Contribution of hydro energy production, economic complexity and technological innovation in achieving an environmentally sustainable Asia

Farah Rana; Bilal Hussain; Abdelmohsen A. Nassani; Ayesha Hussain; Mohamed Haffar; Syed Asif Ali Naqvi

doi:10.1016/j.gsf.2024.101876

Geoscience Frontiers ›› 2024, Vol. 15 ›› Issue (5) : 101876. DOI: 10.1016/j.gsf.2024.101876

Contribution of hydro energy production, economic complexity and technological innovation in achieving an environmentally sustainable Asia

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Abstract

The impact of hydro energy production, economic complexity, urbanization, technological innovation and financial development on environmental sustainability between 1995 and 2017 is examined for a panel of thirteen Asian economies using two environmental proxies— their ecological footprint and CO₂ emissions. The non-parametric Driscoll-Kraay standard error method and the Dumitrescu-Hurlin panel causality test are applied to the data. Our findings show that hydro energy production and technological innovation have a significant negative impact on the environment, thus promoting environmental sustainability. Economic complexity significantly lowers environmental sustainability while the non-linear effect of economic complexity favors environmental sustainability; this confirms the existence of an economic-complexity-based inverted-U-shaped environmental Kuznets curve hypothesis. Moreover, urbanization and financial development significantly decrease environmental sustainability. The results of our study confirm the feedback causality between hydro energy production and carbon dioxide emissions. We recommend expansionary policies regarding hydro energy production that are beneficial for substituting fossil fuel energy. This paves a path towards environmental sustainability in this era of global boiling.

Keywords

Hydro energy production / Environmental sustainability / Global boiling / Economic complexity / Asian countries / Panel corrected standard error

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Farah Rana, Bilal Hussain, Abdelmohsen A. Nassani, Ayesha Hussain, Mohamed Haffar, Syed Asif Ali Naqvi. Contribution of hydro energy production, economic complexity and technological innovation in achieving an environmentally sustainable Asia. Geoscience Frontiers, 2024, 15(5): 101876 https://doi.org/10.1016/j.gsf.2024.101876

CRediT authorship contribution statement

Alfonso Encinas: Conceptualization, Methodology, Investigation, Resources, Writing – original draft, Writing – review & editing, Funding acquisition. Nicolás Henríquez: Methodology, Investigation, Writing – review & editing. Daniel Castro: Investigation. Darío Orts: Conceptualization, Methodology, Investigation, Writing – review & editing. Diego Kietzmann: Methodology, Investigation, Writing – review & editing. Franco Iovino: Methodology, Investigation. Paulo Vásquez: Methodology, Investigation. Andrés Folguera: Investigation, Writing – review & editing. Victor Valencia: Methodology, Writing – review & editing. Facundo Fuentes: Conceptualization, Writing – review & editing.

Declaration of competing interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Acknowledgments

AE was founded by ANID, Fondecyt Regular projects 1151146, and 1200428. NH was founded by ANID, National Doctoral Scholarship.

References

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F. Abbasi, K. Riaz. CO2 emissions and financial development in an emerging economy: an augmented VAR approach. Energy Policy, 90 (2016), pp. 102-114,

CrossRef Google scholar

T.S. Adebayo, D. Kirikkaleli. Impact of renewable energy consumption, globalization, and technological innovation on environmental degradation in Japan: application of wavelet tools. Environ. Dev. Sustain, 23 (2021), pp. 16057-16082,

CrossRef Google scholar

T.S. Adebayo, M.O. Agboola, H. Rjoub, I. Adeshola, E.B. Agyekum, N.M. Kumar. Linking economic growth, urbanization, and environmental degradation in China: what is the role of hydroelectricity consumption?. Int. J. Environ. Res. Public Health, 18 (13) (2021), p. 6975,

CrossRef Google scholar

F.F. Adedoyin, I. Ozturk, F.V. Bekun, P.O. Agboola, M.O. Agboola. Renewable and non-renewable energy policy simulations for abating emissions in a complex economy: Evidence from the novel dynamic ARDL. Renew. Energy, 177 (2021), pp. 1408-1420,

CrossRef Google scholar

I. Ahakwa. The role of economic production, energy consumption, and trade openness in urbanization-environment nexus: a heterogeneous analysis on developing economies along the Belt and Road route. Environ. Sci. Pollut. Res., 30 (17) (2023), pp. 49798-49816,

CrossRef Google scholar

M. Ahmad, P. Jiang, A. Majeed, M. Umar, Z. Khan, S. Muhammad. The dynamic impact of natural resources, technological innovations and economic growth on ecological footprint: An advanced panel data estimation. Resour. Policy, 69 (2020), Article 101817,

