Intelligent pointing increases the fraction of cloud-free CO2 and CH4 observations from space

Nassar, Ray; MacDonald, Cameron G.; Kuwahara, Bruce; Fogal, Alexander; Issa, Joshua; Girmenia, Anthony; Khan, Safwan; Sioris, Chris E.

doi:10.3389/frsen.2023.1233803

Cited by 2 publications

(1 citation statement)

References 41 publications

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“…Second, data is obtained from a unique 12-hr highly elliptical orbit (HEO) that observes both North American and Eurasian high latitude regions for up to eight consecutive hours each. This approach stems from the Arctic Observing Mission (AOM, Nassar et al, 2023) (formerly AIM-North, Nassar et al, 2019), which will carry an imaging spectrometer for making SWIR measurements of CO 2 , CH 4 , and CO in HEO. This idea developed out of an earlier HEO FTS concept (Nassar et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

More Frequent Spaceborne Sampling of X_CO2 Improves Detectability of Carbon Cycle Seasonal Transitions in Arctic‐Boreal Ecosystems

Parazoo,

Keppel‐Aleks,

Sander

et al. 2024

Geophysical Research Letters

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Surface, aircraft, and satellite measurements indicate pervasive early cold season (Augut–September) CO2 emissions across Arctic regions, consistent with increased ecosystem metabolism in plants and soils. A key remaining question is whether cold season sources will become large enough to permanently shift the Arctic into a net carbon source. Polar orbiting GHG satellites provide robust estimation of regional carbon budgets but lack sufficient spatial coverage and repeat frequency to track sink‐to‐source transitions in the early cold season. Mission concepts such as the Arctic Observing Mission (AOM) advocate for flying imaging spectrometers in highly elliptical orbits (HEO) over the Arctic to address sampling limitations. We perform retrieval and flux inversion simulation experiments using the AURORA mission concept, leveraging a Panchromatic imaging Fourier Transform Spectrometer (PanFTS) in HEO. Our simulations demonstrate the potential benefits of increased CO2 sampling for detecting emissions during the early cold season.

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Section: Introductionmentioning

confidence: 99%

More Frequent Spaceborne Sampling of X_CO2 Improves Detectability of Carbon Cycle Seasonal Transitions in Arctic‐Boreal Ecosystems

Parazoo,

Keppel‐Aleks,

Sander

et al. 2024

Geophysical Research Letters

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GHG measurements using an imaging FTS on a stratospheric balloon: a tech demo for the Arctic observing mission

Qian,

Routhier,

et al. 2024

Remote Sensing of Clouds and the Atmosphere XXIX

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The Arctic Observing Mission (AOM) is currently under mission concept study by the Government of Canada for potential implementation with prospective U.S. and European partners. It would use two satellites in a Highly Elliptical Orbit (HEO) to make geostationary-like observations of greenhouse gases (GHGs), air quality species of interest, meteorology, and space weather over northern regions. An imaging Fourier transform spectrometer (iFTS) has been selected as the technology for GHG observations. To elevate the technology readiness level of the iFTS, the Canadian Space Agency (CSA) has awarded contracts to Canadian industry and academia to advance the technology. An iFTS instrument suitable for sub-orbit demonstration has been built. Calibration techniques and software suites for processing the acquired iFTS image data have been developed. The CSA has flown the iFTS instrument in a stratospheric balloon campaign from its CSA-CNES Stratos Balloon Facility based in Timmins, Ontario, Canada to demonstrate its ability to measure GHGs over the boreal forest from an altitude of 37 km. This paper briefly describes the development of the iFTS instrument and its adaptations to the stratospheric balloon platform for sub-orbital flight demonstration. The paper also reports instrument pre-and post-flight calibration, FTS image data processing techniques, retrieval of GHG data products and a brief analysis of these products. The balloon flight demonstration with a sub-optimal geometry and low cost iFTS prototype delivered GHG data products that met all expectations. This work not only elevated the technology readiness level of the iFTS technology, but also provided lessons that greatly benefit the development of the iFTS for the AOM mission.

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Intelligent pointing increases the fraction of cloud-free CO2 and CH4 observations from space

Cited by 2 publications

References 41 publications

More Frequent Spaceborne Sampling of X_CO2 Improves Detectability of Carbon Cycle Seasonal Transitions in Arctic‐Boreal Ecosystems

More Frequent Spaceborne Sampling of X_CO2 Improves Detectability of Carbon Cycle Seasonal Transitions in Arctic‐Boreal Ecosystems

GHG measurements using an imaging FTS on a stratospheric balloon: a tech demo for the Arctic observing mission

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Intelligent pointing increases the fraction of cloud-free CO2 and CH4 observations from space

Cited by 2 publications

References 41 publications

More Frequent Spaceborne Sampling of XCO2 Improves Detectability of Carbon Cycle Seasonal Transitions in Arctic‐Boreal Ecosystems

More Frequent Spaceborne Sampling of XCO2 Improves Detectability of Carbon Cycle Seasonal Transitions in Arctic‐Boreal Ecosystems

GHG measurements using an imaging FTS on a stratospheric balloon: a tech demo for the Arctic observing mission

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More Frequent Spaceborne Sampling of X_CO2 Improves Detectability of Carbon Cycle Seasonal Transitions in Arctic‐Boreal Ecosystems

More Frequent Spaceborne Sampling of X_CO2 Improves Detectability of Carbon Cycle Seasonal Transitions in Arctic‐Boreal Ecosystems