Abstract
The Arctic environment is transforming rapidly due to climate change. Aerosols’ abundance and physicochemical characteristics play a crucial, yet uncertain, role in these changes due to their influence on the surface energy budget through direct interaction with solar radiation and indirectly via cloud formation. Importantly, Arctic aerosol properties are also changing in response to climate change. Despite their importance, year-round measurements of their characteristics are sparse in the Arctic and often confined to lower latitudes at Arctic land-based stations and/or short high-latitude summertime campaigns. Here, we present unique aerosol microphysics and chemical composition datasets collected during the year-long Multidisciplinary drifting Observatory for the Study of Arctic Climate (MOSAiC) expedition, in the central Arctic. These datasets, which include aerosol particle number concentrations, size distributions, cloud condensation nuclei concentrations, fluorescent aerosol concentrations and properties, and aerosol bulk chemical composition (black carbon, sulfate, nitrate, ammonium, chloride, and organics) will serve to improve our understanding of high-Arctic aerosol processes, with relevance towards improved modelling of the future Arctic (and global) climate.
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The Arctic atmosphere is experiencing considerable changes and is warming at a rate up to four times as fast as the rest of the world1,2,3. This phenomenon, referred to as Arctic amplification, has important consequences on the Arctic environment, e.g., more frequent, intense, and longer extreme events4,5 with impacts in mid-latitudes. Regionally, permafrost thawing has repercussions for land-based infrastructure and increases global methane6 and volatile organic compounds7 emissions, while sea ice decline triggers natural resource extraction plans, and social and economic challenges for Arctic indigenous people8. Among the various regional and global processes that contribute to the enhanced Arctic warming, warming through greenhouse gases forcing (e.g., carbon dioxide (CO2)), snow and ice-albedo feedbacks9,10, temperature feedbacks11 (Planck and lapse rate feedbacks), and ocean warming have often been identified as the key drivers of Arctic amplification11,12. Aerosols are a major component in the Arctic’s radiative balance13,14,15,16 and can be from local or remote sources, primary or secondary in origin, and anthropogenically (e.g., industrial activities, traffic and agriculture) or naturally-sourced (e.g., wind-blown dust or snow, sea-spray, and wildfires)16,17. Aerosols can directly affect radiative transfer by absorbing or scattering incoming radiation (aerosol-radiation interaction, ARI) or indirectly, by modulating cloud radiative properties through aerosol-cloud interactions (ACIs). However, ACI remains poorly understood and contributes to the largest uncertainty in radiative forcing estimates18,19, owing to a lack of observational evidence to evaluate models and to understand the sources of aerosols that contribute to cloud and fog formation. This lack of observations is particularly true in the central Arctic Ocean due to the complexity of monitoring in situ atmospheric variables in this remote location.
Most of the present-day knowledge on aerosol processes and seasonality in the Arctic13,14,20,21 has been gained from permanent land-based monitoring stations around the Arctic, e.g., refs. 17,22 or from short high-latitude aircraft, e.g., refs. 21,23,24 or ship-based campaigns, e.g., refs. 25,26,27,28,29, predominantly during summertime. With regard to the summertime bias, it is long known that it cannot represent the full annual aerosol cycle13,14,18,22. More recent results also suggest that land-based observations cannot fully represent the central Arctic Ocean30. Local processes or short regional extreme events may not always be captured at Arctic land-based stations31, highlighting the need for an investigation of more local processes and the local impact of aerosols on the radiative balance through ARI and ACI. The overall scarcity of aerosol observations in the central Arctic Ocean, especially during the dark winter and early spring time, was a key motivation for the international collaboration which led to the “Multidisciplinary drifting Observatory for the Study of Arctic Climate” (MOSAiC) expedition to take place in the central Arctic from October 2019 to September 2020. For an entire year, the Research Vessel (RV) Polarstern32 drifted with the central Arctic sea ice, hosting an extensive suite of experiments designed to study the coupled atmosphere-ice-ocean-ecosystem processes in one of the most climate-sensitive environments on the planet33. In particular, a vast ensemble of high time-resolution instruments for in situ monitoring of the central Arctic aerosols’ abundance and physicochemical characteristics was deployed. From the perspective of improving large-scale numerical models and future climate projections, the expedition provided a large dataset of climate-relevant variables through an entire year, for current and future generations of researchers to build upon. The combination of high time-resolution and year-round continuous measurements will allow for the drivers of seasonal variations to be unravelled, from the build-up of the anthropogenically-driven Arctic haze in winter and spring34,35,36, through the prevalence of naturally-sourced ultrafine particles in summertime29,30,37, to the more pristine autumn season, closing the annual cycle.
In this manuscript, we present an unprecedented year-round dataset of aerosol microphysics and chemical composition measurements performed in the central Arctic Ocean in the Swiss container during the MOSAiC expedition. These include measurements of aerosol particle number concentrations, size distributions, cloud condensation nuclei concentrations, fluorescent aerosol concentrations and properties, as well as aerosol bulk chemical composition and mass concentration (black carbon, sulfate, nitrate, ammonium, chloride and organics). We present an evaluation of the datasets’ quality, inferred from closure analysis between measured and derived variables and from intercomparisons between several of our measurements with redundant ones that were acquired with a close-by and independent instrument suite.
Methods
Instrumental setup
On September 20th 2019, RV Polarstern left Tromsø harbour, Norway, towards the central Arctic Ocean to make year-long measurements, while trapped in the sea ice. The drift began on October 4th 2019, when a suitable ice floe, to which Polarstern could be moored, was found. Apart from a detachment from the original ice floe between May 16th and June 19th 2020, for a logistical round-trip to Svalbard, Polarstern drifted in the central Arctic Ocean sea ice until July 31st 2020, when the original ice floe disintegrated. On August 21st 2020, RV Polarstern was brought to a new ice floe close to the North Pole and drifted again until September 20th 2020. The detailed expedition track, along with the description of all atmospheric measurements performed onboard RV Polarstern, can be found in Shupe et al.33.
