1 Introduction

Measurements of the emission rate of a gas or gases from point and area sources are important in a range of monitoring applications. Several examples include measurement of emissions of CH${}_{\mathrm{4}}$ and volatile organic compounds (VOCs) from oil and gas facilities (well pads, compressor stations, processing plants, etc.) as well as from landfills and composting facilities; CH${}_{\mathrm{4}}$ and N${}_{\mathrm{2}}$O (as well as VOCs) from wastewater treatment plants; CH${}_{\mathrm{4}}$, NH${}_{\mathrm{3}}$, and N${}_{\mathrm{2}}$O from agricultural sites; and VOCs from industrial facilities. In all these examples, there are several important challenges for a measurement system. First, it is desirable to be able to measure emissions of multiple gases simultaneously. Second, the measurement system should be able to handle complex sources such as distributed sources or colocated sources. Finally, it is often desirable to be able to rapidly survey different sources to determine if emissions are present and then to quantify the emissions.

Because of the fundamental importance of emission rate measurements in monitoring and regulation, there is a wide range of different measurement methods that have been developed, all with distinct advantages and disadvantages. We cannot exhaustively review all the techniques here, but instead highlight a few general classes of techniques. The first are ground-based survey techniques with a point sensor (Vaughn et al., 2017; Zhang et al., 2019; Ravikumar et al., 2019; Riddick et al., 2022). One limitation of these techniques is that the vertical distribution of the gas is not measured, so assumptions need to be made about the vertical and horizontal gas dispersion (using an atmospheric transport model). The transport assumptions can be removed by releasing a tracer gas colocated with the unknown emission source (Czepiel et al., 1996; Mønster et al., 2014; Roscioli et al., 2015); however, this requires access to and knowledge of the emission source. To circumvent these challenges, mass balance approaches can be used by measuring in two dimensions, which greatly relaxes the requirements for the transport model. Most frequently, mass balance is performed using point sensors on aircraft (White et al., 1976; Alfieri et al., 2010; Karion et al., 2013; Conley et al., 2017). While effective for large sources, challenges such as flight altitude restrictions, cost, and the requirement for fast sensors can limit applicability and repeat measurements. More recently, uncrewed aerial vehicles (UAVs) have been used for small-scale mass balance (Golston et al., 2018; Gålfalk et al., 2021; Zondlo, 2021; Reuter et al., 2021), although not many sensors meet the precision or size, weight, and power requirements to deploy in this fashion. Long open-path measurements to a UAV were very recently used in conjunction with a Gaussian plume model to determine an emission rate from a point source (Soskind et al., 2023). Finally, several mass balance approaches have been demonstrated using column-integrated measurements including solar occultation flux (which can only be used during daytime or sunny conditions) (Mellqvist et al., 2010; Kille et al., 2017) and airborne lidar (which has focused on methane or carbon dioxide) (Ravikumar et al., 2019; Amediek et al., 2017; Bell et al., 2022; Kunkel et al., 2023; Johnson et al., 2021). There are two significant distinctions between these lidar approaches and the approach discussed here. First, lidar systems are mounted on a larger aircraft, which has added cost and complications but does not require a van and can more easily cover a large area. Second, lidar targets a single species, which is well suited to finding methane leaks in an oil or gas field, for example, while the system here relies on broadband dual-comb spectroscopy that can detect multiple species. If used in conjunction with a mid-infrared dual-comb system, this approach could then simultaneously detect multiple volatile organic compounds beyond methane.

Here, we demonstrate a new mobile micrometeorological mass balance method using a line-integrated sensor (in this case, open-path dual-comb spectroscopy or DCS) in combination with an uncrewed aerial vehicle. This is accomplished by measuring slant columns to a moving UAV that carries a small retroreflector downwind of an emission source as shown in Fig. 1. We test this technique using controlled releases of CH${}_{\mathrm{4}}$ and C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ from both a point source and a small area. A key strength of this technique – and other mass balance techniques – is that it does not rely on a dispersion model. In principle this approach is also compatible with any open-path laser measurement, such as tunable diode laser spectroscopy (Plant et al., 2015; Bailey et al., 2017; Dobler et al., 2017; Bai et al., 2022), but here we use a frequency comb to allow for simultaneous multispecies detection (Coddington et al., 2016; Cossel et al., 2021; Picqué and Hänsch, 2019). For example, while CH${}_{\mathrm{4}}$ and C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ measurements are demonstrated here, open-path dual-comb spectroscopy has been used to retrieve a host of interesting species including CO${}_{\mathrm{2}}$, NH${}_{\mathrm{3}}$, HDO, ethane, formaldehyde (HCHO), CO, and N${}_{\mathrm{2}}$O (Waxman et al., 2017; Ycas et al., 2019; Giorgetta et al., 2021; Herman et al., 2021).

2 Experimental setup

This method builds on our previous demonstration of spatially scanned DCS (Cossel et al., 2017), which is summarized in Fig. 1a. The primary components of the system (Fig. 1b) are the dual-frequency combs, a transmit–receive terminal that sends light over a long open-air path, and a mobile reflector on a quadcopter.

