Contribution of Commuters and Transit Activities on The Road Transport Carbondioxides Emission in Surakarta
Widhi Himawan(1*), Sajidan Sajidan(2), Sunarto Sunarto(3), Prabang Setyono(4), Natasha Nancy(5), Sovia Wijayanti(6)
(1) Doctoral Programme of Environmental Science Post Graduate School of Universitas Sebelas Maret
(2) Bachelor Programme of Biology Education Department Faculty of Teacher Training and Education Universitas Sebelas Maret
(3) Bachelor Programme of Environmental Science Department Faculty of Mathematics and Natural Science Universitas Sebelas Maret
(4) Bachelor Programme of Environmental Science Department Faculty of Mathematics and Natural Science Universitas Sebelas Maret
(5) Bachelor Programme of Environmental Science Department Faculty of Mathematics and Natural Science Universitas Sebelas Maret
(6) Bachelor Programme of Environmental Science Department Faculty of Mathematics and Natural Science Universitas Sebelas Maret
(*) Corresponding Author
Abstract
Road transportation became a main contributor to the emissions of Surakarta City. The driving factor for these conditions is predicted to originate from massive commuting and transit activities. This research covered the administrative area of Surakarta City in July–August 2022. The aim of the research was to determine the impact of commuting and transit on carbon dioxide (CO2) emissions from Surakarta transportation and develop a spatial interpretation of the distribution of emissions. The emission estimation method uses a Tier 3 calculation approach using the Mobilev software. Estimation based on average daily traffic data for 24 hours as well as the character of the monitored path. The results of the study obtained an estimate of road transportation emissions for the City of Surakarta to reach 722795.3 tons of CO2 peryear. Commuter and transit activities contribute to 50.33% of total major road emissions or 133.77% of local vehicle emissions. Commuter and transit emissions in Surakarta City are dominated by private passenger cars (38.26%) and motorcycles (37.71%). Emission distribution shows a pattern of emission load that is greater on the city gate and transit lines than the central business district (CBD) area.
Keywords
Full Text:
PDFReferences
Anderson, T.R., Hawkins, E., and Jones, P.D. (2016). CO2 the greenhouse effect and global warming: from the pioneering work of Arrhenius and Callendar to today’s earth system models. Endeavour 40 (3): 178-187
ASEAN Secretariat. (2019). ASEAN Fuel economy roadmap for the transport sector 2018-2025: with focus on light-duty vehicles. ASEAN Secretariat. Jakarta
Bellard, C., Bertelmeier, C., Leadley, P., Thuolier, W. and F. Courchamp. 2012. Impacts of climate change on the future of biodiversity. Ecology Letters 15 (2012): 365-377
Chee, W.L. and Fernandez, J.L. (2013). Factors that Influence the Choice of Mode of Transport in Penang: A Preliminary Analysis. Procedia - Social and Behavioral Sciences 91 ( 2013 ) 120 – 127
Cheng, Y.H., Chang, Y.H., and Lu, I.J.(2015). Urban transportation energy and carbon dioxide emission reduction strategies. Applied Energy 157 (2015) : 953-973
Das, S. and N. Mangwani. (2015). Ocean acidification and marine microorganisms: responses and consequences. Oceanologia 57 (2015) : 349-361
Denant-Boemont, L., Gate, R., and Gaigne, C. (2018). Urban spatial structure, transport-related emissions, and welfare. Journal of Environmental Economics and Management 89 (2018) : 29-45
European Environment Agency. (2013). EMEP/EEA Air Pollutant Emission Inventory Guidebook 2013, Technical Guidance to Prepare National Emission Inventory. Luxembourg: Publications Office of The European Union
Fan, J.L., Wang, J.X., Li, F., Yu, H., and Zhang, X. (2017). Energy demand and greenhouse gas emission of urban passenger transport in the Internet era: A case study of Beijing. Journal of Cleaner Production (2017)31549-4
Gioli, B., Gualtieri, G., Busillo, C., Calastrini, F., Zaldei, A., and P. Toscano. (2015). Improving high-resolution emission inventories with local proxies and urban eddy covariance flux measurement. Atmospheric Environment 115 : 246-256
Gulia, S., Nagendra, S.M.S., Khare, M., and Khanna, I. 2014. Urban Air Quality Management: A Review. Atmospheric Pollution Research 6 (2015): 286-304
Henderson, R.M., Reinert, S.A., Dekhtyar, P. and Migdal, A. 2018. Climate Change in (2018). Implications in Business. Harvard Business School Publishing. Boston.
Hickman, R., Ashiru, O., Banister, D., 2010. Transport and climate change: Simulating the options for carbon reduction in London. Transport Policy 17 (2), 110–125
Himawan, W. dan Nancy, N. 2022. Dokumen Inventarisasi Gas Rumah Kaca Kota Surakarta Tahun 2022. Dinas Lingkungan Hidup Kota Surakarta
Holz-Rau, C. and Scheiner, J.(2019). Land-use and transport planning – A field of complex cause-impact relationships. Thoughts on transport growth, greenhouse gas emissions, and the built environment. Transport Policy 74 (2019) : 127–137
Intergovernmental Panel on Climate Change. (2006). Guidelines for National Greenhouse Gas Inventories. Institute for The Global Environmental Strategies. Hayama
Intergovernmental Panel on Climate Change. (2014). Climate Change 2014: Synthesis Report. Contribution of Working Groups I, II, and III to The Fifth Assessment Report of The IPCC (Core Writing Team, R.K Pachauri and L.A Meyer (eds.)). IPCC. Geneva
Intergovernmental Panel on Climate Change. (2015). Climate Change 2014: Impacts, Adaptation and Vulnerability. The Fifth Assessment Report Technical Summary. IPCC. Geneva
Lei, H., Zeng, S., Namaiti, A. and Zeng, J. (2023). The Impacts of Road Traffic on Urban Carbon Emissions and the Corresponding Planning Strategies. Land 2023, 12, 800.