Scientific activities during the expedition were carried out both on sea ice (through an instrument network spanning up to 50 km around RV Polarstern) and on the ship itself. The Swiss container was located on the D-deck of RV Polarstern’s bow, for which a schematic of the instrumental and inlet setup is provided in Fig. 1. The container was equipped with three inlets: 1) a total inlet with a flow of >15 L/min and an upper particle cutoff size of 40 μm for sampling particles and hydrometeors, 2) an interstitial inlet with a flow of >17 L/min and equipped with a 1 μm cyclone for sampling interstitial particles only, and 3) a new particle formation (NPF) inlet (not shown in Fig. 1 and not further discussed in the current manuscript). The inlets pointed upwards outside the container, with a length of 1.5 m, for a total approximate height of 15 m above sea level. The total and interstitial inlets were located 3 m apart and connected inside the container to a valve that switched hourly between the two inlets. This allowed for quantification of both activated and non-activated particles in case of foggy conditions for a targeted set of instruments. This design was specifically conceived to study aerosol in-cloud/fog processes, and enables measurements to infer the aerosol sources that are linked with activated and non-activated particles38. Inside the container, the temperature was kept constant around 20 °C and the relative humidity inside the inlets was maintained well below 40% with a heating system following the Global Atmosphere Watch (GAW) standards for aerosol sampling39. Temperature and relative humidity were measured inside bypasses to both inlets with two hygrometers model HC2 (Rotronic AG, Bassersdorf, Switzerland). The recorded time series, averaged to 10 min time resolution from the 5 min native one, were made available on PANGAEA repository (see “Data Records” section). The position of the switching valve (i.e., “interstitial” or “total”) during the campaign is also included in the aforementioned datasets. Summaries of the various measurements and available datasets considered in the current manuscript are provided in Table 1 and Fig. 2, respectively.
Additional instruments from another laboratory container were used for intercomparisons, mass closure analysis, and corrections, including an additional Cloud Condensation Nuclei Counter (CCNC), a Scanning Mobility Particle Sizer (SMPS), and an Ultra-High-Sensitivity Aerosol Spectrometer (UHSAS). These instruments were located in the Aerosol Observing System (AOS) container, operated as part of the United States Department of Energy Atmospheric Radiation Measurement (ARM) user facility40 during MOSAiC. The ARM container was also located on the D-deck of Polarstern’s bow about 1.5 m away from the Swiss container, with a total aerosol inlet of 5 m in length reaching around 18 m above sea level. These datasets are available freely online and a link to access them is provided in the “Data Records” section. More information on the ARM container, its operation and instrumental setup can be found in Uin et al.40, Boyer et al.30, and Angot et al.41.
Inlet losses characterization
The inlet system presented in Fig. 1 was characterized for losses using a particle loss calculator (PLC)42. The overall sampling efficiency is approximated in the model by solving equations for sedimentation, diffusion, turbulent inertial deposition, inertial deposition in sampling line bends, contractions and enlargements or for electrostatic deposition, interception, and coagulation processes42. The aforementioned quantities depend on the inlet system considered (e.g., flow rate, tube length and diameter, inclination angles and curvatures) and on the particle size, such that smaller particles will be more sensitive to diffusion losses through Brownian motion and larger particles to sedimentation losses through gravitational settling. For the calculations, we assumed an averaged particle density of 1.5 g/cm3, representative of the Arctic43,44,45. For each individual pathway leading to the different instruments, with the exception of the AMS, the particle losses inside the sampling lines range from ~30 to ~50% for particles smaller than 5 nm (where only the two CPCs can measure such small particles), from ~10 to ~30% for particles between 5 and 10 nm, from ~0.5 to ~15% for particles between 10 and 100 nm, and from nearly 0 to ~3% for particles between 100 nm and 1000 nm. The AMS was operated at a lower flow rate than the other instruments (0.07 L/min, see “Aerosol chemical composition and mass concentration” section) and the calculated losses for the corresponding sampling lines are consequently higher. In the size range relevant for the AMS (i.e. ~50–1000 nm), the calculated inlet losses are below 10% between 50 and 700 nm and up to 20% between 700 and 1000 nm. In summary, for submicron particles (i.e., 10 to 1000 nm) losses are hence very small (0–10%), in line with losses reported for similar inlet systems deployed at Arctic ground-based stations46, and are not further accounted for.
In the supermicron size range, for the sampling line leading to the CPC3776, we calculated losses between 3 and 20% within the size range from 1 to 3 µm, and larger than 40% above 4 µm. Finally, for the sampling lines leading to the APS and WIBS, calculated losses vary from nearly 0 to 4% for particles smaller than 3 µm, from 4 to 10% for particles between 3 and 5 µm, between 10 and 35% for particles between 5 and 10 µm, and more than 35% for particles larger than 10 µm. Hence, reported supermicron aerosol number concentrations represent a lower estimate.
