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Title: CLIMATE CHANGE MITIGATION APP FOR SUSTAINABLE CITIES USING URBAN GREEN DATA FOR CO2 ABSORPTION
CLIMATE CHANGE MITIGATION APP FOR SUSTAINABLE CITIES USING URBAN GREEN DATA FOR CO2 ABSORPTION

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Papagiannopoulou; D. Tsitsoni; T. Andreopoulou; Z. Xanthopoulou; Tsitsoni V. Morfopoulos; N.
10.5593/sgem2023V/4.2/s19.17
10.5593/sgem2023v/4.2
1314-2704
978-619-7603-65-1
English
23
4.2
•    Prof. DSc. Oleksandr Trofymchuk, UKRAINE 
•    Prof. Dr. hab. oec. Baiba Rivza, LATVIA
Air Pollution and Climate Change
Sustainable cities are urban center engineered to improve their environmental impact through proper urban planning and management. The implementation of green infrastructures is one of the most important characteristics in sustainable cities. Urban green areas play a basic role in the socio-economic development and in the sustainability of the cities. Climate change is one of the factors that needs to be into consideration during the design of sustainable cities, as it constitutes a major problem that humanity has to face. Urban green areas could contribute to mitigate the effects of climate change to cities’ adaptation to these effects. Information and Communication Technologies (ICTs) have an important role in addressing the major challenges related to climate change and sustainable development. They are tools that can be used for the monitoring of climate change, such as the absorption of CO2 by urban trees, the mitigation of its effects contributing to the development of the urban green economy. These tools promote new improved relationships between cities and natural environment. Main aim of this paper is to provide the CO2 absorption by urban green areas taking into account the data that entered in the online application which was constructed in the framework of the European project LIFE CliVut (Climate Value of Urban Trees) LIFE18 GIC/IT/001217.
[1.] Andreopoulou, Z. (2012). Green Informatics: ICT for green and Sustainability, Journal of Agricultural Informatics, 3(2), 1-8.
[2.] Andreopoulou, Z., (2016). Green ICTs for Climate Change Mitigation and Energy Sustainability: EU Challenge. Calitatea, 17(S1), p.492.
[3.] Andreopoulou, Z., Papagiannopoulou D., Tsitsoni, T. (2023). Online app for the evaluation of climate change impact in urban green areas. Proceedings of the 21st International Conference on e-Society 2023, Portugal, 485-488.
[4.] Al-Douri, F.A. (2022). How information and communication tools (ICT) affect the processes and decision-making in professional urban design practice?, URBAN DESIGN International
[Preprint]. Available at: https://doi.org/10.1057/s41289-022- 00196-8.
[5.] Hojer, M. and Wangel, J. (2014). Smart Sustainable Cities: Definition and Challenges. In book: ICT Innovations for Sustainability Edition-Publisher: Springer.
[6.] N’dri, L. M., Islam, M., & Kakinaka, M. (2021). ICT and environmental sustainability: any differences in developing countries?. Journal of Cleaner Production, 297, 126642.
[7.] Pantaloni, M., Marinelli, G., Santilocchi, R., Minelli, A., Neri, D. (2022). Sustainable Management Practices for Urban Green Spaces to Support Green Infrastructure: An Italian Case Study. Sustainability, 14(7): 4243.
[8.] Papagiannopoulou, D., Tsitsoni, T. and Kontogianni, A. (2019). The Contribution of the Park Trees to the Adaptation of a City to Climate Change. The Case of Thessaloniki. www/sustainablemediterraneanconstruction.eu, No. 10 (Accessed in 01- 12-2023).
[9.] Ronchi, S., Arcidiacono, A. and Pogliani, L. (2020). Integrating green infrastructure into spatial planning regulations to improve the performance of urban ecosystems. Insights from an Italian case study. Sustainable Cities and Society, 53.
[10.] Samara T. and Tsitsoni T. (2010). The effects of vegetation on screening road traffic noise from a city ring road. Noise Control Engineering Journal, 59 (1): 68-74.
[11.] Shashua-Bar L. Hoffman M.E., 2000. Vegetation as a climatic component in the design of an urban street: an empirical model for predicting the cooling effect of urban green areas with trees. Energy and Buildings, 31(3): 221-235.
[12.] Tiwari, P., Verma, P. and Raghubanshi, A.S. (2021). Forest phenology as an indicator of climate change: Impact and mitigation strategies in India, Springer Climate, pp. 185–205.
[13.] Tsitsoni, T., Gounaris, N., Kontogianni, A., Xanthopoulou-Tsitsoni, V. (2015) Criteria and Indices for a holistic evaluation of Urban Greening. Greece 2015.
[14.] United States Environmental Protection Agency, (2014). Glossary of Climate Change Terms. http://www.epa.gov/climatechange/glossary.html#Climate_change (Accessed in 25-12-2020).
conference
https://doi.org/10.5593/sgem2023V/4.2/s19.17
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Proceedings of 23rd International Multidisciplinary Scientific GeoConference SGEM 2023
23rd International Multidisciplinary Scientific GeoConference SGEM 2023, 28-30 November, 2023
Proceedings Paper
STEF92 Technology
International Multidisciplinary Scientific GeoConference-SGEM
SWS Scholarly Society; Acad Sci Czech Republ; Latvian Acad Sci; Polish Acad Sci; Russian Acad Sci; Serbian Acad Sci and Arts; Natl Acad Sci Ukraine; Natl Acad Sci Armenia; Sci Council Japan; European Acad Sci, Arts and Letters; Acad Fine Arts Zagreb Croatia; Croatian Acad Sci and Arts; Acad Sci Moldova; Montenegrin Acad Sci and Arts; Georgian Acad Sci; Acad Fine Arts and Design Bratislava; Russian Acad Arts; Turkish Acad Sci.
143-150
28-30 November, 2023
website
9443
urban green areas, sustainable cities, CO2 absorption, ICTs