CrossRef Google scholar

Z. Ahmed, T.S. Adebayo, E.N. Udemba, M. Murshed, D. Kirikkaleli. Effects of economic complexity, economic growth, and renewable energy technology budgets on ecological footprint: the role of democratic accountability. Environ. Sci. Pollut. Res., 29 (17) (2022), pp. 24925-24940,

CrossRef Google scholar

M. Alsaleh, A.S. Abdul-Rahim. The pathway toward pollution mitigation in EU28 region: Does hydropower growth make a difference?. Renew Energy, 185 (2022), pp. 291-301,

CrossRef Google scholar

O.A. Aluko, E.E.O. Opoku, A.O. Acheampong. Economic complexity and environmental degradation: Evidence from OECD countries. Bus. Strategy Environ., 32 (6) (2022), pp. 2767-2788,

CrossRef Google scholar

S. Asumadu-Sarkodie, P.A. Owusu. The relationship between carbon dioxide emissions, electricity production and consumption in Ghana. Energy Source. Part B, 12 (6) (2017), pp. 547-558,

CrossRef Google scholar

G. Aziz, S. Sarwar, K. Nawaz, R. Waheed, M.S. Khan. Influence of tech-industry, natural resources, renewable energy and urbanization towards environment footprints: A fresh evidence of Saudi Arabia. Resour. Policy, 83 (2023), Article 103553,

CrossRef Google scholar

M.A. Baloch, J. Zhang, K. Iqbal, Z. Iqbal. The effect of financial development on ecological footprint in BRI countries: evidence from panel data estimation. Environ. Sci. Pollut. Res., 26 (2019), pp. 6199-6208,

CrossRef Google scholar

D. Balsalobre-Lorente, L. Ibáñez-Luzón, M. Usman, M. Shahbaz. The environmental Kuznets curve, based on the economic complexity, and the pollution haven hypothesis in PIIGS countries. Renew. Energy, 185 (2022), pp. 1441-1455,

CrossRef Google scholar

M.E. Bildirici, S.M. Gökmenoğlu. Environmental pollution, hydropower energy consumption and economic growth: evidence from G7 countries. Renew. Sustainable Energy Rev., 75 (2017), pp. 68-85,

CrossRef Google scholar

F. Bilgili, D. Balsalobre-Lorente, S. Kuşkaya, F. Ünlü, P. Gençoğlu, P. Rosha. The role of hydropower energy in the level of CO2 emissions: An application of continuous wavelet transform. Renew. Energy, 178 (2021), pp. 283-294,

CrossRef Google scholar

L. Charfeddine, Z. Mrabet. The impact of economic development and social-political factors on ecological footprint: A panel data analysis for 15 MENA countries. Renew. Sustainable Energy Rev., 76 (2017), pp. 138-154,

CrossRef Google scholar

W. Chen, Y. Lei. The impacts of renewable energy and technological innovation on environment-energy-growth nexus: New evidence from a panel quantile regression. Renew. Energy, 123 (2018), pp. 1-14,

CrossRef Google scholar

F. Chien, C.C. Hsu, I. Ozturk, A. Sharif, M. Sadiq. The role of renewable energy and urbanization towards greenhouse gas emission in top Asian countries: Evidence from advance panel estimations. Renew. Energy, 186 (2022), pp. 207-216,

CrossRef Google scholar

Danish, Z. Wang. Does biomass energy consumption help to control environmental pollution? Evidence from BRICS countries. Sci. Total Environ., 670 (2019), pp. 1075-1083,

CrossRef Google scholar

M.A. Destek, A. Aslan. Disaggregated renewable energy consumption and environmental pollution nexus in G-7 countries. Renew. Energy, 151 (2020), pp. 1298-1306,

CrossRef Google scholar

A. Dhar, M.A. Naeth, P.D. Jennings, M.G. El-Din. Perspectives on environmental impacts and a land reclamation strategy for solar and wind energy systems. Sci. Total Environ., 718 (2020), Article 134602,

CrossRef Google scholar

B. Doğan, B. Saboori, M. Can. Does economic complexity matter for environmental degradation? An empirical analysis for different stages of development. Environ. Sci. Pollut. Res. Int., 26 (31) (2019), pp. 31900-31912,

CrossRef Google scholar

B. Doğan, O.M. Driha, D. Balsalobre-Lorente, U. Shahzad. The mitigating effects of economic complexity and renewable energy on carbon emissions in developed countries. Sustain. Dev., 29 (1) (2021), pp. 1-12,

