Greenness trends and carbon stocks of mangroves across Mexico

Vázquez‐Lule, Alma; Colditz, René R.; Herrera-Silveira, Jorge A.; Guevara, Mário; Rodríguez-Zúñiga, María Teresa; Cruz, Isabel F.; Ressl, Rainer; Vargas, Rodrigo

doi:10.1088/1748-9326/ab246e

Cited by 24 publications

(15 citation statements)

References 82 publications

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“…(2018) also found that time‐series of 15‐years of four vegetation indexes (gNDVI, EVI, and NDVI) were significantly and negatively correlated with in situ data of temperature and salinity in the Yucatán Peninsula. However, the correlation NDVI‐ambient temperature is site‐specific and can be positive, especially in those sites found in temperate‐humid ecosystems where temperature is not the limiting factor for mangrove growth (Songsom et al., 2019; Vázquez‐Lule et al., 2019). Furthermore, the phenology inferred by Sentinel‐NDVI in our site agreed with field observations of mangrove phenology in the Gulf of California.…”

Section: Discussionmentioning

confidence: 99%

“…In Mexico, they are mostly found in narrow strips along the coastline of the Gulf of California and adjacent to coastal deserts. Sonora and Baja California Sur, two Mexican states that border the Gulf of California, have a mangrove extension of 9,353 (1.42% of the national total) and 24,327 hectares (3.7% of the national total) respectively (Vázquez‐Lule et al., 2019). Although mangroves only occupy 1% of the arid ecosystems of northwestern Mexico, they can store about 28% of the total regional belowground carbon pool (Ezcurra et al., 2016; Ochoa‐Gómez et al., 2019).…”

Section: Introductionmentioning

confidence: 99%

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Environmental Controls on the Temporal Evolution of Energy and CO₂ Fluxes on an Arid Mangrove of Northwestern Mexico

Granados-Martínez¹,

Yépez²,

Sánchez-Mejía³

et al. 2021

JGR Biogeosciences

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This work explored the environmental factors that control the temporal dynamics of vertical energy and carbon fluxes between the atmosphere and arid mangroves located on the coastline of the Gulf of California, Mexico. Net ecosystem exchange (NEE), latent (λE) and sensible heat (H) exchange fluxes were estimated in situ using the eddy covariance technique along with meteorological and hydrological observations during the period November 2017 through November 2019. Moreover, multiyear mangrove phenology at footprint-scale was tracked using remotely sensed vegetation greenness data from Sentinel-2. Our results suggest that the seasonal energy partition and the magnitude of NEE is highly coupled with seasonal changes in the level of tidal flooding, vapor pressure deficit (VPD) and temperature. Low tidal levels facilitate heat transmission to the atmosphere leading the energy partition to H, while the increase in flooding and VPD facilitates the transmission of water vapor resulting in λE dominance. The lowest rate of NEE was observed during the months of highest tidal flooding (June-August) while the highest seasonal rate of NEE matched with the lowest mean flood levels (March-May). Estimated annual NEE for 2018 was −745.3 gC m −2 y −1 while for 2019 was −307.4 gC m −2 y −1 . Our findings suggest a possible trend of decrease in the capacity of carbon sequestration of arid mangroves with rising sea levels and air temperature as a result of global warming.GRANADOS-MARTÍNEZ ET AL.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Environmental Controls on the Temporal Evolution of Energy and CO₂ Fluxes on an Arid Mangrove of Northwestern Mexico

Granados-Martínez¹,

Yépez²,

Sánchez-Mejía³

et al. 2021

JGR Biogeosciences

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“…Respectively, the tropical or subtropical broadleaf evergreen forests are the most productive ecosystems of Mexico (Murray‐Tortarolo et al, ). The wetland category, with high carbon sequestration potential, includes mangroves (and other coastal wetlands), which have been recognized as the ecosystems with higher carbon storage capacity from the site‐specific to the global scales (Adame et al, ; Atwood et al ; Vázquez‐Lule et al, ). Our results represent benchmarks for SOC monitoring across these land cover classes.…”

Section: Discussionmentioning

confidence: 99%

Soil Organic Carbon Across Mexico and the Conterminous United States (1991–2010)