Figure 1

(a) Overview of the experimental concept. The DCS system measures integrated slant columns to a moving UAV. By performing survey scans, the presence and angular position of an emissions source can be rapidly determined. Mass balance scans downwind of the source then enable quantification of the emissions. (b) Details of the experimental setup. Light from the dual-frequency combs is combined in fiber, then launched out of a transmit–receive telescope system located on an azimuth–elevation gimbal to a retroreflector located on a UAV at a typical distance of 200 m. The return light from the retroreflector is separated with a $\mathrm{50}:\mathrm{50}$ beam splitter and measured on a photodetector (PD). This signal is digitized and averaged with a field-programmable gate array (FPGA)-based acquisition system. The lower part of (b) shows the van in the field as well as a photo of the UAV with the retroreflector and sonde (see also Appendix A.)

[Figure omitted. See PDF]

Here, we use robust erbium-doped fiber-based frequency combs operating in the near-infrared (Waxman et al., 2017). The design and operation of these combs have been described in detail previously (Truong et al., 2016). Briefly, the frequency combs have a nominal repetition rate of 200 MHz and a repetition rate difference of $\mathit{\delta }{f}_{\mathrm{rep}}=$ 625 Hz. The combs are both stabilized to a crystal oscillator and continuous-wave reference laser at 1560 nm to maintain mutual coherence between the combs. After amplification, spectral broadening, and spectral filtering to cover bands for C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ (1520–1540 nm) and CH${}_{\mathrm{4}}$ (1610–1670 nm), the light from the two combs is combined in fiber and then launched from a transmit–receive telescope (76.2 mm diameter aperture) to a retroreflector (62.5 mm diameter) located on a UAV (here, a quadcopter). Return light from the retroreflector is collected with the same telescope and reflected off a $\mathrm{50}:\mathrm{50}$ beam splitter to a photodetector. Alignment with the retroreflector is maintained by an image-processing-based pointing servo using an 850 nm LED and Si CMOS camera co-aligned with the main telescope (Cossel et al., 2017). The return power was typically 100–200 $\mathrm{\mu }\mathrm{W}$ with 10 %–20 % power fluctuations between each measured spectrum as well as larger “dropouts” and power drifts due to alignment issues such as sudden UAV movement or yaw of the UAV. These dropouts were usually $<$ 10 % of a single flight. Figure 1b shows a more detailed view of the UAV. In addition to the retroreflector, the UAV also carries several sondes to measure temperature, pressure, humidity, and GPS location, as well as real-time kinematic (RTK) GPS for high-precision relative GPS location of the UAV. However, sufficient location precision was provided by the onboard GPS, so that is used for most of the data presented here. For field operations, the DCS system is housed in a van and connected via fiber to a telescope and fast azimuth–elevation gimbal located at the back of the van as pictured in Fig. 1b. Wind speed and direction were measured with a 3D sonic anemometer located away from the van at $\sim$ 2 m above ground. Additional meteorological parameters (temperature, pressure, independent wind speed and direction) were recorded by a weather station with a 2D sonic anemometer located above the van roof. This second wind measurement was used for redundancy and to verify the 3D sonic measurements. Finally, we measured CH${}_{\mathrm{4}}$ concentrations with a commercial cavity ring-down spectrometer (CRDS) that sampled air from above the roof of the van. This spectrometer was calibrated at the NOAA Global Monitoring Laboratory to provide WMO-traceable CH${}_{\mathrm{4}}$ measurements, which we use to determine the background CH${}_{\mathrm{4}}$ concentration during flights.

The dual-comb signal on the receive photodetector is a time domain interferogram (IGM) that repeats at a rate of $\mathit{\delta }{f}_{\mathrm{rep}}$. We digitize this signal and co-add using a field-programmable gate array (FPGA). Sequential sets of 10 000 IGMs are co-added (with phase correction applied to each set of 100 sequential IGMs). In total this gives a 16 s sampling period. In post-processing, each saved IGM was converted to a transmission spectrum (Fig. 2a) via a Fourier transform and then fit with a spectral transmission model (calculated from HITRAN2008 using the measured temperatures and pressures; Rothman et al., 2009) plus a piecewise polynomial baseline term to determine total column densities for three gases: CH${}_{\mathrm{4}}$, H${}_{\mathrm{2}}$O, and C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ along the laser path, ${\stackrel{\mathrm{‾}}{\mathit{\rho }}}_{\mathrm{g}}={\int }_{\mathrm{0}}^L\mathit{\rho }\left(x,y,z\right)\mathrm{d}r$, where ${\mathit{\rho }}_{\mathrm{g}}(x,y,z)$ is the spatially varying density of the gas, $r$ is the position along the path, and dr is the differential path length (Waxman et al., 2017; Cossel et al., 2021). These total column densities are converted to path-averaged dry mixing ratios for CH${}_{\mathrm{4}}$ and C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ reported in parts per million (ppm) ($\mathrm{\mu }\mathrm{mol}$ mol${}^{-\mathrm{1}}$) or parts per billion (ppb) (nmol mol${}^{-\mathrm{1}}$) using the temperature and pressure from the weather station, the temporally varying path length determined from the UAV GPS location, and the DCS-measured water vapor for the dry-air correction (Waxman et al., 2017). The measurement precision is characterized by the Allan–Werle deviation of the retrieved path-averaged concentration during one flight with no gas release (thus approximately uniform mixing ratios) as shown in Fig. 2b. For this flight, the number of co-added interferograms was reduced to 2500, resulting in measurements every 4 s. At the typical measurement time of 16 s, the CH${}_{\mathrm{4}}$ precision is around 23 ppm m (57 ppb for a round-trip path length of 400 m). This performance is similar to that obtained from Waxman et al. (2017) – 50 ppb extrapolated to the same measurement time and path length – indicating very little degradation due to motion of the UAV.

