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Adopting renewable energies to meet the carbon reduction target: Is forest carbon sequestration cheaper?

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  • Liu, Wan-Yu
  • Chiang, Yi-Hua
  • Lin, Chun-Cheng

Abstract

In most countries, the current goal for greenhouse gas emission reduction is to achieve a 50% reduction by 2050 with a carbon neutrality target. Most energy policies have been to adopt at least 20% renewable energies in the country energy portfolio. This study conducted a comparative cost analysis on various carbon emission reduction options: reducing fossil energies (including coal, natural gas, and petroleum), increasing renewable energies (including hydroelectric power, wind power, photovoltaics, and wood fuel), and increasing afforestation (including coniferous forests, broadleaved forests, and mixed coniferous-broadleaved forests). In analyzing the discounted costs per unit of carbon reduction, this study explored the costs of these options at a fixed amount of carbon reduction, which means the lower the costs, the more effective the carbon emission reduction. Taking Taiwan as an example, the results indicated that coal-fired power has the lowest cost (US$24.80 per ton of CO2). The costs of other energy sources (i.e., natural gas, petroleum, hydroelectric power, wind power, solar power, and wood fuel) are US$79.72–182.17 per ton of CO2. The cost of afforestation for reducing carbon emissions is US$34.68–64.82 per ton of CO2, lower than the cost of adopting renewable energies assuming no technological advancement in current renewable energies.

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  • Liu, Wan-Yu & Chiang, Yi-Hua & Lin, Chun-Cheng, 2022. "Adopting renewable energies to meet the carbon reduction target: Is forest carbon sequestration cheaper?," Energy, Elsevier, vol. 246(C).
    • Handle: RePEc:eee:energy:v:246:y:2022:i:c:s0360544222002316
    DOI: 10.1016/j.energy.2022.123328
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    1. Gren, Ing-Marie & Carlsson, Mattias & Elofsson, Katarina & Munnich, Miriam, 2012. "Stochastic carbon sinks for combating carbon dioxide emissions in the EU," Energy Economics, Elsevier, vol. 34(5), pages 1523-1531.
    2. Liu, Wan-Yu & Lin, Chun-Cheng & Yeh, Tzu-Lei, 2017. "Supply chain optimization of forest biomass electricity and bioethanol coproduction," Energy, Elsevier, vol. 139(C), pages 630-645.
    3. Brian C. Murray & Bruce A. McCarl & Heng-Chi Lee, 2004. "Estimating Leakage from Forest Carbon Sequestration Programs," Land Economics, University of Wisconsin Press, vol. 80(1), pages 109-124.
    4. Vass, Miriam Münnich & Elofsson, Katarina, 2016. "Is forest carbon sequestration at the expense of bioenergy and forest products cost-efficient in EU climate policy to 2050?," Journal of Forest Economics, Elsevier, vol. 24(C), pages 82-105.
    5. Hung, Chung-Pin & Wei, Chiang & Wang, Song Yung & Lin, Far-Ching, 2009. "The study on the carbon dioxide sequestration by applying wooden structure on eco-technological and leisure facilities," Renewable Energy, Elsevier, vol. 34(8), pages 1896-1901.
    6. Alban Kitous, Patrick Criqui, Elie Bellevrat and Bertrand Chateau, 2010. "Transformation Patterns of the Worldwide Energy System - Scenarios for the Century with the POLES Model," The Energy Journal, International Association for Energy Economics, vol. 0(Special I).
    7. Teng, Xiangyu & Liu, Fan-peng & Chiu, Yung-ho, 2021. "The change in energy and carbon emissions efficiency after afforestation in China by applying a modified dynamic SBM model," Energy, Elsevier, vol. 216(C).
    8. Kovacs, Kent F. & Haight, Robert G. & Moore, Karli & Popp, Michael, 2021. "Afforestation for carbon sequestration in the Lower Mississippi River Basin of Arkansas, USA: Does modeling of land use at fine spatial resolution reveal lower carbon cost?," Forest Policy and Economics, Elsevier, vol. 130(C).
    9. Zhang, M.M. & Wang, Qunwei & Zhou, Dequn & Ding, H., 2019. "Evaluating uncertain investment decisions in low-carbon transition toward renewable energy," Applied Energy, Elsevier, vol. 240(C), pages 1049-1060.
    10. Brent Sohngen & Robert Mendelsohn, 2003. "An Optimal Control Model of Forest Carbon Sequestration," American Journal of Agricultural Economics, Agricultural and Applied Economics Association, vol. 85(2), pages 448-457.
    11. Adetoye, Ayoade Matthew & Okojie, Luke O. & Akerele, Dare, 2018. "Forest carbon sequestration supply function for African countries: An econometric modelling approach," Forest Policy and Economics, Elsevier, vol. 90(C), pages 59-66.
    12. Jia, Zhijie & Lin, Boqiang, 2021. "How to achieve the first step of the carbon-neutrality 2060 target in China: The coal substitution perspective," Energy, Elsevier, vol. 233(C).
    13. Salvilla, John Nikko V. & Ofrasio, Bjorn Ivan G. & Rollon, Analiza P. & Manegdeg, Ferdinand G. & Abarca, Ralf Ruffel M. & de Luna, Mark Daniel G., 2020. "Synergistic co-pyrolysıs of polyolefin plastics with wood and agricultural wastes for biofuel production," Applied Energy, Elsevier, vol. 279(C).
    14. Pantelis Capros & Leonidas Mantzos, 2000. "Endogenous learning in European post-Kyoto scenarios: results from applying the market equilibrium model PRIMES," International Journal of Global Energy Issues, Inderscience Enterprises Ltd, vol. 14(1/2/3/4), pages 249-261.
    15. Brini, Riadh, 2021. "Renewable and non-renewable electricity consumption, economic growth and climate change: Evidence from a panel of selected African countries," Energy, Elsevier, vol. 223(C).
    16. Guo, Jinggang & Gong, Peichen, 2017. "The potential and cost of increasing forest carbon sequestration in Sweden," Journal of Forest Economics, Elsevier, vol. 29(PB), pages 78-86.
    17. Münnich Vass, Miriam, 2017. "Renewable energies cannot compete with forest carbon sequestration to cost-efficiently meet the EU carbon target for 2050," Renewable Energy, Elsevier, vol. 107(C), pages 164-180.
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