TX_1~AT/TX_2~AT


International Journal of Energy Economics and Policy | Vol 11 • Issue 1 • 2021 433

International Journal of Energy Economics and 
Policy

ISSN: 2146-4553

available at http: www.econjournals.com

International Journal of Energy Economics and Policy, 2021, 11(1), 433-439.

Energy Sustainability, Energy Financing and Economic Growth 
in Nigeria

Ademola Onabote1,2, Ayobami Jolaade3, Romanus Osabohien2,3*, Oghenetega Otobo3, Christian Ede3, 
Victoria Okafor2,3

1Department of Economics, Landmark University, Omu-Aran, Nigeria, 2Centre for Economic Policy and Development Research, 
Covenant University, Ota, Nigeria, 3Department of Economics and Development Studies, Covenant University, Ota, Nigeria. 
*Email: romanus.osabohien@covenantuniversity.edu.ng

Received: 31 January 2020 Accepted: 15 September 2020 DOI: https://doi.org/10.32479/ijeep.9336

ABSTRACT

Increase in the global population growth has led to a simultaneous increased in demand for energy leading to increased fear of global warming. This 
situation has given the international community a cause for concern and as a result, countries are seeking alternative sources for cleaner and sustainable 
energy. The importance of utilising greener energy sources is evident in the United Nation’s Sustainable Development Goals (SDGs), especially 
Goal 7, Target 2. This study examined the long-run relationship between economic growth, sustainable energy and the different financing options for 
sustainable energy in Nigeria. The Johansen Cointegration test was utilised in order to achieve this objective. The findings showed that different sources 
of sustainable energy and the different types of financing employed in Nigeria have different effects on the economic growth of Nigeria. A long-run 
relationship amongst all three variables was also established. These findings are an indication that with the right policies, SDG 7 could be achieved.

Keywords: Sustainable Energy, Energy Financing, Economic Growth, Sustainable development goals, Nigeria 
JEL Classifications: Q20, Q28, Q43

1. INTRODUCTION

Energy is a highly demanded commodity in the world, and it is 
essential in achieving economic growth and development across 
the globe (Oyedepo, 2012; Onakoya et al., 2013). However, 
the phenomenon of global climate change and global warming, 
which are seen as threats to human existence, has led to a rise in 
the demand for sustainable energy (Simsek and Simsek, 2013; 
Alege et al., 2017). In addition, the global population increase 
has fuelled the demand for sustainable energy. Specifically, the 
continuous increase in the population of Nigeria, standing at about 
200 million people (World Bank, 2019), has caused a rise in the 
country’s demand for and usage of energy.

However, energy in Nigeria is mainly obtained from non-renewable 
sources which are not sustainable. The negative impacts of the 

excessive use of these fuels violate the concepts of sustainable 
energy as it causes environmental degradation through pollutants 
such as gas flaring/emissions from combustions, coal gases/
particulates and oil spillage (Matthew et al., 2018). Therefore, 
there is a need for cleaner energy sources in order to ensure a 
sustainable energy provision in accordance with the sustainable 
development goal (SDG 7).

For this study and following the classical definition given by the 
World Commission on Environment and Development (WCED) 
in 1987, sustainable energy is defined as energy that “meets the 
need of the present generation without compromising the ability 
of the future generations to meet their own energy needs.” This 
definition is as relevant today as it was three decades ago when it 
was initiated. Sustainable energy refers to the energy that is clean 
and renewable, thus making it inexhaustible. Although Nigeria is 

This Journal is licensed under a Creative Commons Attribution 4.0 International License



Onabote, et al.: Energy Sustainability, Energy Financing and Economic Growth in Nigeria

International Journal of Energy Economics and Policy | Vol 11 • Issue 1 • 2021434

the largest oil producer in Africa and possesses both non-renewable 
and renewable (wind, solar, hydropower, and biomass) energy 
sources (Gershon et al., 2019). According to Iwayemi (2012), 
over 40% of the population of Nigeria live without electricity. 
This issue of the incessant power outage is one of the primary 
reasons why over 70% of the Nigerian population lives below 
the poverty line and negatively affect health outcomes (Iwayemi, 
2012; Matthew et al., 2019). Similarly, Charles (2014) pointed 
out that only 10% of the people in the rural area and 30% of the 
total population have access to electricity. This has therefore made 
Nigeria seek other alternative means of power such as the use of 
diesel and petrol generating sets.