Figure 2

(a) Example normalized transmission spectrum (10 min average). C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ is retrieved in the band around 1540 nm and CH${}_{\mathrm{4}}$ is retrieved in the band around 1640 nm. A simulated transmission spectrum for both gases is shown along the top to guide the eye. The slower undulating structure in the spectra is stable over short times and results from the supercontinuum generation and spectral etalons in the system. (b) Allan deviation of ${\stackrel{\mathrm{‾}}{\mathit{\rho }}}_{\mathrm{g}}$ for both CH${}_{\mathrm{4}}$ and C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ at ambient concentration from one flight. The round-trip path length was around 400 m.

[Figure omitted. See PDF]

Flights were performed across 4 different days. Each flight had a maximum duration of $\sim$ 10 min. Several different flight patterns were used; here we focus on horizontal and vertical scans. The UAV was manually piloted for all the flights. Several different leak locations and arrangements were used in order to mimic emission sources that might be observed in the field. Controlled releases of CH${}_{\mathrm{4}}$ and C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ were located $\sim$ 100 m from the van and were conducted using cylinders whose flow rate was either controlled with a mass flow controller or monitored with a flowmeter (see Appendix A for details). For CH${}_{\mathrm{4}}$, the flow rate was set to around 0.22 g s${}^{-\mathrm{1}}$. For C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$, the flow rate was set to around 0.18 g s${}^{-\mathrm{1}}$ but was only used during a subset of releases. These flow rates correspond to a leak of $\sim$ 0.7 kg h${}^{-\mathrm{1}}$ for methane, corresponding to a practical lower bound for systems detecting methane leaks in oil and gas fields (Ravikumar et al., 2019; Johnson et al., 2021; Bell et al., 2022). The flow rate for acetylene was chosen to provide a similar signal level; future tests with multiple species would be coupled with the required species-dependent sensitivity. After the flowmeter or controller, the gas was sent through a piece of PTFE tubing a few meters long whose end was located between 0 m and $\sim$ 5 m above ground level to simulate a point source emission. Small-area diffuse emissions were also simulated by puncturing the PTFE tubing every $\sim$ 30 cm and placing the tubing on the ground across a $\sim$ 2 m diameter area.

3.1 Survey scan for emissions detection

We first demonstrate rapid detection of an emission source and later quantification of its emissions. For detection, the UAV is scanned horizontally at 200 m distance from the telescope – as illustrated by the dotted grey line in Fig. 1a – resulting in measurements across a series of nearly horizontal slant paths. For this demonstration, the source emitted both CH${}_{\mathrm{4}}$ and C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ from a pole $\sim$ 5 m above ground level (AGL) located $\sim$ 100 m away from the launch–receive telescope.

To analyze the results, we calculate the path-averaged enhanced column density ($\mathrm{\Delta }{\stackrel{\mathrm{‾}}{\mathit{\rho }}}_{\mathrm{g}}$) for each gas $g$ (CH${}_{\mathrm{4}}$ and C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$), $\mathrm{\Delta }{\stackrel{\mathrm{‾}}{\mathit{\rho }}}_{\mathrm{g}}={\stackrel{\mathrm{‾}}{\mathit{\rho }}}_{\mathrm{g}}-L⟨{\mathit{\rho }}_{\mathrm{g}}⟩$, where ${\stackrel{\mathrm{‾}}{\mathit{\rho }}}_{\mathrm{g}}$ is the measured column density, $L$ is the path length, and $⟨{\mathit{\rho }}_{\mathrm{g}}⟩$ is the mean background concentration. For CH${}_{\mathrm{4}}$, the background concentration is obtained from the dry mixing ratio from the CRDS using the known air temperature, pressure, and water vapor interpolated to the DCS data timestamp. For C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$, the background concentration is set to the mean of the DCS measurements without any release. Figure 3b shows the CH${}_{\mathrm{4}}$ and C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ path-averaged concentration enhancement ($\mathrm{\Delta }{\stackrel{\mathrm{‾}}{\mathit{\rho }}}_{\mathrm{g}}/L)$ from a single flight consisting of two horizontal scans at different altitudes (scans at both altitudes are aggregated in one plot). As expected, we observe significant enhancements of CH${}_{\mathrm{4}}$ and C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ for slant paths when the UAV is immediately downwind of the emission location. The enhancements persist but decrease in amplitude as the paths move further downwind. Once the presence of an emissions source is detected with a horizontal scan, additional flights can be used for emissions quantification as discussed below. Further localization can be accomplished with more complex flight patterns (Soskind et al., 2023).

