1. Introduction
Air pollution continues to be a relevant and continuously growing problem due to its impact on health, the ecosystems and climate. It is considered the world's largest single environmental health risk and according to the World Health Organization, in 2012 more than 3 million people died prematurely as a result of ambient air pollution exposure (WHO, 2014). The Mexico City Metropolitan Area (MCMA), located within a high altitude basin 2200 masl, has over 21 million inhabitants (WPR, 2014) and although some improvements have been accomplished in recent years, there are still serious issues with the pollution levels. A recent emission inventory for 2012 reports that 5.5 x 1017 J of fuel were burned during that year from the transport (58.8%), industrial (25.2%), residential (13.4%) and commercial (2.6%) sectors. According to this report, the fuel consumption has been steadily growing during the last decades, particularly from the transport sector, which now consists of more than 5 million vehicles burning mostly gasoline and natural gas (SEDEMA, 2013).
Nitrogen dioxide (NO2), produced mainly from the combustion of fossil fuels, is an important air pollutant and a key contributor to photochemical smog. Almost 900 thousand tons of NOx (NO + NO2) were emitted during 2012 (SEDEMA, 2013). Surface NO2 levels have continuously been monitored by the local government and data from Mexico City's automatic air quality monitoring network (Red Automática de Monitoreo Atmosférico, RAMA) is available since 1986 (starting with 10 stations). Currently the network has 29 active stations that are spread throughout the MCMA (http://www.aire.df.gob.mx). Formaldehyde (HCHO) is the most abundant carbonyl compound in the atmosphere; this substance, which comes from primary emissions as well as secondary photochemical production, has harmful carcinogenic properties (García et al., 2006). HCHO levels, with average daily maxima ranging between 22 ppb in July-October to 28 ppb in March-May, have been measured with long-path Fourier Transform Infrared Spectroscopy (FTIR) and Differential Optical Absorption Spectroscopy (DOAS) (Grutter et al., 2005).
There have been some studies to evaluate the vertical column densities of NO2 in Mexico City. Melamed et al. (2009) deployed a zenith scattered light DOAS south-east of Mexico City to characterize pollution transport events during the MILAGRO field campaign in 2006. Data from in situ and ceilometer measurements at particular events were analyzed in conjunction with meteorological data and characteristic transport patterns were identified. Also during MILAGRO on March 10, 2006 a ground-based traversal measurement from east to north-west of the city was carried out with two mobile zenith scattered light DOAS instruments, and a cross-section of the pollution plume could be detected (Johansson et al., 2009). With these measurements the authors were able to estimate the outflow of both NO2 and HCHO from the MCMA on that particular day and compare them with model results. Another study by Rivera et al. (2013) using fixed zenith scattered DOAS measurements within the MCMA, was used to determine the variability of the differential NO2 columns. These were then compared with column amounts derived from surface and mixing layer heights (MLH) from a ceilometer, and those from satellite observations produced by the Ozone Monitoring Instrument (OMI). The ground-based results, both from DOAS and in situ/MLH data, were considerably higher than the OMI column amounts.
Determining the vertical profile of a gas can be accomplished by performing in situ measurements from aircrafts, balloons or unmanned aerial vehicles. However, in order to observe the variability with enough time resolution and for longer time periods, remote sensing techniques are preferred. Active long-path DOAS measurements at different elevation angles using retro-reflectors installed at various heights have been done in order to gain information on the vertical distribution of the pollutants (Stutz et al., 2002), however, the deployment of such an experimental set-up is complicated. MAX-DOAS is a passive technique which measures scattered sunlight at zenith and at different elevation angles, increasing the optical path and thus the sensitivity of the absorbing species (Hönninger et al., 2004a; Platt and Stutz, 2008). Some information on the vertical distribution of the gases can be obtained with this technique by using a radiative transfer model and applying inversion methods on the retrieved SCD. Several MAX-DOAS instruments have been constructed and deployed providing valuable information of the vertical distribution of pollution (Carlson et al., 2010; Coburn et al., 2011; Hönninger et al., 2004b; Hendrick et al., 2014).
