Index

Abstract

This study examined the effect of nonrenewable energy use, output, domestic credit and FDI on environmental pollution in Nigeria through the use of ARDL method from 1980 – 2016. The outcome of the study’s estimation reveals that all the variables possess the long run association. It is indicated that in short and long run conditions, nonrenewable energy use, FDI and trade increased environmental dilapidation, thereby adversely affect environmental quality in Nigeria. However, financial development has negative influence on environmental degradation. The finding clearly illustrates that nonrenewable energy utilization rise environmental pollution in Nigeria. Hence, policymakers should design appropriate policies to enhance environmental quality through policies that will regulate the use nonrenewable energy and backed the policies in promoting the utilization of renewable energy resources, inform of wind, solar and hydro energy. It is essential for government to take anti-corruption measures, that the designed policies are implemented appropriately to achieve the benefits of the policies. This would be very vital in achieving environmental quality, welfare enhancement, poverty reduction as well as sustainable economic development.

Keywords: Non-renewable energy, consumption environmental pollution, GDP, FDI, Nigeria, ARDL.

Received: 18 March 2020 / Revised: 21 April 2020 / Accepted: 25 May 2020/ Published: 26 June 2020

Contribution/ Originality

The study contributes in the existing literature by examining the effect of nonrenewable energy use on environmental pollution in Nigeria, as studies on environmental quality are few in African and Nigeria in particular. The outcome of the study would help policymakers in designing appropriate and effective policies for environmental quality.

1. INTRODUCTION

Due to excessive discharge of greenhouse gas emissions (GHGs) in the past few decades, environmental pollution has become a greatest global issue (Dogan & Seker, 2016). It is emphasized that CO2 accounted for a greater portion of the greenhouse gases that upsurge the level of global heat, so environmental pollution has turned to be a greatest issue of concern (IPCC. 2018). Over the previous years the extent of CO2 explosion in the world has been increasing that seriously affect the ecosystem, economic performance and welfare of the global nations (Danlami, Applanaidu, & Islam, 2018). Thus, the growing nature of the global CO2 discharge has extend more fear of deteriorating effects of the climate change (Tiwari, 2011). The world outflow of the CO2 discharge has increased by 16.49 percent from 1980 – 2013. It implies that about 84 percent rise of CO2 with in the same time span. Banday and Aneja (2018). Furthermore, CO2 explosion from developed and emerging nations increases at 1.3 percent yearly and if the trend continuous it may be double by 2030 in the absence of control measures (IPCC, 2014).

According to Global Carbon Project (2018) CO2 from non-renewable energy consumption increased by 33.1 % to 36.2 % from 2010 to 2017 and are projected to rise by 2.7% with China and India accounting for greater portion. Several studies have illustrates that factors like energy consumption, increase in population, urbanization and the need for greater economic performance in emerging nations are among the causes of low environmental quality (Acaravci & Ozturk, 2010; Sehrawat, Giri, & Mohapatra, 2015). Hence, it is documented that CO2 mitigation measures has to be emphasize for grater environmental quality and sustainable economic performance.

In African countries CO2 have been on growing track since 1950s. Emissions from fuel energy have increased overtime that account for 35 percent as well as gas fuel 16.9 percent. Based on the report documented by the WRI that in Africa the percapita CO2 discharge was 0.8 kt per individual in 2008 and raised to 0.86 kt in 2013. Gbatu (2018) projected that carbon-based pollution in African nations may rise to about 50 percent of the total world share by 2030. In addition, it predicts a severe climate deterioration such as drought, water heat and flood, in most nations for which African countries are no exception. Therefore, African nations have experience high level of heat due to increased temperature level. This situation may result drought, floods, increase in diseases outbreak, loss of the natural ecosystem as well as less agricultural production (IPCC, 2007).
Nigeria is among the greatest nation responsible for the region growth of emissions from non-renewable energy resource. For instance, Figure 1.  indicates that in Nigeria CO2  upsurge from 39,196 kt in 1990 to 96, 280 kt in 2014 (WDI, 2017). The current situation reveals that Nigerians CO2 have coming more severe and dangerous.  In this regard, the high explosion of CO2 in Nigeria, may be linked to the increase in economic activities which has resulted from more utilization of non-renewable energy due to the fact that it is the major oil producers in the African continent. For example, according to WDI (2017) non-renewable energy consumption in Nigeria possessed an increasing trend which shows that energy consumed had increase from 697,613.4003 kg of oil equivalent in 1990 to 763.631.9766 kg of oil equivalent 2014. In addition, the share of biomass and waste energy consumption such as charcoal and other residues have been increased to the turn of 83 percent and it is predominantly from the rural areas (EIA, 2013). Hence, the growth of non-renewable energy consumption in Nigeria may increase the explosion CO2 that cause severe heat deterioration of climate condition. This would result to diseases outbreak, low agricultural performance, increase level of extreme poverty and unemployment. Thus, knowing the influence of nonrenewable energy consumption on environmental pollution in Nigeria will aid the policy makers in formulating appropriate policies to mitigate CO2 and achieve sustainable economic growth and development.

