Allometry and biomass distribution in replanted mangrove plantations at Gazi Bay, Kenya

Kairo, James Gitundu; Bosire, Jared O.; Lang'at, Joseph Kipkorir Sigi; Kirui, Bernard; Koedam, Nico

doi:10.1002/aqc.1046

Cited by 44 publications

(33 citation statements)

References 19 publications

(27 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A review by Komiyama et al (2008) identified 13 species-specific and two common (i.e., multi-species) models for prediction of aboveground biomass of mangroves, while nine speciesspecific models and one common model were identified for belowground biomass. Additional studies on mangroves that developed models for prediction of biomass not present in this review also exist (e.g., Kairo et al 2009;Kauffman and Donato 2012;Sitoe et al 2014). With the exception of the models developed by Kairo et al (2009) in Kenya and Sitoe et al (2014) in Mozambique, most of the models have been developed for mangroves in Asia.…”

Section: Introductionmentioning

confidence: 99%

“…Additional studies on mangroves that developed models for prediction of biomass not present in this review also exist (e.g., Kairo et al 2009;Kauffman and Donato 2012;Sitoe et al 2014). With the exception of the models developed by Kairo et al (2009) in Kenya and Sitoe et al (2014) in Mozambique, most of the models have been developed for mangroves in Asia. The relatively few existing models for belowground biomass may be associated with the labor-intensive nature of sampling belowground biomass for mangrove tree species (Njana et al 2015).…”

Section: Introductionmentioning

confidence: 99%

“…For example, the aboveground model by Chave et al (2005) is based on mangrove data from a limited geographical area (French Guiana and Guadeloupe); thus, the model does not represent mangroves found in Africa and it does not include any dominant species found in Africa. Similarly, the aboveground biomass models from mangroves in Kenya and Mozambique are both based on data from one site, and they have limited sample size (e.g., n=5, Kairo et al 2009; n = 31 for six species, Sitoe et al 2014) and tree size ranges (dbh up to 42 cm, Sitoe et al 2014). Trees with dbh > 40 cm are likely to be found in Tanzania (e.g.…”

Section: Introductionmentioning

confidence: 99%

“…Thus, model tests on real data are preferable, but this is of course seldom possible since suitable data would mostly be collected for calibrating local models, which renders the use of the alien model unnecessary. However, Njana et al (2015) tested selected existing belowground biomass models on relevant data from Tanzania, both common (Komiyama et al 2005) and species-specific (Tamai et al 1986;Comley and McGuinness 2005;Kairo et al 2009). The results revealed large prediction errors for both the common (26-63 %) and species-specific (55-63 %) models.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Above- and belowground tree biomass models for three mangrove species in Tanzania: a nonlinear mixed effects modelling approach

Njana

Bollandsås

Eid

et al. 2015

Annals of Forest Science

View full text Add to dashboard Cite

Abstract& Key message Tested on data from Tanzania, both existing species-specific and common biomass models developed elsewhere revealed statistically significant large prediction errors. Species-specific and common above-and belowground biomass models for three mangrove species were therefore developed. The species-specific models fitted better to data than the common models. The former models are recommended for accurate estimation of biomass stored in mangrove forests of Tanzania. & Context Mangroves are essential for climate change mitigation through carbon storage and sequestration. Biomass models are important tools for quantifying biomass and carbon stock. While numerous aboveground biomass models exist, very few studies have focused on belowground biomass, and among these, mangroves of Africa are hardly or not represented. & Aims The aims of the study were to develop above-and belowground biomass models and to evaluate the predictive accuracy of existing aboveground biomass models developed for mangroves in other regions and neighboring countries when applied on data from Tanzania. & Methods Data was collected through destructive sampling of 120 trees (aboveground biomass), among these 30 trees were sampled for belowground biomass. The data originated from four sites along the Tanzanian coastline covering three dominant species: Avicennia marina (Forssk.) Vierh, Sonneratia alba J. Smith, and Rhizophora mucronata Lam. The biomass models were developed through mixed modelling leading to fixed effects/common models and random effects/speciesspecific models. & Results Both the above-and belowground biomass models improved when random effects (species) were considered. Inclusion of total tree height as predictor variable, in addition to diameter at breast height alone, further improved the model predictive accuracy. The tests of existing models from other regions on our data generally showed large and significant prediction errors for aboveground tree biomass. Handling Editor: Shuqing ZhaoContribution of co-authors: Njana: Took part in design of research, responsible for data collection and preparation, and for data analysis and manuscript development. O. M. Bollandsås: Supervising the work including providing technical guidance on data analysis and commenting on the manuscript. T. Eid: Took part in design of the research, supervising the work, commenting, and manuscript development. E. Zahabu: Supervising the work and commenting on the manuscript. R. Malimbwi: Coordinating the design of research project and commenting on the manuscript.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Above- and belowground tree biomass models for three mangrove species in Tanzania: a nonlinear mixed effects modelling approach