Equivalent black carbon mass concentration
Instrument description and in situ operation
Measurements of equivalent black carbon (eBC) were performed using a commercial aethalometer model AE33 (Magee Scientific, Berkeley, USA). The instrument was connected to the switching valve (Fig. 1), with a sample flow of 2 L/min, biweekly verified. The dual-spot technology of the instrument ensures a real-time compensation of what is referred to as the loading effect47. In practice, the aerosols are collected on a filter and the attenuation of transmitted light is measured at 7 different wavelengths (370, 470, 520, 590, 660, 880 and 950 nm) with a time resolution of 1 s. The instrument reports the measurements as eBC mass concentrations, as inferred from the measured attenuation at the aforementioned wavelengths, using Eq. 16 in Drinovec et al.47. The data obtained from measurements at 880 nm were used for computing and reporting eBC mass concentrations, using the corresponding standard mass absorption cross-section (MAC) value of 7.77 m2g−1 47. Measurements at all wavelengths (λ) were used to report the aerosol optical absorption coefficients, obtained by multiplying the eBC(λ) mass concentrations by the default MAC(λ) values of 18.47, 14.54, 13.14, 11.58, 10.35, 7.77 and 7.19 m2g−1, for the wavelengths 370, 470, 520, 590, 660, 880, and 950 nm, respectively. These can be used for source apportionment or for the computation of the Absorption Ångström Exponent (AAE)48. The instrument’s manufacturer does not report specific values for measurement uncertainties, but a recent study intercomparing multiple AE33 aethalometers estimated that noise (which is not the only source of measurement uncertainty) accounted on average for 10% of the averaged ambient eBC mass concentration49. Noise was defined as one standard deviation of the eBC mass concentration of dry filtered air. The authors reported average noise levels of 31 ng/m3 for eBC measurements at 880 nm and at 1 min time resolution. At 10 min time resolution, this noise level can be estimated to be 9.8 ng/m3 (31/√(10) ≈ 9.8, using Eq. 4 in Fröhlich et al.50). Time-averaging will in this case only lower the electronic noise but not the uncertainties associated with the measurement technique51. We further evaluated the need for a loading effect correction, in addition to the dual-spot compensation, by inspection of the concentration during filter tape changing periods and found that no additional correction was needed.
Data processing and cleaning
As time integration reduces noise (see above), the raw 1 s dataset was first averaged to a time resolution of 1 min. Then, outliers of more than 3 times the median absolute deviation (MAD) from an hourly moving window were removed. This commonly used median-based method for excluding outliers relies on the assumption that the data are normally distributed and then identifies extreme values on both sides of the distribution. A visual inspection of the resulting time series after applying the MAD method confirmed that no “true” signal (i.e., representative of ambient conditions) was removed in the process. After correcting for artefacts that occurred when switching between the total and interstitial inlets, which caused a difference pattern of mean and standard deviation of the measurements between odd and even hours (see the “Inlet switching correction” section, likewise for the two CPC, AMS, and CCNC datasets), the data were finally averaged to a 10 min time resolution. Based on a visual inspection of the entire dataset, we further excluded periods of strong noise and intense negative spikes. These data points may have emerged from the averaging of the initially noisy 1 s time resolution dataset and/or from the dual-spot compensation, which may lead to the presence of a strong negative outlier right after a positive one.
Aerosol chemical composition and mass concentration
Instrument description, in situ operation, and processing of raw data
The bulk size-resolved chemical composition and mass concentration of non-refractory aerosols smaller than 1 µm (NR-PM1) in vacuum aerodynamic diameter (dva), was measured using a High-Resolution Time-of-Flight Aerosol Mass Spectrometer (HR-ToF-AMS, Aerodyne Research, Inc.), for which detailed description, functioning principles and field deployment procedures have been extensively described in the literature52,53. In short, during MOSAiC, ambient air was sampled alternatively every hour from the total and interstitial inlets into an aerodynamic lens with a 1 µm critical orifice and a flow of 0.07 L/min. The particle size was then determined based on the particle time-of-flight (PToF) across a fixed distance in the instrument’s sizing region, under vacuum (~10−5 Torr). The vaporizer, consisting of a resistively heated tungsten surface, was set to a temperature of 600 °C (operating current ~1.25 A), verified in June 2019 with a heater calibration using size selected 225 nm sodium nitrate (NaNO3) particles54. In theory, with a vaporizer temperature of 600 °C, only non-refractory (NR) species (here defined as the species that are flash-vaporized at temperatures below or equal to 600 °C) are measured, such as sulfate (SO42−), nitrate (NO3−), ammonium (NH4+), chloride (Cl−) and some organic matter (Org). Thus, refractory materials such as sea salt, black carbon, crustal material or metal oxides are mainly excluded55. It has, however, been shown that with a proper tuning and calibration of the instrument, sea salt could be detected and quantified, albeit with considerable uncertainties56,57. In the time-of-flight mass spectrometer (ToF-MS), where ions are separated based on their mass-to-charge (m/z) ratio, two operational modes defined by the ion path length are available: the V-mode and the W-mode52. The W mode is characterized by a longer ion flight path, hence a higher spectral resolution but decreased signal intensity due to ion losses along the path. Since the Arctic has very low aerosol concentrations, even during haze conditions, only the V-mode was operated during the expedition, to maximize the signal and to lower the detection limits (reported in Table 2). Furthermore, the instrument was operated sequentially in the “mass spectrum (MS) mode” and “PToF mode” with an effective time resolution of about 90 s. Due to turbo pump failures, the AMS was not running between December 5th 2019 and February 29th 2020, between May 30th 2020 and June 6th 2020, and was completely shut down after July 10th 2020.
