Synergies Between NASA's Hyperspectral Aquatic Missions PACE, GLIMR, and SBG: Opportunities for New Science and Applications

Dierssen, H. M.; Gierach, M.; Guild, L. S.; Mannino, A.; Salisbury, J.; Schollaert Uz, S.; Scott, J.; Townsend, P. A.; Turpie, K.; Tzortziou, M.; Urquhart, E.; Vandermeulen, R.; Werdell, P. J.

doi:10.1029/2023jg007574

Cited by 6 publications

(3 citation statements)

References 101 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This analysis focused exclusively on sensors amenable to the geostatistical determination of the SNR, which precludes the inclusion of fixed-location sensors [19] and in-water sensors on a variety of platforms [11,35,55]. While not discussed, it is implicit in proposed PACE validation activities that airborne sensors would be complemented with fixed-position, shipboard, and autonomous platforms [80]; the same validation methodology would also serve for other imminent hyperspectral missions [81]. This multi-modality approach has many advantages, including capturing a wider range of remote sensing targets than are available from calibration sites, the potential for improved R rs uncertainty [30] and cross-validation of airborne and in-water sensors [32], particularly for sensor web configurations.…”

Section: Discussionmentioning

confidence: 99%

Expanded Signal to Noise Ratio Estimates for Validating Next-Generation Satellite Sensors in Oceanic, Coastal, and Inland Waters

Kudela,

Hooker,

Guild

et al. 2024

Remote Sensing

Self Cite

View full text Add to dashboard Cite

The launch of the NASA Plankton, Aerosol, Cloud, ocean Ecosystem (PACE) and the Surface Biology and Geology (SBG) satellite sensors will provide increased spectral resolution compared to existing platforms. These new sensors will require robust calibration and validation datasets, but existing field-based instrumentation is limited in its availability and potential for geographic coverage, particularly for coastal and inland waters, where optical complexity is substantially greater than in the open ocean. The minimum signal-to-noise ratio (SNR) is an important metric for assessing the reliability of derived biogeochemical products and their subsequent use as proxies, such as for biomass, in aquatic systems. The SNR can provide insight into whether legacy sensors can be used for algorithm development as well as calibration and validation activities for next-generation platforms. We extend our previous evaluation of SNR and associated uncertainties for representative coastal and inland targets to include the imaging sensors PRISM and AVIRIS-NG, the airborne-deployed C-AIR radiometers, and the shipboard HydroRad and HyperSAS radiometers, which were not included in the original analysis. Nearly all the assessed hyperspectral sensors fail to meet proposed criteria for SNR or uncertainty in remote sensing reflectance (Rrs) for some part of the spectrum, with the most common failures (>20% uncertainty) below 400 nm, but all the sensors were below the proposed 17.5% uncertainty for derived chlorophyll-a. Instrument suites for both in-water and airborne platforms that are capable of exceeding all the proposed thresholds for SNR and Rrs uncertainty are commercially available. Thus, there is a straightforward path to obtaining calibration and validation data for current and next-generation sensors, but the availability of suitable high spectral resolution sensors is limited.

show abstract

Section: Discussionmentioning

confidence: 99%

Expanded Signal to Noise Ratio Estimates for Validating Next-Generation Satellite Sensors in Oceanic, Coastal, and Inland Waters

Kudela,

Hooker,

Guild

et al. 2024

Remote Sensing

Self Cite

View full text Add to dashboard Cite

show abstract

“…As the synoptic-scale of multispectral-based ocean color observations from space have revolutionized our understanding of global ocean phytoplankton distribution and related upper ocean processes over the past few decades, a new generation of current and future hyperspectral satellite sensors show potential for another leap forward in remote sensing capabilities by enabling global-scale measurements of phytoplankton diversity (Dierssen et al, 2023;Werdell et al, 2019). Phytoplankton are single-celled, photosynthesizing microalgae ubiquitous in the sunlit upper layer of aquatic environments worldwide, hence directly influence both ocean food webs and global climate.…”

Section: Introductionmentioning

confidence: 99%

Testing a Hyperspectral, Bio‐Optical Approach to Identification of Phytoplankton Community Composition in the Chesapeake Bay Estuary