Figure-1. CO2 kilotonne.

Source: WDI (2017).

The present study differs from earlier studies in such way that application of ARDL technique in the analysis of environmental studies is very limited especially in Nigeria context. Moreover, the present study possess larger sample period in comparison with the earlier studies (Bento & Moutinho, 2016; Farhani & Shahbaz, 2014; Shafiei & Salim, 2014). Furthermore, the study used aggregate form of non-renewable energy consumption (coal, natural gas and oil) and its relationship with environment as most of the earlier studies utilizes total energy consumption and environment (Shafiei & Salim, 2014).

2. LITERATURE REVIEW   

Earlier studies in the literature have analyzes the association among nonrenewable, renewable energy use, Gross Domestic Product (GDP), financial sector performance and CO2. For instance, Shafiei and Salim (2014) employ STIRPAT technique to estimate the influence of nonrenewable energy consumption on CO2 in OECD nations from 1980 – 2011. It is documented that nonrenewable energy promotes CO2. Similarly, Farhani and Shahbaz (2014) applies FMOLS method to investigate the effect of nonrenewable energy on CO2 in MENA countries from 1980 – 2009. The outcome indicates that nonrenewable energy resource increases the level of CO2. Long (2015) documents that nonrenewable energy consumption accelerates the explosion of CO2 in China from 1952 – 2012. Dogan and Seker (2016) use multiple nations analysis to explore the link between nonrenewable energy, GDP, trade and CO2 emissions in European Union nations from 1980 – 2012. The outcome shows that nonrenewable energy promotes the level of CO2. Bento and Moutinho (2016) estimate the association among nonrenewable energy production and CO2 in Italy from 1960 – 2011. The estimate reveals that nonrenewable energy production influence CO2 positively.

Moreover, Wang, Li, and Fang (2018) estimate influence of energy resources on CO2 in Pakistan from 1970 – 2012. They reveal that use of energy upsurges CO2. Sharif (2018) argued that nonrenewable energy accelerates environmental dilapidation in 74 nation from 1990 - 2015. Chen, Wang, and Zhong (2019) use yearly data of china to evaluate the effect of energy production on CO2 using ARDL approach from 1980 – 2014. The outcome indicates nonrenewable energy production explore more CO2. Sarkodie and Strezov (2019) finds positive influence of energy resources on CO2 in emerging nations. Bekun, Alola, and Sarkodie (2019) explore the impact of renewable, nonrenewable consumption of energy and GDP on CO2 for 16 EU nations from 1996 to 2014. The outcome of the study indicates that nonrenewable energy increases CO2 in the selected EU countries, while renewable energy condenses CO2.

In another development, study by Shahbaz, Mutascu, and Azim (2014) studied the association among industrial growth, use of energy resource and CO2 for Romania. It finds that industrial performance and energy increases CO2. Cetin and Ecevit (2017) noted that GDP influenced CO2 positively in Turkey. Wang, Zhang, and Wang (2018)  investigate the influence of output performance on CO2 in 170 nations. They finds that GDP influence CO2 positively. Meanwhile, Javid and Sharif (2016) explore the influence of financial development (FD), income, energy with trade on CO2 in Pakistan. Outcome shows that FD, income, and consumption of energy promote CO2. In another development, Cetin and Ecevit (2017) reveal that financial progress increases CO2 in Turkey. Charfeddine and Kahia (2019) argued that financial sector performance upsurges the capacity of CO2 in MENA economies. Similarly, Gokmenoglu and Sadeghieh (2019) examine the performance of FD, fossil fuel and growth performance on CO2 in Turkey. The outcome shows linkage among FD and CO2. This outcome is in line with the result obtained by Zakaria and Bibi (2019) that FD increase level of environmental dilapidation in South Africa. However, Dogan and Turkekul (2016) analyze the performance of trade on CO2 in the USA and conclude that trade openness improves environmental quality. Zhang (2018) reaffirms that trade openness influenced CO2 negatively in newly industrialized countries.