However, these sources of electricity are not sustainable and the 
continued usage may impact negatively on health outcomes and 
on the economy Matthew et al., 2019. The prospect of having a 
sufficient amount of sustainable energy in Nigeria is high since 
the country is endowed with numerous energy sources that can 
cater for the present and the future energy use. The energy source 
that is presently being invested in by the federal government of 
Nigeria is the hydropower, but it is still insufficient. As a result, 
other forms of sustainable energy (solar, biomass and wind) must 
be encouraged and developed.

Against these backdrops, this study aimed to empirically examine 
the relationship amongst economic growth, sustainable energy 
and the different financing options for sustainable energy in 
Nigeria. This study is structured into five sections; following 
this introductory section is section two which presents some 
insights from the empirical literature. The methodology adopted is 
discussed in section three. Section four discusses the estimations 
and results of the study, while section five concludes the study 
and policy recommendations are provided.

2. EMPIRICAL LITERATURE

It is clear from the literature that the inability to secure the 
required investment in Sub-Saharan African is a hindrance to 
accessing clean energy (Chirambo, 2016). Chirambo (2018) 
using an exploratory research method, investigated numerous 
innovations aimed at increasing the access of sub-Sahara African 
to Sustainable and clean energy. Findings from the study indicate 
the need for a regional institutional regulator to monitor the 
progress of both climate change and clean energy, thereby taking 
an important step towards realising the SGD 7. The relationship 
between energy consumption and economic growth has been 
examined in literature; for example, Shiu and Lam (2004) in a 
study examined the relationship between economic growth and 
electricity consumption in China using the error correction model 
(ECM), the study affirms the presence of co-integration between 
the energy consumption and economic growth.

Literature covering Sub-Saharan African such as Akinlo (2008) 
examined the link between economic growth and energy 
consumption for selected countries in Sub-Saharan Africa. The 
autoregressive distributed lag (ARDL) bounds test and the vector 
error correction model (VECM) were used in order to achieve 
the set objectives. The results from the study showed that for 

Ghana, Cameroon, Zimbabwe, Gambia, Sudan, Cote d’Ivoire 
and Senegal, economic growth and energy consumption were 
co-integrated. In Senegal, Ghana, Sudan and Kenya, it was 
observed that energy consumption was growth-enhancing. The 
study confirmed a two-way causal relationship between economic 
growth and energy consumption for Senegal, Ghana and Gambia. 
While a unidirectional relationship was confirmed for Zimbabwe 
and Sudan, the neutrality hypothesis was established in Nigeria, 
Cameroon, Togo, Kenya and Cote d’Ivoire.

A similar study on the relationship between economic growth and 
energy consumption was conducted by Onakoya et al. (2013). The 
study was limited to the Nigeria economy with a scope covering 
35 years (1975-2010). The Ordinary Least Square method and 
co-integration technique were adopted. The result from the 
analysis indicated that the variables are co-integrated. Further 
analysis reveals a significant and positive relationship amongst 
petroleum, electricity and energy consumption. In a more recent 
study, Mitic et al. (2017) analysed the link between economic 
growth and carbon emissions for 17 transitional economies. The 
authors utilised annual data from 1997 to 2014 and made use of 
both the fully modified OLS (FMOLS) and dynamic ordinary least 
squares (DOLS) approaches in order to achieve their objectives. 
Economic growth and carbon emissions were confirmed to have 
a long-run relationship.

With the use of a structural vector autoregressive (SVAR) 
approach, Silva et al. (2012) analysed the effect of renewable 
energy sources (RES) on the growth of the economy and Carbon 
dioxide emission, employing a sample of four countries from the 
period of 1960 to 2004. The findings of the study show that there 
was an economic cost in terms of economic growth and there is 
also a significant decrease in the CO2 emissions per capita as a 
result of using RES. Jebli and Youssef (2014) examined whether 
there was a causal relationship amongst combustible renewables 
and waste consumption, carbon dioxide (CO2) emission and 
economic growth and using data from five countries in North 
Africa during the period of 1971-2008. The major variable in 
determining economic growth was found to be CO2 emission. 
The study, therefore, recommended that the North Africa region 
can use renewable energy sources in place of fossil fuel in order 
to avoid the depletion of the atmosphere as well as stimulate the 
growth of the economy.

