Natasha, Fairoz, Mohammad, and Rozaimi, Mohammad

Subjects

SEAGRASSES, MARINE algae, CLIMATE change mitigation, MANGROVE plants, CARBON

Abstract

Mangroves, seagrasses and macroalgae form inter‐connected coastal habitats. They are involved in the direct and indirect sequestration and accumulation of blue carbon and are recognized for their role in climate change mitigation. Macroalgae, though residing within or in close proximity to these ecosystems are, however, not perceived as contributing to blue carbon storage. Such habitat connectivity among the mangrove, seagrass, and macroalgal compartments complicates a straightforward assessment of blue carbon storage. In this study, we assessed the contributions of these macrophytes as endmembers to the bulk organic carbon (OC) stocks in surficial (top 30 cm) and deep (31–100 cm) sediment layers of seagrass beds within the Sungai Pulai estuary (Malaysia). Organic carbon stocks in the seagrass sediments ranged from 14.3 to 21.4 Mg OC ha−1 (surficial depths), and 137.9 ± 23.3 (mean ± SE) Mg OC ha−1 for the deep layer. Mangrove‐derived matter contributed a maximum of 65% to the bulk OC pool. The existence of downcore variability indicated that macroalgae contributed up to 16% and were higher than seagrass sources (12%). Our results suggest that macroalgal‐derived and mangrove‐derived organic matter are important contributors to OC sequestration in the estuary. In view of the heterogeneous OC pool that contributes to bulk OC stocks, placing importance on only one OC source may construe an incomplete profile of habitat‐specific capacity for OC storage. This has wider implications for understanding OC subsidies, the effects of which are particularly relevant when one considers the impacts of coastal land use changes on blue carbon storage. [ABSTRACT FROM AUTHOR]

Published

2022

3. Carbon stores from a tropical seagrass meadow in the midst of anthropogenic disturbance.

Author

Rozaimi, Mohammad, Fairoz, Mohammad, Hakimi, Tuan Mohamad, Hamdan, Nur Hidayah, Omar, Ramlan, Ali, Masni Mohd, and Tahirin, Siti Aishah

Subjects

SEAGRASSES, CARBON foams, LIGHT elements, CARBON sequestration, SEDIMENTS

Abstract

Seagrass meadows provide important carbon sequestration services but anthropogenic activities modify the natural ecosystem and inevitably lower carbon storage capacity. The tropical mixed-species meadows in the Sungai Pulai Estuary (Johor, Malaysia) are impacted by such activities. In this study, we provide baseline estimates for carbon stores analysed from sediment cores. In sediment depths up to 100 cm, organic (OC) and inorganic carbon (IC) stores were 43–101 Mg C ha − 1 and 46–83 Mg C ha − 1 , respectively, and are in the lower end of global average values. The bulk of OC (53–98%) originated from seston suggesting that the meadows had low capacity to retain seagrass-derived organic matter. The species factor resulted in some variability in OC stores but did not appear to influence IC values. The low carbon stores in the meadow may be a direct result of sediment disturbances but natural biogeochemical processes are not discounted as possible causal factors. [ABSTRACT FROM AUTHOR]

Published

2017

4. Utilization of carbon substrates by heterotrophic bacteria through vertical sediment profiles in coastal and estuarine seagrass meadows.

Author

Säwström, Christin, Serrano, Oscar, Rozaimi, Mohammad, and Lavery, Paul S.

Subjects

POSIDONIA, SEAGRASSES, HETEROTROPHIC bacteria, COASTAL sediments, ESTUARINE ecology, BACTERIAL communities, CARBON, CARBON cycle, ORGANIC compounds

Abstract

Coastal vegetated ecosystems play an important role in carbon cycling and bacterial communities inhabiting coastal sediments are responsible for the remineralization and processing of organic carbon (OC). We collected 1 m-long sediment cores in Posidonia seagrass meadows from coastal and estuarine sites in Australia that differed in their sedimentary organic and inorganic carbon, nitrogen and mud contents. The metabolic diversity of sediment heterotrophic bacterial communities was characterized at different sediment depths, based on the utilization pattern of 31 individual carbon substrates using Biolog EcoPlates™. High metabolic diversity was recorded at both sites, but the carbon substrate utilization rates and the use of carbohydrates were higher at the coastal site compared to the estuarine site. The heterotrophic bacterial community in the coastal sediment appeared to metabolize a more diverse OC pool compared to the estuarine site, which might partly explain the differences in OC storage among the seagrass habitats studied. The Biolog EcoPlates™ provided a useful tool for characte rising the sediment heterotrophic bacterial communities in the meadows and sediment characteristics and biochemical composition of the organic matter played an important role in shaping heterotrophic bacterial communities and their carbon utilization rates, potentially affecting carbon accumulation and preservation within seagrass sediments. [ABSTRACT FROM AUTHOR]

