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Article

War Impact on Air Quality in Ukraine

by
Rasa Zalakeviciute
1,*,
Danilo Mejia
2,3,
Hermel Alvarez
3,
Xavier Bermeo
4,
Santiago Bonilla-Bedoya
5,
Yves Rybarczyk
6 and
Brian Lamb
7
1
Grupo de Biodiversidad Medio Ambiente y Salud (BIOMAS), Universidad de Las Américas, UDLA, Vía a Nayón, Quito 170124, Ecuador
2
Grupo CATOx, CEA de la Universidad de Cuenca, Cuenca 010107, Ecuador
3
Grupo de Ecología Acuática, Universidad de Cuenca, Cuenca 010107, Ecuador
4
Bermeo-Idrovo Law firm, George Washington y Amazonas, Quito 170520, Ecuador
5
Research Center for the Territory and Sustainable Habitat, Universidad Tecnológica Indoamérica, Machala, Quito 170301, Ecuador
6
Faculty of Data and Information Sciences, Dalarna University, 791 88 Falun, Sweden
7
Laboratory for Atmospheric Research, Washington State University, Pullman, WA 99164-2910, USA
*
Author to whom correspondence should be addressed.
Sustainability 2022, 14(21), 13832; https://doi.org/10.3390/su142113832
Submission received: 15 August 2022 / Revised: 21 September 2022 / Accepted: 5 October 2022 / Published: 25 October 2022
Browse Figures
Review Reports Versions Notes

Abstract

:
In the light of the 21st century, after two devastating world wars, humanity still has not learned to solve their conflicts through peaceful negotiations and dialogue. Armed conflicts, both international and within a single state, still cause devastation, displacement, and death all over the world. Not to mention the consequences that war has on the environment. Due to a lack of published research about war impact on modern air quality, this work studies air pollution evolution during the first months of the Russian-Ukrainian conflict. Satellite images of NO2, CO, O3, SO2, and PM2.5 over Ukrainian territory and PM2.5 land monitoring data for Kyiv were analyzed. The results showed that NO2 and PM2.5 correlated the most with war activities. CO and O3 levels increased, while SO2 concentrations reduced four-fold as war intensified. Drastic increases in pollution (especially PM2.5) from bombing and structural fires, raise additional health concerns, which might have serious implications for the exposed local and regional populations. This study is an invaluable proof of the impact any armed conflict has on air quality, the population, and environment.

1. Introduction

In the light of the 21st century, after going through two devastating world wars in the previous century, it might seem that humanity would finally find a way to solve their conflicts through peaceful negotiations and dialogue. Armed conflicts, both international and within a single state, still cause devastation, displacement, and death. Not to mention the consequences that war has on the natural and built environments. However, this century is not that different from others, with twenty-seven armed and six “devastating” conflicts happening in the world right now, including Afghanistan, Yemen, Ethiopia, South Sudan, Syria, and, recently, Ukraine [1]. The latter is a perfect example of how unpredictably peace can be lost anywhere on the planet. It is especially worrisome due to the involvement of nuclear power and the economic and energetic consequences that already have started to unfold, which might take this disaster to a whole new catastrophic level, and create a global outcome for many years to come.
Such drastic shifts in mass human activities must undoubtedly affect environmental quality through the changes in the anthropogenic pollution emission rates. In 2020, the scientific community was presented with an unprecedented experiment of the effects of global pandemic on modern environmental quality. Several studies analyzed the effects of the restrictions of anthropogenic (i.e., industrial, transport, etc.) activities, enforced by governments to control the spread of COVID-19, had on air quality. As expected, the findings indicated a significant reduction in concentrations of the most common (i.e., criteria) atmospheric pollutants, such as particulate matter (PM), carbon monoxide (CO), nitrogen oxides (NO and NO2) and sulfur dioxide (SO2) [2,3]. Meanwhile, ozone (O3) showed some variations globally, due to its secondary formation nature. Lamentably, despite the dramatic declines in emissions of anthropogenic atmospheric pollutants, the greenhouse gas trends were not detained [4], partly due to a reduction of CO2 ocean uptake and NOx emissions affecting CH4 lifetime and O3 response [5].
A number of studies with a very different focus report that public protests or strikes also tend to significantly limit motorized transport emissions [6,7,8,9]. These exceptional events, however, may create additional sources of pollution, for instance, due to an increased use of private vehicles, or burning, and vandalism in order to create physical barriers [10,11,12]. Even then, an overall reduction in urban pollution levels is reported [13].
While there are various publications focusing on the impact of restrictions for normal human activities (e.g., pandemic and protests), and even the economic and psychological effects of war [14,15,16,17], there are very limited studies on war and its impact on air pollution (see Table A1, Appendix A). Some studies focus on a general understanding of the effects that war might have on air quality and global temperatures in terms of weapon development and use, as well as the economic and environmental burden of rebuilding the war-caused destruction [18,19,20]. Similarly, it is motivating to evaluate the environmental effects of atmospheric emissions of industrial boom after war or, in contrast, of economic crisis [21,22,23]. Other studies focus on the chemical composition of shells, rockets or missiles, which are pulverized during the explosion and will persist for many years in the environment (i.e., metals, etc.) continuously poisoning the environment and human health [24,25]. There are also specific case studies about the Cold War restrictions on the efforts to monitor regional and global air pollution [26], or quantitative risk assessment of premature mortality related to increased PM10 levels due to 1991–1992 Gulf War [27], and a consequent decrease in solar power production [28]. Finally, there are studies on regional air pollution from simultaneous destruction of major industrial sources due to industrial accidents or oil-refinery fires in Serbia [29,30,31]. Very few studies investigate air quality changes during a war (Table A1, Appendix A). In addition, they focus on a single pollutant, mostly PM. Moreover, to the best of our knowledge, there are no studies on the impact of recent wars on air quality. As surprising as it may be, the investigations on concentration changes of regulated atmospheric criteria pollutants during a war are nonexistent, which makes this study pioneer research of its kind.
At the same time, the fluctuations in ambient air quality levels are now a major concern, as air pollution is the world’s greatest environmental threat for premature mortality [32,33]. This is especially true in cities, where almost all urban human population is breathing air quality violating the World Health Organization’s (WHO) recommendations [34,35]. Atmospheric pollutants can cause a diversity of respiratory and cardiovascular health problems [36,37]. The elevated concentrations of air pollution are especially dangerous for at-risk populations: the young, the elderly, and people with compromised health [38].
Therefore, in this work, air quality evolution is assessed during the first weeks of the Russia-Ukraine conflict in a context of the business-as-usual conditions of previous years and weeks. To estimate the impact of the war on air quality in Ukraine, the war impact on concentrations of PM2.5 (particulate matter with aerodynamic diameter ≤2.5 µm), NO2, CO, O3, and SO2 were evaluated by comparing satellite data during periods prior to the war with data during the war. This was done considering a combination of 2-week time periods: (i) the two first weeks of the war (22 February–8 March) in 2022 vs. the same dates of 2019–2021; and then (ii) pre-war air quality (8–21 February) vs. three consecutive 2-week periods the 1–2nd (22 February–8 March), 3–4th (9–22 March) and 5–6th (23 March–6 April) weeks of war of 2022. Since the ground data for the country (except for Kyiv district) are non-existent, satellite images were used to analyze the differences between the air pollution in Ukrainian territory before and during the war. Later, PurpleAir network land data for the capital city Kyiv were analyzed to investigate local air quality dynamics over February–April 2022. While the present work does not focus on the political causes and origins of the conflict, the results of this study offer invaluable insights to the environmental impacts of war and its evolution in the biggest European country. The findings may also benefit physical and public health studies, due to a growing extended period of emission of toxic air pollution.

2. Methodology

2.1. Study Site

The independent republic of Ukraine is located in Central and Eastern Europe, in the south-eastern part of the Eastern European Plain (Figure 1a). Ukraine shares land borders with Belarus in the north, Poland in the west, Slovakia, Hungary, Romania, and Moldova in the southwest, and Russia in the east. The south of Ukraine is bathed by the Black and Azov Seas. It also has a maritime border with Romania, Russia, Bulgaria, Turkey, and Georgia. From north to south the territory of Ukraine stretches for 893 km, from west to east for 1316 km, with a total area of 603,628 km2, occupying 5.7% of Europe and 0.44% of the world [39]. As of 1 March 2011, the total permanent population of Ukraine was 45,564,858 and 43,814,581 in 2021, showing a rapid prewar decline, with almost two thirds of population residing in urban areas [39,40].
Followed by a number of armed conflict warnings and months of preparations by Russia (i.e., ~200,000 Russian troops gathering just outside the Ukrainian borders) and an issued statement by Russia’s political leader on 21 February, followed by a few days (21–23 February 2022) of escalation (Figure 1b), during which Russian military forces began a “special military operation“ in Ukraine on 24 February 2022 [43]. For this study, therefore, we do not consider the days before the invasion as “normal” conditions, but more likely the early days of war. The advances of the Russian army were met with a strong resistance from the Ukrainian army and civilians (Figure 1c,d) [41,42]. Due to the danger of constant bombing, shelling and shooting (i.e., thousands of civilians killed, see Figure 1b) and the destruction of water supply, electricity, and other infrastructures, in six months of conflict, according to the United Nations (UN) migration agency, an estimated 6.5–7 million people were internally displaced, and nearly 3.5–5 million people left Ukraine as war refugees [44,45]. While some people came back, there is still a large quantity of the population trying to evacuate.
According to the World Bank data and predictions, Ukraine’s economy is expected to be set back by 45% due to the war and the consequent destruction of infrastructure [46]. However, the extent of economic damage might further worsen depending on the duration and intensity of the conflict. This consequently causes an extended period of emission of toxic air pollution, as towers of smoke are reported from multiple parts of the country, which might affect human and environmental health in the short- and long-term.