By using a group of eighteen Latin American countries, Al-Mulali 
et al. (2014) investigated the effect of renewable electricity 
consumption and non-renewable electricity consumption on 
the growth of the economy. To this end, the authors made use 
of the vector error correction model (VECM) and Granger 
causality tests. Results of the study confirmed the existence of 
a bidirectional relationship amongst all the variables used in 
the study. The authors found that out of the two energy sources, 
renewable energy was more significant in stimulating economic 
growth. Pao et al. (2014) opined that a sustainable energy economy 
could be enhanced through the creation of clean and fossil fuel 
energy partnerships. They investigated the relationship amongst 
clean energy consumption, unclean energy consumption and 
economic growth of four nations (South Korea, Mexico, Turkey 



Onabote, et al.: Energy Sustainability, Energy Financing and Economic Growth in Nigeria

International Journal of Energy Economics and Policy | Vol 11 • Issue 1 • 2021 435

and Indonesia). The authors recommended that in order to address 
the issues surrounding climate change and energy security, it was 
necessary to develop renewable and nuclear energy sources.

Troster et al. (2018) carried out a study to determine whether there 
is a causal relationship amongst renewable energy consumption, 
the prices of oil and growth of the economy in the United States of 
America. The study made use of the Granger Causality method. The 
results obtained confirmed the presence of a two-way relationship 
amongst the study variables. Despite the extensive research 
conducted on sustainable energy, there are only a few that consider 
the various financing options available in the same model. This is 
the gap in the literature that this study intends to fill as considering 
both sustainable energy and different financing options available, 
important policy-inferences could be made from the results obtained.

3. METHODOLOGY

3.1. Data Source
This study examined the relationship amongst economic growth, 
sustainable energy and the different financing options for 
sustainable energy in Nigeria. In order to achieve this, annual 
data was obtained from the world development indicators 
(WDI), ranging from 1981 to 2014, thus spanning a period of 
34 years. The selection of the period is exclusively based on the 
availability of data for Nigeria. The variables of interest are shown 
in Table 1 with their respective symbols, descriptions, sources 
and measurements. Gross domestic product per capita (GDPPC) 
is used to proxy economic growth; combustible renewables and 
wastes (COREW), alternative and nuclear energy (ALNUE), and 
electricity production from hydroelectric sources (HYDRO) are 
used as proxies for sustainable energy; net official development 
assistance received (NETOD), net taxes on products (TAXES) 
and external debt (EXTDT) are used as proxies for sustainable 
energy financing options.

3.2. Model Specification
This study adopted the method proposed by Maji (2015) and 
modifies in order to suit this study. Our modification draws from the 
introduction of the different financing options available for sustainable 
energy in Nigeria, the baseline model is specified in equation (1).

GDPPCt=f(COREWt, ALNUEt, HYDROt, NETODt,  
  TAXESt, EXTDTt)  (1)

The above expression in equation (1) can be expressed in the 
classic Cobb-Douglas production function form, which is shown 
below:

 

GDPPC ACOREW ALNUE HYDRO

NETOD TAXES EXTDT
t t t t

t t t t

� � � �

� � � �

1 2 3

4 5 6

 (2)

In order to satisfy the linearity condition of the OLS assumption, 
we obtain the natural logarithm transformation of equation (2) 
which yields the following:

LNGDPPCt=a+ω1 LNCOREWt+ω2 LNALNUEt+ω3 LNHYDROt 
 +ω4 LNNETODt+ω5 LNTAXESt+ω6 LNEXTDTt+μt (3)

where a represents the intercept. LN represents the natural 
logarithm. a represent the intercept while μt represent the error 
term. ω1, ω2, ω3, ω4, ω5 and ω6 represent the elasticities of COREW, 
ALNUE, HYDRO, NETOD, TAXES and EXTDT, respectively.

