1 Introduction

Increasing atmospheric methane has driven a 0.5 ${}^{\circ }$C global warming since 1850, making methane abatement a critical means to limit future warming (IPCC, 2021). Methane emissions have a warming potential 80 times higher than carbon dioxide over a 20-year horizon (Myhre et al., 2013; Ocko et al., 2021). Methane is the primary component of natural gas, which is an increasingly important energy source in the US and Canada, accounting for one-third of national energy consumption in 2019 (US International Energy Agency, https://www.iea.org/, last access: 1 May 2021). The production of oil and gas ($\mathrm{O}/\mathrm{G}$) in the US has more than doubled since 2005 (Enverus DrillingInfo, 2020), raising concerns about the climate impacts from methane emissions. National greenhouse gas emission inventory data reported to the United Nations Framework Convention on Climate Change (UNFCCC, 2021) by the US Environmental Protection Agency (EPA) and Environmental and Climate Change Canada (ECCC) governmental agencies report methane emissions from $\mathrm{O}/\mathrm{G}$ sectors of 7.0 Tg a${}^{-\mathrm{1}}$ in the US and 1.6 Tg a${}^{-\mathrm{1}}$ in Canada in 2018 (EPA, 2020; ECCC, 2020), accounting for 13 % of global $\mathrm{O}/\mathrm{G}$ methane emissions (Scarpelli et al., 2020).

Emission inventories reported to the UNFCCC are based on “bottom-up” estimates by applying emission factors to activity data. Many “top-down” studies using measurements of atmospheric methane have shown that the national $\mathrm{O}/\mathrm{G}$ methane emission inventories in the US and Canada are biased low (Brandt et al., 2014; Alvarez et al., 2018; Omara et al., 2018; Maasakkers et al., 2021; Johnson et al., 2017; MacKay et al., 2021). Alvarez et al. (2018) estimated the US $\mathrm{O}/\mathrm{G}$ methane emissions in 2015 to be $\mathrm{13}\pm \mathrm{2}$ Tg a${}^{-\mathrm{1}}$ by extrapolating field observations from nine $\mathrm{O}/\mathrm{G}$ production basins and found the emissions to be 60 % higher than EPA estimates. Maasakkers et al. (2021) and Lu et al. (2022) inferred a factor of 2 underestimate in EPA oil emissions by inversion of Greenhouse Gases Observing Satellite (GOSAT) data. Ground-based and satellite observations for the Permian Basin, the largest oil-producing basin in the US, indicate an emission source of 2.7–3.2 Tg a${}^{-\mathrm{1}}$ (Zhang et al., 2020; Schneising et al., 2020; Robertson et al., 2020; Lyon et al., 2021), 3 times higher than expected based on the EPA reported data. Field and GOSAT measurements over Canada similarly show a factor of 1.5 or greater underestimate of $\mathrm{O}/\mathrm{G}$ emissions in the ECCC inventory (Johnson et al., 2017; Baray et al., 2018, 2021; Atherton et al., 2017; Lu et al., 2022). A likely reason to explain the large discrepancy between the national emission inventories and atmospheric measurements is that the inventories do not properly account for the heavy-tailed emissions due to abnormal operating conditions and malfunctions, including fugitive emissions from venting, leakage, inefficient flaring, and blowouts (Brandt et al., 2014; Zavala-Araiza et al., 2021; Alvarez et al., 2018; Pandey et al., 2019; Duren et al., 2019; Lyon et al., 2021; Rutherford et al., 2021).

While inversion of GOSAT satellite observations has emerged as a powerful tool to quantify methane emissions from different sectors (such as $\mathrm{O}/\mathrm{G}$) on global and continental scales (Cressot et al., 2014; Alexe et al., 2015; Maasakkers et al., 2019; Lu et al., 2021; Turner et al., 2015; Zhang et al., 2021), GOSAT data have limited skill on regional scales because individual sampling tracks are separated by $\sim \mathrm{270}$ km. On the other hand, field campaigns can characterize emissions on regional scales (Alvarez et al., 2018) and from point sources (Frankenberg et al., 2016; Duren et al., 2019), but they are limited in their spatial extent and temporal duration, which is problematic because of the temporal variability and intermittency of emissions (Cusworth et al., 2021; Varon et al., 2021; Lyon et al., 2021).

The Tropospheric Monitoring Instrument (TROPOMI) on board Sentinel-5P is a more recent satellite mission that provides daily continuous methane observations starting in May 2018 (Lorente et al., 2021), considerably increasing the potential for monitoring regional methane emissions from space (Schneising et al., 2020; Zhang et al., 2020; Shen et al., 2021). Here we exploit TROPOMI to better quantify methane emissions from all major $\mathrm{O}/\mathrm{G}$ production basins in the US and Canada with a high-resolution ($\sim \mathrm{25}$ km) inversion of 22 months of data and using the most recent gridded versions of the EPA and ECCC inventories as prior estimates (Maasakkers et al., 2016, with updates; Scarpelli et al., 2022). Our inversion uses an analytical method that provides closed-form error characterization as part of the solution and enables an ensemble approach to assess the sensitivity of the results to the choices of inversion parameters and data filters. This allows us to evaluate the ability of TROPOMI to quantify methane emissions from an individual $\mathrm{O}/\mathrm{G}$ basin as a function of source and observation characteristics. From there we draw general conclusions about the emerging role of satellite observations in quantifying regional methane emissions and evaluating bottom-up emission inventories.

