Precise methane absorption measurements in the 1.64 μm spectral region for the MERLIN mission

Delahaye, Thibault; Maxwell, Stephen E.; Reed, Zachary D.; Lin, Hong; Hodges, Joseph T.; Sung, Keeyoon; Devi, V. Malathy; Warneke, Thorsten; Spietz, Peter; Tran, H.

doi:10.1002/2016jd025024

Cited by 59 publications

(67 citation statements)

References 49 publications

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“…The geophysical auxiliary parameters (surface pressure, temperature profiles and water vapour profiles) are provided by (NWP) centres. Absorption cross sections of methane and other "interfering gases" for the desired temperature and pressure ranges are derived from line-by-line calculations using updated spectroscopic databases in combination with numerical models for the calculation of the integrated weighting function [26]. This method can also be applied to infer additional information on partial CH 4 columns above cloudy scenes by taking the signal reflected (scattered) by cloud particles at cloud tops [66].…”

Section: Methodsmentioning

confidence: 99%

“…Further, the accurate retrieval of these small changes is limited by the knowledge of spectroscopic parameters and of other atmospheric species which may have overlapping absorptions in the same spectral region. Recent progress in the methane spectroscopy in the near-infrared should reduce uncertainty in retrievals (e.g., [26]). CH 4 fluxes emitted from the surface result in small changes in the spatial distributions of the above CH 4 dry column mole fraction (e.g., typically a few ppb, and up to a few tens of ppb, on a day-to-day basis and at a typical model spatial resolution of 200 × 200 km, (see Science Plan of MEthane Remote sensing Lidar missioN (MERLIN) [27] with most of the variation happening in the boundary layer.…”

Section: Introductionmentioning

confidence: 99%

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MERLIN: A French-German Space Lidar Mission Dedicated to Atmospheric Methane

Ehret¹,

et al. 2017

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Abstract:The MEthane Remote sensing Lidar missioN (MERLIN) aims at demonstrating the spaceborne active measurement of atmospheric methane, a potent greenhouse gas, based on an Integrated Path Differential Absorption (IPDA) nadir-viewing LIght Detecting and Ranging (Lidar) instrument. MERLIN is a joint French and German space mission, with a launch currently scheduled for the timeframe 2021/22. The German Space Agency (DLR) is responsible for the payload, while the platform (MYRIADE Evolutions product line) is developed by the French Space Agency (CNES). The main scientific objective of MERLIN is the delivery of weighted atmospheric columns of methane dry-air mole fractions for all latitudes throughout the year with systematic errors small enough (<3.7 ppb) to significantly improve our knowledge of methane sources from global to regional scales, with emphasis on poorly accessible regions in the tropics and at high latitudes. This paper presents the MERLIN objectives, describes the methodology and the main characteristics of the payload and of the platform, and proposes a first assessment of the error budget and its translation into expected uncertainty reduction of methane surface emissions.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

MERLIN: A French-German Space Lidar Mission Dedicated to Atmospheric Methane

Ehret¹,

et al. 2017

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“…Note that the speed dependence of the line mixing parameter was also neglected. In the fitting procedure, the room temperature parameters of our HT + line mixing (LM) model were fixed to those obtained in Delahaye et al (), and only the temperature dependences of Γ 0 , Δ 0 , and ζ were adjusted. To simplify the fitting procedure, in the first step, only spectra measured at the lowest temperature (i.e., 223 K, see Table ) were considered in the fit.…”

Section: Spectra Analysis and Resultsmentioning

confidence: 99%

Measurement and Modeling of Air‐Broadened Methane Absorption in the MERLIN Spectral Region at Low Temperatures

et al. 2019

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The ability to precisely model methane absorption in the R(6) manifold of the 2ν3 band at atmospheric pressure and temperature conditions is a key technical requirement of the German‐French, Methane Remote Sensing Lidar (MERLIN) space mission. To this end, 27 high‐resolution and high‐signal‐to‐noise‐ratio absorption spectra of air‐broadened 12CH4 were recorded using a variable‐temperature frequency‐stabilized cavity ring‐down spectroscopy apparatus. The measurement conditions corresponded to sample temperature, pressure, and methane molar fraction values spanning 220–290 K, 4–110 kPa, and 4–7 μmol/mol, respectively. The measured spectra were fit using the sum of isolated Hartmann‐Tran profiles with the addition of line mixing. For each line within the manifold, all spectroscopic parameters at room temperature were fixed to our previously obtained values (Delahaye et al., 2016, https://doi.org/10.1002/2015JD024524) and only the temperature dependences of the model parameters were adjusted. The results show that the fitted model agrees with the measured methane absorption to better than 0.3% for the entire R(6) manifold spectral region and to within 0.1% at the online position of the MERLIN for all considered pressure and temperature conditions. A first comparison with ground‐based atmospheric measurement was also made showing significant improvement with respect to existing spectroscopic modeling of methane absorption.

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“…Our preliminary radiative transfer calculations show that both lines (Er:YAG at 1645.55 nm and Er:YGG at 1650.96 nm) have similar temperature sensitivity and are well suited for space born CH4 measurements. Recent high accuracy spectroscopic measurements indicate that line mixing effects in the Er:YAG 1645.55 nm line 57 should also be taken into account. We expect similar effects to be present for the Er:YGG line at 1650.96 nm.…”

Section: Icso 2018 International Conference On Space Opticsmentioning

confidence: 99%

The challenges of measuring methane from space with a lidar

Riris

Numata

et al. 2019

International Conference on Space Optics — ICSO 2018

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The global and regional quantification of methane fluxes and identification of its sources and sinks has been highlighted as one of the goals of the NASA 2017 Earth Science Decadal Survey. Detecting methane from space and airborne platforms with an active (laser) remote sensing instrument presents several unique technology and measurement challenges. The instrument must have a single frequency, narrow-linewidth light source, and photon-sensitive detector at the right spectral region to make continuous measurements from orbit, day and night, all seasons and at all latitudes. It must have a high signal to noise ratio and must be relatively immune to biases from aerosol/cloud scattering, spectroscopic and meteorological data uncertainties, and instrument systematic errors. At Goddard Space Flight Center (GSFC), in collaboration with industry, we have developed an airborne instrument to measure methane. Our instrument is a nadir-viewing lidar that uses Integrated Path Differential Absorption (IPDA), to measure methane near 1.65 µm. We sample the absorption line using multiple wavelengths from a narrow linewidth laser source and a sensitive photodetector. This measurement approach provides maximum information content about the CH4 column, and minimizes biases in the XCH4 retrieval. In this paper, we will review our progress to date and discuss the technology challenges, options and tradeoffs to measure methane from space and airborne platforms.

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Precise methane absorption measurements in the 1.64 μm spectral region for the MERLIN mission

Cited by 59 publications

References 49 publications

MERLIN: A French-German Space Lidar Mission Dedicated to Atmospheric Methane

MERLIN: A French-German Space Lidar Mission Dedicated to Atmospheric Methane

Measurement and Modeling of Air‐Broadened Methane Absorption in the MERLIN Spectral Region at Low Temperatures

The challenges of measuring methane from space with a lidar

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