CrossRef Google scholar

J.C. Driscoll, A.C. Kraay. Consistent covariance matrix estimation with spatially dependent panel data. Rev. Econ. Stat., 80 (4) (1998), pp. 549-560

E.I. Dumitrescu, C. Hurlin. Testing for Granger non-causality in heterogeneous panels. Econ. Model., 29 (4) (2012), pp. 1450-1460,

CrossRef Google scholar

P.R. Ehrlich, J.P. Holdren. Impact of Population Growth: Complacency concerning this component of man's predicament is unjustified and counterproductive. Science, 171 (3977) (1971), pp. 1212-1217,

CrossRef Google scholar

F. Emir, S. Karlilar. Application of RALS cointegration test assessing the role of natural resources and hydropower energy on ecological footprint in emerging economy. Eng. & Environ-UK, 34 (4) (2023), pp. 764-779,

CrossRef Google scholar

M. Friedman. The use of ranks to avoid the assumption of normality implicit in the analysis of variance. J. Am. Stat. Assoc., 32 (200) (1937), pp. 675-701,

CrossRef Google scholar

J.M. Gonzalez, J.E. Tomlinson, E.A. Martínez Ceseña, M. Basheer, E. Obuobie, P.T. Padi, S. Addo, R. Baisie, M. Etichia, A. Hurford, A. Bottacin-Busolin, J. Matthews, J. Dalton, M. Smith, J. Sheffield, M. Panteli, J.J. Harou. Designing diversified renewable energy systems to balance multisector performance. Nat. Sustain., 6 (2023), pp. 415-427,

CrossRef Google scholar

U. Habiba, C. Xinbang, S. Ali. Investigating the impact of financial development on carbon emissions: Does the use of renewable energy and green technology really contribute to achieving low-carbon economies?. Gondwana Res., 121 (2023), pp. 472-485,

CrossRef Google scholar

D. Hoechle. Robust standard errors for panel regressions with cross-sectional dependence. Stata J., 7 (3) (2007), pp. 281-312,

CrossRef Google scholar

R. Hren, A. Vujanović, Y. Van Fan, J.J. Klemeš, D. Krajnc, L. Čuček. Hydrogen production, storage and transport for renewable energy and chemicals: An environmental footprint assessment. Renew. Sustain. Energy Rev., 173 (2023), Article 113113,

CrossRef Google scholar

Y. Huang, M. Haseeb, M. Usman, I. Ozturk. Dynamic association between ICT, renewable energy, economic complexity and ecological footprint: Is there any difference between E-7 (developing) and G-7 (developed) countries?. Technol. Soc., 68 (2022), Article 101853,

CrossRef Google scholar

B. Hussain, S.A.A. Naqvi, S. Anwar, M. Usman. Effect of wind and solar energy production, and economic development on the environmental quality: Is this the solution to climate change?. Gondwana Res., 119 (2023), pp. 27-44,

CrossRef Google scholar

Hussein, I., Raman, N., 2010. Reconnaissance studies of micro hydro potential in Malaysia in, Proceedings of the International Conference on Energy and Sustainable Development: Issues and Strategies (ESD 2010), Chiang Mai, Thailand, 1–10, https://doi.org/10.1109/ESD.2010.5598802.

International Energy Agency (IEA), 2021. World Energy Outlook 2021. IEA, Paris. https://www.iea.org/reports/world-energy-outlook-2021.

International Renewable Energy Agency (IRENA). Renewable Capacity Highlights 2021. IRENA, UAE (2021)

A. Jahanger. Impact of globalization on CO2 emissions based on EKC hypothesis in developing world: the moderating role of human capital. Environ. Sci. Pollut. Res., 29 (2022), pp. 20731-20751,

CrossRef Google scholar

A. Javed, A. Rapposelli, F. Khan, A. Javed. The impact of green technology innovation, environmental taxes, and renewable energy consumption on ecological footprint in Italy: Fresh evidence from novel dynamic ARDL simulations. Technol. Forecast. Soc., 191 (2023), Article 122534,

CrossRef Google scholar

A. Khaliq, J. Mamkhezri. Asymmetrical analysis of economic complexity and economic freedom on environment in South Asia: A NARDL approach. Environ. Sci. Pollut. Res., 30 (2023), pp. 89049-89070,

CrossRef Google scholar

S. Khan, W. Yahong, A.A. Chandio. How does economic complexity affect ecological footprint in G-7 economies: the role of renewable and non-renewable energy consumptions and testing EKC hypothesis. Environ. Sci. Pollut. Res., 29 (2022), pp. 47647-47660,