The AMS data were analyzed and processed using SQUIRREL (SeQUential Igor data RetRiEvaL) v1.65B and PIKA (Peak Integration by Key Analysis) v1.25B58 within the IGOR Pro v9.00 software (Wavemetrics, Inc., Lake Oswego, OR, USA). This was done separately for the three different periods of available measurements, Oct-Dec, Mar-May, and Jun-Jul, as the instrument was each time in a different state (after long down times). The ionization efficiency of nitrate (IENO3), and relative ionization efficiencies of ammonium and sulfate (RIENH4 and RIESO4, respectively) were determined (see Table 2) using standardized mass balance methods with regular on-site calibrations using monodisperse, number concentration-defined, ammonium nitrate (NH4NO3), and ammonium sulfate ((NH4)2SO4) particles55,59,60. IENO3 corresponds to the total number of ions detected per number of molecules vaporized and is used as a calibration factor to calculate the mass concentration of the different species in nitrate equivalent, while relative ionization efficiencies (such as RIENH4 and RIESO4) are used to get the species’ absolute mass concentration from the nitrate equivalent one. For the Oct-Dec period, IENO3 and RIENH4 values were obtained from averaging the values derived for all calibration procedures during the period (SD(IENO3/airbeam) = 5.54 * 10−13, SD(RIENH4) = 0.025), while a single calibration was used to retrieve RIESO4. Similarly, IENO3 and the RIE values for the Mar-May period were obtained from a single calibration on April 12th. For the Jun-Jul period, the calibrations failed to produce usable results due to instrumental turbo pump failures and the values from the Mar-May period were used for both RIENH4 and RIESO4. Within PIKA, the fragmentation table was adapted for air fragmentation patterns using periods of zero measurements, performed on a regular basis (several times per month) using High-Efficiency Particulate Absorbing (HEPA) filters. In particular, the abundance of isotopic nitrogen 15 (15N2+) at m/z 29 was adjusted by constraining 15N2+ to N2+ in order to determine CHO+ abundance, since CHO+ and 15N2+ are less than 0.001 m/z apart. In V-mode, the deployed HR-ToF-AMS has a mass resolving power of about 2100 (m/Δm)52 so that, at m/z 29, we can reliably separate ions at 0.014 m/z apart (29/2100 = 0.014). The fractional amount of CO2+ in the gas phase was adjusted similarly by determining the relation between CO2+ (m/z 44) and C2H3O+ (m/z 43) during filter periods. A time-dependent airbeam correction factor was applied to the dataset (medians of 1.23, 0.99, and 0.93 for the Oct-Dec, Mar-May, and Jun-Jul periods, respectively), along with a time and composition-dependent collection efficiency (CDCE)61, accounting for particles bouncing of the heater.
Regarding measurement uncertainties, there is no strict consensus for their quantification, as they depend on a large variety of factors (e.g., the IENO3 estimation, collection efficiency (CE) estimation, and chemical composition)56. Bahreini et al.62 estimated the propagated, overall uncertainty for the total AMS mass concentration to 20–35%, where the uncertainty in CE estimation and RIEs of the different species are the major contributors to the overall uncertainty61. A statistical ion counting error can however be computed, assuming that the probable distribution of counted ions can be modelled as a Poisson distribution60. Summing the errors for all m/z that contribute to each species (i.e. SO42−, NO3−, NH4+, Cl−, and Org), we get median error contributions to the measured mass concentrations of 1.99, 34.35, 20.22, 43.29 and 9.73% for SO42−, NO3−, NH4+, Cl−, and Org, respectively, for the Mar-May period. Hence, depending on the considered species, these can represent a small or substantial part of the overall measurement uncertainty mentioned above.
Data filtering and switching correction
The following periods were removed from the final dataset: when the airbeam correction factor was larger than 2 or smaller than 0, outliers (defined as more than 3 times the standard deviation of half an hour moving average), all calibrations, filter periods and data non-representative of ambient conditions (e.g., electronic interferences at the proximity of a cellphone or any period with a disconnection of the AMS inlet from the main ambient line for diverse reasons).
Scaling factor from mass closure with the ARM SMPS
A mass closure analysis between the AMS and ARM SMPS was performed independently for the three periods Oct-Dec, Mar-May and Jun-Jul, and yielded the following slopes: 0.271 (R2 = 0.016), 1.543 (R2 = 0.816) and 2.893 (R2 = 0.912) for the three respective periods. For the Oct-Dec period, the R2 value is very low (0.016) as a result of the forcing of the linear regression through the origin. This value, which represents the statistical goodness of the fit (not to be confounded with a measure of the correlation), changes to 0.576 if the linear regression is not forced through zero. In other words, the measurements from the two instruments during this period are not randomly distributed in a point cloud but are well correlated (Pearson’s correlation ρ = 0.759), despite the low R2 value reported (see Fig. 3). The resulting slopes mentioned above can be used as scaling factors ( = 1/slope) on the AMS data (see “Usage Notes” section). A detailed description of the mass closure analysis and resulting comparison is provided in the “Technical Validation” section.
Coarse mode aerosol size distribution
Instrument description
The TSI 3321 Aerodynamic Particle Sizer Spectrometer (APS) measured aerosol number size distributions between 0.5 and 20 μm (aerodynamic diameter) in 52 bins, with a total (sheath + aerosol sample) flow of 4.5 L/min. The measurement principle is based on the acceleration of particles in response to the accelerated sample flow, and the particle time of flight between two laser beams is converted to an aerodynamic diameter, as larger particles have higher inertia and thus accelerate more slowly. The manufacturer reports a +/− 10% measurement uncertainty for the model 3321, as one could expect from the common 10% counting error associated with optical counting of particles63.
Data processing and correction
The data were processed using Python and the 20 s raw data were averaged to 1 min intervals. Time periods with zero filter measurements (using HEPA filters), which served to verify the instrument’s proper functioning, and periods with unstable flow that affected number concentrations were removed. As the APS had some flow rate irregularities during the campaign, we compared the size distribution against the WIBS and UHSAS (operated in the ARM container) and a correction factor for the APS size distributions was applied per bin based on the comparison of WIBS and APS number size distributions. This process, and the resulting comparison, are further discussed in the “Technical Validation” section.