2.2. Satellite Data and Analysis

Since most of the on-line monitoring stations have been removed or destroyed due to war activities, the air quality assessment for the country was performed using satellite data. The concentration columns (µmol m−2) of gases and particulate matter used in this research project are products of the TROPOMI instrument on board the Sentinel-precursor (S5P). This satellite carries instruments for the measurement of various pollutants such as NO2, CO, SO2, and O3 [47]. In addition, concentration images (µg m−3) of PM2.5 forecast, obtained from the European Centre for Medium-Range Weather Forecasts (ECMWF), were used [10]. For our analysis, the Google Engine (GGE) platform was used [48].
Maps illustrating air pollution were produced using QGIS Madeira software version 3.4.14 [49].
The S5P satellite data resolution of concentration (mol m−2) columns is 1 km2 per pixel. Knowing that Sentinel 5P TROPOMI has some bands to identify the concentration of different pollutants, for NO2 the “tropospheric_NO2_column_number_density” band, showing the tropospheric vertical column of NO2, was used [50]. For CO, the band “CO_column_number_density” which refers to the vertically integrated CO column density was used [51]. For SO2, the band “SO2_column_number_density”, which means using vertical column density of SO2 at ground level, calculated using the DOAS technique, was used [52]. For O3, the band “O3_column_number_density” which contains total atmospheric column of O3 between the surface and the top of atmosphere from the Royal Netherlands Meteorological Research Institute (KNMI) was used [53,54]. Finally, for the PM2.5, medium-term weather forecasts (ECMWF) were used, specifically the particulate_matter_d_less_than_25_um_surface band that measures PM2.5 particles with 45 km2 resolution at the Earth’s surface.
For this study, daily images were separated into two groups. The first group includes the beginning dates of the conflict in different years (2019–2022): (i) 22 February–8 March 2019; (ii) 22 February–8 March 2020; (iii) 22 February–8 March 2021; and (iv) 22 February–8 March 2022. The pollution levels for 2019 are the most representative of business-as-usual (BAU) conditions. Meanwhile, the same 2-week period in 2020 was right before the COVID-19 pandemic, thus it could also be considered as BAU conditions. The period of 22 February–8 March of 2021 was BAU affected by COVID-19 pandemic.
The second group includes a single 2-week period right before the war and three 2-week periods (6 weeks) during the war: (i) 8 February–21 February 2022; (ii) 22 February–8 March 2022; (iii) 9 March–22 March 2022; and (iv) 23 March–6 April 2022. Later, another 2-week period (weeks 7–8 of war: 7 April–24 April 2022) was added to further study PM2.5 concentrations in the Kyiv region, as military activities around Kiev were very turbulent during the first two months of the war. Since an average image was obtained for each selected date range, raster spatial analysis tools were used to obtain the averages and one standard deviation for the study weeks. To observe the maximum values over a selected period, the average pixels with the highest values were chosen for that period in the territory of Ukraine. To calculate the above-mentioned statistics, the raw satellite pixel data were cleaned from negative <0.5 values. To calculate the above statistics, the raw satellite pixel data (NO2, CO, O3, and SO2) were used for the quality indicator, which was used to select only good quality data (data > 0.5), which eliminates cloud-covered scenes, errors, and problematic retrievals [50,51,52,54].
The Google Earth Engine (GEE) platform was used to download L3 level products, which uses HARP commands that provide high resolution images.
To study the dynamics of air quality during the war in the region of Kiev, where the fighting was the most intense during the study period, some additional analyses were performed using Empirical Bayesian kriging (EBK). This method allows superior quantification of the uncertainty in the predictions and makes probabilistic statements at high geographical resolution of PM2.5 or other air pollutants [55,56]. Using this method, 0.03 km2 spatial resolution images were obtained.
Statistical analyses were performed for all criteria pollutants for the polygons of the whole Ukraine and the region of Kyiv. Sensitivity analysis was performed between different years and weeks for each criteria pollutant using statistical inference tests. A t-test was performed to compare the concentrations of air pollutants during 22 February–8 March 2022 vs. 22 February–8 March of 2019–2021. This type of analysis shows whether there are significant differences for the three pairwise comparisons: 2019 vs. 2022; 2020 vs. 2022; and 2021 vs. 2022. If p value is < 0.05, it means the difference between the data from the first two weeks of the war vs. same period of BAU years is significant. The percentage change was calculated between the 2022 and 2019–2020 (BAU). In addition, a one-way ANOVA was performed to compare the concentrations of five criteria pollutants over the 2-week periods of war. Five 2-week periods (pre-war air quality) (8–21 February 2022); the 1–2nd weeks of war (22 February–8 March 2022); the 3–4th weeks of war (9–22 March 2022); the 5–6th weeks of war (23 March–6 April 2022); the 7–8th weeks of war (7–24 April 2022) were run for PM2.5. Total of four 2-week periods were analyzed for NO2, CO, and O3 (pre-war air quality (8–21 February 2022); the 1–2nd weeks of war (22 February–8 March 2022); the 3–4th weeks of war (9–22 March 2022); and the 5–6th weeks of war (23 March–6 April 2022). Finally, only three 2-week periods were analyzed for SO2 (the 1–2nd weeks of war) (22 February–8 March 2022); the 3–4th weeks of war (9–22 March 2022); the 5–6th weeks of war (23 March–6 April 2022), due to the cloudiness obstruction on satellite images. The results of this type of statistical test show whether there are significant differences between pollutant concentrations in the region between different weeks of war. If F value is > F critical (p < 0.05), the difference of concentration between the weeks is considered significant.

2.3. PurpleAir PM2.5 Data in Kyiv, Ukraine

For a study of Kyiv’s regional evolution in air quality, open source available PM2.5 land data were downloaded from PurpleAir Sensor data download tool for existing Ukrainian air quality stations at https://www.purpleair.com/sensorlist?key=DE94YTZ7Z3RM4JLQ&show=52643. This tool allows you to download PurpleAir sensor data in CSV format for selected sensors. Out of four registered PurpleAir stations (Figure 1b), all in the proximity to Kyiv (Figure 1b), only three had data for the study period (Dmitrovichi (Station 4) did not have data): Station 1 (Shepeleva) and Station 2 (Hlepcha) had complete data sets, while Station 3 (Shevchenkove) had a few days of missing data. The PM2.5 data were downloaded for 1 February–28 April 2022, which includes the 2-week pre-war period and six weeks of war studied in this paper. The data was handled following PurpleAir sensor correction procedure established by [57], suggested for the international use [58]:
PM2.5 corrected = 0.524 × [PurpleAirCF = 1; avgAB] − 0.0852 × RH + 5.72
where, RH stands for relative humidity (%) at the station; PAcf = 1; avgAB = PurpleAir higher correction factor data averaged from the A and B channels. Each station has data for A and B channels, which were averaged and then corrected using the Equation (1). The hourly time series of PM2.5 data were presented to show the air quality dynamics in the most intensely confronted and defended area of Ukraine in the first months of the war. To be able to compare with the satellite data, PurpleAir land data were also averaged over corresponding 2-week periods. Finally, statistical analyses of Single Factor ANOVA were done for each station to study if PM2.5 levels were significantly different over the two weeks prewar and eight weeks of the war.

3. Results and Discussion

3.1. Air Quality during First Two Weeks of the War vs. Business-as-Usual Conditions

Satellite images of 2-week average vertical column concentrations of five criteria pollutants (NO2, CO, O3, SO2, and PM2.5) are presented in Figure 2 for 22 February–8 March of 2019, 2020, 2021, and 2022. The contrast between the first two weeks of war in 2022 compared against the same period of previous years is necessary to analyze the impact of this exceptional event on air pollution (Table 1). The pollution levels in 2019 are the most representative of business-as-usual (BAU) conditions. This 2-week period in 2020 was right before the COVID-19 pandemic, thus it could also be considered as BAU conditions. The period between 22 February–8 March of 2021 was affected by COVID-19 pandemic.

3.1.1. NO2 during Two Weeks of War vs. Business-as-Usual Conditions

Because of the war, the concentrations of NO2 decreased the most from all the gaseous criteria pollutants. Tropospheric column concentrations of NO2 were significantly (p = 0.00) higher during BAU conditions in 2019 (28.4 ± 12.9 µmol m−2, Figure 2a) and 2020 (27.2 ± 10.3 µmol m−2, Figure 2b), when compared to the first two weeks of war (21.1 ± 9.9 µmol m−2, Figure 2d, Table 1). In 2020, the year of COVID-19 pandemic (the sanitary emergency was established on 20 March 2020 in Ukraine), the pre-pandemic conditions’ NO2 levels were slightly lower than in 2019, except for in the Kyiv region and the Eastern territory—the most industrialized areas of the country (Table 1, Figure 2a,b). In post-pandemic year 2021 (Figure 2c, Table 1), the anthropogenic activity was reestablished (23.4 ± 13.2 µmol m−2) and can be confirmed by the increased NO2 levels in the western part of the country and around Kyiv, with peak levels of around 178 µmol m−2.
The analysis of NO2 concentrations in the Kyiv region showed that overall NO2 concentrations were higher than over the whole of Ukraine during the 2-week periods of early spring (February 22–March 8), during all four studied years.
NO2 levels during the first weeks of war were 24.1% lower for the whole country and 40.42% lower for the capital when compared to BAU conditions (Figure 2d, Table 1). This reduction could be attributed to the diminished anthropogenic activity during the beginning phases of the war, as previously seen in COVID-19 studies [2]. Particularly limited spikes of NO2 can be observed in the eastern territory (max: 139.7 µmol m−2), the area with the most consistently active war activity, including conflicts that started in 2014 (Figure 2d) [42]. Due to the multiple explosions and combustion processes, some scattered pollution spikes, too small in their scale to be urban emissions, show up in the context of the overall low background levels. One distinction is Crimea, where the NO2 levels in 2022 were higher than during the previous years (Figure 2d). This is a disputed territory of Ukraine since 2014, which may be more active in terms of sustaining normal anthropogenic activity.
These findings compare well to other studies reporting NO2 levels over urban areas [59]. Concentrations ranging around 33–116 µmol m−2 are normally found over remote regions, 150–200 µmol m−2 over cities, while concentrations over 500 µmol m−2 are a health concern [59,60].