Published

2016

5. Key biogeochemical factors affecting soil carbon storage in Posidonia meadows.

Author

Serrano, Oscar, Ricart, Aurora M., Lavery, Paul S., Mateo, Miguel Angel, Arias-Ortiz, Ariane, Masque, Pere, Rozaimi, Mohammad, Steven, Andy, and Duarte, Carlos M.

Subjects

POSIDONIA, CARBON in soils, BIOGEOCHEMISTRY, CARBON sequestration, SEAGRASSES, WATER depth

Abstract

Biotic and abiotic factors influence the accumulation of organic carbon (Corg) in seagrass ecosystems. We surveyed Posidonia sinuosa meadows growing in different water depths to assess the variability in the sources, stocks and accumulation rates of Corg. We show that over the last 500 years, P. sinuosa meadows closer to the upper limit of distribution (at 2-4m depth) accumulated 3- to 4-fold higher Corg stocks (averaging 6.3 kg Corg m-2) at 3- to 4-fold higher rates (12.8 g Corg m-2 yr-1) compared to meadows closer to the deep limits of distribution (at 6-8m depth; 1.8 kg Corg m-2 and 3.6 g Corg m-2 yr-1). In shallower meadows, Corg stocks were mostly derived from seagrass detritus (88% in average) compared to meadows closer to the deep limit of distribution (45% on average). In addition, soil accumulation rates and fine-grained sediment content (< 0.125 mm) in shallower meadows (2.0 mm yr-1 and 9 %, respectively) were approximately 2-fold higher than in deeper meadows (1.2 mm yr-1 and 5 %, respectively). The Corg stocks and accumulation rates accumulated over the last 500 years in bare sediments (0.6 kg Corg m-2 and 1.2 g Corg m-2 yr-1) were 3- to 11-fold lower than in P. sinuosa meadows, while fine-grained sediment content (1 %) and seagrass detritus contribution to the Corg pool (20 %) were 8- and 3-fold lower than in Posidonia meadows, respectively. The patterns found support the hypothesis that Corg storage in seagrass soils is influenced by interactions of biological (e.g., meadow productivity, cover and density), chemical (e.g., recalcitrance of Corg stocks) and physical (e.g., hydrodynamic energy and soil accumulation rates) factors within the meadow. We conclude that there is a need to improve global estimates of seagrass carbon storage accounting for biogeochemical factors driving variability within habitats. [ABSTRACT FROM AUTHOR]

Published

2016

6. Influence of water depth on the carbon sequestration capacity of seagrasses.

Author

Serrano, Oscar, Lavery, Paul S., Rozaimi, Mohammad, and Mateo, Miguel Ángel

Subjects

WATER depth, CARBON sequestration, SEAGRASSES, CLIMATE change, CARBON cycle, MARINE ecology

Abstract

The actual estimates of carbon stocks beneath seagrass meadows worldwide are derived from few data, resulting in a tendency to generalize global carbon stocks from a very limited number of seagrass habitats. We surveyed Posidonia oceanica and Posidonia sinuosa meadows along depth-induced gradients of light availability to assess the variability in their sedimentary organic carbon (Corg) stocks and accretion rates. This study showed a fourfold decrease in Corg stocks from 2-4 m to 6-8 m depth P. sinuosa meadows (averaging 7.0 and 1.8 kg m−2, respectively; top meter of sediment) and a fourteenfold to sixteenfold decrease from shallow (2 m) to deep (32 m) P. oceanica meadows (200 and 19 kg m−2 average, respectively; top 2.7 m of sediment). The average Corg accretion rates in shallow P. sinuosa meadows were higher (10.5 g m−2 yr−1) than in deeper meadows (2.1 g m−2 yr−1). The reduction of sedimentary Corg stocks and accretion rates along depth-related gradients of light reduction suggests that irradiance, controlling plant productivity, meadow density, and sediment accretion rates, is a key environmental factor affecting Corg storage potential of seagrasses. The results obtained highlighted the exceptional carbon storage capacity of P. oceanica meadows at Balearic Islands (Spain), containing the highest areal Corg stocks of all seagrasses (estimated in up to 691-770 kg m−2 in 8-13 m thick deposits). Seagrass communities are experiencing worldwide decline, and reduced irradiance (following e.g., eutrophication or sediment regime alterations) will lead to photoacclimation responses (i.e., reduced plant productivity and shoot density), which may impact the carbon sequestration capacity of seagrasses. [ABSTRACT FROM AUTHOR]