Fluorescent aerosol measurements
Instrument description
The Wideband Integrated Bioaerosol Sensor – New Electronics Option (WIBS NEO; Droplet Measurement Technologies, Longmont, CO, USA) is designed to measure fluorescent aerosols. It measures the size, asymmetry and fluorescence of particles with an optical diameter of 0.5 to 20 µm. The instrument uses a laser at 635 nm wavelength to detect single particles. Detected particles are excited by two ultraviolet (UV) xenon flashlamps at wavelengths of 280 and 370 nm and their emitted light is measured by two photomultipliers with bandwidths of 310–400 nm, and 420–650 nm. The WIBS counts excited particles at a maximum frequency of 125 Hz, which corresponds to a maximum concentration of 2.5*104 particles/L with a sample flow of 0.3 L/min. The manufacturer does not report a specific measurement uncertainty, but the counting error from the optical counter is about 10%63. Measurements of the background intensity were performed automatically every 26 h for 5 min by firing the UV flashlamps in the absence of any particles. Weekly zero measurements were performed with HEPA filters and the sample flow was verified weekly.
Data processing
The data were processed for each month separately with the WIBS toolkit v1.36 for IGOR (Droplet Measurement Technologies). According to Savage et al.64 and Moallemi et al.65, excited particles were classified as fluorescent if their fluorescent intensity exceeded the background intensity by three standard deviations (3σ) and as hyper-fluorescent if the fluorescent intensity exceeded the background intensity by 9σ. Excited particles with a lower fluorescent intensity were considered to be non-fluorescent. The combination of two excitation wavelengths and two emission detector wavebands allows the classification of fluorescent particles into seven types: A, B, C, AB, AC, BC, and ABC66. With a careful data analysis, these classification types can be used to understand the sources of the measured fluorescent aerosols. Averaged time series data at 1 h time resolution were created for the following parameters, for excited, fluorescent, and hyper-fluorescent particles: particle number size distribution and fluorescence. Zero measurements were removed from the final dataset.
CCNC
Instrument description
The Cloud Condensation Nuclei Counter (CCNC), model CCN-100 from Droplet Measurement Technologies (DMT, Boulder, USA) consists of a cylindrical continuous-flow chamber in which aerosols are exposed to a defined, constant supersaturation. The supersaturation is generated by applying a temperature gradient at the column walls, and as diffusion of water vapor in air is faster than diffusion of heat67, the column centerline is supersaturated. Particles form droplets when they activate at a supersaturation lower than the set supersaturation and activated droplets are counted by an optical particle counter.
The measurements were performed in 1-h cycles, with a 0.5 L/min sample flow and an external 2 L/min make up flow, where the supersaturations 0.15, 0.2, 0.3, 0.5 and 1.0% were measured. The supersaturation of 0.15% is measured for 20 min, as it takes longer to equilibrate, and the remaining supersaturations were measured for 10 min each. The instrument was calibrated in July 2019 before the campaign, and in March and April 2020 during the campaign. Based on the inter-variability of the calculated supersaturation levels during these calibrations, we can expect values ranging from 0.15–0.20, 0.20–0.25, 0.29–0.33, 0.43–0.5, 0.78–1.0% for the nominal supersaturations of 0.15, 0.2, 0.3, 0.5 and 1.0%, respectively. The counting error for the CCNC is associated with the error in the optical counting of particles and is about 10%46,63.
Data processing
Data were removed during the cooling cycle (i.e., the time when the measurement cycle starts again and the temperature is cooled to set the lowest supersaturation), which corresponds roughly to the first 10 min of each hour (so 50% of the 0.15% supersaturation period). Also, the first minute of data after switching to the next supersaturation step were removed, to account for temperature stabilization in the instrument’s column. Data were finally averaged to 1 min time resolution (native one as 1 sec) for each supersaturation level separately.
Total particle number concentration
Instruments
To measure the total particle number concentration behind both inlets, we used two condensation particle counters (CPCs), one model 3025 by TSI, Inc. (referred to as CPC3025) and one model 3776 by TSI, Inc. (referred to as CPC3776). We ran the CPC3025 behind the interstitial inlet and the CPC3776 behind the total inlet (see Fig. 1). The minimum detectable particle diameter (50% counting efficiency, dp50) for the CPC3025 (CPC3776) is 3 nm (2.5 nm) with a maximum detectable particle concentration of 9.99*104 cm−3 (3*105 cm−3). For particle number concentration below the maximum threshold, the manufacturer reports a measurement’s uncertainty of +/− 10%. The sample air of both CPC’s (sample flow: 0.3 L/min for each) was taken directly from the inlet lines, when they entered the container and before it was distributed to other instruments, and the sample lines of both instruments had a length of 400 mm, for comparability. We performed weekly zero tests with HEPA filters on both CPCs.
Data processing
Both datasets were cleaned from calibration and zero-check filter periods. Additionally, data from the CPC3025 was used to create a pollution detection algorithm (PDA), which is described in Beck et al.68. The pollution flag derived from the PDA was used to clean other instruments’ data from primary pollution influences (see “Pollution detection” section).
Inlet switching correction
We applied two corrections. First, the switching valve caused data distortion, observed at every full hour (i.e., when the valve turns and the ambient sampling changes from one inlet to another, there is a brief moment with underpressure in the inlet lines). Consequently, all data points within ± 2 min of the full hours were conservatively removed for the instruments located behind the switching valve (i.e., AE33, AMS, and CCNC).