3.1.2. CO during Two Weeks of War vs. Business-as-Usual Conditions

Total CO column concentrations, with sensitivity for the tropospheric boundary layer due to its longer atmospheric lifetime, demonstrate a regional pollution behavior and less variable pre-war atmospheric column levels at around 36.3 ± 1.2–37.1 ± 1.3 mmol m−2, during BAU conditions (Figure 2e–h and Table 1). It can also be perceived that the concentrations of CO during the early spring (February 22–March 8) of all four studied years are higher over the region of Kyiv when compared to the whole country (Table 1).
These values also compare well to the levels in other global cities varying around 26–40 mmol m−2 [59]. As expected, some increase in CO levels can be noted in Kyiv and coastal areas during the “normal” year of 2019 (Figure 2e).
During the two first weeks of war in 2022 a significant (p = 0.00) but small reduction in CO levels (35.2 ± 1.3 mmol m−2) can be noted for Ukraine (−3.83%) and Kyiv (−2.73%), when compared to BAU conditions in 2019 and 2020 (Figure 2h, Table 1). It is reasonable, as all combustion sources, such as motor vehicles, power stations, waste incinerators, domestic cooking, etc., emit carbon monoxide. Therefore, there must be a certain effect in CO levels due to a reduction in human circulation, and processes including industries, power production, and urban infrastructure, due to the devastating war conditions. Airstrikes and explosion combustion processes must generate CO emissions due to fires; however, it does not seem to be the case for peak levels that remain lower than usual (Table 1).

3.1.3. O3 during Two Weeks of War vs. Business-as-Usual Conditions

The interpretations of total column of O3 are somewhat more complicated due to its secondary nature of formation, thus making it more difficult to determine the direct impact of the war on its concentrations. It means that O3 concentrations might increase following a drop in anthropogenic NOx levels, which has been reported in relation to NOx concentration drop during the COVID-19 pandemic [2,61] and ozone weekend effect [62]. NO2 reduction was witnessed in this work as well. Consequently, in Figure 2i–l, although spatially significant (p = 0.00), small increases in O3 levels from BAU can be observed for Ukraine (2.45%) and Kyiv (3.38%) during the first two weeks of war in 2022 (Figure 2i–l, Table 1). Concentrations of O3 are almost always (except 2019) higher for Kyiv, when compared to the wider territory of Ukraine. However, peak O3 levels (171.0–184.8 mmol m−2) seem to have a regional influence trend, varying between the northeastern (2019 and 2021) and southern (2020 and 2022) regions of the country, and reaching its maximum peak concentration in early spring of 2019.
The total column of ozone levels varies between 40 mmol m−2 (tropics) and 200 mmol m−2 (poles), thus the concentrations reported by this study (159.5 ± 5.4–173.7 ± 6.3 mmol m−2) compare well (Table 1) to the elevated levels globally reported for midlatitudes [63].

3.1.4. SO2 during Two Weeks of War vs. Business-as-Usual Conditions

In 2021 (Figure 2o) and 2022 (Figure 2p), more areas with increased total column SO2 levels were observed, with the average concentrations at 0.99 ± 0.87 mmol m−2 and 1.07 ± 0.98 mmol m−2, respectively (Table 1). A trail of higher SO2 concentrations, compared to the background levels, is seen along the most industrialized areas of the country along the Dnieper River in 2019 (Figure 2m). In 2020 (Figure 2n), a similar behavior can be observed. Meanwhile, in 2021 an overall increase in background SO2 and clear higher levels of SO2 in Kyiv are reported, with the highest peak levels (24.1 mmol m−2) over the studied period (Table 1).
During the first 2-weeks of war in 2022 (Figure 2p), western Ukraine registered higher overall SO2 levels than before, peaking at 19.3 mmol m−2 and over the whole country averaging at the maximum value of 1.07 ± 0.98 mmol m−2. Over the first weeks of the war, SO2 concentrations increased 38.06% for the whole country and 10% for the capital city, when compared to BAU conditions. In addition, Kyiv SO2 concentrations were significantly (p = 0.00) lower during the first two weeks of war than the same period in the two previous years (Figure 2m–p). Again, as in the case of NO2, SO2 levels in Crimea were twice as high than in the previous years. The attacks of southern Ukraine originating from Crimea might help explain this. Similar evolution is seen in the eastern part of the country, possibly due to military activities in Donetsk and Luhansk regions and a consequent use of fossil fuels. In addition, destruction of fuel storage facilities is a common tactic reported in this war, thus further explaining an increase in SO2 concentrations despite the reduction of “normal” anthropogenic activities.
Globally observed SO2 total column levels range between 1 and 100 mmol m−2, with levels that could jump to around 20 mmol m−2 over the major cities [64]. Thus, levels reported in this study compare well with previous research findings.

3.1.5. PM2.5 during Two Weeks of War vs. Business-as-Usual Conditions

Finally, PM2.5 demonstrated the most drastic significant (p = 0.00) reduction in the country-wide concentration average of 3.7 ± 0.8 µg m−3 during the first two weeks of war in 2022 when compared to BAU conditions (~6 µg m−3) (Figure 2q–t, Table 1). PM2.5 levels in the capital city were lower than in the rest of the country during every studied year, indicating fair living conditions for urban population, and suggesting other-than-mobile sources for this pollutant. PM2.5 concentrations over the whole country dropped 38.33% and in Kyiv, decreased by 30.82%, reaching the levels under WHO’s restricted health standard of 5 µg m−3 for annual averages (Table 1). There are, however, a few flash points around Kyiv and Donetsk, all along the borders of military actions, indicating smoke particles from localized bomb or missile destruction, which would generate fire and smoke (Figure 2t). There were over a hundred cases of explosions all over the country (Figure 1), aimed at the major cities, during the first days of the conflict [42], which might help explain the more localized pollution “hotspots”, rather than regional particle pollution spread from urban areas.

3.2. Air Quality Changes during Six Weeks of War

When studying the first six weeks of the conflict and the two weeks before the war, clear changes in air quality can be seen over Ukraine (Figure 3 and Table 2). The statistical analysis showed that there is significant difference (p < 0.05) between all the studied periods for all the criteria pollutants indicating war dynamics impact on regional air quality.

3.2.1. NO2 Concentration Change during Six Weeks of War

When analyzing the concentrations of NO2 before the war started, elevated levels in the region of Kyiv and the eastern territories of the country can be observed (Figure 3a, Table 2). However, after the 22nd of February, the situation changes drastically, and since F > F critical (p < 0.05), the difference of NO2 concentrations between all the weeks is considered significant. Overall levels of NO2 drop (−28.23%) from 29.4 ± 13.7 µmol m−2 to 21.1 ± 9.9 µmol m−2 (Figure 3b, Table 2). An even larger NO2 concentration reduction was observed for Kyiv (−58.98%). During 22 February–8 March 2022, the whole country was indicating a significant (p < 0.05) reduction in NO2 pollution, which is a strong indicator of reduced anthropogenic activity, such as motorized transport, industry, etc. (Figure 3b, Table 2). This can be explained by the fact, that starting very early on, many parts of Ukraine (i.e., Lviv, Kyiv, Kharkiv, Mariupol, Kherson, etc.) received a huge number (at least a hundred) of Russian army airstrikes or shelling [42]. The situation in the streets became very dangerous, and thus people were forced to escape or hide in the underground shelters. Military attacks started from the north towards the capital, from the south, from Crimea towards Mariupol and Kherson, and from the east towards Kyiv, Mariupol, and Kharkiv (Figure 1b) [42]. During the 3–4th weeks of war in early to mid-March, Russian artillery started hitting civilian targets, as the ground advances were restricted by the Ukrainian counterattacks. This can be seen in the satellite maps of 9–22 March 2022, especially of NO2 and PM2.5 concentrations in Kharkiv and Mariupol (east) and Kyiv and Lviv (West) (Figure 3c,s and Table 2). During this period, although significantly (p < 0.05) lower than before the war, concentrations increased to 24.2 ± 10.8 µmol m−2 for Ukraine and to 37.89 µmol m−2 for Kyiv. In fact, NO2 levels were higher in the capital during all studied weeks (Table 2). During the 5–6th weeks of war and on, heavy shelling took place in the Donbass region [42]. This can be seen in Figure 2d, where the eastern territory is the only area with increased NO2 concentrations (Table 2). Significantly (p < 0.05) lower overall concentrations during the 5–6th weeks of the war point to the localization of the Russian attacks in eastern Ukraine (Figure 3d, Table 2).
While there are no studies that discuss war related NO2 concentration change, other studies might help support these findings. For example, reduction in NO2 concentrations were reported related to negative fluctuations in GDP in some parts of the Middle East, in the years following the Gulf War [23]. Drop in NO2 concentrations up to ~70% was also reported in many countries during the strict quarantine phases of the COVID-19 pandemic [2]. However, probably due to the nature of public protests, including restrictions on circulation and simultaneously burning barricades or other objects, this type of study is more suitable for comparison to war conditions. NO2 concentrations dropped 31.5–32.36% during the public protests in the Ecuadorian capital comparing the best to the findings of this study [13].

3.2.2. CO and O3 Concentration Changes during Six Weeks of War

On the other hand, CO, O3, and PM2.5 show different trends. Concentrations of all these pollutants were higher in Kyiv compared to the country. An overall increase, although significant (p < 0.05), was very small (4.19%) for CO at 35.3 ± 1.2–37.1 ± 0.9 µmol m−2 by the 3–4th week of the war and (6.44%) for O3 at 159.1 ± 1.3–173.3 ± 1.5 µmol m−2 by the 1–2nd week of war (Figure 3e–l and Table 2). These increases are also more regional, due to the total column concentration data, spreading over a bigger area, unlike the localized events described with NO2 pollution. In contrast to reported CO concentration reduction, as also shown here during the first two weeks of the war for Ukraine and Kyiv, during unusual events such as global pandemic or local political protests, O3 concentrations tend to increase, as also shown in this work due to war activities [2,13]. An increase in CO concentrations might be an indicator of an increase of war related combustion activities (e.g., fires, explosions, etc.), as opposed to the sole impact of global restrictions on human circulation.