From the above it is observed from the reviewed literature most of the studies on nonerasable energy resources and environment are concentrated in developed nations and very few studies in Africa, especially Nigeria. In addition, the use of aggregate of coal, oil and natural gas as measurement of nonrenewable energy consumption has not been much utilized by the earlier studies. Hence, the present study examine the effect of nonrenewable energy consumption using aggregate of coal, oil and natural gas on pollution in Nigeria.

3. DATA AND TECHNIQUE OF ANALYSIS

3.1. Data

Yearly data for CO2 per capita (metric tons), non-renewable energy (aggregate of coal, gas and oil consumption in in quadrillion Btu), GDP per capita (current USD), financial progress (domestic credit percent of GDP), foreign direct investment (net inflow percent of GDP) and trade (aggregate imports and exports percent of GDP) from 1980 – 2016. The data on non-renewable energy was obtained from Energy Information Administration (EIA), while other variables were from world development indicator (WDI). For easy interpretation the variable are changed to log. Table 1 denotes the statistical nature of the variables used in the study. It is clearly indicated that GDP obtains greater value for the mean variation and standard deviation.

Table-1. Statistical nature of the variables.

Variables	Min	Max	Mean	SD
LCO2	4.01	4.67	4.42	0.20
LNRC	0.26	0.89	0.29	0.25
LGDP	5.59	8.07	6.87	0.72
LFD	1.60	3.10	2.17	0.39
LFDI	1.35	1.75	0.33	0.77
LTO	2.21	3.97	3.38	0.51

3.2. Model Specification

3.2.1. Stationarity Test

Augmented dicky fuller ADF test was used in the study to be sure about the intergradation order and stationarity level. In addition, Philips Peron (PP) test was also employed to reconfirm the stationary of the variables. Hence, the following equation describe the ADF test:

In this equation N (t, l) = 1[t/ (1+l)] and l symbolizes the lags

3.2.2. The Model of Analysis           

The link  among environmental pollution and the independent variables is analyzed by the use of a modified model of Farhani and Shahbaz (2014) and it is specified in Equation 3.

LENP = f (LNRC, LGDP, LFD, LFDI, LTO)                                                       (3)

From the above equation LENP, LNRC, LGDP, LFD, LFDI and LTO indicates the environmental pollution, non-renewable energy utilization, economic performance, financial progress, foreign direct investment and trade, respectively. The study applies Autoregressive Distributed Lag (ARDL) technique for the long-run estimation. This is for the reason that the method came up with the efficient estimation. Therefore, Equation 4 demonstrates the model.

 Thus, to ascertain the existence of long-run connotation among the variables, F-statistics most be higher than UCB as reaffirmed  by Pesaran, Shin, and Smith (2001). Furthermore, the adjustment for the variables to long run  is reaffirm by the nagetaive and significant value of  error correction term.       

4. RESULT

It is essential to know the stationary of the variables. Thus,the study applies ADF and PP tests for staionarity. The outcome in Table 2 shows that all the variables are stationary in the first defference.

Table-2.  Stationarity tests.

Variable	ADF LEVEL		PP LEVEL		ADF First Diff		PP First Diff
LENP	-1.467571	(0.5383)	-1.489647	(0.5274)	-6.045920*	(0.0000)	-6.045920*	(0.0000)
LNRC	-1.274320	(0.6308)	-1.065555	(0.7186)	-8.283121	(0.0000)	-8.456220	(0.0000)
LGDP	-0.706361	(0.8325)	-0.806799	(0.8051)	-6.253656*	(0.0000)	-6.059980*	(0.0000)
LFD	-1.522669	(0.5109)	-1.637134	(0.4538)	-4.777802*	(0.0005)	-15.35809*	(0.0000)
LFDI	-2.492898	(0.1255)	-2.492898	(0.1255)	-10.16182*	(0.0000)	-10.1500*	(0.0000)
LTO	-2.021591	(0.2767)	-2.313555	(0.1733)	-7.314498*	(0.0000)	-7.314498*	(0.0000)

Notes:* signifies statistically significance at one percent level.