Guevara

Arroyo

Brunsell

et al. 2020

Global Biogeochemical Cycles

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Soil organic carbon (SOC) information is fundamental for improving global carbon cycle modeling efforts, but discrepancies exist from country‐to‐global scales. We predicted the spatial distribution of SOC stocks (topsoil; 0–30 cm) and quantified modeling uncertainty across Mexico and the conterminous United States (CONUS). We used a multisource SOC dataset (>10 000 pedons, between 1991 and 2010) coupled with a simulated annealing regression framework that accounts for variable selection. Our model explained ~50% of SOC spatial variability (across 250‐m grids). We analyzed model variance, and the residual variance of six conventional pedotransfer functions for estimating bulk density to calculate SOC stocks. Two independent datasets confirmed that the SOC stock for both countries represents between 46 and 47 Pg with a total modeling variance of ±12 Pg. We report a residual variance of 10.4 ±5.1 Pg of SOC stocks calculated from six pedotransfer functions for soil bulk density. When reducing training data to define decades with relatively higher density of observations (1991–2000 and 2001–2010, respectively), model variance for predicted SOC stocks ranged between 41 and 55 Pg. We found nearly 42% of SOC across Mexico in forests and 24% in croplands, whereas 31% was found in forests and 28% in croplands across CONUS. Grasslands and shrublands stored 29 and 35% of SOC across Mexico and CONUS, respectively. We predicted SOC stocks >30% below recent global estimates that do not account for uncertainty and are based on legacy data. Our results provide insights for interpretation of estimates based on SOC legacy data and benchmarks for improving regional‐to‐global monitoring efforts.

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“…An initial investigation showed that~1/3 of the apparent GPP increase from 2000 to 2019 was due to interpolation. We are currently investigating this topic further, as other work has found increasing GPP over time for mangroves in Mexico (Vázquez-Lule et al, 2019). One potential future avenue is to use data from NOAA's Coastal Change Analysis Program to map dynamic changes , although this approach could coarsen the spatial resolution and bring greater wetland classification errors.…”

Section: Reducing Bc Model Uncertaintymentioning

confidence: 98%

Tidal Wetland Gross Primary Production Across the Continental United States, 2000–2019

Feagin

Forbrich

Huff

et al. 2020

Global Biogeochemical Cycles

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We mapped tidal wetland gross primary production (GPP) with unprecedented detail for multiple wetland types across the continental United States (CONUS) at 16‐day intervals for the years 2000–2019. To accomplish this task, we developed the spatially explicit Blue Carbon (BC) model, which combined tidal wetland cover and field‐based eddy covariance tower data into a single Bayesian framework, and used a super computer network and remote sensing imagery (Moderate Resolution Imaging Spectroradiometer Enhanced Vegetation Index). We found a strong fit between the BC model and eddy covariance data from 10 different towers (r2 = 0.83, p < 0.001, root‐mean‐square error = 1.22 g C/m2/day, average error was 7% with a mean bias of nearly zero). When compared with NASA's MOD17 GPP product, which uses a generalized terrestrial algorithm, the BC model reduced error by approximately half (MOD17 had r2 = 0.45, p < 0.001, root‐mean‐square error of 3.38 g C/m2/day, average error of 15%). The BC model also included mixed pixels in areas not covered by MOD17, which comprised approximately 16.8% of CONUS tidal wetland GPP. Results showed that across CONUS between 2000 and 2019, the average daily GPP per m2 was 4.32 ± 2.45 g C/m2/day. The total annual GPP for the CONUS was 39.65 ± 0.89 Tg C/year. GPP for the Gulf Coast was nearly double that of the Atlantic and Pacific Coasts combined. Louisiana alone accounted for 15.78 ± 0.75 Tg C/year, with its Atchafalaya/Vermillion Bay basin at 4.72 ± 0.14 Tg C/year. The BC model provides a robust platform for integrating data from disparate sources and exploring regional trends in GPP across tidal wetlands.

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Greenness trends and carbon stocks of mangroves across Mexico

Cited by 24 publications

References 82 publications

Environmental Controls on the Temporal Evolution of Energy and CO₂ Fluxes on an Arid Mangrove of Northwestern Mexico

Environmental Controls on the Temporal Evolution of Energy and CO₂ Fluxes on an Arid Mangrove of Northwestern Mexico

Soil Organic Carbon Across Mexico and the Conterminous United States (1991–2010)

Tidal Wetland Gross Primary Production Across the Continental United States, 2000–2019

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Greenness trends and carbon stocks of mangroves across Mexico

Cited by 24 publications

References 82 publications

Environmental Controls on the Temporal Evolution of Energy and CO2 Fluxes on an Arid Mangrove of Northwestern Mexico

Environmental Controls on the Temporal Evolution of Energy and CO2 Fluxes on an Arid Mangrove of Northwestern Mexico

Soil Organic Carbon Across Mexico and the Conterminous United States (1991–2010)

Tidal Wetland Gross Primary Production Across the Continental United States, 2000–2019

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Environmental Controls on the Temporal Evolution of Energy and CO₂ Fluxes on an Arid Mangrove of Northwestern Mexico

Environmental Controls on the Temporal Evolution of Energy and CO₂ Fluxes on an Arid Mangrove of Northwestern Mexico