3.2.3. SO2 Concentration Change during Six Weeks of War

This similar behavior, demonstrated by reduction in NO2 concentrations, was also observed for SO2. Concentrations of SO2 dropped significantly (p < 0.05) at about four times below the previous concentrations at the end of the six weeks of fighting in Ukraine, from 1.6 ± 2.1 mmol m−3 to 0.4 ± 0.3 mmol m−3 (Figure 3m-p and Table 2). The reduction in SO2 concentrations in Kyiv is also significant (p < 0.05), but not as strong (−27.78%) by the 5–6th weeks of the war. In fact, the levels of SO2 increased in Kyiv during the first two weeks of war, indicating an increase in low quality (high sulfur count) fuel combustion. This could apply to military vehicles use in the region or use of fossil fuels to survive (i.e., cooking, heating, etc.). It is further supported by the fact that before the war and until the 5th week of the war, the levels of SO2 were always higher in the country-wide average vs. the capital.
No prior war impact studies exist which investigate SO2 level changes during such an event; thus this study can only be compared to other types of studies, such as the COVID-19 pandemic or public protests. Sokhi and colleagues [2] showed 25–60% reduction in SO2 concentrations, varying across the countries, depending on the level of strictness implemented nationally to stop the spread of the virus. Meanwhile, only ~7% reduction in SO2 levels was registered during the violent public protest in Quito, Ecuador [13].

3.2.4. PM2.5 Concentration Change during Six Weeks of War

Finally, PM2.5 is the most interesting case pollutant when studying the impact of war dynamics on air quality. Since F > F critical (p < 0.05), the difference of concentrations between all the studied weeks (i.e., before and during the war) is considered significant. In addition, PM2.5 concentrations during 3–6th weeks of the war were higher than the remaining weeks in Ukraine and Kyiv. Over the six weeks of war its concentrations almost tripled in terms of average values from 3.7 ± 0.8 µg m−3 to > 9.4 ± 1.9 µg for the whole country and from 4.66 to 11.48 µg m−3 for Kyiv (Table 2 and Figure 3r-t). Findings of this work can be partially compared to other studies, showing 1.5–3 times increase in PM10 levels over the duration of war due to the burning of oil fields and other military activities [27,28]. Furthermore, parts of the country at the 5–6th week of war approached peak concentrations of 24.2 µg m−3 (Figure 3t), which is significantly above the WHO’s recommended safe levels for 24-h exposure (15 µg m−3) [65]. We also note that these data represent PM2.5 concentrations averaged over 14-day periods. Therefore, the violation of health standards for an extended period surely will cause serious short- and long-term health problems in the exposed population. This suggests that the country, as war intensified, was more regularly covered with elevated PM levels (e.g., smoke), and a massive area of the country found itself exposed to unhealthy levels of particulate air pollution.

3.3. Air Quality Monitoring Data in Kyiv

The military operation started from multiple attack points (Figure 1b). The invasion from the northern borders of the country was aimed at taking over the Ukrainian capital, Kyiv. Encountered with a huge resistance and strategic blockages of the roads (e.g., destroyed bridges, flooded territories, etc.) the military forces of Russia, in fact, never entered the capital, but halted near the eastern edges of Kyiv, where apart from intense bombing and destruction, war crimes were executed in several small towns, such as Bucha and Borodyanka (Figure 4). This war-caused significant (p < 0.00) air pollution intensification can be seen in the hourly data of PM2.5 concentrations from all three available PurpleAir stations at 3–6th weeks of the war (Figure 4a,d,e, Table A2, Appendix A). This increase in PM2.5 pollution in the region of Kyiv can also be seen in satellite maps previously analyzed for Ukraine (Section 3.2, Figure 3s,t).
PM2.5 levels in the capital did not change much until 19–21 March 2022. During the later dates, often during night hours, peak levels climbed over 100 µg m−3 (Figure 4a,d) due to the intensification of the efforts to take the capital city. A 2-week average PM2.5 concentration indicated a significant (p < 0.05) 46–77% increase among three monitoring stations by the 3–4th weeks of military actions when compared to pre-war normal air quality conditions (Table A2, Appendix A). These findings compare well to the findings in limited previous studies on PM10. For example, during the 1991 Gulf War PM10 levels increased 1.5–3 times over the duration of war due to the burning of oil fields and other military activities [27,28]. By the 4–5th weeks, the Russian military was bombing civilian and military objects, including bus/train stations, hospitals, schools, theaters, etc. This resulted in 33–150% increase in PM2.5 (Table A2, Appendix A). Once these efforts brought no fruit and the Ukrainian resistance held on the defense, the Russian army withdrew and moved towards the eastern parts of the country, showing a decline in PM2.5 concentrations by the 7–9th weeks of war (Figure 4f, Table A2, Appendix A).
When considering war activity, even though, the probability of a nuclear disaster is always the biggest worry for humanity (i.e., Ukraine’s large nuclear power system, and Russia’s nuclear weapon power), there are countless other consequences to the environment and human health as a result of this invasion. Some of the impacts are short lived, while others will remain for a long time. The toxic emissions, such as heavy metals, cement, asbestos, polycyclic aromatic hydrocarbons (PAHs), polychlorinated biphenyls (PCBs), and polychlorinated furans and dioxins, among others, originating from military activities (e.g., destruction of cities, and industrial, fuel, or acid storage facilities, etc.), will end up contaminating not only the air, but also water and soil, through wet and dry deposition [66]. There are multiple reports of governmental and civil buildings (i.e., airport, police, television or bus stations, as well as theatres, apartment buildings or private houses), factories, power plants (including Chernobyl), fuel or nitric acid storage tanks on fire and columns of smoke rising in numerous cities across the country [67]. The fact that in this work an increase in PM2.5 levels was reported also suggests possible consequences from toxic smoke exposure. Since the use of heavy metals in weapons has increased following the WWII, every armed conflict adds large amounts of Pb and Hg [Mercury(II) fulminate] as a result of explosions [68]. In addition, Zn, Cu, Ni, Pb, and Cr are commonly utilized to coat bullets, missiles, gun barrels, and military vehicles [69,70], while Ba, Sb, and B are compounds that are used to prime weapons [71].
This study contains invaluable proof of the impacts of this war or any other armed conflict on environmental problems, specifically air pollution, implying negative health effects on the local population caught in the middle of this anthropogenic disaster. The health effects will touch not only the local population, but also the combating armies and quite possibly the surrounding countries, as shown in other studies [29,30,31]. While there is no way to currently examine PM chemistry, previous investigations [31] reviewed in this work suggest a huge amount of toxic chemicals affecting Ukrainian territory, which will have long-term health implications on the people and the environment.
Over two billion people were globally affected by more than 2500 disasters and 40 major conflicts since the year 2000 [72]. In the case of war, there are established guidelines regarding the protection of the natural environment in armed conflicts [72,73]. However, in an actual war, these rules are often omitted, and the responsible parties are put on trial later for their behavior during wartime. Unfortunately, the damage to the environment, infrastructure, and human health have already been done and continues to take place in Ukraine and other countries. At this point, apart from the war casualties, it is hard to estimate the actual health impact to the people of Ukraine and Russia, as confirmed by previous studies. Even years after a war, an actual impact can only be estimated with high uncertainties [27]. Therefore, the limitations of air pollution exposure to the human population are challenging due to war-disrupted public health recordkeeping. In this work, however, we present a robust estimate of air quality conditions in the country during the early, more intense, and widespread phases of the war, which will serve to later evaluate expected impacts on public health.

4. Conclusions

This study is the first of its kind to comprehensively study war’s impact on modern air quality. Here, available (satellite and ground) data for five criteria pollutants (NO2, CO, O3, SO2, and PM2.5), averaged over a few different 2-week periods, were studied to help evaluate the impact of the Russia-Ukraine war on air pollution over the Ukrainian territory. Three different types of analyses were performed: (i) comparison of satellite data during the two first weeks of the war in 2022, with the same 2-week period in 2019, 2020, and 2021 for all criteria pollutants for Ukraine and Kyiv; (ii) comparison of satellite data of 2-weeks prior to the war and first six weeks (three 2-week periods) of the war for all criteria pollutants for Ukraine and Kyiv; and (iii) comparison of PM2.5 data from three functioning PurpleAir monitoring stations in Kyiv region during two weeks before the war and eight first weeks (four 2-week periods) of the war. Statistical analyses (t-test and one-way ANOVA) showed a significant difference (p < 0.05) between all the studied periods for all criteria pollutants, indicating that air quality was affected by war compared to business-as-usual (BAU) conditions. And not only that, but also varied during the duration of the war covered by this study.
An overall reduction of 24.1% of NO2 concentrations can be seen from BAU levels for Ukraine and 40.42% for Kyiv, reaching its lowest levels averaging at 21.1 ± 9.9 µmol m−2 in 2022 during the periods of the first two weeks of the war on 22 February–8 March. This reduction continued over to the sixth week of the war (the term of this study for the gas pollutants). The same high reduction was registered for PM2.5 of 38.33% (Ukraine) and 30.82% (Kyiv), reaching ~3.7 µg m−3, and much lower reduction for CO: −3.83% (Ukraine) and 2.73 (Kyiv) dropping to ~35.2 mmol m−2 nationally. This reduction can be attributed to a diminished anthropogenic activity, as many parts of Ukraine received a huge quantity of Russian airstrikes or shelling, forcing people to emigrate or hide in the underground shelters. A reduction in peak concentrations for these pollutants was also observed. The analysis of the evolution of war shows a continuous reduction in peak NO2 concentrations; however, the average levels slightly increase on the 3–4th week of war (9–22 March 2022). This is possibly due to the intensification of airstrikes and bombing as war progressed. In contrast, overall higher O3 (2.45% for Ukraine and 3.38% for Kyiv) and SO2 (38.06% for Ukraine and 10% for Kyiv) levels were reported during the first two weeks of the war compared to BAU conditions. However, over the course of the war, the SO2 levels reduced fourfold for the whole country and 27.78% for the Kyiv region, while PM2.5 demonstrated the most drastic increase in concentrations nationally, reaching the highest levels, especially, in the Kyiv region, at 9.4 ± 1.9 µg m−3. A few other hot-spots around Kyiv and Donetsk along the borders of Russian military activities suggest a prolonged exposure to smoke particle pollution from the localized bomb or missile explosions and military and civil object destruction. Parts of the country were exceeding the WHO recommended safe levels for short- and long-term exposure. Once the Russian army failed to take the Ukrainian capital, the PM2.5 by 8th week of war the concentrations of PM2.5 reduced in that region.
When considering war, apart from the inexcusable loss of life and massive economic losses, there are immeasurable concerns for the environment and the human health of those not involved directly in the fighting (i.e., civilians). Some of the resulting pollution impacts are short-lived, while others persist for a long time. The toxic emissions, originating from military actions and destruction, will go on contaminating not only the atmosphere, but also water and soil, through wet and dry deposition. This study, therefore, is an invaluable quantification of the impact this war or any other armed conflict has on the local population caught in the middle of this anthropogenic tragedy. The pollution-related health problems will affect not only the local population, but also the combating armies and the surrounding territories. Unfortunately, at this point, there is no way to examine the actual health impacts or the chemistry of PM pollution due to safety concerns for scientists. However, previous investigations suggest massive quantities of toxic chemicals released in Ukrainian territory, which will unquestionably have long-term regional health implications for people and the environment.