Li, S., Xue, F., Xia, C., Zhang, J., Bian, A., Lang, Y., and Zhou, J. (2022). A Big Data-based Cossemmuting Carbon Emissions Accounting Method-A Case of Hangzhou. Land 2022, 11, 900
Liu, H., Li, Y.X., Yu, F.J., Lu, C., Yang, N., Liu, Z.L. and Zhao, M. (2022). Evolution and spatial distribution of road carbon emissions in Beijing-Tianjin-Hebei region. China Environ. Sci. 2022, 1–12.
Nikinmaa, M. (2013). Climate change and ocean acidification – aquatic with aquatic toxicology. Aquatic Toxicology 126 (2013) : 365-372
Noussan, M. and Jarre, M. (2021). Assessing Commuting Energy and Emissions Savings through Remote Working and Carpooling: Lessons from an Italian Region. Energies 2021, 14, 7177
Nurdiani, D., Astuti, W., dan Rini, E.F. (2019). Kesesuaian system transportasi umum di Kota Surakarta terhadap konsep transportation for liveable city. Jurnal Desa Kota 1 (1) : 71-83
Nurhidayat, A., Widyastuti, H., Sucipto and Utomo, D.P. (2018). Model of Transportation Mode Selection between private vehicle and Serpon-Tanahabang Commuting Line. Advances in Engineering Research (AER), volume 147
Obermayr, C. 2017. Sustainable City Management: Informal Settlements in Surakarta, Indonesia. The Urban Book Series. Springer International Publishing. Switzerland
Rasca, S. and Saeed, N. (2022). Exploring the factors influencing the use of public transport by commuters living in networks of small cities and towns. Travel Behaviour and Society 28 (2022) 249-263
Selamena, D.P.J., Cong, Y., Lin, F., Ardisa, F., Novella, U., Kurosawa, T., Sako, M., Ohtani, Y., and Fujiyama, I. (2021). Changes in CO2 Emissions in Online Student Learning Activities Due to the COVID-19 Pandemic in Indonesia and Japan. IOP Conf. Series: Earth and Environmental Science 933 (2021) 012022
Setyono, P., Himawan, W., and Sari, C.P. (2020). Mitigating carbon dioxide emission from mobility based on the bottom-up approach in the central business district of Surakarta City. The 4th International Conference on Climate Change 2019 (The 4th ICCC 2019. IOP Conference Series: Earth and Environmental Science 423 (2020) 012002
Setyono, P., Himawan, W., Sari, C.P., Gunawan, T., and Murti, S.H. 2020. Greenhouse Gas Pollution Based on Energy use and its Mitigation Potential in the city of Surakarta, Indonesia. Indonesian Journal of Geography 52 (1) : 1-7.
Shahbazi, H., Taghvaee, S., Hosseini, V., and H. Afhsin. 2016. A GIS-based emission inventory development for Tehran. Urban Climate 17 (2016): 216-229.
Shuai, C., Liyin, S., Jiao, L., Wu, Y., and Tan, Y. (2017). Identifying key impact factors on carbon emission: Evidence on panel and time series data of 125 countries from 1999-2011. Applied Energy 187 (2017): 310-325.
Suhadi, D.R., Febrina, A.S., Setyono, P., Himawan,W., Pramadhony, Mahalana, A., Zakaria, M., Krisnawaty, L., Tambun, J.H., Harsono, Rena, T., Darojat, R., dan R.M. Rumapea. (2013). Pedoman Teknis Penyusunan Inventarisasi Emisi Pencemaran Udara di Perkotaan. Jakarta : Kementerian Lingkungan Hidup Republik Indonesia
Sutton-Parker, J. 2021. Determining commuting greenhouse gas emissions abatement achieved by information technology-enabled remote working. Procedia Computer Science 191 (2021) 296–303
Statistics Agency of Surakarta. (2022). Surakarta dalam angka tahun 2022.
Tuayharn, K., Kaewtatip, P., and Ruangjirakit, K. (2015). ICE Motorcycle dan electric motorcycle: Environmental and Economic Analysis. SAE International TSAE-15IC-0100
World Meteorological Organization. (2020). WMO Statement on the State of the Global Climate Change in 2019. Publication Board of WMO. Geneva.
Xue, L. K., Wang, T., Gao, J., Ding, A. J., Zhou, X. H., Blake, D. R., and Zhang, Q. Z. (2014). Ground-level ozone in four Chinese cities: precursors, regional transport and heterogeneous processes. Atmospheric Chemistry and Physics. 14 (23): 13175-13188.
DOI: https://doi.org/10.22146/ijg.83164
Article Metrics
Abstract views : 1056 | views : 561Refbacks
- There are currently no refbacks.
Copyright (c) 2024 Widhi Himawan, Sajidan Sajidan, Sunarto Sunarto, Prabang Setyono, Natasha Nancy, Sovia Wijayanti
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
Accredited Journal, Based on Decree of the Minister of Research, Technology and Higher Education, Republic of Indonesia Number 225/E/KPT/2022, Vol 54 No 1 the Year 2022 - Vol 58 No 2 the Year 2026 (accreditation certificate download)
ISSN 2354-9114 (online), ISSN 0024-9521 (print)
IJG STATISTIC