Second, during some periods, we observed a difference pattern of mean and standard deviation of the measurements between even and odd hours, most probably caused by a persistent pressure drop in the inlet lines, resulting in a proportional reduction of the concentration measurements. For the two CPC datasets, we corrected for this artefact by calculating two correction factors, derived by dividing the median particle number concentrations of 3 minutes before (after) the start (end) of the affected period by the median particle number concentration of 3 minutes after (before) the start (end) of the affected period. The data points of the affected period (i.e. during interstitial inlet measurements) were then multiplied by the linearly interpolated correction factor at the corresponding timestamp69. The data points of the total inlet measurement period were chosen as the reference to represent the “true” values as they corresponded to the ambient levels (baseline) of surrounding unaffected periods. For the aethalometer, AMS, and CCNC measurements, negative values or near-zero concentrations prevented the use of this multiplication/division-based method (increased offset if the affected period has negative values or unphysical division by zero), so that an adapted addition/subtraction-based method was used. There, the 1-h arithmetic mean of interstitial inlet measurements and the mean of the two adjacent hours of total inlet measurements were subtracted, and the resulting difference was added as a constant to the data points of the interstitial inlet measurements. This information is provided in the metadata of the published datasets. Finally, such a difference pattern was not observed for the WIBS and APS datasets, so that no corrections were needed.
In the Arctic, significant concentration changes can happen under certain conditions, e.g., changing wind direction, changing transport pattern, and evolving boundary layer dynamics. However, the 1-h cyclicity at which we observe the differences discussed above, and the evident relation with the switching valve operation indicate that such variations are non-representative of the “true” Arctic aerosol loading baseline and need to be corrected for. Each affected period was visually inspected, before and after correction, to ensure that the “true” variability in the signal (e.g., smooth increase/decrease in concentration during the passing of an air mass) would not be affected by these corrections.
Pollution detection
Atmospheric measurements of aerosols can be challenging in pristine locations such as the central Arctic due to disturbing emissions from local activities (e.g., exhaust by Polarstern’s engine and vents, skidoos, on-ice diesel generators68).
Thus, the aethalometer, WIBS, CCNC, and CPC3025 data were cleaned from the influence of fresh local pollution emissions using a pollution flag developed by Beck et al.68, where a multi-step pollution detection algorithm (PDA) was applied to the interstitial CPC dataset (CPC3025) at 1 min time resolution. This pollution flag identified 62% of all available data points, at 1 min time resolution, as being influenced by local pollution emissions. Spring and summer are most affected by local contamination while winter is least affected68. Additionally, for the WIBS data, data points with more than 10 polluted minutes within an hour were removed from the final dataset. For the aethalometer, this pollution flag was converted to the 10 min time resolution of the final dataset by setting a condition, where, if more than 1 data point is polluted in a 10 min moving window, the entire 10 min period is defined as polluted. An additional pollution flag, this time derived from applying the PDA to the CPC3776 dataset, was used to clean the CPC3776 time series. The following parameters were used in the PDA script to derive this pollution flag: power law filter with a = 0.35 cm−3s−1 and m = 0.58 s−1, and with upper and lower thresholds of 104 cm−3 and 60 cm−3, respectively. The neighbouring points filter was activated along with the median deviation filter with a median factor of 1.4. Finally, the sparse filter was also activated, with a window size of 30 data points and a sparse threshold of 6 data points. Overall, this pollution flag identified 69% of available measurements, at 1 min time resolution, as being polluted. Applying two different pollution flags for the two CPCs was needed as the two instruments may not have had exactly the same exposure to fresh local emissions from the ship’s stack due to the difference in the inlet locations and heights. This is partly seen in the different percentages of data points identified as polluted (62% when the PDA is applied to the CPC3025 dataset and 69% when applied to the CPC3776 dataset).
Since ship pollution observed on RV Polarstern peaked at a diameter of approximately 30 nm68, the APS dataset was less affected by pollution, also reflected in the smaller amount of pollution spikes compared to datasets including smaller diameters. Therefore, the PDA was applied to the APS total number concentration with the following parameters: interquartile range (IQR) filter with an IQR window of 2880 min and an IQR factor of 1.7. The upper threshold was set to 300 particles/cm3 and the neighbour decision was activated. Additionally, the median filter was applied with a median time window of 30 min and a median factor of 1.5, and the sparse filter, with a window size of 30 data points, and a sparse threshold of 20 data points. As a result, 16% of all available APS measurements, at 1 min time resolution, are defined as polluted.
Similarly, aerosols with sizes in which freshly emitted particles from the ship’s stack are found, are not efficiently measured by the AMS. This caused the CPC pollution mask to classify AMS data points as polluted, while they did not appear (visually and chemically) to be polluted. Consequently, a separate pollution mask was developed to remove freshly emitted pollution, following a cosine similarity approach described by Dada et al.31. In short, a minimum of two spectra, representative of fresh pollution, were chosen per month and averaged to create a reference spectrum of known pollution. We selected these spectra based on wind direction (possible influence of the ship’s emissions mainly between 120 and 240° from the stack), concentrations of ship emissions markers measured by the AMS (e.g., C4H7+, C4H9+ and C6H7+) and observations from other instruments consistent with fresh pollution (CPC and aethalometer). We then computed the similarity between this reference spectrum and each of the data points using the following formula (Eq. 1):
where A and B are the spectra at each data point and the reference polluted spectrum, respectively, and Ai and Bi are the components of these vectors (i.e. the fragments of the spectra). A threshold, above which data are considered polluted, was chosen at the cos θ value where 80% of the data points were outside of the 120–240° wind direction polluted window. We applied this method separately on three different periods, Oct-Dec, Mar-May and Jun-Jul and found thresholds of 0.41, 0.59 and 0.61, respectively. Additionally, a sparse filter with a moving window spanning 60 datapoints (approx. 1h30) was applied to define periods as entirely polluted, where more than 60% of the data points within the window were already classified as polluted by the cosine similarity method. With this method, 49% of the available AMS measurements, at 90 sec time resolution, are identified as being directly influenced by local pollution emissions.