2 Data and methods

2.1 Satellite observations

We use the TROPOMI methane retrieval version 2.02 from Lorente et al. (2021) for the period May 2018–February 2020. TROPOMI is on board the polar sun-synchronous Sentinel-5 Precursor satellite with a $\sim \mathrm{13}:\mathrm{30}$ local overpass time and provides daily global coverage in cloud-free conditions with $\mathrm{7}\times \mathrm{7}$ km spatial resolution at nadir ($\mathrm{7}\times \mathrm{5.5}$ km since August 2019) (Hu et al., 2016; Veefkind et al., 2012). The column-averaged methane dry mixing ratio (XCH${}_{\mathrm{4}}$) is retrieved using the sunlight backscattered by the Earth's surface in the shortwave infrared (SWIR) 2.3 $\mathrm{\mu }$m spectral band using the RemoTeC full-physics algorithm with near-uniform sensitivity down to the surface. We do not consider observations after February 2020 because the Covid-19 pandemic could significantly affect $\mathrm{O}/\mathrm{G}$-related emissions (Lyon et al., 2021). We only use good-quality XCH${}_{\mathrm{4}}$ retrievals that meet the following recommended criteria: (1) qa_value $\ge \mathrm{0.5}$, (2) blended albedo $\le \mathrm{0.85}$, and (3) surface altitudes $\le \mathrm{2}$ km (Fig. S1 in the Supplement). The blended albedo is a weighted difference of near-infrared (NIR) and SWIR albedos to filter scenes covered by snow (Wunch et al., 2011). The resulting total number of TROPOMI observations is $\mathrm{7}\times {\mathrm{10}}^{\mathrm{6}}$ in the US and Canada for May 2018–February 2020. The number of observations per $\mathrm{0.25}\times \mathrm{0.3125}$${}^{\circ }$ inversion grid cell is typically in the 100–1000 range and exceeds 1000 in the southwestern US (Fig. S2).

When validated with the ground-based measurements from the Total Column Carbon Observing Network (TCCON), TROPOMI XCH${}_{\mathrm{4}}$ has a mean bias of $-\mathrm{3.4}\pm \mathrm{5.6}$ ppb globally and $\mathrm{6.4}\pm \mathrm{4.1}$ ppb for the US (Lorente et al., 2021). We also intercompared the TROPOMI data to GOSAT data from the University of Leicester version 9.0 Proxy XCH${}_{\mathrm{4}}$ retrieval (Butz et al., 2011; Parker et al., 2020) and find the mean TROPOMI–GOSAT difference to be $-\mathrm{5.4}\pm \mathrm{6.9}$ ppb in North America (Fig. S3). The mean bias in the TROPOMI data is effectively corrected in the specification of boundary conditions. The regional bias (standard deviation of the mean bias) is below the 10 ppb threshold recommended by Buchwitz et al. (2015) for successful inversions.

2.2 Gridded national bottom-up inventories

Prior anthropogenic methane emissions in the US and Canada are from the sector-resolved national inventories produced by the EPA (Inventory of U.S. Greenhouse Gas Emissions and Sinks) and ECCC and spatially allocated to a $\mathrm{0.1}\times \mathrm{0.1}$${}^{\circ }$ grid by Maasakkers et al. (2016) for the US in 2012 and Scarpelli et al. (2022) for Canada in 2018. We extrapolated the US emissions for the $\mathrm{O}/\mathrm{G}$ production sector to 2018 based on upstream well data in the Enverus DrillingInfo database (Enverus DrillingInfo, 2020) together with EPA national totals for $\mathrm{O}/\mathrm{G}$ production, gas processing, transmission, and distribution (EPA, 2020). Emissions from the oil and gas are assumed to be constant throughout each year with no seasonality. Prior anthropogenic emission totals for the continental US and Canada are 31.7 Tg a${}^{-\mathrm{1}}$, with major contributions from livestock (10.7 Tg a${}^{-\mathrm{1}}$), oil and gas (8.6 with 7.0 for the US and 1.6 Tg a${}^{-\mathrm{1}}$ for Canada), landfills (6.4 Tg a${}^{-\mathrm{1}}$), coal (3.2 Tg a${}^{-\mathrm{1}}$), wastewater treatment (0.72 Tg a${}^{-\mathrm{1}}$), and others. Prior wetland emissions with $\mathrm{0.5}\times \mathrm{0.5}{}^{\circ }$ spatial resolution for individual months are taken from the mean of the nine highest-performing members of the WetCHARTS v1.3.1 inventory ensemble (Ma et al., 2021). Figure S4 shows the distribution of the prior methane emissions over the study domain. Although the EPA and ECCC bottom-up inventories report oil and gas emissions separately, spatial overlap between the two makes specific attribution difficult, and we therefore combine them here.

2.3 GEOS-Chem forward model simulations and inverse model setup

We use the GEOS-Chem 12.7.0 chemical transport model (10.5281/zenodo.1343546) as the forward model to relate methane emissions to the atmospheric methane columns observed by TROPOMI. GEOS-Chem is driven by GEOS-FP reanalysis meteorological fields from the NASA Global Modeling and Assimilation Office (GMAO) (Lucchesi, 2013) with $\mathrm{0.25}\times \mathrm{0.3125}{}^{\circ }$ resolution. Here we use a nested version of GEOS-Chem with $\mathrm{0.25}\times \mathrm{0.3125}{}^{\circ }$ horizontal resolution and dynamic boundary conditions from a $\mathrm{4}\times \mathrm{5}{}^{\circ }$ global simulation. Following Shen et al. (2021), we correct the local boundary conditions on a daily basis by scaling to the ratio of TROPOMI and GEOS-Chem columns averaged over the neighboring $\pm \mathrm{1000}$ km and $\pm \mathrm{15}$ d.