Published

2014

7. Variability in the Carbon Storage of Seagrass Habitats and Its Implications for Global Estimates of Blue Carbon Ecosystem Service.

Author

Lavery, Paul S., Mateo, Miguel-Ángel, Serrano, Oscar, and Rozaimi, Mohammad

Subjects

SEAGRASSES, HABITATS, CARBON sequestration, MEADOWS, WATER depth, CARBON pricing

Abstract

The recent focus on carbon trading has intensified interest in ‘Blue Carbon’–carbon sequestered by coastal vegetated ecosystems, particularly seagrasses. Most information on seagrass carbon storage is derived from studies of a single species, Posidonia oceanica, from the Mediterranean Sea. We surveyed 17 Australian seagrass habitats to assess the variability in their sedimentary organic carbon (Corg) stocks. The habitats encompassed 10 species, in mono-specific or mixed meadows, depositional to exposed habitats and temperate to tropical habitats. There was an 18-fold difference in the Corg stock (1.09–20.14 mg Corg cm−3 for a temperate Posidonia sinuosa and a temperate, estuarine P. australis meadow, respectively). Integrated over the top 25 cm of sediment, this equated to an areal stock of 262–4833 g Corg m−2. For some species, there was an effect of water depth on the Corg stocks, with greater stocks in deeper sites; no differences were found among sub-tidal and inter-tidal habitats. The estimated carbon storage in Australian seagrass ecosystems, taking into account inter-habitat variability, was 155 Mt. At a 2014–15 fixed carbon price of A$25.40 t−1 and an estimated market price of $35 t−1 in 2020, the Corg stock in the top 25 cm of seagrass habitats has a potential value of $AUD 3.9–5.4 bill. The estimates of annual Corg accumulation by Australian seagrasses ranged from 0.093 to 6.15 Mt, with a most probable estimate of 0.93 Mt y−1 (10.1 t. km−2 y−1). These estimates, while large, were one-third of those that would be calculated if inter-habitat variability in carbon stocks were not taken into account. We conclude that there is an urgent need for more information on the variability in seagrass carbon stock and accumulation rates, and the factors driving this variability, in order to improve global estimates of seagrass Blue Carbon storage. [ABSTRACT FROM AUTHOR]

Published

2013

8. Nitrogen dynamics within an estuarine seagrass meadow under heavy anthropogenic influence.

Author

Ashikin, Che Nurul, Rozaimi, Mohammad, Arina, Natasha, Fairoz, Mohammad, and Hidayah, Nur

Subjects

POSIDONIA, SEAGRASSES, NITROGEN, ECOSYSTEM services, MEADOWS

Abstract

Nitrogen is essential for seagrass productivity but excesses in nitrogen exposure contribute to declines in meadow health. This study reports baseline data of bulk nitrogen loadings and contents in surficial sediments and seagrass tissues to determine the extent of nitrogen inputs in meadows of Sungai Pulai estuary (Johor, Malaysia). The sediment contained relatively low nitrogen loadings (mean range of 91–94 g N m−2) with likely origins from land-based sources. At the meadow-level, Enhalus acoroides, Cymodocea serrulata and Thalassia hemprichii are the most important species as nitrogen sinks. The highest δ15N values of seagrass tissues were recorded for T. hemprichii (10.7 ± 0.4‰), which indicated an elevated capacity for internal recycling of nitrogen. The data demonstrates the provision of ecosystem services by the meadows in mitigating excess nitrogen imported into the estuary. Seagrasses health, however, needs to be at optimum levels for the effectiveness of the meadow as a nutrient sink. Image 1 • Coastal and environmental changes place the meadows at risk to excess N inputs. • Reference baselines into contemporary N loadings are presented. • The meadow location makes it susceptible in receiving N from upstream sources. • Foundation seagrass species balances N recycling and N sink capacity. • Quantifying N at the meadow-scale assists in conceptualising budget models. [ABSTRACT FROM AUTHOR]