Data Records
Table 3 summarizes data records for the datasets described in this work, with links to the open access PANGAEA repository, where they can be freely downloaded in tab-delimited text format. Table 4 summarizes the list of attributes and respective definition for the various files archived on PANGAEA. All datasets contain the following common variables: “Date/Time” (date and time of measurements in UTC), “Event” (event list of MOSAiC campaign PS122), and “Latitude” and “Longitude” of RV Polarstern in degrees north and east respectively.
The ARM CCNC, SMPS, and UHSAS datasets are freely available on the ARM open access data repository (https://adc.arm.gov/discovery/#/).
Technical Validation
AMS vs. SMPS mass closure
A mass closure analysis was performed between the total NR-PM1 calculated from the AMS (Eq. 2) and the one approximated from the particle counts, at mobility diameters (dm), measured by the SMPS located in the ARM container. We subtracted the aethalometer-derived eBC mass from the SMPS-derived PM1 mass, since BC is not measured by the AMS due to its refractory nature.
To account for the difference in cutoff sizes between the AMS (<1 µm, dva) and the SMPS (10–500 nm, dm), we assumed that the particles’ shape is spherical, and it follows that dva is roughly equal to dm, multiplied by the time and chemical-dependant particle density (ρcomp, Eq. 3)70,71,72,73.
We assumed a density of 1.75 g/cm3 for ammonium nitrate and ammonium sulfate74, 1.52 g/cm3 for ammonium chloride74, 1.2 g/cm3 for organic aerosols75, and 1.77 g/cm3 for black carbon76. When translated into dva, SMPS measurements ranged from 13 to 600 nm. We then compared the AMS mass integrated over all sizes versus the mass integrated between 13 and 600 nm in dva, and retrieved the slope of the linear regression between the two. The difference in cutoff sizes between the two instruments was then accounted for by dividing the AMS mass by the resulting slope value of 1.2622. The SMPS-derived PM1 mass was then calculated using ρcomp and assuming spherical particle shape. Both AMS and SMPS-derived PM1 time series were averaged to the common resolution of 10 min (that of the final eBC dataset) before proceeding to the comparison.
The mass closure analysis was performed independently for the three periods Oct-Dec, Mar-May and Jun-Jul, and yielded the following slopes (1/scaling factors): 0.271 (R2 = 0.016), 1.543 (R2 = 0.816) and 2.893 (R2 = 0.912) for the three respective periods, as shown in Fig. 3. Note that all datapoints under the influence of local pollution emissions were excluded from the analysis. Furthermore, the period from November 10th to December 5th, 2019 was also excluded from the Oct-Dec mass closure analysis, because of nearly continuous storm conditions, which resulted in strong discrepancies between the AMS and SMPS (potentially related to elevated sea salt concentration that could not be measured by the AMS due to their refractory nature). Hence, it is worth mentioning that sea salt is missing in this mass closure analysis and therefore the scaled AMS results represent an upper estimate. Finally, the scaling factors are not applied by default on the final dataset and are given as a reference depending on the needs of the user. We acknowledge that there is a large variability in the range of scaling factors depending on the period of the year, and overall large discrepancies between the AMS-derived PM1 and the SMPS-derived one. Nevertheless, as discussed in the “Aerosol chemical composition and mass concentration” section, the AMS measurement uncertainties are subject to a variety of influencing factors, including the estimation of IENO3 and RIEs from calibrations, the calculation of the CDCE and the single ion counting errors, that may add up to nearly 40% overall uncertainty62,77. These uncertainties are also much larger than the range of calculated inlet losses for the AMS sampling line (mostly below 10%, as presented in the “Inlet losses characterization” section) so that the losses cannot serve as an argument to explain the observed discrepancies. The fact that the instrument was each time in a different state, after long down times, can also explain part of the variability observed here. Also, the sea salt contribution to the aerosol population changes throughout the year22 and introduces various degrees of PM1 mass underestimation. Despite these discrepancies, the SMPS and AMS signals co-vary similarly, as inferred from the high R2 value for Mar-May (R2 = 0.816) and Jun-Jul (R2 = 0.912) periods (less so for the Oct-Dec period, where the forcing of the regression through the origin introduces a large bias). Given (1) the relative measurement uncertainties for both instruments (about 10% for the SMPS78 and up to 40% for the AMS62), (2) the fundamentally different measurement methods employed by the two instruments, and (3) the low aerosol mass concentration in the Arctic that makes the instruments work close to their detection limits, we believe that the measurements performed with the AMS are trustworthy, especially when the scaling factors calculated here are applied to the dataset.
Comparison of particle number size distribution from the APS and WIBS
To compare the size distribution of the APS and WIBS, we first corrected the APS aerodynamic diameter da based on experiments with Polystyrene latex (PSL) spheres (Eq. 4).
Then, da corrected was converted to the physical diameter dp, assuming it is equivalent to the optical diameter (Eq. 5)72.
Where ρp = 2.17 g cm−3 is the particle density based on the assumption that sea salt (NaCl) is the most abundant contribution to the central Arctic coarse mode aerosol, ρ0 = 1 g cm−3 is the standard density, and χ is the particle shape factor, which was set to 1.05 based on Zieger et al.79. The formula is typically used for smaller particle sizes for which the free molecular regime applies72 but resulted in the best agreement of the overlapping diameters in the particle number size distributions of the APS and WIBS. The APS number size distributions are only reported for diameters larger than 1.058 μm (da) as the concentration drop for smaller sizes disagrees with the WIBS and UHSAS data (Fig. 4b). After correction, a good agreement was found between the APS and the WIBS total concentration (R2 = 0.93, Fig. 4c).