CrossRef Google scholar

S. Kihombo, Z. Ahmed, S. Chen, T.S. Adebayo, D. Kirikkaleli. Linking financial development, economic growth, and ecological footprint: what is the role of technological innovation?. Environ. Sci. Pollut. Res., 28 (43) (2021), pp. 61235-61245,

CrossRef Google scholar

S. Kuşkaya, F. Bilgili, E. Muğaloğlu, K. Khan, M.E. Hoque, N. Toguç. The role of solar energy usage in environmental sustainability: Fresh evidence through time-frequency analyses. Renew. Energy, 206 (2023), pp. 858-871,

CrossRef Google scholar

E. Lau, C.C. Tan, C.F. Tang. Dynamic linkages among hydroelectricity consumption, economic growth, and carbon dioxide emission in Malaysia. Energy Sources, Part B: Econ., Plann. Policy, 11 (11) (2016), pp. 1042-1049

H. Liu, S. Liang, Q. Cui. The nexus between economic complexity and energy consumption under the context of sustainable environment: evidence from the LMC Countries. Int. J. Environ. Res. Public Health, 18 (1) (2021), p. 124,

CrossRef Google scholar

A. Mehrjo, S. Satari Yuzbashkandi, M.H. Eskandari Nasab, H. Gudarzipor. Economic complexity, ICT, biomass energy consumption, and environmental degradation: evidence from Iran. Environ. Sci. Pollut. Res., 29 (2022), pp. 69888-69902,

CrossRef Google scholar

S. Nasreen, S. Anwar, I. Ozturk. Financial stability, energy consumption and environmental quality: Evidence from South Asian economies. Renew. Sustain. Energy Rev., 67 (2017), pp. 1105-1122,

CrossRef Google scholar

S. Nathaniel, S.A.R. Khan. The nexus between urbanization, renewable energy, trade, and ecological footprint in ASEAN countries. J. Clean. Prod., 272 (2020), Article 122709,

CrossRef Google scholar

NS Energy, 2019. Hydropower in China and other top generators across Asia. https://www.nsenergybusiness.com/features/hydropower-china-top-generators-asia/#:∼:text=Asia%20accounted%20for%20about%2042,energy%20capacity%20was%202%2C394GW .

R.W. Parks. Efficient estimation of a system of regression equations when disturbances are both serially and contemporaneously correlated. J. Am. Stat. Assoc., 62 (318) (1967), pp. 500-509,

CrossRef Google scholar

U.K. Pata. Renewable energy consumption, urbanization, financial development, income and CO2 emissions in Turkey: testing EKC hypothesis with structural breaks. J. Clean. Prod., 187 (2018), pp. 770-779,

CrossRef Google scholar

U.K. Pata, M. Aydin. Testing the EKC hypothesis for the top six hydropower energy-consuming countries: evidence from Fourier Bootstrap ARDL procedure. J. Clean. Prod., 264 (2020), Article 121699,

CrossRef Google scholar

U.K. Pata, V. Yilanci, B. Hussain, S.A.A. Naqvi. Analyzing the role of income inequality and political stability in environmental degradation: evidence from South Asia. Gondwana Res., 107 (2022), pp. 13-29,

CrossRef Google scholar

U.K. Pata, S. Yurtkuran, Z. Ahmed, M.T. Kartal. Do life expectancy and hydropower consumption affect ecological footprint? Evidence from novel augmented and dynamic ARDL approaches. Heliyon, 9 (9) (2023), p. e19567

M.H. Pesaran. A simple panel unit root test in the presence of cross-section dependence. J. Appl. Econom., 22 (2) (2007), pp. 265-312,

CrossRef Google scholar

L.N. Proskuryakova, O. Saritas, S. Sivaev. Global water trends and future scenarios for sustainable development: The case of Russia. J. Clean. Prod., 170 (2018), pp. 867-879,

CrossRef Google scholar

M.Z. Rafique, Y. Li, A.R. Larik, M.P. Monaheng. The effects of FDI, technological innovation, and financial development on CO2 emissions: evidence from the BRICS countries. Environ. Sci. Pollut. Res., 27 (2020), pp. 23899-23913,

CrossRef Google scholar

M. Sahoo, N. Sethi. The intermittent effects of renewable energy on ecological footprint: evidence from developing countries. Environ. Sci. Pollut. Res., 28 (2021), pp. 56401-56417,

CrossRef Google scholar

S. Salem, N. Arshed, A. Anwar, M. Iqbal, N. Sattar. Renewable energy consumption and carbon emissions—testing nonlinearity for highly carbon emitting countries. Sustainability, 13 (21) (2021), p. 11930,