Figure 3

(a) Detection and location concept using a constant altitude horizontal scan. (b) Map of the results for CH${}_{\mathrm{4}}$ (left) and C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ (right) from a flight with both CH${}_{\mathrm{4}}$ and C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ releases. The van is located at (0, 0) and the UAV relative position is shown by the dots. For this flight, two horizontal scans were completed at 5 m and 9 m a.g.l. The release location is shown by a blue dot, and the wind direction is shown by a blue arrow. The release was at a height of $\sim$ 2 m a.g.l., and the mean wind speed was 2 m s${}^{-\mathrm{1}}$. Each measurement path is shown by a solid line, shaded by the path-averaged CH${}_{\mathrm{4}}$ or C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ enhancement over background (see text for details). For both gases, a sudden increase in the enhancement is visible $\sim$ 5 m downwind of the leak source.

[Figure omitted. See PDF]

3.2.1 Methods

In order to perform emissions rate quantification, the UAV flew a vertical profile downwind of the emissions source as illustrated in Fig. 4a. An example altitude profile recorded by the GPS on board the UAV is shown as an inset. In this case, two vertical profiles between $\sim$ 2 and 30 m above ground level were performed during a single flight. Flights were also conducted with a single vertical scan during the flight. The flight patterns result in a series of measurements of the column density (or path-integrated concentration), ${\stackrel{\mathrm{‾}}{\mathit{\rho }}}_{\mathrm{g}}\left(z\right)$, for each gas species $g$ and UAV height $z$ with 16 s integration times.

Figure 4

(a) Diagram of the measurement configuration for flux determination from an emission source. The UAV is located a distance $L$ from the DCS system and is scanned vertically with altitude above ground level given by $z$. The DCS system measures a slant column from the comb system to the UAV and back, as the UAV slowly changes altitude. The plume is transported by the wind vector denoted by $\mathit{U}$ (with the component perpendicular to the measurement plane given by ${\mathit{U}}_y$) and intersects the measurement plane a distance $d$ from the comb system. The inset shows an example UAV altitude profile (above ground level) for one flight. (b) Example data from one flight. CH${}_{\mathrm{4}}$ enhancement (top) above background versus UAV altitude. Integrated flux versus (bottom) altitude.

[Figure omitted. See PDF]

To determine the flux, $F$, we start by following other mass balance approaches (Alfieri et al., 2010; Karion et al., 2013; Mellqvist et al., 2010). With the geometry of Fig. 4, we assume the $x$ axis is defined by the path from the telescope to the UAV position projected on the ground, and the $z$ axis is vertical. We can then write the flux through a closed surface $S$ as 1$$F={∯}_S\mathrm{\Delta }\mathit{\rho }\left(x,y,z\right)\mathit{U}\cdot d\mathit{A},$$ where $\mathit{U}$ is the wind velocity vector, $d\mathit{A}$ is the incremental area of the surface, and $\mathrm{\Delta }\mathit{\rho }\left(x,y,z\right)$ is the gas density above background. If we assume a significant $y$ component to the wind velocity vector, ${\mathit{U}}_y$, then the entire plume passes through the $x$–$z$ plane. Thus, the total flux is found by integrating the enhanced concentration across the $x$–$z$ plane or 2$$F=\int \int \mathrm{\Delta }\mathit{\rho }\left(x,z\right){\mathit{U}}_y\mathrm{d}x\mathrm{d}z.$$ However, because the DCS system is measuring a slant column between a fixed point and a moving point – i.e., it measures $\mathrm{\Delta }\stackrel{\mathrm{‾}}{\mathit{\rho }}(r,\mathit{\theta })={\int }_{\mathrm{0}}^L\mathrm{\Delta }\mathit{\rho }\left(r,\mathit{\theta }\right)\mathrm{d}r$ – we convert Eq. (2) to polar coordinates and restrict the integrals to the plane shown in Fig. 4a ($\mathrm{0}\le \mathit{\theta }\le {\mathit{\theta }}_{\max }$), assuming that the end position of the UAV in both $x$ and $z$ coordinates lies beyond the plume. Then, 3$$F={\int }_{\mathrm{0}}^{{\mathit{\theta }}_{\max }}{\mathit{U}}_y{\int }_{\mathrm{0}}^L\mathit{\rho }\left(r,\mathit{\theta }\right)rdrd\mathit{\theta }.$$ Note the presence of the additional $r$ term in the integral, which means that this integral is not directly what the DCS system measures. To evaluate this, we assume that $\mathit{\rho }\left(r,\mathit{\theta }\right)=\mathrm{\Delta }\stackrel{\mathrm{‾}}{\mathit{\rho }}\left(\mathit{\theta }\right)\mathit{\delta }\left(r-d/\cos \mathit{\theta }\right)$. That is, we assume the plume is localized to intersect the measurement plane at $x=d$. Then, 4$$F={\int }_{\mathrm{0}}^{{\mathit{\theta }}_{\max }}{\mathit{U}}_y{\int }_{\mathrm{0}}^L\mathrm{\Delta }\stackrel{\mathrm{‾}}{\mathit{\rho }}\left(\mathit{\theta }\right)\mathit{\delta }\left(r-{\displaystyle \frac{d}{\cos \mathit{\theta }}}\right)rdrd\mathit{\theta }.$$ Evaluating the radial integral gives 5$$F={\int }_{\mathrm{0}}^{{\mathit{\theta }}_{\max }}{\mathit{U}}_y\mathrm{\Delta }\stackrel{\mathrm{‾}}{\mathit{\rho }}\left(\mathit{\theta }\right){\displaystyle \frac{d}{\cos \mathit{\theta }}}d\mathit{\theta }.$$ Converting back to Cartesian coordinates with $z=L_{\mathrm{0}}\tan \mathit{\theta }$ and assuming that $z\lesssim L/\mathrm{4}$ finally gives 6$$F\approx {\displaystyle \frac{d}{L_{\mathrm{0}}}}{\int }_{\mathrm{0}}^H{\mathit{U}}_y\mathrm{\Delta }\stackrel{\mathrm{‾}}{\mathit{\rho }}\left(z\right)\mathrm{d}z,$$ where $H$ is the maximum altitude. Equation (6) is derived for the delta-function plume but is valid for other plume shapes where $d$ is defined using the mass-weighted mean. In addition, it assumes that $d$ and $L_{\mathrm{0}}$ are constant through one flight. We note that the $d/L_{\mathrm{0}}$ correction is unnecessary if both the launch and reflector could be moved together, in which case Eq. (2) can be evaluated directly. We can intuitively understand the presence of the $d/L_{\mathrm{0}}$ by looking again at a narrow plume intersecting the measurement plane at $x=d$. The effective altitude range at the plume is $\frac{d}{L_{\mathrm{0}}}H$ instead of $H$; thus, we need to do a change of variable to $z^{\prime }=\frac{d}{L_{\mathrm{0}}}z$ when calculation the altitude integral.