CCN number closure and comparison with the ARM CCN dataset
To validate the measurements performed with the CCNC, we first performed a number-closure study with the SMPS data. At very high supersaturations (SS), most particles activate as droplets and the CCN concentrations measured by the CCNC are expected to be comparable, under certain conditions, to the total particle number concentrations derived from the size distribution measurements of the SMPS46. In practice, we expect the CCN number concentrations measured with the CCNC at 1% SS to be equal to the integrated SMPS number concentrations, starting with a diameter larger than 30 nm (SMPS>30nm, particles smaller than 30 nm might be below the activation diameter and will not be counted by the CCNC)46. The results from this analysis are presented in Fig. 5a, where the slope of the linear regression between the particle number concentrations measured with the CCNC at 1% SS versus the SMPS>30nm is equal to 0.84 (R2 = 0.98). Note that a period between December 5th and 12th 2019 was excluded from the regression computation, as elevated concentrations of (hydrophobic/non-hygroscopic) eBC (as measured with the aethalometer) greatly influenced the particles’ droplet activation and thus the CCN count from the CCNC. We also compared the measurement from our CCNC with those from the neighbouring CCNC in the ARM container, at 0.3, 0.5 and 1% SS (Fig. 5b–d). The two instruments agree well in general, with differences ranging from 8% at 0.3% SS to 14% at 0.5% SS, which fall within the range of uncertainty for both instruments (≈ 10%, propagated to 22.5% when considering the intercomparison of the two46,63).
Intercomparison between the two CPCs
The particle number concentrations measured by the two CPCs were compared to assure the quality of each dataset. For the comparison, datapoints under the influence of local pollution from ship emissions were discarded and 1 min averaged data were used for both CPCs. Figure 6 shows the results of this comparison, where a slope of 1.166 (R2 = 0.95) was found for the fitted linear regression between the CPC3776 and CPC3025 measured number concentrations. In general, the measurements from the two instruments agree well, with a tendency for the CPC behind the interstitial inlet (CPC3025) to underestimate particle number concentrations during periods of high number concentrations for typical Arctic air (approx. > 300 particles/cm3). These periods were mainly observed during summer months (June, July and August) where the particle size distribution is dominated by ultrafine and Aitken mode particles30, with a number of NPF events. As the minimum nominal detectable particle diameter differs for the two instruments (2.5 nm for the CPC3776 and 3 nm for the CPC3025), the occurrence of NPF events contributes to the observed difference at high particle number concentrations between the two instruments (not shown).
Usage Notes
We strongly encourage the reader to refer to the datasets’ metadata, published on PANGAEA (see Sect. Data Records), for further details on data usage. Pollution flags and/or quality-check flags are provided with each dataset and should be carefully applied before further data analysis. For the AMS, the scaling factors from the mass closure analysis with the SMPS are not applied to the dataset by default. The user is left with the decision to apply them or compute new ones.
The temperature measurements in the total and interstitial inlet can be used to convert measurements into Standard Temperature and Pressure (STP) conditions.
Code availability
The pollution detection algorithm described in Beck et al.80 to identify and flag periods of primary polluted data is available on Zenodo (https://doi.org/10.5281/zenodo.5761101).
High Resolution ToF-AMS Analysis guide from J. L. Jimenez research group’s wiki (CIRES, University of Colorado at Boulder, USA): https://cires1.colorado.edu/jimenez-group/wiki/index.php/High_Resolution_ToF-AMS_Analysis_Guide (last accessed: 03/03/2022).
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Acknowledgements
Data reported in this manuscript were produced as part of the international Multidisciplinary drifting Observatory for the Study of Arctic Climate (MOSAiC) expedition with the tag MOSAiC20192020, with activities supported by Polarstern expedition AWI_PS122_00. The authors would like to thank the teams at the Paul Scherrer Institute and INAR for their land-based support during the MOSAiC expedition. We also thank all those who contributed to MOSAiC and made this endeavour possible81. This research was funded by the Swiss National Science Foundation (grant no. 200021_188478) and the Swiss Polar Institute (grant no. DIRCR-2018-004). J.S. holds the Ingvar Kamprad chair for extreme environments research, sponsored by Ferring Pharmaceuticals. This project has received funding from the European Union’s Horizon 2020 research and innovation program under grant agreement no. 101003826 via project CRiceS (Climate Relevant interactions and feedbacks: the key role of sea ice and Snow in the polar and global climate system), and from the Academy of Finland (grants no. 337552, 333397, and 337549). A subset of data was obtained from the Atmospheric Radiation Measurement (ARM) User Facility, a U.S. Department of Energy (DOE) Office of Science User Facility managed by the Biological and Environmental Research Program. We acknowledge funding from the US Department of Energy grant no. DE-SC0022046 and DE-SC0019251, and NOAA Cooperative agreement NA22OAR4320151.
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L.L.J.Q., I.B., J.S., T.J. and T.L. conducted the measurements in the Swiss container during MOSAiC. S.H. provided the CCNC and performed the first calibration in June 2019. C.K. is the lead mentor for the ARM SMPS. J.U. is the lead mentor for the ARM CCNC and UHSAS. B.H., N.B., I.B., H.A. and L.D. prepared the final quality-controlled datasets for the instruments located in the Swiss container, with help from J.S., K.R.D., M.B., Z.B., T.P., M.K., M.S., J.L., M.L. and M.D.S. B.H. wrote the manuscript with contribution from all co-authors. J.S. obtained the funding and conceived the field measurements for the Swiss Container.
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Heutte, B., Bergner, N., Beck, I. et al. Measurements of aerosol microphysical and chemical properties in the central Arctic atmosphere during MOSAiC. Sci Data 10, 690 (2023). https://doi.org/10.1038/s41597-023-02586-1
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DOI: https://doi.org/10.1038/s41597-023-02586-1
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