In this work, we present the technical characteristics of the MAX-DOAS instrument constructed at the National Autonomous University of Mexico (UNAM) as well as some results of the first retrieved SCDs at low elevation angles. Four instruments, installed within the MCMA to form a MAX-DOAS network in Mexico City, are fully automated allowing continuous daily operation throughout the year. A code has been developed based on radiative transfer and inversion models using the measurements from all the elevation angles in order to obtain more information on the vertical distribution and thus a better estimate of the vertical column densities (VCD's). The code and the results will be presented in a forthcoming paper.
2. Experimental
2.1 Instrumentation
We have designed and developed an instrument based on the Multi Axis Differential Optical Absorption Spectroscopy (MAX-DOAS) technique in the Spectroscopy Lab of the Centro de Ciencias de la Atmósfera (Center for Atmospheric Sciences) at UNAM. This instrument can automatically and continuously measure the spectroscopically-resolved solar scattered radiation at different elevation angles. It is composed of the two main parts described below: the scanner and the acquisition/control units.
2.1.1 Scanner
The scanner collects, with a narrow field-of-view (FOV), atmospheric scattered solar radiation at different elevation angles and sends it to the acquisition/control unit for spectroscopic analysis. Figure 1 shows the parts that make up the scanner, which is installed in the open sky. Light is collected by a telescope (fig. 1b) constructed with a plano-convex quartz lens (Edmund Optics, Ø = 25.4 mm, f = 100 mm), mounted inside a hollow Nylamid cylinder (resistant to sunlight) custom manufactured to hold the lens and the optical fiber connector at the other end, at a depth corresponding to the focal length of the lens.
The telescope body has a motor-controlled shutter (Fig. 1b) installed close to where the optical fiber is connected. A 5 mm slot is cut across the Nylamid cylinder allowing the light path to be obstructed just before the optical fiber connector when the shutter plate is closed. The shutter, used for measurements of the dark spectra between scans, is mounted to the telescope body with a Nylamid ring and a fixing screw. It consists of a circular plate (50 mm in radius) which is rotated with an angle of 55° into the slot using a small stepper motor (Mercury, 7.5° per step). An optical switch is used to indicate the open position of the shutter plate.
The telescope is fixed and introduced into an enclosure (NEMA-rated type 3), so that only 10 mm of the telescope is out of the box. A 50.8 mm x 100 mm PVC pipe, painted in black, is placed around the telescope to keep it under shadow and for protection (fig. 1a). The scanner enclosure (200 x 200 x 120 mm) is resistant to sunlight, hermetically sealed to protect the inner parts from external conditions like rain, wind and bugs, and uses gland connectors for the cables (optical fiber and communication cable). These factors are important when operating the instruments during long periods and in harsh weather conditions (e.g. Hönninger et al., 2004b; Carlson et al., 2010; Galle et al., 2010).
Light converges within the telescope at the focal point where the optical fiber connector is located and is transmitted through an optical fiber (Fiber Tech Optica, quarz, 6 m long, Ø = 0.6 mm), which exits the box just across the telescope opening, into the acquisition/control unit. The current optical configuration allows us to have a theoretical FOV of 0.31°.
The entire scanner enclosure can be rotated so that the telescope can point at different elevation angles. This is accomplished by a stepper motor (Oriental Motors, PK266-02A) which is installed at the center of the scanning enclosure with the rotation axis looking outward (Fig. 1b). The axis of the motor is fastened to an outer plate that can be fixed to the vertical pole of a tripod, a wall, etc., allowing for the scanner to rotate in a range between -90° and 90° with respect to the zenith position (0°). The motor can make movements of 0.1° and a switch installed at one corner of the scanning box with a stopper fixed to the outer plate, is used as a reference to indicate the start position of each scan.