To calculate the flux from a vertical scan, we first interpolate the auxiliary data (UAV location, wind speed and direction, CRDS CH${}_{\mathrm{4}}$) to the DCS data timestamp and filter the DCS data for low a signal-to-noise ratio (for example, if the telescope tracking lost alignment briefly). Then, we determine $\mathrm{\Delta }{\stackrel{\mathrm{‾}}{\mathit{\rho }}}_{\mathrm{g}}$ as in Sect. 3.1. Finally, Eq. (6) is numerically integrated to obtain the total flux.

The result of the numerical integration of Eq. (6) versus altitude is shown in Fig. 4b for one flight. For this flight, the CH${}_{\mathrm{4}}$ enhancement profile shows a clear peak between 0 and 10 m a.g.l., which corresponds to a rapid increase in the integrated flux. After 10 m a.g.l., the enhancement has dropped back to background levels and remains near background up to 50 m a.g.l. As expected from this enhancement profile, the integrated flux shows a steady increase from 0 to 10 m a.g.l., after which it remains relatively constant up to 50 m. The variations between 10 and 50 m are driven by measurement noise and provide an estimate of the sensitivity of the flux determination. Note that any offset between the CRDS background and the DCS background would lead to a linear slope during this period from 10 to 50 m, which is not observed in the measurements. From these data, it is also clear that a future system could dispense with the separate CRDS sensor at the van and instead use flat high-AGL measurements or measurements taken upwind of the source by, e.g., combining the scans in Figs. 3 and 4.

Flights were performed across 4 different days (see Appendix A for details of the flights used). Approximately 20 vertical profile flights were conducted; however, on several flights, the wind direction was wrong or shifted early in the flight and caused the plume to miss the measurement path. We note that this information is known in the field from of the meteorological sensors, and the measurement can simply be repeated when the wind has stabilized. In addition, on two flights, the integrated flux was still increasing at the final altitude, indicating that the slant path did not reach the top of the plume, so these flights were discarded from the analysis. In total, 16 flights had sufficient data to determine a flux. Of these, four flights were performed with no release and were evaluated to determine “background” flux. Figure 5 shows a summary of the CH${}_{\mathrm{4}}$ flux determined for these flights.

Figure 5

CH${}_{\mathrm{4}}$ and C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ flux determination for flights with a release and without a release (“background”). A single flight corresponds to a single point for CH${}_{\mathrm{4}}$ and for C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$. For each set, the mean is shown by a diamond and the standard deviation indicated by the vertical lines. The CH${}_{\mathrm{4}}$ release rate was 0.22 g s${}^{-\mathrm{1}}$ and the C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ rate was 0.18 g s${}^{-\mathrm{1}}$ as indicated by the dashed horizontal lines.