Figure 1

TROPOMI methane observations and prior estimates of oil and natural gas emissions in the US and Canada. (a) TROPOMI satellite observations of the column-averaged dry methane mixing ratio (XCH${}_{\mathrm{4}}$) averaged from May 2018 to February 2020, mapped to $\mathrm{0.25}\times \mathrm{0.3125}{}^{\circ }$ resolution and corrected for surface topography as 7 ppb km${}^{-\mathrm{1}}$ (Kort et al., 2014). This elevation correction is only for visualization. We conduct the inversions for the five rectangular domains shown in black that account for over 98 % of $\mathrm{O}/\mathrm{G}$ emissions in the continental US and Canada. (b) Gridded national inventory emissions from the oil and natural gas sectors in the US and Canada in 2018 used as prior estimates in our inversion of TROPOMI observations. Grid cells with emission fluxes $\mathit{<}\mathrm{0.1}$ metric ton a${}^{-\mathrm{1}}$ km${}^{-\mathrm{2}}$ are shown in white. The boundaries of the 19 major $\mathrm{O}/\mathrm{G}$ basins are shown on the map, and the names of these basins can be found in Fig. S11.

[Figure omitted. See PDF]

The inversion optimizes a state vector defined by gridded methane emissions for the domain of interest. This involves constructing a Jacobian matrix $\mathbf{K}$ that describes the sensitivity of model XCH${}_{\mathrm{4}}$ to each emission state vector element. The construction is done by conducting sensitivity simulations in GEOS-Chem for the inversion period perturbing individual state vector elements in turn, and this is readily done on a high-performance cluster as a massively parallel problem. To reduce the computational cost, we limit the high-resolution inversion to the five domains where the $\mathrm{O}/\mathrm{G}$ sources in the US and Canada are concentrated (Fig. 1 and more details in Fig. S5). These five domains encompass over 98 % of total $\mathrm{O}/\mathrm{G}$ emissions, 97 % of oil production, and 99 % of gas production in the continental US and Canada according to bottom-up information (Enverus DrillingInfo, 2020; Maasakkers et al., 2016; Scarpelli et al., 2022).

In each domain, we construct the state vector as follows. First, all native $\mathrm{0.25}\times \mathrm{0.3125}{}^{\circ }$ grid cells with prior $\mathrm{O}/\mathrm{G}$ emissions $\mathit{>}\mathrm{0.5}$ Gg a${}^{-\mathrm{1}}$ are treated as independent state vector elements. These grid cells account for 93 % of total $\mathrm{O}/\mathrm{G}$ emissions in the US and Canada. Second, we aggregate grid cells that are inside each domain but with $\mathrm{O}/\mathrm{G}$ emissions $\mathit{<}\mathrm{0.5}$ Gg a${}^{-\mathrm{1}}$ into clusters using a $k$-means algorithm based on adjacency and consistency in prior sectoral emissions, following Turner and Jacob (2015). The average size of these clusters is $\mathrm{1}\times \mathrm{1}{}^{\circ }$, and they allow us to retrieve another 5 % of total $\mathrm{O}/\mathrm{G}$ emissions in the US and Canada, adding up to 98 %. Third, we aggregate grid cells that are outside each domain but that are within 4${}^{\circ }$ in distance into 16 clusters using the $k$-means algorithm based on adjacency (Fig. S6), following Shen et al. (2021). These clusters are designed to correct for errors in boundary conditions, and they are not used for $\mathrm{O}/\mathrm{G}$ source attribution. Altogether, the model estimates 3650 independent flux variables in the United States and Canada (Table S2 in the Supplement). Methane sinks from oxidation and uptake by soils are included in GEOS-Chem, but we do not optimize them here since they are irrelevant in nested model simulations where the loss of methane is by ventilation outside the domain (Varon et al., 2022).

We solve for the posterior estimates of methane emissions (state vector $\mathit{x}$) in the US and Canada using Bayesian inverse analysis with Gaussian error statistics. The inversion finds the optimal estimate of $\mathit{x}$ by minimizing the cost function $J$ given by

1$$\begin{array}{rl}J\left(\mathit{x}\right)& ={\left(\mathit{x}-{\mathit{x}}_{\mathrm{A}}\right)}^T{\mathbf{S}}_{\mathrm{A}}^{-\mathrm{1}}\left(\mathit{x}-{\mathit{x}}_A\right)\\ & +\mathit{\gamma }{\left(\mathit{y}-\mathbf{K}\mathit{x}\right)}^T{\mathbf{S}}_{\mathrm{O}}^{-\mathrm{1}}\left(\mathit{y}-\mathbf{K}\mathit{x}\right),\end{array}$$ where ${\mathit{x}}_{\mathrm{A}}$ is the prior estimate, $\mathbf{K}$ is the Jacobian matrix, $\mathit{y}$ is the vector of TROPOMI observations, ${\mathbf{S}}_{\mathrm{A}}$ and ${\mathbf{S}}_{\mathrm{O}}$ are covariance matrices for prior and observational errors, and $\mathit{\gamma }$ is an additional regularization factor (Brasseur and Jacob, 2017). The relationship between emissions and methane concentration (XCH${}_{\mathrm{4}}$) is strictly linear since the sinks are not optimized (Varon et al., 2022). We construct the observational error covariance matrix ${\mathbf{S}}_{\mathrm{O}}$ by applying the residual error method, which assumes that the statistics of residual error (after removing the mean bias) between the observations and a GEOS-Chem simulation with prior emissions define the observational error variance (Heald et al., 2004; Wecht et al., 2014). Both ${\mathbf{S}}_{\mathrm{A}}$ and ${\mathbf{S}}_{\mathrm{O}}$ are taken as diagonal, and we use $\mathit{\gamma }$ to avoid overfitting. For native grid cells, we assume 50 % error standard deviation for all anthropogenic and natural emissions on the $\mathrm{0.25}\times \mathrm{0.3125}{}^{\circ }$ grid. For the grid-cell clusters, we assume the error standard deviation to be $\frac{\mathrm{50}\mathit{\%}}{\sqrt{p}}$, where $p$ is the number of grid cells in each cluster.