Author Contributions

Conceptualization, R.Z., B.L and Y.R.; methodology, R.Z., D.M. and Y.R.; software, S.B.-B., D.M. and H.A.; validation, R.Z., Y.R. and B.L.; formal analysis, R.Z., D.M. and Y.R.; investigation, R.Z., D.M. and X.B.; resources, R.Z.; data curation, R.Z. and D.M.; writing—original draft preparation, R.Z.; writing—review and editing, B.L., X.B., R.Z., D.M., S.B.-B. and Y.R.; visualization, D.M. and R.Z. supervision, R.Z.; project administration, R.Z.; funding acquisition, R.Z. All authors have read and agreed to the published version of the manuscript.

Funding

This research received funding from Universidad de Las Americas, Ecuador, for the funding of AMB.RZ.22.03 project.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

The data was acquired from Google Earth Engine, a cloud-based platform for planetary-scale geospatial analysis. Satellite data (TROPOMI in Sentinel—precursor (S5P) and European Centre for Medium-Range Weather Forecasting) of atmospheric criteria pollution (NO2, CO, O3, SO2 and PM2.5) over the Ukrainian territory were used.

Acknowledgments

We would like to thank Universidad de Las Americas and other involved universities for their continuous support in trusting us and helping us do scientific research. We would also like to express our moral support to all unfortunate civilians caught in the middle of the wars in the world.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

Appendix A

Table
Table A1. Relevant Scopus literature review for the topic of war/armed/conflict and air quality/pollution.
Table A1. Relevant Scopus literature review for the topic of war/armed/conflict and air quality/pollution.
YearAuthorsTitlePollutant Analyzed
1982Hays, S.P.From Conservation to Environment: Environmental Politics in the United States Since World War Two [21]
1993El-Shobokshy, M. S. & Al-Saedi, Y. G.The impact of the gulf war on the Arabian environment—I. Particulate pollution and reduction of solar irradiance [28]Inhalable dust particles (<15 μm) during the war
2000Melas, D., et al.The war in Kosovo [31]VOCs transport during the war
2001Vukmirović, Z.B., et al.Regional air pollution caused by a simultaneous destruction of major industrial sources in a war zone. The case of April Serbia in 1999 [29]Organic PM2.5 transport during the war
2004Vukmirovic, Z.B., et al.Regional Air Pollution Originating from Oil-Refinery Fires under War Conditions [30] Organic PM2.5 transport during the war
2008Uekoetter, F.A twisted road to earth day: Air pollution as an issue of social movements after World War II [20]
2008White, R., et al.Premature mortality in the Kingdom of Saudi Arabia associated with particulate matter air pollution from the 1991 Gulf War [27]PM10 during the war
2009Philip K. HopkeContemporary threats and air pollution [19]
2012Protopsaltis, C.Air pollution caused by war activity [18]
2015Lelieveld J., at al.Abrupt recent trend changes in atmospheric nitrogen dioxide over the Middle East [23]NO2 after the war
2016Rothschild, R.Détente from the air: Monitoring air pollution during the cold war [26]
2019Brimblecombe, P.War and Urban-Industrial Air Pollution in the UK and the US [22]
2021Hadei, M., et al.A systematic review and meta-analysis of human biomonitoring studies on exposure to environmental pollutants in Iran [24]
Table
Table A2. Anova single factor analysis for three available ground-level monitoring stations for PM2.5: Station 1 (Shepeleva); Station 2 (Hlepcha); and Station 3 (Shevchenko). w0 is 2–21 February 2022; w1 is 22 February–8 March 2022; w3 is 9–22 March 2022; w4 is 23 March–6 April 2022.
Table A2. Anova single factor analysis for three available ground-level monitoring stations for PM2.5: Station 1 (Shepeleva); Station 2 (Hlepcha); and Station 3 (Shevchenko). w0 is 2–21 February 2022; w1 is 22 February–8 March 2022; w3 is 9–22 March 2022; w4 is 23 March–6 April 2022.
ANOVA: Single Factor for Station 1—Shepeleva
SUMMARY
GroupsCountSumAverageVariance
w0_S1_SHEPELEVA3367256.66521.59722204.9428
w1_S1_SHEPELEVA3366202.09518.45862164.4583%increase
w2_S1_SHEPELEVA33610,599.0531.54481778.53346.05956
w3_S1_SHEPELEVA3369662.83528.75844620.420333.15806
w4_S1_SHEPELEVA3364625.55913.76654139.8192
ANOVA
Source of VariationSSdfMSFp-valueF crit
Between Groups71,859.98417964.9930.887087.63 × 10−252.37724
Within Groups974,2381675581.6346
Total1,046,0981679
ANOVA: Single Factor for Station 2—Hlepcha
SUMMARY
GroupsCountSumAverageVariance
w0_S2_HLEPCHA3363962.49611.7931463.14862
w1_S2_HLEPCHA3364186.88612.4609734.1438%increase
w2_S2_HLEPCHA3366260.40218.63215201.343657.99139
w3_S2_HLEPCHA3365951.27817.71214191.891850.19016
w4_S2_HLEPCHA3362700.0698.0359232.85577
ANOVA
Source of VariationSSdfMSFp-valueF crit
Between Groups26,098.0746524.51962.330173.71 × 10−492.37724
Within Groups175,333.51675104.6767
Total201,431.61679
ANOVA: Single Factor for Station 3—Shevchenko
SUMMARY
GroupsCountSumAverageVariance
w0_S3_SHEVCH3363767.27511.2121396.98908
w1_S3_SHEVCH80905.581211.3197648.45489%increase
w2_S3_SHEVCH3366683.62519.89174523.32677.41274
w3_S3_SHEVCH2236242.83327.994771182.927149.6829
w4_S3_SHEVCH3362462.4787.32880362.97594
ANOVA
Source of VariationSSdfMSFp-valueF crit
Between Groups71,253.89417813.4746.966496.38 × 10−372.378743
Within Groups495,340.31306379.2805
Total566,594.21310