[Figure omitted. See PDF]

For the 12 flights with a CH${}_{\mathrm{4}}$ release, the mean flux determined was 0.19 $\pm$ 0.11 g s${}^{-\mathrm{1}}$ to within 1 standard deviation. The mean agrees within 15 % of the expected flux of 0.22 g s${}^{-\mathrm{1}}$, while the standard deviation indicates 56 % uncertainty for a single flight. Of these 12 flights, four flights had a point release and eight flights had a diffuse release, illustrating the capability to measure both types of emissions. No obvious differences were observed for the two release types. For these flights, the distance of the measurement plane downwind from the source varied from $\approx$ 10 to $\approx$ 60 m. The four background flights give a mean of 0.008 $\pm$ 0.014 g s${}^{-\mathrm{1}}$. We estimate the detection limit for CH${}_{\mathrm{4}}$ fluxes as twice the deviation of these background flights, or about 0.03 g s${}^{-\mathrm{1}}$. For five flights, C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ was also released at 0.18 g s${}^{-\mathrm{1}}$ with measured flux values of 0.15 $\pm$ 0.05 g s${}^{-\mathrm{1}}$, again in good agreement with the release rate. The C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ background flights give a mean of 0.008 $\pm$ 0.04 g s${}^{-\mathrm{1}}$.

The uncertainty in the flux determination is a result of several contributions. First, we note that the accuracy of the methane gas concentration measured by DCS is at the level of $\sim$ 1 % (Waxman et al., 2017) and is not a significant contribution. The uncertainty arises in the conversion of these measurements to a flux determination via Eq. (6) due to several effects. First, incorrect measurement of the background gas concentrations (for example, due to biases between two CH${}_{\mathrm{4}}$ measurement systems) could lead to an error in $\mathrm{\Delta }{\stackrel{\mathrm{‾}}{\mathit{\rho }}}_{\mathrm{g}}$ and a corresponding error in the flux. However, such a bias will result in a linear slope even without a gas flux. From the data in Fig. 4b for altitudes $>$ 10 m, we see no evidence of a linear slope. This is also true in the background flights. Again, this is not surprising given the accuracy of both DCS and the cavity ring-down spectrometer used for the background gas measurements, and we conclude that the evaluation of $\mathrm{\Delta }{\stackrel{\mathrm{‾}}{\mathit{\rho }}}_{\mathrm{g}}$ is not a significant source of uncertainty.

Errors in ${\mathit{U}}_y$ will lead directly to errors in the determined flux. We estimate an upper limit on this error by comparing the two different wind sensors. Their values of ${\mathit{U}}_y$ averaged over a 10 min flight agree to within $\pm$20 % and typically better. The difference is dominated by uncertainty in the wind speed, rather than the wind direction, given the geometry chosen here where the plume is approximately normal to the measurement plane. (The uncertainty in the wind direction, however, is important below in the determination of $d$.) The difference in ${\mathit{U}}_y$ between the anemometers is likely due to true wind differences at the location of the wind sensors. It is possible that a UAV-based wind measurement could reduce this error and improve the flux determination.

There are three sources of uncertainty associated with the value of $d$ in Eq. (1). First, errors in the source location will cause errors in the determination of $d$. Assuming a random source location uncertainty of $\mathrm{\Delta }x$, the corresponding uncertainty in $d$ will also be $\mathrm{\Delta }x$. For the measurements here, the source location was known to better than 1 m, so this uncertainty is negligible. In the case of an initially unknown source location, the approximate location will need to be determined well enough to meet the target accuracy goals based on the measurement configuration. For example, to keep this uncertainty below $\pm$20 %, the source location needs to be known to within $\pm$0.2 $d$. For the flights here with $d\approx$ 100 m, the location would need to be known within $\pm$20 m. In the case of a uniform diffuse source, the effective weighted center of the source needs to be known to this level. Second, even with a known source location, uncertainty in the wind direction $\mathrm{\Delta }\mathit{\varphi }$ will also lead to an uncertainty in $d$. There are two potential sources of wind direction errors: a static bias during one measurement between the measured wind direction at the sensor and the actual wind direction along the plume trajectory and a temporally varying difference between them. A static bias over one flight will lead to an error given by $\mathrm{\Delta }\mathit{\varphi }\times d_{\mathrm{dw}}$, where $d_{\mathrm{dw}}$ is the downwind distance between the source and the measurement plane. Following the geometry here, the downwind distances are $<$ 50 m so that a $\pm$30${}^{\circ }$ wind direction error (estimated from the mean difference between the two anemometers during different flights) corresponds to $\pm$25 m error in $d$ or $\pm$25 % error in the flux for $d=\mathrm{100}$ m. To investigate the impact of the within-flight variability, we recalculated the flux using a time-varying value of $d$ (i.e., mapping $d$ to a slowly varying function $d\left(z\right)$ within Eq. 6 using the known values of UAV altitude $z$ as a function of time). For the 10 CH${}_{\mathrm{4}}$ release flights, the change in flux was in all cases $<$ 13 %, with a change in the mean value of 1.4 %, indicating that the impact of temporally varying wind direction differences is minimal. As mentioned above, the static bias could be reduced by measuring the wind direction at the UAV itself. Furthermore, these wind-direction-related errors are minimized with longer measurement paths, which also help to reduce the impact of source location uncertainties. Third and finally, the use of $d$ in Eq. (1) relied on the assumption that the weighted centroid of the plume followed the wind direction from the source to the measurement plane. Plume dynamics are complex and there is some inherent uncertainty in the plume evolution over time. As an estimate of this effect, we assume that the plume centroid is offset on average by at most ${\mathit{\sigma }}_y$ from the expected location based on the mean wind direction. The value of ${\mathit{\sigma }}_y$ can be taken as the average beam spread in a Gaussian plume model (Seinfeld and Pandis, 2006). For typical daytime conditions with high solar insolation and $\sim$ 2 m s${}^{-\mathrm{1}}$ wind speeds (stability class “A”), ${\mathit{\sigma }}_y\approx \mathrm{15}$m, which corresponds to a $\pm$15 % error for $d=\mathrm{100}$ m. The combination of the assumed 20 % uncertainty from the source location, 25 % uncertainty from the wind direction, and 15 % uncertainty from the plume location yields a total $\sim$ 35 % uncertainty related to $d$.