The analytical solution for ${\mathrm{\nabla }}_{x}J\left(\mathit{x}\right)=\mathrm{0}$ yields the optimal estimate $\widehat{\mathit{x}}$ for the state vector, the corresponding posterior error covariance matrix $\widehat{\mathbf{S}}$, and the averaging kernel matrix $\mathbf{A}$ as follows: $$\begin{array}{}\text{2}& {\displaystyle }\widehat{\mathit{x}}={\mathit{x}}_{\mathrm{A}}+{\left(\mathit{\gamma }{\mathbf{K}}^T{\mathbf{S}}_{\mathrm{O}}^{-\mathrm{1}}\mathbf{K}+{\mathbf{S}}_{\mathrm{A}}^{-\mathrm{1}}\right)}^{-\mathrm{1}}\mathit{\gamma }{\mathbf{K}}^T{\mathbf{S}}_{\mathrm{O}}^{-\mathrm{1}}\left(\mathit{y}-\mathbf{K}{\mathit{x}}_{\mathrm{A}}\right),\text{3}& {\displaystyle }{\widehat{\mathbf{S}}}^{-\mathrm{1}}=\mathit{\gamma }{\mathbf{K}}^T{\mathbf{S}}_{\mathrm{O}}^{-\mathrm{1}}\mathbf{K}+{\mathbf{S}}_{\mathrm{A}}^{-\mathrm{1}},\text{4}& {\displaystyle }\mathbf{A}=\mathbf{I}-\widehat{\mathbf{S}}{\mathbf{S}}_{\mathrm{A}}^{-\mathrm{1}},\end{array}$$ where $\mathbf{I}$ is the identity matrix. The averaging kernel matrix $\mathbf{A}$ defines the sensitivity of the posterior solution to the true state, and the diagonal terms of $\mathbf{A}$ are the averaging kernel sensitivities diagnosing the ability of the inversion to quantify emissions for the corresponding state vector elements independently of the prior estimates. The trace of $\mathbf{A}$ quantifies the degrees of freedom for the signal (DOFS), representing the number of independent pieces of information that can be effectively optimized in the inversion (Brasseur and Jacob, 2017).

The regularization term $\mathit{\gamma }$ is intended to account for unresolved observational error covariances in the inversion and thus to avoid overfit to observations. Following Lu et al. (2021), we choose $\mathit{\gamma }$ such that ${\left(\widehat{\mathit{x}}-{\mathit{x}}_{\mathrm{A}}\right)}^T{\mathbf{S}}_{\mathrm{A}}^{-\mathrm{1}}\left(\widehat{\mathit{x}}-{\mathit{x}}_{\mathrm{A}}\right)\approx n$, where $n$ is the number of state vector elements, as would be expected from a chi-squared distribution with $n$ degrees of freedom. This yields $\mathit{\gamma }$ in the range 0.1–0.4 with a best estimate of 0.2 (Fig. S7). We previously found a similar range of $\mathit{\gamma }$ using the $L$-curve method in a previous regional inversion of TROPOMI data for eastern Mexico (Shen et al., 2021).

Figure 2

Corrections to oil and natural gas methane emissions in the US EPA and Canadian ECCC national inventories from the inversion of TROPOMI methane observations (May 2018–February 2020). (a) Posterior correction factors to the gridded national inventory estimates shown in Fig. 1b and used as prior estimates in the inversion. The boundaries of the 19 major $\mathrm{O}/\mathrm{G}$ basins are shown on the map, and the names of these basins can be found in Fig. S11. (b) Posterior $\mathrm{O}/\mathrm{G}$ methane emissions. For panels (a) and (b), grid cells with prior $\mathrm{O}/\mathrm{G}$ emissions $\mathit{<}\mathrm{0.1}$ metric ton a${}^{-\mathrm{1}}$ km${}^{-\mathrm{2}}$ are shown in white (consistent with Fig. 1b). (c) Prior and posterior emissions in the 19 oil and gas basins, arranged in decreasing order of posterior emissions. Delaware is a subregion of the Permian Basin. Vertical bars indicate the $\mathrm{2}\times$ error standard deviations from the inversion ensemble. Striped bars for the Permian and Delaware basins show the results of an inversion where the prior estimate of emissions from the oil and gas production sector was increased by a factor of 4 from the EPA inventory, reflecting previous evidence that the EPA inventory is too low.

[Figure omitted. See PDF]

We evaluate the inversion by comparing the column-averaged methane from TROPOMI to GEOS-Chem simulations using prior and posterior estimates (Fig. S8). The prior simulation has a negative bias of 10–15 ppb across most $\mathrm{O}/\mathrm{G}$ basins and a positive bias of 10–20 ppb in the central and eastern US. GEOS-Chem simulations based on posterior estimates (as shown in Fig. 2) can reduce the negative bias to 0–10 ppb in most $\mathrm{O}/\mathrm{G}$ basins, and especially in the southwestern US, where the TROPOMI observation frequency is high (Figs. S2 and S9).

