References
- Bezyk Y, Górka M, Sówka I, Nęcki J and Strąpoć D, 2023. Temporal dynamics and controlling factors of CO2 and CH4 variability in the urban atmosphere of Wroclaw, Poland. Science of the Total Environment 893: 164771, DOI 10.1016/j.scitotenv.2023.164771.
- Davis KJ, Deng A, Lauvaux T, Miles NL, Richardson SJ, Sarmiento DP, Gurney KR, Hardesty RM, Bonin TA, Brewer WA, Lamb BK, Shepson PB, Harvey RM, Cambaliza MO, Sweeney C, Turnbull JC, Whetstone J and Karion A, 2017. The Indianapolis Flux Experiment (INFLUX): A test-bed for developing urban greenhouse gas emission measurements. Elementa: Science of the Anthropocene 5: 21.
- Fang SX, Zhou LX, Tans PP, Ciais P, Steinbacher M, Xu L and Luan T, 2014. In situ measurement of atmospheric CO2 at the four WMO/GAW stations in China. Atmospheric Chemistry and Physics 14(5): 2541–2554.
- Jasek-Kamińska A, Zimnoch M, Wachniew P and Różański K, 2020. Urban CO2 budget: Spatial and seasonal variability of CO2 emissions in Krakow, Poland. Atmosphere 11: 629. DOI 10.3390/atmos11060629.
- Kuc T, 1991. Concentration and carbon isotopic composition of atmospheric CO2 in Southern Poland. Tellus 43B: 373–378.
- Kuc T, Różański K, Zimnoch M, Necki J, Chmura L and Jelen D, 2007. Two decades of regular observations of 14CO2 and 13CO2 content in atmospheric carbon dioxide in central Europe: Long term changes of regional anthropogenic Fossil CO2 emissions. Radiocarbon 49(2): 807–816.
- Lauvaux T, Miles NL, Deng A, Richardson SJ, Cambaliza MO, Davis KJ, Gaudet B, Gurney KR, Huang J, O’Keefe D, Song Y, Karion A, Oda T, Patarasuk R, Razlivanov I, Sarmiento D, Shepson P, Sweeney C, Turnbull J and Wu K, 2016. High-resolution atmospheric inversion of urban CO2 emissions during the dormant season of the Indianapolis Flux Experiment (INFLUX). Journal of Geophysical Research: Atmospheres 121(10): 5213–5236.
- Lin JC, Mitchell L, Crosman E, Mendoza DL, Buchert M, Bares R, Fasoli B, Bowling DR, Pataki D, Catharine D, Strong C, Gurney KR, Patarasuk R, Baasandorj M, Jacques A, Hoch S, Horel J and Ehleringer J, 2018. CO2 and carbon emissions from cities: Linkages to air quality, socioeconomic activity, and stakeholders in the Salt Lake City urban area. Bulletin of the American Meteorological Society 99(11): 2325–2339.
- Marcotullio PJ, Hughes S, Sarzynski A, Pincetl S, Sanchez Pena L, Romero-Lankao P, Runfla D and Seto KC, 2014. Urbanization and the carbon cycle: Contributions from social science. Earth’s Future 2(10): 496–514.
- Metya A, Datye A, Chakraborty S, Tiwari YK, Sarma D, Bora A and Gogoi N, 2021. Diurnal and seasonal variability of CO2 and CH4 concentration in a semi-urban environment of western India. Scientific Reports 11(1): 2931.
- Moore J and Jacobson AD, 2015. Seasonally varying contributions to urban CO2 in the Chicago, Illinois, USA region: Insights from a high-resolution CO2 concentration and δ13C record Urban CO2 concentrations and δ13C values from the Chicago, IL, USA region. Elementa: Science of the Anthropocene, 3:000052. DOI: 10.12952/journal.elementa.000052
- Necki JM, Galkowski M, Chmura L, Gerbig C, Zimnoch M, Zieba D, Bartyzel J, Wolkowicz W and Różański K, 2016. Regional representativeness of CH4 and N2O mixing ratio measurements at high-altitude mountain station Kasprowy Wierch, Southern Poland. Aerosol and Air Quality Research, 16(3): 568–580, DOI 10.4209/aaqr.2015.05.0357.
- Necki JM, Schmidt M, Różański K, Zimnoch M, Korus A, Lasa J, Graul R and Levin I, 2003. Six-year record of atmospheric carbon dioxide and methane at a high-altitude mountain site in Poland. Tellus 55B: 94.
- Pawlak W, Fortuniak K and Siedlecki M, 2010. Measurements of vertical carbon dioxide net flux in the center of Lodz – preliminary results from the period 2006–2009. Acta Agrophysica. Rozprawy i Monografie 2(179): 59–70.
- Piotrowska N, Pazdur A, Pawełczyk S, Rakowski A, Sensuła B and Tudyka K, 2019. Human activity recorded in carbon isotopic composition of atmospheric CO2 in Gliwice urban area and surroundings (Southern Poland) in the Years 2011–2013. Radiocarbon 62(1): 141–156, DOI 10.1017/RDC.2019.92.