Finally, Eq. (2) implicitly assumes the plume location is fixed over the measurement. However, if the vertical position of the plume changes during the measurement, then we have not truly measured the instantaneous flux of Eq. (2). Assuming a flight with vertical velocity, $V$, and a time-dependent concentration $\mathrm{\Delta }\mathit{\rho }\left(x,z,t\right)$, the actual measured quantity is

7$$F^{\prime }=\int \int \mathrm{\Delta }\mathit{\rho }\left(x,z,V^{-\mathrm{1}}z\right){\mathit{U}}_y\mathrm{d}x\mathrm{d}z,$$ where we ignore the corrections due to the slanted path since they have already been discussed. To estimate the resulting error from vertical translation of the cloud during the measurement, we use a Gaussian plume model, 8$$\begin{array}{rl}\mathrm{\Delta }\mathit{\rho }\left(x,z,t\right)=& {\displaystyle \frac{{\mathit{U}}_{y}F}{\mathrm{2}\mathit{\pi }{\mathit{\sigma }}_x{\mathit{\sigma }}_z}}\exp \left(-{\displaystyle \frac{{\left(x-x_{\mathrm{0}}\right)}^{\mathrm{2}}}{\mathrm{2}{\mathit{\sigma }}_x^{\mathrm{2}}}}\right)\\ & \exp \left(-{\displaystyle \frac{{\left(z-z_{\mathrm{0}}\left(t\right)\right)}^{\mathrm{2}}}{\mathrm{2}{\mathit{\sigma }}_z^{\mathrm{2}}}}\right),\end{array}$$ where the centroid of the two-dimensional plume position is given by $\left(x_{\mathrm{0}},z_{\mathrm{0}}\right)$ with corresponding widths ${\mathit{\sigma }}_x$ and ${\mathit{\sigma }}_y$. We write the slowly varying time dependence of the vertical position as $z_{\mathrm{0}}\left(t\right)=z_{\mathrm{0}}+\mathit{\delta }{z}_{\mathrm{0}}\left(t\right)$. To lowest order, the vertical position changes due to a small average vertical wind velocity component, ${\mathit{U}}_z$, over the roughly 2 min measurement time, giving $\mathit{\delta }{z}_{\mathrm{0}}\left(t\right)={\mathit{U}}_{z}t$ where $t=V^{-\mathrm{1}}z$. Substitution of Eq. (8) into Eq. (7) and a Taylor expansion about $\mathit{\delta }{z}_{\mathrm{0}}$ yields the fractional error of the measured quantity compared to the desired flux, 9$$\begin{array}{rl}\left|{\displaystyle \frac{F^{\prime }}{F}}-\mathrm{1}\right|=& {\displaystyle \frac{{\mathit{U}}_z}{\sqrt{\mathrm{2}\mathit{\pi }}{\mathit{\sigma }}_z^{\mathrm{3}}V}}\int z\left(z-z_{\mathrm{0}}\right)\\ & \exp \left(-{\displaystyle \frac{{\left(z-z_{\mathrm{0}}\right)}^{\mathrm{2}}}{\mathrm{2}{\mathit{\sigma }}_z^{\mathrm{2}}}}\right)\mathrm{d}z={\displaystyle \frac{{\mathit{U}}_z}{V}}.\end{array}$$ For our flights, we had chosen a relatively slow vertical velocity of $V\approx \mathrm{0.2}$ m s${}^{-\mathrm{1}}$. Based on measurements from the 3D anemometer, we find a typical vertical wind speed of $\sim$ 0.05 m s${}^{-\mathrm{1}}$, giving an error of $\sim$ 25 %.