CrossRef Google scholar

S.A.R. Shah, D. Balsalobre-Lorente, M. Radulescu, Q. Zhang, B. Hussain. Revising the tourism-induced environment Kuznets curve hypothesis in top 8 Asian economies: the role of ICT and renewable energy consumption. J. Hosp. Tour. Technol. (2022)

O. Sinaga, O. Alaeddin, N.H. Jabarullah. The Impact of Hydropower Energy on the Environmental Kuznets Curve in Malaysia. Int. J. Energy Econ. Policy, 9 (1) (2018), pp. 308-315

Y. Sun, Q. Bao, W. Siao-Yun, M. ul Islam, A. Razzaq. Renewable energy transition and environmental sustainability through economic complexity in BRICS countries: Fresh insights from novel Method of Moments Quantile regression. Renew. Energy, 184 (2022), pp. 1165-1176,

CrossRef Google scholar

Y. Sun, W. Tian, U. Mehmood, X. Zhang, S. Tariq. How do natural resources, urbanization, and institutional quality meet with ecological footprints in the presence of income inequality and human capital in the next eleven countries? Resour. Policy, 85 (A) (2023), Article 104007,

CrossRef Google scholar

U.S. Energy Information Administration (U.S. EIA), 2016. International Energy Outlook 2016. U.S. EIA, Washington, DC, www.eia.gov/forecasts/ieo/pdf/0484(2016).pdf.

G.A. Uddin, M. Salahuddin, K. Alam, J. Gow. Ecological footprint and real income: panel data evidence from the 27 highest emitting countries. Ecol. Indic., 77 (2017), pp. 166-175,

CrossRef Google scholar

M. Ummalla, A. Samal. The impact of hydropower energy consumption on economic growth and CO2 emissions in China. Environ. Sci. Pollut. Res., 25 (2018), pp. 35725-35737,

CrossRef Google scholar

M. Ummalla, A. Samal, P. Goyari. Nexus among the hydropower energy consumption, economic growth, and CO2 emissions: evidence from BRICS countries. Environ. Sci. Pollut. Res., 26 (2019), pp. 35010-35022,

CrossRef Google scholar

United Nations (UN), 2022. The Sustainable Development Goals Report 2022. https://unstats.un.org/sdgs/report/2022/ .

United Nations Environment Programme (UNEP), 2022. Emissions Gap Report 2022. https://www.unep.org/resources/emissions-gap-report-2022.

Z. Wang, Q. Bui, B. Zhang. The relationship between biomass energy consumption and human development: Empirical evidence from BRICS countries. Energy, 194 (2020), Article 116906,

CrossRef Google scholar

S. Wang, M.W. Zafar, D.G. Vasbieva, S. Yurtkuran. Economic growth, nuclear energy, renewable energy, and environmental quality: Investigating the environmental Kuznets curve and load capacity curve hypothesis. Gondwana Res., 129 (2023), pp. 490-504,

CrossRef Google scholar

S. Wei, W. Wei, A. Umut. Do renewable energy consumption, technological innovation, and international integration enhance environmental sustainability in Brazil?. Renew Energy, 202 (2023), pp. 172-183,

CrossRef Google scholar

J. Westerlund. Testing for error correction in panel data. Oxf. Bull. Econ. Stat., 69 (6) (2007), pp. 709-748,

CrossRef Google scholar

D. Xie, N. Saeed, S. Akhter, T. Kumar. A step towards a sustainable environment in top Asian countries: the role of higher education and technology innovation. Econ. Res. - Ekonomska Istraživanja, 36 (3) (2023), Article 2152359,

CrossRef Google scholar

R. York, E.A. Rosa, T. Dietz. STIRPAT, IPAT and ImPACT: analytic tools for unpacking the driving forces of environmental impacts. Ecol. Econ., 46 (3) (2003), pp. 351-365,

CrossRef Google scholar

J. Yu, Y.M. Tang, K.Y. Chau, R. Nazar, S. Ali, W. Iqbal. Role of solar-based renewable energy in mitigating CO2 emissions: evidence from quantile-on-quantile estimation. Renew. Energy, 182 (2022), pp. 216-226,

CrossRef Google scholar

S. Zheng, M. Irfan, F. Ai, M.A.S. Al-Faryan. Do renewable energy, urbanisation, and natural resources enhance environmental quality in China? Evidence from novel bootstrap Fourier Granger causality in quantiles. Resour. Policy, 81 (2023), Article 103354,

CrossRef Google scholar