McKibben,

Schollaert Uz,

Palacios

2024

Earth and Space Science

Self Cite

View full text Add to dashboard Cite

The multi‐to hyperspectral evolution of satellite ocean color sensors is anticipated to enable satellite‐based identification of phytoplankton biodiversity, a key factor in aquatic ecosystem functioning and upper ocean biogeochemistry. In this work the bio‐optical Phytoplankton Detection with Optics (PHYDOTax) approach for deriving taxonomic (class‐level) phytoplankton community composition (PCC, e.g. diatoms, dinoflagellates) from hyperspectral information is evaluated in the Chesapeake Bay estuary on the U.S. East Coast. PHYDOTax is among relatively few optical‐based PCC differentiation approaches available for optically complex waters, but it has not yet been evaluated beyond the California coastal regime where it was developed. Study goals include: (a) testing the approach in a turbid estuary including novel incorporation of colored dissolved organic matter (CDOM) and non‐algal particles (NAP), and (b) performance assessment with both synthetic mixture and field data sets. Algorithm skill was robust on synthetic mixtures. Using field data, cryptophyte and/or cyanophyte phytoplankton groups were predicted, but diatom and dinoflagellate detection was not conclusive. For one field data set, small but significant improvements were observed in predicted PCC groups when tested with incorporation of CDOM and NAP into the algorithm, but not for the second field data set. Sensitivity to three hyperspectral‐relevant spectral resolutions (1, 5, 10 nm) was low for all field and synthetic data. PHYDOTax can identify some phytoplankton groups in the estuary using hyperspectral, field‐collected measurements, but validation‐quality data with broad temporospatial coverage are needed to determine whether the approach is robust enough for science applications.

show abstract

“…Frontiers in Nanotechnology frontiersin.org models require larger datasets and narrower sensor bands with adequate signal-to-noise ratios. Despite entering a new hyperspectral satellite era, the availability of field information to construct and validate globally applicable models for most applications remains limited (Dierssen et al, 2023).…”

Section: Introductionmentioning

confidence: 99%

Bringing satellite and nanotechnologies together: unifying strengths against pollution and climate change

Ferral,

Bonansea,

Scavuzzo

et al. 2024

Front. Nanotechnol.

View full text Add to dashboard Cite

Nowadays, we witness remarkable technological progress alongside unprecedented challenges that threaten the delicate balance of our planet’s ecological system. Environmental contamination plays a central role in this, with rapid urbanization, industrialization, mining and agricultural practices intensifying the introduction of pollutants into the environment. This article highlights the potential synergy between two fields operating at vastly different scales: satellite technology and nanotechnology. This article delves into the offerings of each of these disciplines and examines how they can mutually contribute to the detection, prevention and mitigation of environmental pollution. Satellites play a crucial role in identifying and monitoring large-scale polluted areas, offering comprehensive insights into environmental challenges. They are indispensable in tracking air, water pollution levels, assessing land degradation, and monitoring changes in ocean health with relatively high spatial and temporal resolution. Nanotechnology leverages the unique properties of materials at sub-micron scale by offering amplified chemical reactivity and new optical, electronic, and magnetic attributes, enabling selective and sensitive sensors and rapid and efficient contaminant capture/degradation strategies. Emerging nanomaterials, along with nature-inspired and self-powered or self-sustaining designs, broaden capabilities for efficient solutions. Advanced nanocharacterization techniques deepen material understanding and quantification, while nanofabrication allows precise design of functional nano-devices. We believe the synergistic relationship between both fields can yield cooperative solutions, expediting effective measures and greatly influencing policy decisions. This article advocates for the collaboration between these two disciplines to foster impactful progress in facing global challenges.

show abstract

Synergies Between NASA's Hyperspectral Aquatic Missions PACE, GLIMR, and SBG: Opportunities for New Science and Applications

Cited by 6 publications

References 101 publications

Expanded Signal to Noise Ratio Estimates for Validating Next-Generation Satellite Sensors in Oceanic, Coastal, and Inland Waters

Expanded Signal to Noise Ratio Estimates for Validating Next-Generation Satellite Sensors in Oceanic, Coastal, and Inland Waters

Testing a Hyperspectral, Bio‐Optical Approach to Identification of Phytoplankton Community Composition in the Chesapeake Bay Estuary

Bringing satellite and nanotechnologies together: unifying strengths against pollution and climate change

Contact Info

Product

Resources

About