As shown by the background flights, the uncertainty due to DCS measurement noise is expected to contribute $\pm$6 % for a CH${}_{\mathrm{4}}$ flux of 0.22 g s${}^{-\mathrm{1}}$. So, when we combine the $\pm$20 % uncertainties associated with the values of ${\mathit{U}}_y$, $\pm$35 % uncertainty in $d,$ and $\pm$25 % uncertainty from a time-dependent $z_{\mathrm{0}}$, we estimate a total estimated uncertainty of $\sim$ $\pm$50 % in the measured flux values for a single flight, which is in good agreement with the observed uncertainty. Finally, we note that the uncertainties associated with ${\mathit{U}}_y$ , $d,$ and $z_{\mathrm{0}}$ described above are statistical (driven by atmospheric variability and plume dynamics) and are thus expected to average down with multiple measurements, as observed here with the low mean bias in the flux determination.

We have demonstrated a rapid mass balance method for flux determination using path-integrated slant column measurements between a ground-based measurement system and a UAV located at varying heights above ground. Using a near-infrared dual-comb spectroscopy system, we show flux quantification of CH${}_{\mathrm{4}}$ to within 50 % with a single $<$ 10 min flight and an estimated detection limit of 0.03 g s${}^{-\mathrm{1}}$ (2$\mathit{\sigma }$), which would enable detection of emissions from 25 head of cattle or from a single pneumatic controller. It is estimated that 90 % of all oil field emissions come from sources that are 10 times larger than this limit (Brandt et al., 2016). We can also simultaneously determine C${}_{\mathrm{2}}$H${}_{\mathrm{2}}$ fluxes with similar performance. This study was designed as a proof of concept for the method. Due to available resources and other logistical considerations, as well as some equipment malfunctions, the measurements were limited in scope. The next step is to do more extensive testing over a range of release conditions, for example, at a facility such as the Methane Emissions Technology Evaluation Center (METEC) (Edie et al., 2020; Riddick et al., 2022).

This new methodology has several potential advantages compared to other flux measurement methods. First, a key advantage is that no atmospheric dispersion model is needed since the flux is determined directly from the data. This also means that multiple spatially separated sources or areal sources can also be measured, although in an area with many sources, care needs to be taken so that the background is appropriate for the sources of interest. A limitation of the specific flight pattern shown is that the source location needs to be approximately known; however, this limitation can be overcome either with a priori information (e.g., if the equipment or facility to be measured is known) or by performing spatial scans first. In addition, modified flight patterns such as flying vertically and then horizontally toward the source could likely overcome this limitation. Second, the methodology is flexible, so it can be used to determine fluxes for any gas that can be measured with open-path dual-comb spectroscopy or other open-path spectroscopy such as active differential optical absorption spectroscopy (Stutz et al., 2016). In particular, CO${}_{\mathrm{2}}$, NH${}_{\mathrm{3}}$, HDO, ethane, formaldehyde (HCHO), CO, and N${}_{\mathrm{2}}$O have all been measured with DCS (Waxman et al., 2017; Ycas et al., 2019; Giorgetta et al., 2021; Herman et al., 2021). By only requiring the lightweight retroreflector to be flown, a small UAV can be used regardless of the gas or gases to be measured.

Combined, these advantages give the capability for rapid, easily deployable, multispecies flux measurements from point or distributed sources. This could be beneficial, for example, to survey emissions from fields, agricultural facilities, wastewater treatment plants, and oil and gas facilities. In addition, with further engineering of mobile DCS, measurements could be conducted from a moving van (similar to the solar occultation flux technique; Mellqvist et al., 2010), allowing for flexible and rapid coverage of a wide area.

Appendix A Details on the release conditions

Flights were conducted on 7 different days at the Table Mountain facility near Boulder, CO (40.13112, $-$105.24065). However, only flights from 4 days were able to be used here due to technical issues. On each day, the specific release location was chosen based on the local wind and was sometimes moved if the wind shifted. Flights occurred during daylight, from approximately 10:00–17:00 LT (Mountain Daylight Time). Between 5 and 10 flights were flown per day. Several different flight patterns were flown including the vertical scans used here as well as some flights based on a vertical–radial plume-mapping approach; however, as those flights only contained a few vertical steps, they could not be used for the flux analysis here. Table A1 lists the flights that were used as well as a summary of meteorological conditions for each flight.

Release information for the processed flights.

Figure A1

Photo of the setup for the controlled releases. (a) The van that housed the dual-comb spectrometer with a 2D sonic anemometer and the weather station (Gill GMX500) mounted to its roof. (b) Standard gas cylinders provided methane and/or acetylene at $>$ 99 % purity. The flow was set by an Alicat MC-20SLPM flow controller with a specified accuracy of $\pm$0.6 %, after which PTFE tubing led to the release point, as discussed in the text. Gas flow for the second gas was set with a ball valve and monitored with a float flowmeter (estimated accuracy $\pm$10 %) A second 3D anemometer (RM Young model 81000 three-axis ultrasonic) provided three-dimensional wind data. The uncertainties in the flow rates were negligible compared to the larger total 50 % uncertainties discussed in the text. As can be seen, the terrain was quite flat with a low cover of grass and brush ($<$ 1 m high) typical of the western United States.

[Figure omitted. See PDF]