We designed a control board (Fig. 1c), which consists of a microcontroller (AVR architecture) that obtains data from the temperature sensor (Maxim 18B20, accuracy ±0.5 °C) inside the scanner, the optical switch of the shutter and the external switch for the scanner's position. It receives and sends information to the computer, within the acquisition/control unit, through a connection cable. It contains two motor drivers for controlling both motors, one for the shutter and the other for the scanner position. A dual axis accelerometer (Analog Devices, accuracy ± 0.1°) has been incorporated to the control board to determine, with previous calibration, the relative orientation of the telescope in each predetermined measurement position with respect to the zenith.
2.1.2 Acquisition and control unit
The acquisition and control unit is a resistant metallic housing (400 x 400 x 200 mm) which is typically installed indoors on the wall not too far from the scanner. It receives the light collected by the scanner, sends it to the spectrometer, controls and reads the motors and sensors, and records the information in a computer.
The small grating spectrometer (Ocean Optics, USB2000+) receives the light from the optical fiber. It has a crossed asymmetric Czerny-Turner configuration, uses a Charge-Coupled Device (CCD) detector array (Sony ILX511B) of 2048 pixels with an integration time adjustable between 1 ms to 65 s. This spectrometer, which has been used successfully by Galle et al. (2002), Hönninger et al. (2004b), Sinreich et al. (2005), and Johansson et al. (2009) in similar applications, was customized to operate at a spectral resolution of 0.69 nm full width at half maximum (FWHM); it has a grating with a groove density of 1800 lines/mm, a slit of 50 μm wide x 1 mm high, an holographic UV blaze wavelength, and wavelength range of 286 to 510 nm.
It is important to have the spectrometer temperature-stabilized because the dark current, electronic offset and the wavelength/pixel ratio of the detector are sensitive to temperature changes, which could also modify the optical properties of the spectrometer like the alignment and the line shape (Carlson et al., 2010; Coburn et al., 2011). We have therefore implemented an accurate temperature controller by attaching a Peltier cell (Multicomp) and three temperature sensors (Maxim 18B20, accuracy ±0.5 °C) to the spectrometer, and wrapped it in a Styrofoam box. As it can be seen in Figure 2b, the spectrometer was placed within a ventilated aluminum enclosure, which together with a heatsink (150 x 60 x 20 mm) at the warm side of the Peltier module allowed us to stabilize the temperature of the spectrometer at 20 °C with a ±0.5 °C precision. A fan (24 VDC, 0.1 A) extracts the hot air generated by the heatsink out of the box.
The control board in Figure 2b was designed to read data from the temperature sensors attached to the spectrometer, the Peltier cell and the heatsink, to regulate the current applied to the Peltier and to decide when the fan should be turned on. A power supply (24 VDC and 10A) is used to operate the control boards and power the stepper motors. The microcontroller AVR (8-bit) in the control board receives and sends information to the computer through an RS-232 port.
A laptop computer (Dell, Latitude 2021) with 3 USB ports, Ethernet and Linux operating system was fixed to the door of the acquisition/control unit. It runs a custom written program (C++, Qt platform) for controlling the hardware. A script running within this program is used to define the measurement sequence, spectrometer temperature and dark offset acquisition. The sequence includes two zenith measurements, one serving as the reference spectrum and one with closed shutter serving for the dark offset corrections. All the spectra and related information are stored in the computer for further processing. The computer has an internet port and the instrument can therefore be accessed remotely to download data and monitor its operation.
2.2 Measurement characteristics
2.2.1 Instrument operation
Once initialized, the instrument will continuously measure sequences and the times of the day to start and end operation can be set to avoid night records. We typically operate the instrument 12 h a day, beginning at 7:00 and finishing at 19:00 LT. In each scan, the scanner moves to the start position indicated by a stopper switch, moves to the zenith position (0°) taking a spectrum which is saved as reference, then moves to the position -90° with respect to the zenith and performs a cycle of measurements at the specified angles. In each position a maximum of 200 acquisitions are averaged to reduce the noise of the recorded spectra. When the scan is completed, the shutter is closed and a dark offset is recorded. The offset, however, is found to have a variability which is typically smaller than 3% thanks to a ±0.3 °C stabilization of temperature, which is kept throughout the day.