References

  1. Council on Foreign Relations. Global Conflict Tracker. Impact U.S. 2022. Available online: https://www.cfr.org/global-conflict-tracker/?category=us (accessed on 4 April 2022).
  2. Sokhi, R.S.; Singh, V.; Querol, X.; Finardi, S.; Targino, A.C.; de Fatima Andrade, M.; Pavlovic, R.; Garland, R.M.; Massagué, J.; Kong, S.; et al. A global observational analysis to understand changes in air quality during exceptionally low anthropogenic emission conditions. Environ. Int. 2021, 157, 106818. [Google Scholar] [CrossRef] [PubMed]
  3. Venter, Z.S.; Aunan, K.; Chowdhury, S.; Lelieveld, J. COVID-19 lockdowns cause global air pollution declines. Proc. Natl. Acad. Sci. USA 2020, 117, 18984–18990. [Google Scholar] [CrossRef] [PubMed]
  4. Liu, Z.; Ciais, P.; Deng, Z.; Lei, R.; Davis, S.J.; Feng, S.; Zheng, B.; Cui, D.; Dou, X.; Zhu, B.; et al. Near-real-time monitoring of global CO2 emissions reveals the effects of the COVID-19 pandemic. Nat. Commun. 2020, 11, 5172. [Google Scholar] [CrossRef] [PubMed]
  5. Laughner, J.; Neu, J.; Schimel, D.; Wennberg, P.; Barsanti, K.; Bowman, K.; Abhishek, C.; Croes, B.; Fitzmaurice, H.; Henze, D.; et al. Societal shifts due to COVID-19 reveal large-scale complexities and feedbacks between atmospheric chemistry and climate change. Proc. Natl. Acad. Sci. USA 2021, 118, e2109481118. [Google Scholar] [CrossRef] [PubMed]
  6. Brimblecombe, P. Street protests and air pollution in Hong Kong. Environ. Monit. Assess. 2020, 192, 295. [Google Scholar] [CrossRef]
  7. Chiquetto, J.B.; Alvim, D.S.; Rozante, J.R.; Faria, M.; Rozante, V.; Gobo, J.P.A. Impact of a truck Driver’s strike on air pollution levels in São Paulo. Atmos. Environ. 2021, 246, 118072. [Google Scholar] [CrossRef]
  8. Basagaña, X.; Triguero-mas, M.; Agis, D.; Pérez, N.; Reche, C.; Alastuey, A.; Querol, X. Effect of public transport strikes on air pollution levels in Barcelona (Spain). Sci. Total Environ. 2018, 610–611, 1076–1082. [Google Scholar] [CrossRef]
  9. Dantas, G.; Siciliano, B.; Freitas, L.; de Seixas, E.G.; da Silva, C.M.; Arbilla, G. Why did ozone levels remain high in Rio de Janeiro during the Brazilian truck driver strike? Atmos. Pollut. Res. 2019, 6, 2018–2029. [Google Scholar] [CrossRef]
  10. Zalakeviciute, R.; Alexandrino, K.; Mejia, D.; Bastidas, M.G.; Oleas, N.H.; Gabela, D.; Chau, P.N.; Bonilla-Bedoya, S.; Diaz, V.; Rybarczyk, Y. The effect of national protest in Ecuador on PM pollution. Sci. Rep. 2021, 11, 17591. [Google Scholar] [CrossRef]
  11. Debone, D.; Leirião, L.F.L.; Miraglia, S.G.E.K. Air quality and health impact assessment of a truckers’ strike in Sao Paulo state, Brazil: A case study. Urban Clim. 2020, 34, 100687. [Google Scholar] [CrossRef]
  12. Meinardi, S.; Nissenson, P.; Barletta, B.; Dabdub, D.; Rowland, F.S.; Blake, D.R. Influence of the public transportation system on the air quality of a major urban center. A case study : Milan, Italy. Atmos. Environ. 2008, 42, 7915–7923. [Google Scholar] [CrossRef] [Green Version]
  13. Zalakeviciute, R.; Rybarczyk, Y.; Alexandrino, K.; Bonilla-Bedoya, S.; Mejia, D.; Bastidas, M.; Diaz, V. Gradient Boosting Machine to Assess the Public Protest Impact on Urban Air Quality. Appl. Sci. 2021, 11, 12083. [Google Scholar] [CrossRef]
  14. Gillespie, R.D. Psychological Effects of War on Citizen and Soldier; W. W. Norton & Co.: New York, NY, USA, 1942. [Google Scholar]
  15. Leavitt, L.A.; Fox, N.A. The Psychological Effects of War and Violence on Children, 1st ed.; Psychology Press: New York, NY, USA, 1933. [Google Scholar]
  16. Koubi, V. War and Economic Performance. J. Peace Res. 2005, 42, 67–82. [Google Scholar] [CrossRef] [Green Version]
  17. Cheung, F.; Kube, A.; Tay, L.; Diener, E.; Jackson, J.J.; Lucas, R.E.; Ni, M.Y.; Leung, G.M. The impact of the Syrian conflict on population well-being. Nat. Commun. 2020, 11, 3899. [Google Scholar] [CrossRef]
  18. Protopsaltis, C. Air pollution caused by war activity. In WIT Transactions on Ecology and The Environment: Air Pollution XX; WIT Press: Southampton, UK, 2012; Volume 157, p. 93. [Google Scholar] [CrossRef] [Green Version]
  19. Hopke, P.K. Contemporary threats and air pollution. Atmos. Environ. 2009, 43, 87–93. [Google Scholar] [CrossRef]
  20. Uekoetter, F. A twisted road to earth day: Air pollution as an issue of social movements after world war II. In Natural Protest: Essays on the History of American Environmentalism; Egan, M., Crane, J., Eds.; Routledge: New York, NY, USA, 2008; pp. 163–183. [Google Scholar] [CrossRef]
  21. Hays, S.P. From Conservation to Environment: Environmental Politics in the United States Since World War Two. Environ. Rev. 1982, 6, 14–41. [Google Scholar] [CrossRef]
  22. Brimblecombe, P. War and Urban-Industrial Air Pollution in the UK and the US; Palgrave Studies in World Environmental History; Laakkonen, S., McNeill, J.R., Tucker, R.P., Vuorisalo, T., Eds.; Palgrave Macmillan: Cham, Switzerland, 2019; pp. 69–80. [Google Scholar] [CrossRef]
  23. Lelieveld, J.; Beirle, S.; Hörmann, C.; Stenchikov, G.; Wagner, T. Abrupt recent trend changes in atmospheric nitrogen dioxide over the Middle East. Sci. Adv. 2015, 1, e1500498. [Google Scholar] [CrossRef] [PubMed]
  24. Hadei, M.; Shahsavani, A.; Hopke, P.K.; Naseri, S.; Yazdanbakhsh, A.; Sadani, M.; Mesdaghinia, A.; Yarahmadi, M.; Rahmatinia, M.; Fallah, S.; et al. A systematic review and meta-analysis of human biomonitoring studies on exposure to environmental pollutants in Iran. Ecotoxicol. Environ. Saf. 2021, 212, 111986. [Google Scholar] [CrossRef] [PubMed]
  25. World Health Organization. Health risks of heavy metals from long-range transboundary air pollution; World Health Organization: Geneva, Switzerland, 2007.
  26. Rothschild, R. Détente from the Air: Monitoring Air Pollution during the Cold War. Technol. Cult. 2016, 57, 831–865. [Google Scholar] [CrossRef] [PubMed]
  27. White, R.H.; Stineman, C.H.; Symons, J.M.; Breysse, P.N.; Kim, S.R.; Bell, M.L.; Samet, J.M. Premature Mortality in the Kingdom of Saudi Arabia Associated with Particulate Matter Air Pollution from the 1991 Gulf War. Hum. Ecol. Risk Assess. 2008, 14, 645–664. [Google Scholar] [CrossRef]
  28. El-Shobokshy, M.S.; Al-Saedi, Y.G. The impact of the gulf war on the Arabian environment—I. Particulate pollution and reduction of solar irradiance. Atmos. Environ. Part A Gen. Top. 1993, 27, 95–108. [Google Scholar] [CrossRef]
  29. Vukmirović, Z.B.; Unkašević, M.; Lazić, L.; Tošić, I. Regional air pollution caused by a simultaneous destruction of major industrial sources in a war zone. The case of April Serbia in 1999. Atmos. Environ. 2001, 35, 2773–2782. [Google Scholar] [CrossRef]
  30. Vukmirovic, Z.; Lazic, L.; Tosic, I.; Unkasevic, M. Regional Air Pollution Originating from Oil-Refinery Fires under War Conditions BT—Air Pollution Modeling and Its Application XIV; Gryning, S.-E., Schiermeier, F.A., Eds.; Springer: Boston, MA, USA, 2004; pp. 741–742. [Google Scholar] [CrossRef]
  31. Melas, D.; Zerefos, C.; Rapsomanikis, S.; Tsangas, N.; Alexandropoulou, A. The war in Kosovo. Environ. Sci. Pollut. Res. 2000, 7, 97–104. [Google Scholar] [CrossRef] [PubMed]
  32. Sohrabi, S.; Zietsman, J.; Khreis, H. Burden of Disease Assessment of Ambient Air Pollution and Premature Mortality in Urban Areas: The Role of Socioeconomic Status and Transportation. Int. J. Environ. Res. Public Health 2020, 17, 1166. [Google Scholar] [CrossRef] [Green Version]
  33. WHO. Ambient Air Pollution: Health Impacts. Air Pollut. 2018. Available online: https://www.who.int/airpollution/ambient/health-impacts/en/ (accessed on 4 April 2022).
  34. ABC News. WHO Says 99% of World’s Population Breathes Poor-Quality Air—ABC News. Health (Irvine. Calif). 2022. Available online: https://abcnews.go.com/Health/wireStory/99-worlds-population-breathes-poor-quality-air-83860782 (accessed on 4 April 2022).
  35. World Health Organization. Air Pollution. Health Top. Pollut. 2022. Available online: https://www.who.int/health-topics/air-pollution#tab=tab_1 (accessed on 4 April 2022).
  36. Jiang, X.-Q.; Mei, X.-D.; Feng, D. Air pollution and chronic airway diseases: What should people know and do? J. Thorac. Dis. 2016, 8, E31–E40. [Google Scholar] [CrossRef] [PubMed]
  37. Lee, B.-J.; Kim, B.; Lee, K. Air pollution exposure and cardiovascular disease. Toxicol. Res. 2014, 30, 71–75. [Google Scholar] [CrossRef]
  38. EPA. Are you at risk from particles? How can particles affect your health? Office of Air and Radiation, EPA-452/F-03-001. 2003, 11, 40–41. Available online: https://www.airnow.gov/sites/default/files/2018-03/pm-color.pdf (accessed on 11 April 2022).
  39. Proukraine. Tepитopiя Укpaїни—Укpaїнa. Inf. Ukr. 2022. Available online: http://proukraine.net.ua/?page_id=20 (accessed on 28 March 2022).
  40. The World Bank. Population, Total—Ukraine|Data. 2021. Available online: https://data.worldbank.org/indicator/SP.POP.TOTL?locations=UA (accessed on 18 September 2022).
  41. BBC News. Ukraine War in Maps: Tracking the Russian Invasion—BBC News. Europe. 2022. Available online: https://www.bbc.com/news/world-europe-60506682 (accessed on 6 April 2022).
