A Web-Based Observatory for Biogeochemical Assessment in Coastal Regions

Rodrigues, Marta; Martins, Renato Parkinson; Rogeiro, J.; Fortunato, A. B.; Oliveira, Anabela; Cravo, Alexandra; Jacob, James S.; Rosa, Alexandra; Azevedo, Ana; Freire, P.

doi:10.3808/jei.202100450

Cited by 12 publications

(15 citation statements)

References 50 publications

(77 reference statements)

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“…The framework is anchored in the concept of observatories, adapted here to integrate both monitoring data, from in-situ and remote sources, and numerical models that address all relevant physical processes at stake. Unlike previous applications of the concept of observatories in the coastal analysis [15], the MOSAIC framework integrates both hydrodynamics and morphodynamic monitoring and predictions as the evolution of the topo-bathymetry during energetic events is fundamental for an accurate evaluation of flooding and overtopping in coastal regions.…”

Section: Methodology Descriptionmentioning

confidence: 99%

“…Computational frameworks and their associated interfaces have been developed over the last two decades to address flooding issues (e.g., [9][10][11]) or multi-hazard predictions. The Water Information Forecast framework-based platforms [12], dedicated to multiple hazards, are an example of the latter, addressing floods [12], oil spills [13], fecal contamination [14] and biogeochemical evolution due to anthropogenic and climate changes [15]. These types of instruments are at the core of nowadays support flood tools for coastal managers and civil protection agencies, gathering the relevant data and forecasts, and making them available in a user-friendly way (e.g., [16,17]).…”

Section: Introductionmentioning

confidence: 99%

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Multi-Hazard WebGIS Platform for Coastal Regions

et al. 2021

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The combined action of waves, surges and tides can cause flooding, erosion and dune and structure overtopping in many coastal regions. Addressing emergency and risk management in these areas require a combination of targeted campaigns and real-time data that measure all phenomena at stake and can be used to develop comprehensive monitoring platforms. These monitoring platforms can support the development of prediction tools that address all hazards in an integrated way. Herein, we present a methodology focused on multi-hazard coastal alert and risk, and its implementation in a tailored WebGIS platform. The MOSAIC platform offers a one-stop-shop capacity to access in-situ and remote sensing data, and hydrodynamic and morphodynamic predictions, supported by numerical models: SCHISM and XBeach. Information is structured on a local observatory scale, with regional forcings available for the correct interpretation of local hazards effects. This implementation can be further applied and extended to other coastal zones. The MOSAIC platform also provides access to a detailed database of past hazardous events, organized along several risk indicators, for the western coast of Portugal. The combination of features in the platform provides a unique repository of hazard information to support end-users for both emergency and long term risk planning actions.

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Section: Methodology Descriptionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Multi-Hazard WebGIS Platform for Coastal Regions

et al. 2021

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“…The calibration and validation of the model were performed by comparison with several datasets, including water levels, salinity, water temperature, dissolved oxygen, inorganic nutrients and chlorophyll-a data. Prior results showed the model's ability to represent the main spatial and temporal patterns of circulation and water quality in the test site [18] [19]. Water level information is obtained in several (76) sampling points along a cross-section of the simulation mesh using a time step of 60 s. Bathymetry data for the Tagus Estuary is depicted in Fig.…”

Section: Tidal Dynamics In the Tagus Estuarymentioning

confidence: 99%

“…6 alongside a given interpolation of the bathymetry mesh along the communication link path between the transmitter and receiver. Further details about the model implementation can be found in [18] and [19].…”

Section: Tidal Dynamics In the Tagus Estuarymentioning

confidence: 99%

“…the point which determines both the relative height of the antennas to the surface medium and its relative permittivity (e.g., water or soil with varying water content). To accomplish this with high-precision, we resort to state-of-the-art hydrodynamic modelling of an estuary [18], [19], which provides water level estimations at any point along the link path (spatial) and the tidal cycle (temporal), but also the corresponding water content of the soil (physical) of the reflection point. This latter aspect is crucial for the path loss estimation in the estuarine intertidal zone, since if the reflection point falls within this area, it will vary from dry to wet regions (or vice-versa) following the tide dynamics, also possibly changing the relative altitude w.r.t.…”

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confidence: 99%

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Modeling LoRa Communications in Estuaries for IoT Environmental Monitoring Systems

et al. 2022

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Low-power wide-area networks are extending beyond the conventional terrestrial domain. Coastal zones, rivers, wetlands, among others, are nowadays common deployment settings for Internet-of-Things nodes where communication technologies such as LoRa are becoming popular. In this article, we investigate large-scale fading dynamics of LoRa line-of-sight links deployed over an estuary with characteristic intertidal zones, considering both shore-to-shore and shore-to-vessel communications. We propose a novel methodology for path loss prediction which captures i) spatial, ii) temporal and iii) physical features of the RF signal interaction with the environmental dynamics, integrating those features into the two-ray propagation model. To this purpose, we resort to precise hydrodynamic modeling of the estuary, including the specific terrain profile (bathymetry) at the reflection point. These aspects are key to accounting for a reflecting surface of varying altitude and permittivity as a function of the tide. Experimental measurements using LoRa devices operating in the 868~MHz band show major trends on the received signal power in agreement with the methodology's predictions.

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Global water availability and its distribution under the Coupled Model Intercomparison Project Phase Six scenarios

2022

Intl Journal of Climatology

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Changes in the hydrological cycle have widespread consequences and remain uncertain under climate change. We analyse the changes in major water components of the hydrological cycle, that is, precipitation (P), runoff (Q), evapotranspiration (E), precipitation minus evapotranspiration (P − E), and terrestrial water storage (S), and quantify the uncertainties across the 21st century with Phase Six of the Coupled Model Intercomparison Project (CMIP6) simulations. The multimodel ensemble based on over 10 GCMs shows that P − E and Q share similar trends with P, with increases expected in northern high latitudes of Eurasia and North America, South Asia, and eastern Africa, and decreases expected in Central America, the Mediterranean, and the Amazon. The seasonal changes in S at mid and high latitudes are behind the large seasonal shifts in Q while changes in P − E are dominantly affected by P. The equatorial regions are expected to have the largest changes and intermodel variability. From low emission scenario SSP1‐2.6 to high emission scenario SSP5‐8.5, the spatial patterns for future changes remain consistent while more drastic and more widespread changes are expected globally over time with warming for all water components. Larger intermodel variability is also found under higher emission scenarios. The study provides a comprehensive perspective on the assessment of annual and seasonal changes in all water components within the hydrological cycle as well as the associated uncertainty with the latest CMIP6 simulations under three representative scenarios, providing the most updated climate information for formulating appropriate mitigation and adaptation.

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A Web-Based Observatory for Biogeochemical Assessment in Coastal Regions

Cited by 12 publications

References 50 publications

Multi-Hazard WebGIS Platform for Coastal Regions

Multi-Hazard WebGIS Platform for Coastal Regions

Modeling LoRa Communications in Estuaries for IoT Environmental Monitoring Systems

Global water availability and its distribution under the Coupled Model Intercomparison Project Phase Six scenarios

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