- Röckmann T, Eyer S, Van Der Veen C, Popa ME, Tuzson B, Monteil G, Houweling S, Harris E, Brunner D, Fischer H, Zazzeri G, Lowry D, Nisbet EG, Brand WA, Necki JM, Emmenegger L and Mohn J, 2016. In situ observations of the isotopic composition of methane at the Cabauw tall tower site. Atmospheric Chemistry and Physics 16(16): 10469–10487.
- Różański K, Necki J, Chmura L, Sliwka I, Zimnoch M, Bielewski J, Galkowski M, Bartyzel J and Rosiek J, 2014. Anthropogenic changes of CO2, CH4, N2O, CFCl3, CF2Cl2, CCl2FCClF2, CHCl3, CH3CCl3, CCl4, SF6 and SF5CF3 mixing ratios in the atmosphere over southern Poland. Geological Quarterly 58(4): 673–684.
- Sensuła B, 2023. Poziom CO2 w powietrzu atmosferycznym w Gliwicach – pierwsze wyniki badań przełomowych. In: Pikoń K and Bogacka M, eds., Contemporary problems of power engineering and environmental protection 2022. Politechnika Śląska, Gliwice: 94–103.
- Sensuła B, Chmura Ł, Nęcki J and Zimnoch M, 2023a. The atmospheric carbon dioxide level in Gliwice, Kraków and Kasprowy Wierch in the end of the summer and the beginning of the fall, 2022. In: Pikoń K and Bogacka M, eds., Contemporary problems of power engineering and environmental protection 2022. Politechnika Śląska, Gliwice: 55–60.
- Sensuła B, Michczyński A, Piotrowska N and Wilczyński S, 2018. Anthropogenic CO2 emission records in scots pine growing in the most industrialized region of Poland from 1975 to 2014. Radiocarbon 60(4): 1041–1053, DOI 10.1017/RDC.2018.59.
- Sensuła B, Piotrowska N, Nowińska K, Koruszowic M, Lazaj D, Osadnik R, Paluch R, Stasiak B and Strączek B, 2023b. Characteristics of pine needles exposed to pollution in Silesia, Poland: Carbon isotopes, IWUE, and trace element concentrations in pine needles. Radiocarbon 65(1): 233–246, DOI 10.1017/RDC.2023.1.
- Sensuła B, Toroń B, Rocznik J, Sasiela A, Świątkowski J and Tomaszowska A, 2022. Characteristics of pine needles exposed to multi-source pollution in Silesia: Radiocarbon concentration in pine needles and elemental analysis of the needles’ surface deposits. Radiocarbon 64(6): 1333–1344, DOI 10.1017/RDC.2022.85.
- Vardag SN, Gerbig C, Janssens-Maenhout G and Levin I, 2015. Estimation of continuous anthropogenic CO2: Model-based evaluation of CO2, CO, δ13C(CO2) and Δ14C(CO2) tracer methods, Atmospheric Chemistry and Physics 15: 12705–12729, DOI 10.5194/acp-15-12705-2015.
- WEB site:
http://www.hydrowskaz.pl/ . Accessed 2023 June 27. - WEB site:
https://dane.imgw.pl/datastore . Accessed 2023 June 27. - WEB site:
https://gml.noaa.gov/ccgg/trends/ . Accessed 2023 June 2. - WEB site:
https://stilt.icos-cp.eu/viewer/ . Accessed 2023 June 27. - WEB site:
https://www.manualsdir.com/manuals/408536/vaisala-gmp343.html . Accessed 2023 June 2. - Zimnoch M, Florkowski T, Nęcki JM, Neubert REM, 2004. Diurnal variability of δ13C and δ18O of atmospheric CO2 in the urban atmosphere of Kraków, Poland. Isotopes in Environmental and Health Studies 40(2): 129–143.
- Zimnoch M, Jelen D, Galkowski M, Kuc T, Necki J, Chmura L, Gorczyca Z, Jasek A and Różański K, 2012. Partitioning of atmospheric carbon dioxide over central Europe: composition. Isotopes in Environmental and Health Studies 48(3): 421–433.
- Zimnoch M, Morawski F, Kuc T, Samek L, Bartyzel J, Gorczyca Z, Skiba A and Różański K, 2020. Summer–winter contrast in carbon isotope and elemental composition of total suspended particulate matter in the urban atmosphere of Krakow, Southern Poland. Nukleonika 65(3): 181–191.
- Zimnoch M, Necki J, Chmura L, Jasek A, Jelen D, Galkowski M, Kuc T, Gorczyca Z, Bartyzel J and Różański K, 2018. Quantification of carbon dioxide and methane emissions in urban areas: Source apportionment based on atmospheric observations. Mitigation and Adaptation Strategies for Global Change 24(6): 1051–1071, DOI 10.1007/s11027-018-9821-0.