  42. Institute for the Study of War. Ukraine Conflict Updates; Press ISW: Oxford, UK, 2022; Available online: https://www.understandingwar.org/backgrounder/ukraine-conflict-updates (accessed on 4 May 2022).
  43. Mankoff, J.; Centre for Strategic and International Studies. Russia’s War in Ukraine: Identity, History, and Conflict. 2022. Available online: www.csis.org/analysis/russias-war-ukraine-identity-history-and-conflict (accessed on 9 August 2022).
  44. United Nations. More than 2 Attacks a Day on Ukraine Health Facilities; 6.5 Million Now Internally Displaced. UN News. Glob. Perspect. Hum. Stories. 2022. Available online: https://news.un.org/en/story/2022/03/1114342 (accessed on 4 April 2022).
  45. BBC News. How Many Ukrainian Refugees Are There and Where Have They Gone? Russ. war. 2022. Available online: https://www.bbc.com/news/world-60555472 (accessed on 13 September 2022).
  46. Euronews. Russia’s War Will Shrink Ukraine’s Economy by 45% This Year, World Bank Says. World Ukr. 2022. Available online: https://www.euronews.com/2022/04/11/russia-s-war-will-shrink-ukraine-s-economy-by-45-this-year-world-bank-says (accessed on 11 April 2022).
  47. Zalakeviciute, R.; Vasquez, R.; Bayas, D.; Buenano, A.; Mejia, D.; Zegarra, R.; Diaz, V.; Lamb, B. Drastic Improvements in Air Quality in Ecuador during the COVID-19 Outbreak. Aerosol Air Qual. Res. 2020, 20, 1783–1792. [Google Scholar] [CrossRef]
  48. Gorelick, N.; Hancher, M.; Dixon, M.; Ilyushchenko, S.; Thau, D.; Moore, R. Google Earth Engine: Planetary-scale geospatial analysis for everyone. Remote Sens. Environ. 2017, 202, 18–27. [Google Scholar] [CrossRef]
  49. QGIS.org. QGIS Geographic Information System. Open Source Geospatial Foundation Project. 2022. Available online: https://www.qgis.org/es/site/ (accessed on 5 April 2022).
  50. European Space Agency. Sentinel-5 Precursor Level 2 Nitrogen Dioxide—Sentinel Online. Copernicus Sentin. (Processed by ESA), TROPOMI Lev. 2 Nitrogen Dioxide Total Column Prod. Version 02. 2021. Available online: https://sentinels.copernicus.eu/web/sentinel/data-products/-/asset_publisher/fp37fc19FN8F/content/sentinel-5-precursor-level-2-nitrogen-dioxide (accessed on 19 September 2022).
  51. European Space Agency. Sentinel-5 Precursor Level 2 Carbon Monoxide—Sentinel Online. Copernicus Sentin. (Processed by ESA), 2021, TROPOMI Lev. 2 Carbon Monoxide Total Column Prod. Version 02. 2021. Available online: https://sentinels.copernicus.eu/web/sentinel/data-products/-/asset_publisher/fp37fc19FN8F/content/sentinel-5-precursor-level-2-carbon-monoxide (accessed on 19 September 2022).
  52. tropomi.eu. Sulphur Dioxide. DATA Prod. 2022. Available online: http://www.tropomi.eu/data-products/sulphur-dioxide (accessed on 5 April 2022).
  53. European Space Agency. Sentinel-5 Precursor Level 2 Tropospheric Ozone—Sentinel Online [WWW Document]. Copernicus Sentin. (Processed by ESA), TROPOMI Lev. 2 Tropospheric Ozone Prod. Version 02. 2020. Available online: https://sentinels.copernicus.eu/web/sentinel/data-products/-/asset_publisher/fp37fc19FN8F/content/tropomi-level-2-tropospheric-ozone (accessed on 19 September 2022).
  54. Xue, R.; Wang, S.; Li, D.; Zou, Z.; Chan, K.L.; Valks, P.; Saiz-Lopez, A.; Zhou, B. Spatio-temporal variations in NO2 and SO2 over Shanghai and Chongming Eco-Island measured by Ozone Monitoring Instrument (OMI) during 2008–2017. J. Clean. Prod. 2020, 258, 120563. [Google Scholar] [CrossRef]
  55. Beloconi, A.; Chrysoulakis, N.; Lyapustin, A.; Utzinger, J.; Vounatsou, P. Bayesian geostatistical modelling of PM10 and PM2.5 surface level concentrations in Europe using high-resolution satellite-derived products. Environ. Int. 2018, 121, 57–70. [Google Scholar] [CrossRef]
  56. Vicedo-Cabrera, A.M.; Biggeri, A.; Grisotto, L.; Barbone, F.; Catelan, D. A Bayesian kriging model for estimating residential exposure to air pollution of children living in a high-risk area in Italy. Geospat. Health 2013, 8, 87–95. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  57. Evans, R.; Larkin, S.; Barkjohn, K.J.; Clements, A.; Holder, A. EPA tools and resources webinar AirNow fire and smoke map: Extension of the US-wide correction for purple PM2.5 sensors. EPA Res. Dev. 2021. Available online: https://www.epa.gov (accessed on 5 March 2022).
  58. Johnson, B.K.; Frederick, S.; Holder, A.; Clements, A. Air sensors: PurpleAir, AirNow Fire and Smoke Map, and their use internationally. In Proceedings of the U.S. State Department Embassy Fellows Program Monthly Virtual Meeting, Durham, NC, USA, 3 December 2020. [Google Scholar]
  59. van Geffen, J.; Boersma, K.F.; Eskes, H.; Sneep, M.; ter Linden, M.; Zara, M.; Veefkind, J.P. S5P TROPOMI\chem{NO_2} slant column retrieval: Method, stability, uncertainties and comparisons with OMI. Atmos. Meas. Tech. 2020, 13, 1315–1335. [Google Scholar] [CrossRef] [Green Version]
  60. Sannigrahi, S.; Kumar, P.; Molter, A.; Zhang, Q.; Basu, B.; Basu, A.S.; Pilla, F. Examining the status of improved air quality in world cities due to COVID-19 led temporary reduction in anthropogenic emissions. Environ. Res. 2021, 196, 110927. [Google Scholar] [CrossRef] [PubMed]
  61. Liu, F.; Wang, M.; Zheng, M. Effects of COVID-19 lockdown on global air quality and health. Sci. Total Environ. 2021, 755, 142533. [Google Scholar] [CrossRef] [PubMed]
  62. Huryn, S.M.; Gough, W.A. Impact of urbanization on the ozone weekday/weekend effect in Southern Ontario, Canada. Urban Clim. 2014, 8, 11–20. [Google Scholar] [CrossRef]
  63. DATA.GOV, n.d. Sentinel-5P TROPOMI Total Ozone Column 1-Orbit L2 7km x 3.5km V1 (S5P_L2__O3_TOT) at GES DISC. Metadata. Available online: https://catalog.data.gov/dataset/sentinel-5p-tropomi-total-ozone-column-1-orbit-l2-7km-x-3-5km-v1-s5p-l2-o3-tot-at-ges-disc (accessed on 5 May 2022).
  64. European Space Agency. Sentinel-5 Precursor Level 2 Sulphur Dioxide—Sentinel Online. Copernicus Sentin. (Processed by ESA), TROPOMI Lev. 2 Sulphur Dioxide Total Column. Version 02. 2020. Available online: https://sentinels.copernicus.eu/web/sentinel/data-products/-/asset_publisher/fp37fc19FN8F/content/sentinel-5-precursor-level-2-sulphur-dioxide (accessed on 19 September 2022).
  65. WHO. WHO Global Air Quality Guidelines: Particulate Matter (PM2.5 and PM10), Ozone, Nitrogen Dioxide, Sulfur Dioxide and Carbon Monoxide; World Health Organization: Geneva, Switzerland, 2021.
  66. Velázquez, J. The Climate Crisis and the Invasion of Ukraine ‘Have the Same Roots’, Says Expert. Euronews.green Nat. 2022. Available online: https://www.euronews.com/green/2022/03/22/the-climate-crisis-and-the-invasion-of-ukraine-have-the-same-roots-says-expert (accessed on 4 September 2022).
  67. MAXAR Technologies. Satellite-Imagery. Products. 2022. Available online: https://www.maxar.com/products/satellite-imagery (accessed on 4 May 2022).
  68. Gębka, K.; Bełdowski, J.; Bełdowska, M. The impact of military activities on the concentration of mercury in soils of military training grounds and marine sediments. Environ. Sci. Pollut. Res. Int. 2016, 23, 23103–23113. [Google Scholar] [CrossRef] [PubMed]
  69. Audino, M.J. Use of Electroplated Chromium in Gun Barrels; DoD Metal Finishing Workshop: Washington, DC, USA, 2006. [Google Scholar]
  70. Casey, T. US Military Targets Toxic Enemy #1: Hexavalent Chromium; CleanTechnica: Long Beach, CA, USA, 2009. [Google Scholar]
  71. Kara, I.; Lisesivdin, S.B.; Kasap, M.; Er, E.; Uzek, U. The Relationship Between the Surface Morphology and Chemical Composition of Gunshot Residue Particles. J. Forensic Sci. 2015, 60, 1030–1033. [Google Scholar] [CrossRef] [PubMed]
  72. UN Environment Programme. UNEP—UN Environment Programme: Report. Protecting the Environment during Armed Conflict: An Inventory and Analysis of International Law. 2022. Available online: https://www.unep.org/resources/report/protecting-environment-during-armed-conflict-inventory-and-analysis-international (accessed on 13 September 2022).
  73. International Committee of the Red Cross. Protection of Natural Environment. Guidelines on Protection of Natural Environment in Armed Conflict. 2022. Available online: https://www.icrc.org/en/document/guidelines-protection-natural-environment-armed-conflict-rules-and-recommendations-relating (accessed on 13 September 2022).
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Figure 1. The territory of Ukraine (a) in the context of Europe; Ukrainian cities (yellow markers), attacks (flame markers) and monitoring stations (black numbered markers) (b); and an evolution of Russian occupation and advances and Ukrainian resistance in 3 April 2022 (c) and 6 April 2022 (d), (a breaking point in the war evolution, after which point, Russian forces focused on the occupation of eastern and southern Ukraine (at least by mid-May 2022)). Illustration adapted from the source Institute for the Study of War [41,42].
Figure 1. The territory of Ukraine (a) in the context of Europe; Ukrainian cities (yellow markers), attacks (flame markers) and monitoring stations (black numbered markers) (b); and an evolution of Russian occupation and advances and Ukrainian resistance in 3 April 2022 (c) and 6 April 2022 (d), (a breaking point in the war evolution, after which point, Russian forces focused on the occupation of eastern and southern Ukraine (at least by mid-May 2022)). Illustration adapted from the source Institute for the Study of War [41,42].