Njana

Bollandsås

Eid

et al. 2015

Annals of Forest Science

View full text Add to dashboard Cite

show abstract

“…Mangrove ecosystems also support high floral and faunal biodiversity [9,[12][13][14] and sequester significant amounts of CO 2 [15,16]. While numerous studies have measured above-ground biomass in mangrove trees (e.g., [17][18][19][20][21][22][23][24][25][26]), comparatively few have quantified above-and below-ground carbon (C) pools, including soil (i.e., [15,[27][28][29][30][31][32][33][34]); however, it is the deep, organic material enriched soils that contain the vast majority of C stocks [35][36][37][38]. Factoring in soil, mangroves have been found to be amongst the most carbon-dense forests in the tropics, with similar or greater above-and exceptionally larger below-ground stocks compared with the terrestrial systems reported in several studies [15,27,[32][33][34]39].…”

Section: Introductionmentioning

confidence: 99%

Ecological Variability and Carbon Stock Estimates of Mangrove Ecosystems in Northwestern Madagascar

Jones

Ratsimba

Ravaoarinorotsihoarana

et al. 2014

Forests

View full text Add to dashboard Cite

Mangroves are found throughout the tropics, providing critical ecosystem goods and services to coastal communities and supporting rich biodiversity. Despite their value, world-wide, mangroves are being rapidly degraded and deforested. Madagascar contains approximately 2% of the world's mangroves, >20% of which has been deforested since 1990 from increased extraction for charcoal and timber and conversion to small to large-scale agriculture and aquaculture. Loss is particularly prominent in the northwestern Ambaro and Ambanja bays. Here, we focus on Ambaro and Ambanja bays, presenting dynamics calculated using United States Geological Survey (USGS) national-level mangrove maps and the first localized satellite imagery derived map of dominant land-cover types. The analysis of USGS data indicated a loss of 7659 ha (23.7%) and a gain of 995 ha (3.1%) from 1990-2010. Contemporary mapping results were 93.4% accurate overall (Kappa 0.9), with producer's and user's accuracies ≥85%. Classification results allowed partitioning mangroves in to ecologically meaningful, spectrally distinct strata, wherein field measurements facilitated estimating the first total carbon stocks for mangroves in Madagascar. Estimates suggest that higher stature closed-canopy mangroves have average total vegetation carbon values of 146.8 Mg/ha (±10.2) and soil organic OPEN ACCESSForests 2014, 5 178 carbon of 446.2 (±36.9), supporting a growing body of studies that mangroves are amongst the most carbon-dense tropical forests.

show abstract

Inter‐ and intraspecific variation in mangrove carbon fraction and wood specific gravity in Gazi Bay, Kenya

et al. 2018

View full text Add to dashboard Cite

Abstract. The tropical mangrove ecosystem harbors great potential for carbon offsetting schemes because of their exceptionally high carbon sequestration potential. These cannot only generate an income for local communities by financially compensating for the non-exploitation of protected or replanted stands, but also simultaneously reduce emissions due to forest degradation and deforestation, thereby helping to counteract the global threat on these forests. As carbon is directly monetized through offsetting carbon emissions, accurate species-specific estimation of carbon content in trees is essential and reduces the propagation of errors generated by accounting uncertainties. Accordingly, this study assessed variation in both carbon fraction and wood specific gravity among and within the 10 mangrove species occurring in Gazi Bay, Kenya. Significant interspecific differences were found with values ranging from 45.8% (Avicennia marina) to 49.8% (Ceriops tagal) for carbon fraction and from 0.58 (Sonneratia alba) to 0.93 (Pemphis acidula) for wood specific gravity. The influence of environmental factors (soil salinity, stand density, and elevation a.s.l. as a proxy for multiple interrelated conditions) was investigated, but only elevation a.s.l. appeared to have a species-specific though moderate influence only on carbon fraction. Significant differences in carbon fraction and wood specific gravity were found between stem, aerial roots, and branches of Rhizophora mucronata. In contrast, no significant differences in carbon fraction were found among different stem tissues of A. marina, C. tagal and R. mucronata, the Bay's most abundant species. These results provide insight in carbon content variation, confirming the importance of considering species-specific or even sitespecific values of carbon fraction and wood specific gravity, thereby rendering future carbon accounting more accurate.

show abstract

Allometry and biomass distribution in replanted mangrove plantations at Gazi Bay, Kenya

Cited by 44 publications

References 19 publications

Above- and belowground tree biomass models for three mangrove species in Tanzania: a nonlinear mixed effects modelling approach

Above- and belowground tree biomass models for three mangrove species in Tanzania: a nonlinear mixed effects modelling approach

Ecological Variability and Carbon Stock Estimates of Mangrove Ecosystems in Northwestern Madagascar

Inter‐ and intraspecific variation in mangrove carbon fraction and wood specific gravity in Gazi Bay, Kenya

Contact Info

Product

Resources

About