Table 3 illustrates The outcome of the bound test. It shows that cointegration exists among the variables since the F-statistc value is higer than the UBC value.

Table-3. Outcome of the bound test.

F-stat	1%I(0)	I(1)	5% I(0)	I(1)
8.80	3.41	4.68	2.62	3.79

Table 4 explains the estimated outcome of the model. Thus, it indicated that in the short-run nonrenewable energy resources, FDI and trade promote environmental pollution in Nigeria. The table further illustrate that adjustment toward long-run is estimated to about 84 percent significant at 1 percent. Furthermore, the long-run estimation reveals that the aggregate of coal, gas and oil became the major influential factor in instigating environmental pollution in Nigeria. This implies that an increase in aggregate of coal, gas and oil by 1 percent results to increase in environmental dilapidation by 0.53 percent. The explosion of emissions from coal, oil and gas is justified in Nigeria due to the fact that the country produce enormous amount of nonrenewable resource that promote higher energy consumption. It means by implication of this outcome environmental pollution increased by 0.53 percent due consumption of coal, gas and oil. Hence, this effect will dependently, endorse high cost in attaining sustainable economic development, reduction in poverty and welfare improvement. Therefore, policymakers should take appropriate policies to enhance environmental quality. This could be achieved through regulations on nonrenewable energy consumption and backed the policies in promoting the use of renewable energy resources, like wind, solar and hydro energy. This outcome is in line with result obtained by Farhani and Shahbaz (2014); Dogan and Seker (2016). Likewise, a 1 percent rise in FDI leads to 0.156 percent increase in environmental degradation. Also, a 1 percent upsurge in trade result in environmental pollution to increase by 0.082 percent. However, it indicates that a percent upsurge in financial progress cause environmental pollution to decline by 0.23 percent.                                             

Table-4.  Estimated outcome.

Variables	Coeff	SE	t-Stat	Prob
Short run estimates ∆LNRC	0.621307**	0.080847	7.684963	0.0000
∆LGDP	0.061171***	0.055329	1.105594	0.2863
∆LFD	-0.072849	0.057077	-1.276321	0.2213
∆LFDI	0.094463**	0.019814	4.767550	0.0002
∆LTO	-0.102062**	0.031580	-3.231879	0.0056
ECT(-1)	-0.849475	0.167596	-5.068594	0.0001
Long run estimates
LNRC	0.530391**	0.073723	7.194413	0.0000
LGDP	0.072153	0.041222	1.750321	0.1005
LFD	-0.232772	0.087512	-2.659896	0.0178
LFDI	0.156317	0.030102	5.192935	0.0001
LTO	0.082762	0.040654	2.035761	0.0598
C	3.946651	0.194162	20.326540	0.0000

Notes: ***, ** as well as * signifies significant of the Coeff on 1, 5 and 10 percent.

Table 5 came up with post estimation checks of the model utilizes in the study. The outcome reveals that the free from heteroscedasticity and serial correlation problems as well as the residual are normally distributed.

Table-5. Checks of the model.

Test	F-statistics	Probability	Result
Breusch-Pagan Test.	0.539140	0.8742	No Heteroskedasticity
Breusch-Godfrey Test	0.570058	0.5773	No Serial Correlation
Jarque-Bera	0.223489	0.8947	Normally Distributed

5. CONCLUSION

In this study the effect of nonrenewable energy resources, output growth, financial sector performance and FDI on environmental pollution examined in Nigeria through applying ARDL method from 1980 – 2016. The outcome of the study’s estimation reveals that all the variables possess the long run association. It is reveal that in both the short-run and long run nonrenewable energy use, FDI and trade increased environmental dilapidation, thereby adversely affect environmental quality in Nigeria. However, financial development improves environmental quality as it reduce environmental degradation.