4. ESTIMATIONS AND RESULTS

4.1. Unit Root Tests
A fundamental requirement when dealing with times series data 
is to test for the existence of unit root in order to determine the 
stationarity of the series. This is due to the non-stationary property 
of time series. The consequences of using non-stationary data for 
econometric analysis is that it usually leads to a spurious result. 
The Philip Phillips-Peron (PP) unit root test and the Augmented 
Dickey-Fuller (ADF) unit root test was conducted in order to show 
whether the following log-linearised time series are stationary or 
not: COREW,ALNUE,HYDRO,NETOD,TAXES and EXTDT. 
Table 2 show’s us the result of the unit root test. All the variables of 
importance in this paper are stationary after first differencing. Thus, 
using these series eliminates the possibility of obtaining spurious 
empirical results. With stationarity established, the Cointegration 
test is carried out so as to achieve the objective of this study.

4.2. Johansen Cointegration Test
This paper employs the widely-used Johansen Cointegration test 
(Johansen, 1991). It is used to show whether the explanatory and 
explained variables possess a long-run relationship. The result of 
the Cointegration test is shown in Tables 3 and 4, respectively. 
Both the Trace statistic and the maximum Eigen statistic reveal 4 
co-integrating equations amongst the selected variables of interest. 
This thus supports that a long-run relationship exists amongst 
economic growth, sustainable energy and the different financing 
options for sustainable energy.

4.3. Granger Causality Test
After establishing that the variables are co-integrated, this 
study goes ahead to determine the causal relationship that 

Table 1: Data description and measurement
Symbol Description Source Measurement
GDPPC Gross domestic product per capita World Development Indicators (2017) Constant Naira (₦)
COREW Combustible renewables and wastes World Development Indicators (2017) Percentage of total energy
ALNUE Alternative and nuclear energy World Development Indicators (2017) Percentage of total energy
HYDRO Electricity production from hydroelectric sources World Development Indicators (2017) Percentage of total energy
NETOD Net official development assistance received World Development Indicators (2017) Percentage of GNI
TAXES Net taxes on products World Development Indicators (2017) Constant Naira (₦)
EXTDT External debt World Development Indicators (2017) Percentage of Gross National Income
Source: Authors



Onabote, et al.: Energy Sustainability, Energy Financing and Economic Growth in Nigeria

International Journal of Energy Economics and Policy | Vol 11 • Issue 1 • 2021436

Table 2: PP and ADF unit root tests
Variables PP test ADF test

Level First difference Level First difference Decision
LNGDPPC 0.261009 −4.242329* 0.542457 −4.257043* I(1)
LNCOREW −2.594056 −6.408230* −2.518695 −5.695536* I(1)
LNALNUE −1.344122 −6.867076* −1.402457 −6.844402* I(1)
LNHYDRO 0.048891 −6.829895* −1.103063 −0.554822* I(1)
LNNETOD −2.536004 −5.021321* −2.959760 −5.199612* I(1)
LNTAXES −1.918897 −4.846880* −1.922424 −3.754164* I(1)
LNEXTDT −0.252437 −4.839246* −0.145566 −4.841518* I(1)
Source: Authors’ Computation Using EViews 10 Software. *indicate the 1% level of significance for the test critical values

Table 4: Johansen Cointegration test (maximum Eigen 
statistic)
Hypothesised 
number of CEs

Eigen 
value

Max-Eigen 
statistic

0.05 critical 
value

Prob.**

None* 0.937457 69.29751 46.23142 0.0000
At most 1* 0.898236 57.12738 40.07757 0.0003
At most 2* 0.793800 39.47269 33.87687 0.0097
At most 3* 0.725451 32.31564 27.58434 0.0114
At most 4 0.353448 10.90255 21.13162 0.6570
At most 5 0.178246 4.907847 14.26460 0.7534
At most 6 0.003820 0.095695 3.841466 0.7570
Source: Authors’ computation using EViews 10 Software. *denotes rejection of the null 
hypothesis at the 0.05 level. **MacKinnon-Haug-Michelis (1999) P-values

Table 3: Johansen cointegration test (trace statistic)
Hypothesised 
number of CEs