Following Shen et al. (2021), we write the sectorial posterior correction for each grid cell as $$\begin{array}{}\text{5}& {\displaystyle }{f}_i={\displaystyle \frac{\mathit{\eta }{\mathit{\alpha }}_i{\mathit{\sigma }}_{i,\mathrm{nation}}^{\mathrm{2}}\left(f_{\mathrm{0}}-\mathrm{1}\right)}{{\mathit{\sigma }}_{\mathrm{0}}^{\mathrm{2}}}}+\mathrm{1}\left(\mathrm{1}\le i\le M\right),\text{6}& {\displaystyle }\mathit{\eta }={\displaystyle \frac{{\mathit{\sigma }}_{\mathrm{0}}^{\mathrm{2}}}{{\sum }_{i=\mathrm{1}}^M{\mathit{\alpha }}_i^{\mathrm{2}}{\mathit{\sigma }}_{i,\mathrm{nation}}^{\mathrm{2}}}},\end{array}$$ where ${\mathit{\alpha }}_i$ is the local fraction of emissions of each sector $i$ taken from the prior and $f_i$ is the posterior correction factor for that sector in this grid cell, $f_{\mathrm{0}}$ is the posterior scaling factor for that state vector element, ${\mathit{\sigma }}_{\mathrm{0}}$ is the prior error standard deviation, $M$ is the number of source sectors, and ${\mathit{\sigma }}_{i,\mathrm{nation}}$ refers to the error standard deviations in the national totals obtained from Maasakkers et al. (2016) and Bloom et al. (2017). The posterior correction factor will be adjusted more for a specific sector if this sector has a higher percentage in the prior emissions and higher prior uncertainty.

2.6 Inversion ensemble and uncertainty analysis

Starting from the baseline inversion as described above, we conducted an ensemble of sensitivity inversions to test the robustness of our results to different inversion parameters and selection of TROPOMI observations. The 24-member ensemble includes (1) setting the regularization factor $\mathit{\gamma }$ to 0.1 and 0.4 (0.2 in the baseline), (2) increasing the prior $\mathrm{O}/\mathrm{G}$ emissions by 50 % (EPA and ECCC in the baseline), (3) a prior error standard deviation of 75 % (50 % in the baseline), and (4) removing TROPOMI data with shortwave infrared albedo $\mathit{<}\mathrm{0.05}$ (12 % of total TROPOMI observations). The posterior covariance matrix $\widehat{\mathbf{S}}$ describes the error within the choice of each set of inversion parameters, and the ensemble allows us to explore the uncertainty arising from the selection of these inversion parameters. We use the Monte Carlo method to estimate the posterior uncertainty from the ensemble. For each of the 24 members, we generate 100 samples from the posterior distribution, which yields 2400 samples in total for each grid cell. We report error statistics on the inversion results as 2 standard deviations ($\mathrm{2}\mathit{\sigma }$) corresponding to the 95 % confidence level.

3 Quantification of oil and natural gas emissions in the US and Canada using TROPOMI

Figure 1a shows the spatial distribution of the TROPOMI column-averaged dry-air mole fraction of methane (XCH${}_{\mathrm{4}}$) (Lorente et al., 2021) in the US and Canada from May 2018 to February 2020. The data shown in Fig. 1a are corrected for topography following Kort et al. (2014), but this correction is not used in the inverse analysis because the GEOS-Chem forward model accounts for topography. The largest values are along the southeastern coastal areas and the Mississippi River, where wetland emissions are the dominant source (Fig. S10). Anthropogenic enhancements are also apparent in $\mathrm{O}/\mathrm{G}$ basins, including the Central Valley in California, the Permian Basin, the Anadarko Basin, the Dallas–Fort Worth–Barnett Shale area, and southwestern Pennsylvania. Figure 1b shows the bottom-up $\mathrm{O}/\mathrm{G}$ methane emissions from the US and Canada in 2018 based on the gridded versions of the EPA and ECCC national inventories (Maasakkers et al., 2016; Scarpelli et al., 2022), which are used as prior estimates in our inversion framework. Here the original gridding of US EPA emissions for the year 2012 (Maasakkers et al., 2016) has been extrapolated to 2018 on the basis of the updated national inventory (EPA, 2020) and updated information about $\mathrm{O}/\mathrm{G}$ wells (Enverus DrillingInfo, 2020).

Figure 2a shows the optimized posterior correction factors for $\mathrm{O}/\mathrm{G}$ emissions relative to the EPA and ECCC inventories (Fig. 1b). Figure 2b shows the corresponding posterior emissions, and Fig. 2c shows the results for the 19 $\mathrm{O}/\mathrm{G}$ basins (more details can be found in Fig. S11). Although the national maps show patterns of upward and downward correction factors, emissions for the 19 $\mathrm{O}/\mathrm{G}$ basins show general increases except for parts of the Marcellus Basin in southwestern Pennsylvania, California's Central Valley, and the Denver–Julesburg Basin. Emissions are dominated by a small number of basins where the correction factors to the national inventories are in excess of 2, except for the Marcellus Basin. The Permian Basin is the largest basin-wide source (2.9 Tg a${}^{-\mathrm{1}}$), a factor of 4.7 larger than the 0.62 Tg a${}^{-\mathrm{1}}$ in the extrapolated gridded EPA inventory, and accounts for 25 % of total US $\mathrm{O}/\mathrm{G}$ emissions in the posterior estimate. The average posterior uncertainty is 20 % ($\mathrm{2}\mathit{\sigma }$) for the first 9 largest $\mathrm{O}/\mathrm{G}$ basins and 34 % ($\mathrm{2}\mathit{\sigma }$) for the 10 smaller ones, indicating that TROPOMI can more effectively quantify the emissions from the larger basins.

