Meriam M. Calipayan,
Mark P. Bello, Raffy D. Aloquin, Marvin C. Aculan, and Shirleen Grace A.
Brillantes, from the different institute of the Philippines. wrote a
research article about, Carbon Storage and Biomass of Mangrove Forests in
Samar, Philippines. entitled, Diversity, stand structure, biomass and carbon
storage potential of natural and planted Mangrove Forests in Samar, Philippines.
This research paper published by the Journal of Biodiversity and Environmental Sciences (JBES). an open access scholarly research journal on Biodiversity. under
the affiliation of the International Network For Natural Sciences |
NNSpub. an open access multidisciplinary research journal publisher.
Abstract
Samar is one of the
provinces in the Philippines with the most extensive remaining mangrove forest.
However, information on ecology and carbon sequestration capacity is limited.
Thus, this study aims to assess the species diversity, community structure, and
carbon stock in the natural and planted mangrove stands in Zumarraga, Samar.
The transect-line method was used to collect vegetation analysis and diversity
data, while biomass estimation used an allometric equation. Fifteen sampling
plots of 10 m x 10 m were established in each sampling site, representing
the seaward, middleward, and landward zones. The species composition of these
areas consists of 11 species belonging to 5 families. Biodiversity indices
indicated very low species diversity for both types of mangrove forests. Avicennia
marina was the most important species, with an importance value (IVI) of
168.55% (natural stand) and 75.61% (planted stand). The total carbon stock was
71.97 t C ha⁻¹ in the natural stand and 391.44 t C ha-1 in the planted
stand. Overall, even if both mangrove stands have very low species diversity,
their ability to store and sequester carbon cannot be undermined, as evident in
the biomass and carbon stock values. Thus, sustainable management strategies
and efforts should be made to protect this naturally grown and planted mangrove
ecosystem.
Introduction
Mangrove forests are coastal wetland ecosystems considered one of Earth's most highly productive ecosystems, contributing various functions and services to surrounding coastal areas (Van Oudenhoven et al., 2015). It provides many useful human products, such as charcoal, medicines, and building materials (Barbier et al., 2011). Moreover, mangroves aid in regulating floods, erosion, and saltwater intrusion (Camacho et al., 2020) and as a buffer for coastal communities against storms and typhoons (Polidoro et al., 2010). Aside from that, this habitat also provides food and livelihood for coastal residents (Gevaña et al., 2018). Furthermore, mangroves play an important role in the health of coastal ecosystems. Their intricate root network stabilizes sediments and enhances water clarity, providing a perfect home for many marine organisms (Arceo-Carranza et al., 2021).
Recently, blue carbon ecosystems like mangroves have received international attention as a valuable tool for mitigating the impacts of climate change. This coastal ecosystem is rich in biodiversity and one of the world's most significant carbon sinks, trapping and storing a remarkable amount of carbon within its dense root systems and forest soils (Alongi, 2014; Howard et al., 2014). Since the carbon trapped in the soil is difficult to decompose, this allows the stored carbon to stay in the soil for a long time, further emphasizing its vital importance in moderating the global climate (Castillo and Breva, 2012). Mangroves can hold up to 1023 t C ha-1 and five times more organic carbon than rainforests (Donato et al., 2011; Kaufman et al., 2018). Previous studies have emphasized that the bulk of this carbon is stored belowground, particularly in soil and roots (Donato et al., 2011).
Despite
their importance, mangrove forests face numerous threats and challenges.
Anthropogenic activities such as urbanization (Marchio et al., 2016),
aquaculture (Primavera, 2006; Garcia et al., 2014), and overexploitation
(McLeod and Sam, 2006) have led to the widespread degradation of mangrove
habitats. Climate change also poses a significant risk to mangroves with rising
sea levels and increased frequency and intensity of storms (Gilman et al.,
2008; Abino et al., 2014a). Globally, it is estimated that mangrove forests
lost at a rate of 2.74% in 1996- 2007 and 1.58% in 2007-2016 (Hagger et al.,
2022). Brander et al. (2012) forecast a decline from 6,042 to 2,082 ha for the
mangrove forests in Southeast Asia between 2000 to 2050. According to Gevaña et
al. (2018), the country's mangrove forest cover is estimated at 356,000 ha with
a decadal deforestation rate of 0.5%. The main drivers of this huge loss are
various anthropogenic activities, including deforestation, land conversion for
agriculture, aquaculture, and coastal development (Primavera et al., 2004;
Garcia et al., 2014).
The western part of
Samar has a relatively long coastline, extending over 300 km (Abino et al.,
2014a). Its mangrove forests constitute 7% of the total mangrove area of the
country (FMB, 2011). As one of the provinces in the Philippines with the most
extensive remaining mangroves, its biomass carbon sequestration and storage
potential is also expected to be huge. However, there is limited information on
Samar's natural and planted mangrove stands' composition, structure, and carbon
storage potential. Hence, this study provides information on the diversity,
structural complexity, and carbon storage potential of mangroves in the
province. The objectives of the present study were to (i) identify mangrove
species composition and diversity, (ii) determine the mangrove community
structure, and (iii) evaluate the biomass and carbon stock concentration. The
data collected from this study provides more comprehensive information for
properly implementing mangrove conservation programs and developing
local-specific climate change mitigation strategies.
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