Eigen 
value

Trace 
statistic

0.05 Critical 
value

Prob.**

None* 0.937457 214.1193 125.6154 0.0000
At most 1* 0.898236 144.8218 95.75366 0.0000
At most 2* 0.793800 87.69443 69.81889 0.0010
At most 3* 0.725451 48.22174 47.85613 0.0462
At most 4 0.353448 15.90610 29.79707 0.7189
At most 5 0.178246 5.003541 15.49471 0.8084
At most 6 0.003820 0.095695 3.841466 0.7570

exists, if any, amongst the variables. Table 5 presents the 
result from the granger causality test. From the results, it is 
seen that a unidirectional causal relationship exists for all the 
pairs considered except for combustible renewables and wastes 
and gross domestic product per capita. Specifically, there is a 
unidirectional causal relationship flowing from gross domestic 
product per capita to alternative and nuclear energy, electricity 
production from hydroelectric sources, net official development 
assistance received and external debt. Also, a unidirectional 
causal relationship flowing from net taxes on products to gross 
domestic product per capita was discovered.

4.4. Impulse Response Functions
The granger causality test, despite being useful in pointing out 
the direction of causality that exists between any two variables, is 
not able to provide inferences concerning the variables of interest 
beyond the time period utilised. As a result, forecasts cannot be 
made from it. In addition, the granger causality test is silent as 
to the sign of the relationship existing between the variables. 
Due to these reasons, this study goes ahead to determine the 
impulse responses over a 10-year period when there is a one 
standard deviation positive innovation to another variable. The 

results from the impulse response functions (IRFs) are shown 
in Figure 1.

From Figure 1, it is seen that gross domestic product per capita 
rises for two periods following a positive shock to itself. In the 
third period, it declines before increasing again in the subsequent 
period. The gross domestic product per capita witnesses an initial 
decline in after a shock to combustible renewables and wastes. 
However, in the third period, it begins to experience a rise and goes 
on to become positive in the fifth period. After there is a shock to 
alternative and nuclear energy, gross domestic product per capita 
witnessed a sharp decline. In the third period, its response becomes 
stable, although it remains negative. Gross domestic product per 
capita is unaffected by a shock to electricity production from 
hydroelectric sources in the first period. However, it turns negative 
in the subsequent periods.

Initially, after a shock to Net official development assistance 
received, gross domestic product per capita witnesses a sharp 
increase before levelling up in the third period. Gross domestic 
product per capita experiences a steep decline following a shock to 
net taxes on products before becoming stable in the second period. 
In addition, it is seen that the response of gross domestic product 
per capita to a shock to external debt is negative.

4.5. Variance Decomposition (VD)
After obtaining the IRFs for gross domestic product per capita, 
this study goes ahead to determine its variance decomposition 
(VD). Table 6 presents the result and it shows that in Period 
1, the variation to gross domestic product per capita is entirely 
due to a shock to itself. Further down the time periods, this 
variation is attributed to other shocks. In Period 2, the share 
of the variation caused by gross domestic product per capita 
shock drops by almost 50%. In that same period, net official 
development assistance received and combustible renewables 
and wastes shock account for a significant portion of the 
variation which is 21.92% and 10.08% respectively. In period 
3, net official development assistance received shock accounts 
for most of the variation in gross domestic product per capita 
and this pattern continues till Period 10. In Period 10, 29.76%, 
15.49% and 15.39% of the variation in gross domestic product 
per capita is attributed to net official development assistance 
received, electricity production from hydroelectric sources 
and alternative and nuclear energy shocks respectively, which 
account for more than 60% of the variation in gross domestic 
product per capita.



Onabote, et al.: Energy Sustainability, Energy Financing and Economic Growth in Nigeria

International Journal of Energy Economics and Policy | Vol 11 • Issue 1 • 2021 437

Figure 1: Impulse response functions of gross domestic product per capita

Table 6: Variance decomposition of LNGDPPC
Period S.E. LNGDPPC LNCOREW LNALNUE LNHYDRO LNNETOD LNTAXES LNEXTDT
1 0.031756 100.0000 0.000000 0.000000 0.000000 0.000000 0.000000 0.000000
2 0.050520 52.47670 10.08269 6.324804 9.27E-05 21.92322 5.465196 3.727295
3 0.074124 25.30278 10.73332 18.63761 3.694274 32.40070 4.096656 5.134657
4 0.090231 21.46517 8.407405 17.28343 9.001069 32.95313 3.719407 7.170378
5 0.100831 22.50783 6.746559 16.05354 11.61277 32.04404 3.377349 7.657921
6 0.113467 22.66838 6.216855 16.40277 11.78809 32.65459 3.048219 7.221101
7 0.127427 21.92036 5.545049 16.25144 13.04742 32.87856 2.871500 7.485668
8 0.138268 22.18331 5.309401 16.03804 14.32551 31.79167 2.681258 7.670811
9 0.148294 22.72895 5.750867 15.68034 15.07325 30.63809 2.525362 7.603135
10 0.158563 22.98264 6.565083 15.38946 15.49003 29.76037 2.376495 7.435926
Source: Authors’ computation using EViews 10 software