The underestimate of emissions by the gridded EPA inventory in the Permian has been pointed out before using satellite observations, including TROPOMI (Zhang et al., 2020), GOSAT (Maasakkers et al., 2021), point source imagers (Irakulis-Loitxate et al., 2021), and field studies (Lyon et al., 2021), and attributed in part to rapidly increasing oil and gas production (Zhang et al., 2020). Increasing our prior estimate of emissions in the Permian from 0.62 to 2.2 Tg a${}^{-\mathrm{1}}$ to reflect this knowledge increases our posterior estimate by 30 % to 3.7 Tg a${}^{-\mathrm{1}}$ (Fig. 2c, more details in Fig. S12), a relatively small response reflecting the strong information available from TROPOMI observations. Splitting the TROPOMI observations into two periods, and with prior estimates of 0.62–2.2 Tg a${}^{-\mathrm{1}}$, we find posterior emissions of 2.5–3.4 Tg a${}^{-\mathrm{1}}$ for May 2018–March 2019 and 3.0–3.8 Tg a${}^{-\mathrm{1}}$ for April 2019–February 2020, indicating an increase over the period. The $\mathrm{O}/\mathrm{G}$ emissions in the Delaware subbasin increase from 0.83 to 0.97 Tg a${}^{-\mathrm{1}}$ in response to the changes in prior emissions from 0.12 to 0.45 Tg a${}^{-\mathrm{1}}$. Assuming an average methane content of 80 % for this natural gas, our posterior emission range of 2.9–3.7 Tg a${}^{-\mathrm{1}}$ corresponds to a 3.5 %–4.6 % loss rate (natural gas production in the Permian was $\mathrm{5.4}\times {\mathrm{10}}^{\mathrm{6}}$ MMcf from May 2018 to February 2020; Enverus DrillingInfo, 2020).

Figure 3

Bottom-up and top-down estimates of national oil and natural gas methane emissions in the US and Canada. Estimates from this work are shown as quantile plots for the inversion ensemble. The top and bottom of the box are the 25th and 75th percentiles, the vertical bars are for the minimum and maximum, and the center line is the 50th percentile. Mean emissions $\pm \mathrm{2}$ standard deviations from the inversion ensemble are $\mathrm{12.6}\pm \mathrm{2.1}$ Tg a${}^{-\mathrm{1}}$ for the US and $\mathrm{2.2}\pm \mathrm{0.6}$ Tg a${}^{-\mathrm{1}}$ for Canada. Symbols show previous estimates, including EPA (2020) for 2018 (which equals the prior estimate for our work), EDGAR v6.0 (Crippa et al., 2020) for 2018, Alvarez et al. (2018) for 2015, Maasakkers et al. (2021) for 2010–2015, Lu et al. (2022) for 2010–2017, ECCC (2020) for 2018 (used as the prior estimate for our work), Baray et al. (2021) for 2010–2015, and Chan et al. (2020) for 2010–2017. Maasakkers et al. (2021) and Lu et al. (2022) did not include the $\mathrm{O}/\mathrm{G}$ emissions in Alaska, so we add 0.1 Tg a${}^{-\mathrm{1}}$ of emissions (EPA, 2020; Maasakkers et al., 2016) here to obtain the US national total.

[Figure omitted. See PDF]

We derive national totals for $\mathrm{O}/\mathrm{G}$ emissions in the US and Canada by aggregating the posterior emissions from Fig. 2 and retaining the prior EPA and ECCC estimates for 0.2 Tg a${}^{-\mathrm{1}}$ of $\mathrm{O}/\mathrm{G}$ emissions outside the inversion domains (including Alaska). Figure 3 compares our results to previous studies, most of which are for emissions before 2017. Our satellite-derived US estimate in 2018–2020 is $\mathrm{12.6}\pm \mathrm{2.1}(\pm \mathrm{2}\mathit{\sigma })$ Tg a${}^{-\mathrm{1}}$, which is 80 % higher than the bottom-up inventory reported by the EPA (EPA, 2020) and the Emissions Database for Global Atmospheric Research (EDGAR version v6.0) (Crippa et al., 2020). About 70 % of this underestimate is from five $\mathrm{O}/\mathrm{G}$ basins, including Permian, Haynesville, Anadarko, Eagle Ford, and Barnett, which are in total responsible for 40 % of US $\mathrm{O}/\mathrm{G}$ emissions (Fig. 2). Our US national estimate is comparable to the facility-based estimate for 2015 by Alvarez et al. (2018) that can better account for the heavy-tailed emissions and that was found to be consistent with aircraft measurements. We find lower emissions than Alvarez et al. (2018) in Denver–Julesburg, Fayetteville, Uinta, West Arkoma, San Juan, and northeastern Pennsylvania, which could be due to decreasing $\mathrm{O}/\mathrm{G}$ production in these basins (Fig. S13). This is offset by fast-growing emissions in the Permian, where the $\mathrm{O}/\mathrm{G}$ production almost doubled from 2015 to 2019 (Enverus DrillingInfo, 2020; Zhang et al., 2020). Our US national estimate for $\mathrm{O}/\mathrm{G}$ emissions is also comparable to previous inversions of GOSAT and in situ data for 2010–2017 (Maasakkers et al., 2021; Lu et al., 2022) and to Lu et al. (2022) reporting increasing emissions in the oil-producing basins but decreasing emissions in gas-producing basins over the period. When normalized by annual natural gas production ($\mathrm{4.1}\times {\mathrm{10}}^{\mathrm{7}}$ MMcf, US EIA, assuming the average CH${}_{\mathrm{4}}$ content is 80 %) in 2019, the national $\mathrm{O}/\mathrm{G}$ mean leakage rate (including all $\mathrm{O}/\mathrm{G}$ sectors) inferred from our work is 2.0 % in the US.