For the results presented in this work, dark spectra are not used in the analysis. However, dark spectra measured after each scan will be considered in the analysis of VCD's (in a forthcoming paper).
In each cycle 36 spectra are recorded at different elevation angles, as well as one reference spectrum and one dark spectrum, taking less than 5 min to be completed. Although the duration of each cycle can vary, an average of 150 cycles is recorded per day. Figure 3 shows a drawing of (a) the elevation angles and (b) an example of the measured spectra within a sequence. The integration time is adjusted for each cycle by the intensity in the reference spectrum. It is also shown in the figure how the orientation of the scanner is defined by an azimuth angle with respect to the north.
2.2.2 Network sites
Four MAX-DOAS instruments were constructed and deployed in the metropolitan area of Mexico City. The locations of these stations are shown in the map on Figure 4, which are overlaid on average NO2 column densities from the OMI satellite product (Rivera et al., 2013).The underlying map produced with Cartopy (Met Office, 2015) uses map tiles from Open Street Map (OSM) Contributors(c) (https://www.openstreetmap.org). All instruments require internet services, electricity and safeguarding for continued monitoring, for this reason the instruments are located in four RAMA air quality stations. These stations measure continuous ground surface NO2, fine particulate matter (PM2.5) and other parameters, which are of great value for further analysis of the retrieved column densities.
A summary of the station characteristics including their geographical location, altitude and telescope's azimuth angle (TAA) is included in Table I. A brief description of the stations is provided below.
UNAM. This station is located south of the city in our university campus, specifically on the rooftop of the Centro de Ciencias de la Atmósfera. The building has a measurement platform with sophisticated instrumentation which is part of the Red Universitaria de Observatorios Atmosféricos (University Network of Atmospheric Observatories, RUOA [www.ruoa.unam.mx]). The area towards the west is mostly residential and the ecological reserve of Pedregal de San Ángel can be found to the southwest; in contrast, the east and north directions of the station are highly urbanized.
ACAT. The Acatlan station is located in the northwestern part of the city in a highly urbanized area with buildings surrounded by two parks, one of them to the south and the other to the north. The station is hosted by the campus of UNAM's Facultad de Estudios Superiores (School of Graduate Studies). The region is highly urbanized and at 1 km distance towards the east there is a principal road with heavy vehicular load (FIMEVIC, 2001). The Naucalpan industrial park is less than 4 km away towards the southeast of the station.
CUAT. The instrument at Cuautitlán is located inside an ecological park named Xochitla, in the far north of the city. This area has different points of interest; 1 km to the southwest of the station is the state highway with heavy transport use of factory products, and to the south there is an industrial park with different factories. This site should track pollution transport events to and from the city as has been described by Jazcilevich et al. (2003).
VALL. This station is located close to the downtown area in the Vallejo district. This is an industrial and highly urbanized area with a huge quantity of motor vehicles. This station is hosted by the operational office ofthe RAMA network and has therefore a large amount of instrumentation for atmospheric monitoring.
3. Spectral analysis
Spectra were evaluated using the QDOAS (v. 2.105) software (Danckert et al., 2013). For NO2 (shown in Fig. 5a) the retrieval was conducted in the 405 to 465 nm wavelength window. Differential cross-sections of NO2 at 298 K (Vandaele et al., 1998), O3 at 221 K and 241 K (Burrows et al., 1999), oxygen dimer O4 (Hermans et al., 1999), and a Ring spectrum generated at 273 K from a high resolution Kurucz file using the QDOAS software (Danckert et al., 2013), were included in the analysis.
For HCHO the retrieval was conducted in the 335 to 357 nm wavelength window. Differential cross-sections of HCHO (Meller and Moortgat, 2000), BrO (Wilmouth et al., 1999), NO2 (Vandaele et al., 1998), O3 at 221 K and 241 K (Burrows et al., 1999), oxygen dimer O4 (Hermans et al., 1999), and the previous Ring spectrum were also used for this analysis.