Hence, policymakers in Nigeria should take appropriate policies to enhance environmental quality through policies that will regulate the use nonrenewable energy and backed the policies in promoting the utilization of renewable energy resources, like wind, solar and hydro energy. This would be very essential in achieving environmental quality, welfare enhancement, poverty reduction as well as sustainable economic development. Meanwhile, the limitations of the present study is on the fact that it does not capture some important factors that may influence environmental quality due to unavailability of data and the study is based on single country analysis. Hence, studies in the future should consider other variables like energy price in their model and to extend their studies on cross country analysis.

Funding: This study received no specific financial support.

Competing Interests: The authors declare that they have no competing interests.

Acknowledgement: All authors contributed equally to the conception and design of the study.

REFERENCES

Acaravci, A., & Ozturk, I. (2010). On the relationship between energy consumption , CO2 emissions and economic growth in Europe. Energy, 35(12), 5412–5420.Available at: http://dx.doi.org/10.1016/j.energy.2010.07.009 .

Banday, U. J., & Aneja, R. (2018). Countries energy consumption, economic growth and CO 2 emissions: Evidence from G7 countries. World Journal of Science, Technology and Sustainable Development.

Bekun, F. V., Alola, A. A., & Sarkodie, S. A. (2019). Toward a sustainable environment : Nexus between CO 2 emissions , resource rent , renewable and nonrenewable energy in 16-EU countries. Science of the Total Environment, 657, 1023–1029.Available at: https://doi.org/10.1016/j.scitotenv.2018.12.104.

Bento, P. J. C., & Moutinho, V. (2016). CO 2 emissions, non-renewable and renewable electricity production, economic growth, and international trade in Italy. Renewable and Sustainable Energy Reviews, 55, 142–155.Available at: http://dx.doi.org/10.1016/j.rser.2015.10.151 .

Cetin, M., & Ecevit, E. (2017). The impact of financial development on carbon emissions under the structural breaks: Empirical evidence from Turkish economy. International Journal of Economic Perspectives, 11(1), 64-78.

Charfeddine, L., & Kahia, M. (2019). Impact of renewable energy consumption and financial development on CO2 emissions and economic growth in the MENA region: A panel vector autoregressive (PVAR) analysis. Renewable Energy, 139, 198–213.Available at: https://doi.org/10.1016/j.renene.2019.01.010.

Chen, Y., Wang, Z., & Zhong, Z. (2019). CO2 emissions, economic growth, renewable and non-renewable energy production and foreign trade in China. Renewable Energy, 131, 208-216.Available at: https://doi.org/10.1016/j.renene.2018.07.047.

Danlami, A. H., Applanaidu, S.-D., & Islam, R. (2018). Movement towards a low carbon emitted environment: A test of some factors in Malaysia. Environment, Development and Sustainability, 20(3), 1085-1102.Available at: https://doi.org/10.1007/s10668-017-9927-7.

Dogan, E., & Seker, F. (2016). Determinants of CO2 emissions in the European Union: The role of renewable and non-renewable energy. Renewable Energy, 94, 429-439.Available at: https://doi.org/10.1016/j.renene.2016.03.078.

Dogan, E., & Turkekul, B. (2016). CO 2 emissions, real output, energy consumption, trade, urbanization and financial development: Testing the EKC hypothesis for the USA. Environmental Science and Pollution Research, 23(2), 1203-1213.Available at: https://doi.org/10.1007/s11356-015-5323-8.

Dogan, E., & Seker, F. (2016). The influence of real output, renewable and non-renewable energy, trade and financial development on carbon emissions in the top renewable energy countries. Renewable and Sustainable Energy Reviews, 60(3), 1074-1085.

EIA, U. (2013). Annual energy outlook 2013. Washington. D. C, 60-62.

Farhani, S., & Shahbaz, M. (2014). What role of renewable and non-renewable electricity consumption and output is needed to initially mitigate CO2 emissions in MENA region? Renewable and Sustainable Energy Reviews, 40, 80-90.Available at: https://doi.org/10.1016/j.rser.2014.07.170.

Gbatu, A. P. (2018). What precipitates growth in CO 2 emissions ? New evidence from a panel of economic community of West African states ECOWAS. International Journal of Energy Sector Management, 13(2), 277–297.

Global Carbon Project. (2018). Supplemental data of global carbon budget 60. Australia.