Our top-down estimate in Canada is $\mathrm{2.2}\pm \mathrm{0.6}(\pm \mathrm{2}\mathit{\sigma })$ Tg a${}^{-\mathrm{1}}$, which is 40 % higher than the most recent ECCC-reported emissions (ECCC, 2020) and EDGAR v6 (Crippa et al., 2020) in 2018 and is at the lower end of other top-down studies (2.3–3.6 Tg a${}^{-\mathrm{1}}$) for 2010–2017 (Baray et al., 2021; Maasakkers et al., 2021; Chan et al., 2020; Lu et al., 2022). When normalized by annual natural gas production ($\mathrm{7.1}\times {\mathrm{10}}^{\mathrm{6}}$ MMcf, UNFCC https://unfccc.int/documents/271492 (last access: 1 May 2021), assuming the average CH${}_{\mathrm{4}}$ content is 90 %) in 2019, the national $\mathrm{O}/\mathrm{G}$ mean leakage rate is 1.8 % in Canada.

We also calculated posterior emissions from the $\mathrm{O}/\mathrm{G}$ sector using TROPOMI observations in different seasons. Here the prior $\mathrm{O}/\mathrm{G}$ emissions remain constant over different seasons, so any changes in the posterior correction factors are determined by the inversion of the satellite data. Overall, the spatial distributions of posterior correction factors in spring, summer, and fall are consistent with that using the year-round data, especially in the south, where TROPOMI observation density is high (Fig. S2). The posterior corrections from using wintertime data are slightly different in Canada and the northeastern US because of the low observation density and low averaging kernel sensitivities (Fig. S14).

Figure 4

Methane emissions from 14 oil and natural gas production basins in the US. Estimates from field campaigns are compared to the gridded EPA and ECCC inventories for the US and Canada (a) and to results from our TROPOMI inversion using these inventories as prior estimates (b). The $\mathrm{1}:\mathrm{1}$ line is dashed, and correlation coefficients ($R$) are shown in the inset. More details, including references for the field campaigns, can be found in Table S1. Circles represent the same nine basins in Alvarez et al. (2018), and triangles are the new basins included in this study.

[Figure omitted. See PDF]

A unique feature of our work is the use of satellite observations to quantify emissions at high resolution for individual $\mathrm{O}/\mathrm{G}$ basins, building up to the national scale for the US and Canada. A number of aircraft and ground-based field campaigns previously estimated emissions from individual basins (Table S1). These field campaigns were carried out between 2013 and 2020 (with many of those field measurements taken before 2015), whereas our satellite observational period is for 2018–2020, which could affect the comparison. Intermittency of emissions is another factor that would affect the interpretation of results from field campaigns (Cusworth et al., 2021; Varon et al., 2021). Figure 4 compares the basin-scale emission estimates from these field campaigns to the gridded EPA and ECCC inventories and to our TROPOMI inversion results. The inventories are consistently lower by a factor of 1.5–3. Results from our TROPOMI inversion are more consistent with the field campaigns, especially for the large $\mathrm{O}/\mathrm{G}$ basins ($\mathit{>}\mathrm{0.5}$ Tg a${}^{-\mathrm{1}}$) such as the Permian, its Delaware subbasin, Haynesville, and Barnett. The correlation coefficient ($R$) between TROPOMI-derived posterior estimates and field measurements is 0.96 compared to 0.85 for the EPA and ECCC inventories. Overall, the results offer quantitative support of our TROPOMI inversion for high-emitting basins ($\mathit{>}\mathrm{0.5}$ Tg a${}^{-\mathrm{1}}$) but suggest that TROPOMI measurements provide only a limited constraint on the emission quantification of lesser-emitting basins. We examine below more broadly the parameters governing the capability of TROPOMI to quantify basin-scale emissions.

5

Assessing the quantification efficacy of TROPOMI for $\mathrm{O}/\mathrm{G}$ basins

TROPOMI is designed to quantify emissions on a regional scale, and a critical question for methane emission controls is whether it can do so at the scale of individual $\mathrm{O}/\mathrm{G}$ basins. Results in Figs. 2c and 4 indicate successful quantification of basin-scale emissions exceeding 0.5 Tg a${}^{-\mathrm{1}}$. The inherent TROPOMI limitations can be understood by examining the averaging kernel (AK) sensitivities of our inversion system. The AK sensitivities (diagonal terms of the AK matrix) measure the ability of the inversion to quantify the true emissions independently of the prior estimate ($\mathrm{1}$: fully, $\mathrm{0}$: not at all). Our inversion assumes a fixed (50 %) prior emission error standard deviation on the $\mathrm{0.25}\times \mathrm{0.3125}{}^{\circ }$ grid, so that absolute prior errors scale with the magnitude of emissions and decrease with the size of the basin. On the other hand, observational errors as estimated by the residual error method (Heald et al., 2004) generally remain in the 10–20 ppb range for individual observations and decrease with the number of observations. It follows that the ability of our TROPOMI inversion to quantify basin-scale emissions increases with the magnitude of emissions and with the number of observations. The observation density is highest in the southwestern US, where TROPOMI retrievals are most often successful (arid regions, clear skies, homogeneous surfaces), and thus the AK sensitivities are highest for $\mathrm{O}/\mathrm{G}$ fields in those regions and in particular for the Permian Basin (Figs. S2 and S9). We also estimate the relative error reduction from prior to posterior estimates, and our results show that the uncertainty decreases by an average of 40 % (0 %–80 %) across the 19 $\mathrm{O}/\mathrm{G}$ basins (Fig. S15).

Figure 5

Relationship of the relative standard deviation (we use $\mathrm{2}\mathit{\sigma }$ here) of satellite-derived posterior estimates with different variables, including (a) the number of TROPOMI observations per year, (b) the satellite observation density, (c) prior emissions, (d) posterior emissions, and (e) averaging kernel sensitivities. The correlation coefficients are shown in the inset. The boundaries of the 19 $\mathrm{O}/\mathrm{G}$ basins are overlain on the map, and the names of these basins can be found in Fig. S11.