The high resolution spectra were convolved with a slit function of the spectrometer measured with a low pressure Hg lamp. Typical retrieval fits are shown in Figure 5. For this example, the retrieved NO 2 SCD was 4.71 x 1017 molecules/cm2 with a fitting error of 2.43 x 1015. For HCHO, the retrieved SCD was 1.96 x 1017 molec/cm2 with an error of 2.31 x 1016. The corresponding residuals were of the order of 10-3 RMS, as expected for compact DOAS systems.
4. Results
We present the results from measurements recorded at the UNAM station in the period from January 2013 to November 2014. Only SCDs of NO2 and HCHO retrieved at angles of 70° and -70° are presented here, chosen to enhance sensitivity through longer optical paths and to ensure that the measurements had no interference by any object surrounding the observation site. The results from these two viewing orientations are shown independently in order to identify differences when viewing east and west, respectively.
All measurements were filtered to ensure a good fit from the QDOAS retrieval. The elevation angle for the reference spectrum should be close to 0°, so a variation of this angle should not exceed ±1.2°. During the period from July 2013 to September 2013, the instrument at UNAM station had problems with the tuning of the elevation angle for the reference spectrum. Therefore, instead of the original reference spectrum, a measurement from the scan with an elevation angle in the range of ±5° was chosen as a replacement for the reference spectrum. All the data is treated and presented in a fixed local time corresponding to UT-06, avoiding summer time corrections. After filtering the data, 373 days of measurements with 55 950 individual spectra are considered in this analysis.
4.1 NO2
Figure 6 shows the average diurnal cycles (solid blue lines) from the NO 2 differential slant columns (at ± 70° zenith angles) measured during the entire period towards the east (circles) and west (triangles) sides of the UNAM station. These curves peak at around 11:0012:00 LT, which is consistent to what was observed by Rivera et al. (2013) during 2010-2011 with zenith scattered DOAS measurements, and also to the behavior reported in the emission inventory (SEDEMA, 2013).
To complement the analysis, surface NO2 concentrations measured at two RAMA stations located towards the east (UAX, 110°, 8.2 km) and towards the west (PED, 266°, 2.9 km) were compiled and averaged. The dashed lines in Figure 6 are the average surface concentrations of NO2 in ppb measured at these two RAMA stations, respectively. The surface concentrations (black) peak at least an hour earlier than the columns (gray) because the growth of the mixing layer during the late morning causes the concentrations at the surface to be diluted.
Due to the difference in methodologies and units, a direct comparison of surface and column amounts is not possible, however, in both cases a higher NO 2 is observed west of the UNAM station (triangles) than towards the east (circles). A simple explanation for this phenomenon is given by studies like that of Jazcilevich et al. (2003), reporting a general wind pattern towards the southwest corner of the MCMA transporting pollution predominately in this direction and presenting the slightly larger values of N02 seen in Figure 6. In average, N02 in PED starts lower and grows larger than in UAX after 9 h. This is also seen in the east-west slant column measurements and could be characteristic of a photochemically produced N02 from fresh emissions, which are released in larger amounts in the eastern and northern parts of the observation site.
A vertical column, in molecules/cm2, was estimated by scaling the surface concentration (average of UAX and PED) with the height of the mixing layer and assuming a homogeneous distribution of N02 throughout the layer. The MLH is available at the UNAM station from backscattering measurements of pulsed laser light performed by a commercial ceilometer (Vaisala, model CL31), which is operated continuously at this site. It is important to say that for the sake of comparison with the SCDs measured with the MAX-D0AS instrument, that reconstructed vertical columns were multiplied by the geometrical factor of 2.9, obtained from 1/cos 70°. The magenta line in Figure 6 represents thus the slant column of N02 reconstructed from surface concentrations and measured MLH's. As one would expect by comparing similar quantities, the slant columns measured with the MAX-D0AS instrument and the reconstructed column peak at approximately the same time.