Published

2020

9. Algal contribution to organic carbon sequestration and its signatures in a tropical seagrass meadow.

Author

Arina, Natasha, Hidayah, Nur, Hazrin-Chong, Nur Hazlin, and Rozaimi, Mohammad

Subjects

*SEAGRASSES, *MANGROVE plants, *CARBON sequestration, *GLOBAL environmental change, *STABLE isotope analysis

Abstract

Algae form prolific coastal habitats and contribute the largest carbon dioxide (CO 2) flux globally. Most of the algal biomass is transported to the coastal ocean as particulate organic matter (OM), of which the contribution of carbon occurs mainly in depositional environments. Identifying the algal contribution alongside other major sources of organic carbon (OC) is crucial for determining allochthonous and autochthonous contributions in blue carbon habitats. In this study, we identified the algal contribution to OC storage in the seagrass meadow of Tanjung Adang Shoal (Johor, Malaysia) using dual-stable isotope measurements (δ13C and δ15N) and environmental DNA (eDNA) analysis. Stable isotope analysis showed that mangrove plants are the largest contributor to organic carbon pool in the sediments, followed by seston, macroalgae, epiphytes and seagrasses. The combined proportions of sestonic, macroalgal and epiphytic inputs as algal-derived organic matter had contributed a cumulative of 41.4–55.4% of organic matter in the bulk sediment. The eDNA method was used to examine bulk sediments and determine the types of algae present in the seagrass meadow at the genus/family level. Results showed that the main macroalgae present were from member of Coralinalles, Cladophoraceae and Ulvaceae, while diatoms were the predominant microalgae found in the sediment. These findings shed light on the importance of algae in carbon sequestration in the seagrass ecosystem. Understanding the role of algae in carbon storage and their interactions with sediment is crucial in the face of global and local environmental changes. • Quantifying algal contributions provide burial insights into blue carbon storage. • The proportion of algal organic carbon in seagrass sediments is presented. • Algae contributes more organic matter into the sediments compared to seagrass. • Diatoms dominate the algal DNA pool by having the highest relative abundance. [ABSTRACT FROM AUTHOR]

Published

2023

10. Linking the ecological roles of Jania adhaerens and Ulva reticulata in seagrass meadows based on variations of tissue δ13C and δ15N.

Author

Arina, Natasha, Zainee, Nur Farah Ain, Raynusha, Chandran, Hengjie, Tan, and Rozaimi, Mohammad

Subjects

*SEAGRASSES, *POSIDONIA, *ULVA, *NUTRIENT cycles, *STABLE isotopes, *CARBON sequestration, *NUTRIENT uptake

Abstract

The capacity of macroalgae to absorb, hold, and release the relative amounts of carbon (C) and nitrogen (N) in its environment varies. C and N stable isotopes can be used to gain a better understanding of the ecosystem services of nutrient cycling by quantifying its usage in macroalgae. In this study, we conducted an in situ δ13C and δ15N tracer study of the macroalgae Ulva reticulata and Jania adhaerens in the seagrass meadows of Sungai Pulai estuary, Johor. Bulk tissues were labelled with enriched sodium bicarbonate (NaH13CO 3) and ammonium chloride (15NH 4 Cl). Within 1 to 18 days post-enrichment, the macroalgae were measured for C N contents and stable isotope signatures. U. reticulata showed more bulk losses for excess 13C and 15N compared to J. adhaerens. J. adhaerens tended to retain greater %C and %N incorporated in its tissues. There was a clear distinction between the amount of C and N retained and lost in the tissues of each species. The amount of nutrients, especially C, that remained at the end of the experiment demonstrated that both macroalgae species are capable of short-term carbon sequestration, with implications for meadow-scale nutrient subsidies. Higher N uptake and retention in the biomass of the macroalgae, especially in U. reticulata , suggest their relatively high growth capacity. Understanding the C and N dynamics and loss rate of the whole plant provides an estimation of the nutrient uptake and retention capacity of the macroalgae. Such insights are important as a means to formulating steps in preserving the ecological balance of marine ecosystems. [Display omitted] • C and N isotope signatures of Jania adhaerens and Ulva reticulata are reported. • After pulsing with 13C and 15N, these macroalgae were placed in a seagrass meadow. • Variations of δ13C and δ15N in their tissues were measured over 18 days. • J. adhaerens retained more of the initial 13C and 15N tracers than U. reticulata. • C and N changes allow insights into ecological roles of nutrient cycling. [ABSTRACT FROM AUTHOR]

Published

2023

11. Reconstruction of centennial-scale fluxes of chemical elements in the Australian coastal environment using seagrass archives.