[Figure omitted. See PDF]

We examined more broadly the variables influencing the ability of our TROPOMI-based inversion system to quantify emissions at the basin scale. These variables include (a) emissions (prior and posterior emissions), (b) the number of satellite observations, and (c) other geophysical properties and satellite retrieval parameters (e.g., the albedo, surface altitude, or surface roughness). Of all these variables, emissions and the number of satellite observations show the strongest correlation with the posterior uncertainty for the 19 $\mathrm{O}/\mathrm{G}$ basins; the correlation coefficient $R$ can be as high as $-\mathrm{0.7}$, a result consistent with AK sensitivities (Fig. 5, more details in Fig. S16). Results across these $\mathrm{O}/\mathrm{G}$ basins show that our inversion framework can quantify area methane emissions with an average uncertainty below 30 % if the emission rates exceed 0.2 Tg a${}^{-\mathrm{1}}$ and the number of observations exceeds 5000 a${}^{-\mathrm{1}}$. If we normalize the number of observations by the basin area, it suggests that our inversion framework can quantify large basin-scale sources where the satellite data density is greater than 0.3 counts km${}^{-\mathrm{2}}$ a${}^{-\mathrm{1}}$ (Fig. 5). This encompasses many $\mathrm{O}/\mathrm{G}$ fields at mid-latitudes, though $\mathrm{O}/\mathrm{G}$ fields in the tropics are more of a challenge because they are often collocated with wetlands (Nigeria, Venezuela) and therefore have extensive cloudiness (Fig. S17). For areas with lower data density, a reliable quantification may need the support of other observations (e.g., other satellites, field measurements) or more accurate facility-scale information. From the data in Fig. 5, the basin-scale posterior relative uncertainty (%) of our inversion framework can be estimated using the following equation: 7$$z=-\mathrm{15}{\log }_{\mathrm{10}}{\mathit{x}}_{\mathrm{1}}-\mathrm{13}{\mathit{x}}_{\mathrm{2}}-\mathrm{17}\left(R^{\mathrm{2}}=\mathrm{0.53}\right),$$ where $z$ is the posterior relative uncertainty (%), ${\mathit{x}}_{\mathrm{1}}$ is the bottom-up emission (Tg a${}^{-\mathrm{1}}$) for the basin, and ${\mathit{x}}_{\mathrm{2}}$ is the satellite data density (in counts km${}^{-\mathrm{2}}$ a${}^{-\mathrm{1}}$).

We further test this conclusion by examining 1000 pseudo-basins that are generated randomly with varying locations and area sizes (Fig. S18) in the US and Canada. Unlike the 19 $\mathrm{O}/\mathrm{G}$ basins that are usually located in arid regions with denser observations, these 1000 pseudo-basins can encompass more complicated satellite-observing conditions and sectorial emission constitutions. As seen from Fig. S19, our inversion framework can constrain the posterior $\mathrm{O}/\mathrm{G}$ emissions with an uncertainty $\mathit{<}\mathrm{30}$ % in areas with $\mathrm{O}/\mathrm{G}$ emission rates >0.2–0.5 Tg a${}^{-\mathrm{1}}$, and the number of observations is higher than $\mathrm{5}\times {\mathrm{10}}^{\mathrm{3}}$ a${}^{-\mathrm{1}}$. Our result suggests that TROPOMI can be useful in assessing large-area sources with emissions exceeding 0.2–0.5 Tg a${}^{-\mathrm{1}}$ and observation counts exceeding 5000 a${}^{-\mathrm{1}}$.

In summary, we have shown that TROPOMI satellite observations can successfully quantify methane emissions from the oil and natural gas ($\mathrm{O}/\mathrm{G}$) sector in the US and Canada and resolve the contributions from individual production basins. This involved inversions of TROPOMI observations for 22 months (May 2018–February 2020) at $\mathrm{0.25}\times \mathrm{0.3125}{}^{\circ }$ resolution in the $\mathrm{O}/\mathrm{G}$ production basins and other $\mathrm{O}/\mathrm{G}$-emitting grid cells, accounting for over 98 % of total $\mathrm{O}/\mathrm{G}$ emissions in the continental US EPA and Canadian ECCC national inventories used as prior estimates for the inversion. We conducted an ensemble of inversions to determine the sensitivity of results to different weightings of observations, different prior estimates and associated uncertainties, and the addition of data-quality filters. We find that national methane emissions from the $\mathrm{O}/\mathrm{G}$ sector are $\mathrm{12.6}\pm \mathrm{2.1}(\pm \mathrm{2}\mathit{\sigma })$ Tg a${}^{-\mathrm{1}}$ in the US and $\mathrm{2.2}\pm \mathrm{0.6}(\pm \mathrm{2}\mathit{\sigma })$ Tg a${}^{-\mathrm{1}}$ in Canada, which are 80 % and 40 % higher than the national bottom-up inventories, respectively. About 70 % of the discrepancy in the EPA inventory can be attributed to five $\mathrm{O}/\mathrm{G}$ basins, the Permian, Haynesville, Anadarko, Eagle Ford, and Barnett basins, which in total account for 40 % of US emissions. Our satellite-derived emission estimates show good consistency with in situ field measurements for large $\mathrm{O}/\mathrm{G}$ basins with emissions higher than 0.5 Tg a${}^{-\mathrm{1}}$. Further examination of the error budget of the inversion suggests that the TROPOMI observations can quantify emission rates with an uncertainty (2$\mathit{\sigma }$) better than 30 % in areas with emissions exceeding 0.2–0.5 Tg a${}^{-\mathrm{1}}$ and observation counts exceeding 5000 a${}^{-\mathrm{1}}$. Many large $\mathrm{O}/\mathrm{G}$ basins at mid-latitudes meet these criteria for successful source quantification.