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Figure 2. Concentrations of air criteria pollutants: NO2 (ad), CO (eh), O3 (il), SO2 (mp), and PM2.5 (qt), in Ukraine during 22 February 22–8 March periods of 2019–2022. Data averages for 2-week period of 22 February–8 March are presented by years: the first column shows 2019 (a,e,i,m,q), the second column shows 2020 (b,f,j,n,r), the third column shows 2021 (c,g,k,o,s) and the last (most right) column shows the first two weeks of war in 2022 (d,h,l,p,t).
Figure 2. Concentrations of air criteria pollutants: NO2 (ad), CO (eh), O3 (il), SO2 (mp), and PM2.5 (qt), in Ukraine during 22 February 22–8 March periods of 2019–2022. Data averages for 2-week period of 22 February–8 March are presented by years: the first column shows 2019 (a,e,i,m,q), the second column shows 2020 (b,f,j,n,r), the third column shows 2021 (c,g,k,o,s) and the last (most right) column shows the first two weeks of war in 2022 (d,h,l,p,t).
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Figure 3. Evolution of concentrations of air criteria pollutants: NO2 (ad), CO (eh), O3 (il), SO2 (mp), and PM2.5 (qt), in Ukraine during the Russia-Ukraine war of 2022. Data averages are presented by 2-week periods: first column shows pre-war air quality (8–21 February 2022) (a,e,i,m,q), and three consecutive columns show the 1–2nd (22 February–8 March 2022) (b,f,j,n,r), 3–4th (9–22 March 2022) (c,g,k,o,s), and 5–6th (23 March–6 April 2022) (d,h,l,p,t) weeks of war.
Figure 3. Evolution of concentrations of air criteria pollutants: NO2 (ad), CO (eh), O3 (il), SO2 (mp), and PM2.5 (qt), in Ukraine during the Russia-Ukraine war of 2022. Data averages are presented by 2-week periods: first column shows pre-war air quality (8–21 February 2022) (a,e,i,m,q), and three consecutive columns show the 1–2nd (22 February–8 March 2022) (b,f,j,n,r), 3–4th (9–22 March 2022) (c,g,k,o,s), and 5–6th (23 March–6 April 2022) (d,h,l,p,t) weeks of war.
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Figure 4. The upper (a) panel shows PM2.5 land data for Kyiv’s three functioning stations (PurpleAir), corrected hourly data (grey scale lines), and 2-week averages (grey circle markers) compared to the 2-week average satellite all-Ukraine averages (black diamond markers) and maximum values (black line markers). The 2-week periods are indicated by the blue vertical separating lines. Spatial representation of PM2.5 satellite data for Kyiv and its surrounding territories are presented in lower panels: (b) pre-war air quality (8–21 February 2022); (c) the 1–2nd weeks of war (22 February–8 March 2022); (d) the 3–4th weeks of war (9–22 March 2022); (e) 5–6th weeks of war (23 March–6 April 2022); (f) 7–8th weeks of war (7–24 April 2022).
Figure 4. The upper (a) panel shows PM2.5 land data for Kyiv’s three functioning stations (PurpleAir), corrected hourly data (grey scale lines), and 2-week averages (grey circle markers) compared to the 2-week average satellite all-Ukraine averages (black diamond markers) and maximum values (black line markers). The 2-week periods are indicated by the blue vertical separating lines. Spatial representation of PM2.5 satellite data for Kyiv and its surrounding territories are presented in lower panels: (b) pre-war air quality (8–21 February 2022); (c) the 1–2nd weeks of war (22 February–8 March 2022); (d) the 3–4th weeks of war (9–22 March 2022); (e) 5–6th weeks of war (23 March–6 April 2022); (f) 7–8th weeks of war (7–24 April 2022).
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Table
Table 1. Statistics for criteria pollutants (NO2, CO, O3, SO2, and PM2.5) in Ukraine during February 22–March 8, 2019–2022. This period shows the first two weeks of the Russia-Ukraine war of 2022 compared with the same dates of three previous years. The first value of each cell shows an average for the whole country, the next value shows one standard deviation or the spatial variability of the data, while the third value shows the maximum value for the country. Business-as-usual conditions (BAU) periods are marked with * while BAU affected by COVID-19 pandemic are marked with **. The average values for the region of Kyiv are added in bold. Percentage (%) change from BAU for Ukraine and Kyiv are added at the two last rows of the table.
Table 1. Statistics for criteria pollutants (NO2, CO, O3, SO2, and PM2.5) in Ukraine during February 22–March 8, 2019–2022. This period shows the first two weeks of the Russia-Ukraine war of 2022 compared with the same dates of three previous years. The first value of each cell shows an average for the whole country, the next value shows one standard deviation or the spatial variability of the data, while the third value shows the maximum value for the country. Business-as-usual conditions (BAU) periods are marked with * while BAU affected by COVID-19 pandemic are marked with **. The average values for the region of Kyiv are added in bold. Percentage (%) change from BAU for Ukraine and Kyiv are added at the two last rows of the table.
NO2
µmol m−2		CO
mmol m−2		O3
mmol m−2		SO2
mmol m−2		PM2.5
µg m−3
2019 *28.4 ± 12.9/
158.9//39.79		36.9 ± 1.4/46.3//37.49 173.7 ± 6.3/184.8//173.550.88 ± 0.71/13.69//0.595.9 ± 1.7/21.7//5.89
2020 *27.2 ± 10.3/157.6//41.8236.3 ± 1.2/45.5//36.51164.6 ± 2.3/171.0//164.980.67 ± 0.36/12.7//1.216.1 ± 1.4/19.2//4.72
2021 **23.4 ± 13.2/178.1//36.4037.1 ± 1.3/42.2//38.34159.5 ± 5.4/171.0//160.800.99 ± 0.87/24.1//2.447.7 ± 1.8/12.4//4.79
202221.1 ± 9.9/139.7//24.3135.2 ± 1.3/36.7//35.99173.3 ± 1.5/178.6//174.981.07 ± 0.98/19.3//0.993.7 ± 0.8/9.7//3.67
% change Ukraine−24.10−3.832.4538.06−38.33
% change Kyiv−40.42−2.733.3810−30.82
Table
Table 2. Statistics for criteria pollutants (NO2, CO, O3, SO2, and PM2.5) in Ukraine during the Russia-Ukraine war of 2022. Data are presented by 2-week periods: the first row shows pre-war air quality (8–21 February 2022), and the three consecutive rows show the 1–2nd (22 February–8 March 2022), 3–4th (9–22 March 2022) and 5–6th (23 March–6 April 2022) weeks of war. The first value in each cell represents an average for the whole country, the next value shows one standard deviation or the variability of the data, while the third value shows the maximum value for the country. Business-as-usual conditions (BAU) periods are marked with *. The average values for the region of Kyiv are added in bold. Percentage (%) change from BAU (i.e., two weeks before the war “w0”) for Ukraine and Kyiv (in bold) are added at the end for each of three 2-week periods.
Table 2. Statistics for criteria pollutants (NO2, CO, O3, SO2, and PM2.5) in Ukraine during the Russia-Ukraine war of 2022. Data are presented by 2-week periods: the first row shows pre-war air quality (8–21 February 2022), and the three consecutive rows show the 1–2nd (22 February–8 March 2022), 3–4th (9–22 March 2022) and 5–6th (23 March–6 April 2022) weeks of war. The first value in each cell represents an average for the whole country, the next value shows one standard deviation or the variability of the data, while the third value shows the maximum value for the country. Business-as-usual conditions (BAU) periods are marked with *. The average values for the region of Kyiv are added in bold. Percentage (%) change from BAU (i.e., two weeks before the war “w0”) for Ukraine and Kyiv (in bold) are added at the end for each of three 2-week periods.
NO2
(µmol m−2)		CO
(mmol m−2)		O3
(mmol m−2)		SO2
(mmol m−2)		PM2.5 (µmol m−2)
w0: 8–21 February *29.4 ± 13.7/237.3//54.9135.3 ± 1.2/36.8//36.43159.1 ± 1.3/161.0//164.391.6 ± 2.1/30.9//0.904.2 ± 0.8/12.2//4.66
w1–2: 22 February–8 March21.1 ± 9.9/139.7//22.5235.2 ± 1.3/36.7//35.99173.3 ± 1.541.9/178.6//174.981.1 ± 0.9/19.3//0.983.7 ± 0.8/9.7//4.75
w3–4:
9–22 March		24.2 ± 10.8/176.7//37.6837.1 ± 0.9/39.1//37.96171.7 ± 4.6/181.6//169.420.84 ± 0.4/11.6//0.845.2 ± 1.0/11.6//9.47
w5–6:
23 March–6 April		22.3 ± 7.7/93.6//31.8936.8 ± 1.1/39.6//37.55160.0 ± 2.0/167.3//162.880.4 ± 0.3/11.1//0.659.4 ± 1.9/24.2//11.48
% change w1–2 vs. w0−28.23//
−58.98		−0.28//−1.218.93//6.44−31.25//8.89−11.90//1.93
% change w3–4 vs. w0−17.69//
−31.38		5.09//4.197.92//3.06−47.5//−6.6723.81//103.22
% change w5–6 vs. w0−24.15//
−41.92		4.25//3.070.57//−0.92−75//−27.78123.81//146.35
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Zalakeviciute, R.; Mejia, D.; Alvarez, H.; Bermeo, X.; Bonilla-Bedoya, S.; Rybarczyk, Y.; Lamb, B. War Impact on Air Quality in Ukraine. Sustainability 2022, 14, 13832. https://doi.org/10.3390/su142113832

AMA Style

Zalakeviciute R, Mejia D, Alvarez H, Bermeo X, Bonilla-Bedoya S, Rybarczyk Y, Lamb B. War Impact on Air Quality in Ukraine. Sustainability. 2022; 14(21):13832. https://doi.org/10.3390/su142113832

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Zalakeviciute, Rasa, Danilo Mejia, Hermel Alvarez, Xavier Bermeo, Santiago Bonilla-Bedoya, Yves Rybarczyk, and Brian Lamb. 2022. "War Impact on Air Quality in Ukraine" Sustainability 14, no. 21: 13832. https://doi.org/10.3390/su142113832

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