There are differences, however, in both the form and magnitude of the diurnal cycles from the reconstructed (magenta) and measured (blue) slant column densities. Inhomogeneity in the vertical distribution of the gas from the presence of inversion and residual layers at specific times may explain some of the differences observed, which has to some extent been documented specifically for the MCMA by several authors (Fast and Zhong, 1998; Lezama et al., 2002; Shaw et al., 2007; Melamed et al., 2009; Stremme et al., 2009). To account for the significant discrepancy of approximately 40% smaller columns of the measured slant columns with respect to the reconstructed ones from surface and MLH measurements, other aspects have also to be considered.
The calculation of the geometrical factor performed here assumes that scattering of photons takes place above the mixed layer and that all photons travel their way through the slant column to the instrument. However, there is scattering within the mixing layer of photons coming directly from the sun towards the line-of-sight of the instrument. Assuming single scattering, the absorption by a given gas would be less apparent, and an underestimation of the real column would be produced.
In this context it should also be mentioned that the difference between the diurnal cycle of the slant column towards east and west might partly be influenced by the evident differences in the relative angle of the sun and the corresponding viewing angles. This may cause that one particular direction may experience more absorption above the scattering height than the other and that the phase function dependence contributes to the observed differences. This latter effect might be small for the spectral window above 400 nm used to retrieve NO2, but could be important for shorter wavelengths like those used in the analysis of HCHO.
4.2 HCHO
The average diurnal cycle of formaldehyde slant columns measured towards the east at a zenith angle of 70° (circles) and towards the west at -70° (triangles) from the UNAM station is presented in Figure 7. A large difference between the two observation directions is observed. In the mornings, a strong HCHO peak can be detected towards the east which is not seen when pointing west. This peak at 8:00 LT is consistent to what was measured by Grutter et al. (2005) in downtown Mexico City, where maxima of near surface concentrations were reported to occur during the early morning.
It is known that in Mexico City a significant amount of HCHO is associated with primary emissions (Garcia et al., 2006). It is not surprising to find high values towards the east because in this direction a large population density, a number of avenues and thus heavy traffic can be found. West of UNAM is characterized to have areas with vegetation, low urbanization and low emissions. Typical meteorological conditions in the MCMA comprise calm winds until about noon and then ventilation picks up and blows the pollution, frequently towards the southwest (Jazcilevich et al., 2003). This could explain the cross-over between the east and west curves in Figure 7 showing a progressive growth HCHO concentration from more aged masses to the west of the observation site.
5. Conclusions
In this article we have presented the design, construction and implementation of an instrument based on the MAX-DOAS technique. Four of these instruments, which now constitute a new network, have been installed and are operating in strategic locations within the MCMA. We have focused on describing the technical characteristics of both the scanning and acquisition units, and demonstrating their ability to detect NO2 and HCHO in the atmosphere, which are key photochemical pollutants.
It is demonstrated in this work that the instruments are capable of producing valuable information from the diurnal variability of the measured slant columns of these gases. Filtered data from a period spanning almost two years are used in this analysis and compared to the reconstructed column amounts from measured surface concentrations and the heights of the mixing layer. Interesting features become apparent which can be related to the location of these particular sites within the city and the meteorological patterns associating the transport of pollutants. The results and discussion presented, however, also suggest the need to (1) incorporate the radiative transfer into the analysis and (2) include the data from instruments at other locations.
There are many limitations of not taking advantage of the full multi-axis capability of these instruments and we have therefore developed a computational code based on a radiative transfer model and an inversion algorithm to gain information on the vertical distribution of the gases. This work is in preparation and will be presented elsewhere.
Future studies using all four sites will make it possible to understand the relationship between these chemical species and different environments, emission characteristics and meteorological patterns within the metropolitan area. The VCDs which will be obtained from these measurements have the potential to improve the air quality models currently deployed in the region for evaluating mitigation scenarios, for example, and to validate satellite products which are increasingly being used to acquire more information on the spatial distribution of the pollution in several parts of the world.