Gokmenoglu, K. K., & Sadeghieh, M. (2019). Financial development, CO2 emissions, fossil fuel consumption and economic growth: The case of Turkey. Strategic Planning for Energy and the Environment, 38(4), 7-28.Available at: https://doi.org/10.1080/10485236.2019.12054409.

IPCC. (2007). Climate change. Synthesis Report. Contribution of Working Groups I, II & III to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Geneva.

IPCC. (2014). Climate change synthesis Report, contribution of Working Groups I, II and III to the fifth Assessment Report of the Intergovernmental Panel on Climate Change. Geneva, Switzerland: IPCC.

IPCC. (2018). Annex I: Glossary Matthews, J.B.R, In: Global Warming of 1.5°C. An IPCC Special Report on the Impacts of Global Warming of 1.5°C above Pre-Industrial Levels and Related Global Greenhouse Gas Emission Pathways, in the Context of Strengthening the. 541–562, Geneva.

Javid, M., & Sharif, F. (2016). Environmental Kuznets curve and financial development in Pakistan. Renewable and Sustainable Energy Reviews, 54, 406-414.Available at: https://doi.org/10.1016/j.rser.2015.10.019.

Long, X. (2015). Nonrenewable energy , renewable energy , carbon dioxide emissions and economic growth in China from 1952 to 2012. Renewable and Sustainable Energy Reviews, 52, 680–688.Available at: http://dx.doi.org/10.1016/j.rser.2015.07.176 .

Pesaran, M. H., Shin, Y., & Smith, R. J. (2001). Bounds testing approaches to the analysis of level relationships. Journal of Applied Econometrics, 16(3), 289-326.Available at: https://doi.org/10.1002/jae.616.

Sarkodie, S. A., & Strezov, V. (2019). Effect of foreign direct investments, economic development and energy consumption on greenhouse gas emissions in developing countries. Science of the Total Environment, 646, 862-871.Available at: https://doi.org/10.1016/j.scitotenv.2018.07.365

Sehrawat, M., Giri, A. K., & Mohapatra, G. (2015). The impact of financial developmen, economic growth and energy consumption on environmental degradation: Evidence from India. Management of Environmental Quality, 26(5), 666–682.Available at: https://doi.org/10.1108/meq-05-2014-0063.

Shafiei, S., & Salim, R. A. (2014). Non-renewable and renewable energy consumption and CO2 emissions in OECD countries: A comparative analysis. Energy Policy, 66, 547-556.Available at: https://doi.org/10.1016/j.enpol.2013.10.064.

Shahbaz, M., Mutascu, M., & Azim, P. (2014). Environmental Kuznets curve in Romania and the role of energy consumption. Renewable and Sustainable Energy Reviews, 165–173.Available at: http://dx.doi.org/10.1016/j.rser.2012.10.012 .

Sharif, A. (2018). The dynamic relationship of renewable and nonrenewable energy consumption with carbon emission: A global study with the application of heterogeneous panel estimations. Renewable Energy(133), 685–691.

Tiwari, A. K. (2011). A structural VAR analysis of renewable energy consumption, real GDP and CO2 emissions: Evidence from India. Economics Bulletin, 31(2), 1793-1806.

Wang, S., Li, G., & Fang, C. (2018). Urbanization, economic growth, energy consumption, and CO2 emissions: Empirical evidence from countries with different income levels. Renewable and Sustainable Energy Reviews, 81, 2144-2159.Available at: https://doi.org/10.1016/j.rser.2017.06.025.

Wang, Z., Zhang, B., & Wang, B. (2018). The moderating role of corruption between economic growth and CO2 emissions: Evidence from BRICS economies. Energy, 148, 506-513.Available at: https://doi.org/10.1016/j.energy.2018.01.167.

WDI. (2017). World development indicators: Energy dependency, efficiency and carbon dioxide emissions, 0-4. Washington, DC.

Zakaria, M., & Bibi, S. (2019). Financial development and environment in South Asia: The role of institutional quality. Environmental Science and Pollution Research, 26(8), 7926-7937.Available at: https://doi.org/10.1007/s11356-019-04284-1.

Zhang, S. (2018). Is trade openness good for environment in South Korea? The role of non-fossil electricity consumption. Environmental Science and Pollution Research, 25(10), 9510-9522.Available at: https://doi.org/10.1007/s11356-018-1264-3.

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