Author

Serrano, Oscar, Davis, Grace, Lavery, Paul S., Duarte, Carlos M., Martinez-Cortizas, Antonio, Mateo, Miguel Angel, Masqué, Pere, Arias-Ortiz, Ariane, Rozaimi, Mohammad, and Kendrick, Gary A.

Subjects

*POSIDONIA australis, *SEAGRASSES, *CHEMICAL elements, *COASTS, *MARINE ecology, *BIOGEOCHEMICAL cycles, *HOLOCENE Epoch

Abstract

The study of a Posidonia australis sedimentary archive has provided a record of changes in element concentrations (Al, Fe, Mn, Pb, Zn, Cr, Cd, Co, As, Cu, Ni and S) over the last 3000 years in the Australian marine environment. Human-derived contamination in Oyster Harbor (SW Australia) started ~ 100 years ago (AD ~ 1900) and exponentially increased until present. This appears to be related to European colonization of Australia and the subsequent impact of human activities, namely mining, coal and metal production, and extensive agriculture. Two contamination periods of different magnitude have been identified: Expansion period (EXP, AD ~ 1900–1970) and Establishment period (EST, AD ~ 1970 to present). Enrichments of chemical elements with respect to baseline concentrations (in samples older than ~ 115 cal years BP) were found for all elements studied in both periods, except for Ni, As and S. The highest enrichment factors were obtained for the EST period (ranging from 1.3-fold increase in Cu to 7.2-fold in Zn concentrations) compared to the EXP period (1.1-fold increase for Cu and Cr to 2.4-fold increase for Pb). Zinc, Pb, Mn and Co concentrations during both periods were 2- to 7-fold higher than baseline levels. This study demonstrates the value of Posidonia mats as long-term archives of element concentrations and trends in coastal ecosystems. We also provide preliminary evidence on the potential for Posidonia meadows to act as significant long-term biogeochemical sinks of chemical elements. [ABSTRACT FROM AUTHOR]

Published

2016

12. Coralline macroalgae contribution to ecological services of carbon storage in a disturbed seagrass meadow.

Author

Arina, Natasha, Raynusha, Chandran, Hidayah, Nur, Zainee, Nur Farah Ain, Prathep, Anchana, and Rozaimi, Mohammad

Subjects

*SEAGRASSES, *POSIDONIA, *LOCAL budgets, *OCEAN acidification, *BIOGEOCHEMICAL cycles, *CALCIUM carbonate, *CARBON

Abstract

Coralline macroalgae are globally distributed rhodopyhtes that remove carbon from their immediate environment and transform it into carbonate sediments through the senescence of their calcified tissues. In this study, the calcium carbonate (CaCO 3) stocks in the tissue of Jania adhaerens and sediments in Tanjung Adang Shoal, Johor were quantified for a 13-month study period. The detailed maps of the geographical distribution based on the spatial and temporal variations of biomass and CaCO 3 were also assessed. The highest amount of biomass, CaCO 3 and organic carbon (OC) stocks in the tissues showed the highest in May 2018 and May 2019. The biomass values ranged from 65 to 143 g DW m−2, which contained 53–147 g CaCO 3 m−2 and 3–11 g OC m−2. These findings provided insights into the biogeochemical cycling of these inputs, which can be used to estimate the overall carbon budget of the macrophyte meadow. • Monsoon events affect the variability of Jania adhaerens distribution. • Drift accumulation of J. adhaerens was highest during the inter-monsoon season. • Senescence of J. adhaerens contributes to carbonate deposition. • The calcified tissues of J. adhaerens are susceptible to ocean acidification. • Measuring CaCO 3 stocks of J. adhaerens helps in understanding local carbon budgets. [ABSTRACT FROM AUTHOR]

Published

2020