Table 5: Pairwise granger causality test
Null hypothesis F-statistic Prob. Decision Causality
LNCOREW does not granger cause LNGDPPC
LNGDPPC does not granger cause LNCOREW

0.45226
1.39569

0.6409
0.2650

Accept 
Accept

None

LNALNUE does not granger cause LNGDPPC
LNGDPPC does not granger cause LNALNUE

1.25789
9.63044

0.3004
0.0007

Accept 
Reject

Unidirectional

LNHYDRO does not granger cause LNGDPPC
LNGDPPC does not granger cause LNHYDRO

0.16484
10.8212

0.8489
0.0004

Accept 
Reject

Unidirectional

LNNETOD does not granger cause LNGDPPC
LNGDPPC does not granger cause LNNETOD

0.91778
7.91546

0.4115
0.0020

Accept 
Reject

Unidirectional

LNTAXES does not granger cause LNGDPPC
LNGDPPC does not granger cause LNTAXES

3.69340
0.57867

0.0431
0.5698

Reject
Accept

Unidirectional

LNEXTDT does not granger cause LNGDPPC
LNGDPPC does not granger cause LNEXTDT

1.60022
5.40273

0.2204
0.0106

Accept
 Reject

Unidirectional

Source: Authors’ computation via E Views 10

5. CONCLUSION AND POLICY 
RECOMMENDATIONS

It is seen that, sustainable energy (except combustible renewables 
and wastes) and the various financing options (except net official 
development assistance received) would contribute negatively 

to the growth of the Nigerian economy. At first, combustible 
renewables and wastes negatively affects economic growth and 
this may be as a result of the indiscriminate felling of trees by its 
users as a source of energy. Felling of trees without replanting 
may bear a negative influence on the environment, the people 
and in turn, the economy. However, its contribution to economic 
growth later becomes positive. Perhaps, this may be due to the 



Onabote, et al.: Energy Sustainability, Energy Financing and Economic Growth in Nigeria

International Journal of Energy Economics and Policy | Vol 11 • Issue 1 • 2021438

overshadowing positive effect of the use of this source of energy 
which in the long run is cheaper. Wood fuel is a component of 
combustible renewables and wastes and it is a cheaper alternative 
to energy for both rural and urban dwellers. By using the relative 
cheaper energy source, the economy is boosted. However, caution 
must be taken so as not to witness a counter-effective reaction of 
this energy source due to deforestation. Rather, policy measures 
should be put in place in order to discourage deforestation and 
encourage afforestation, which would, in turn, contribute to the 
sustainability of this energy source. In addition, monitoring bodies 
should be set up in order to guard against the felling of trees 
without proper approval from the appropriate authorities.

It is also seen that both alternative and nuclear energy and 
electricity production from hydroelectric sources contribute 
negatively to the economy. The reason for the negative contribution 
of electricity generated from hydro sources to economic growth 
in Nigeria may be attributed to the negative spill-over effects of 
making use of hydropower. Some of these negative spill-over 
effects include an inadequate number of hydro-electric plants in 
Nigeria the poor maintenance and upgrade to modern technologies, 
inability to meet growing electricity demand under the present 
capacity of hydro-electric plants. The negative contribution of 
alternative and nuclear energy to economic growth in Nigeria may 
be attributed to its under-development and poor usage in Nigeria. 
Due to its low production, this source of energy is expensive in 
Nigeria, both to producers and consumers and as a result, it may 
contribute negatively to the economy.

This result calls for a swift response on the part of the government 
and other stakeholders in the Nigerian energy sector. Being a 
country surrounded by large bodies of water and having rainy 
reasons, Nigeria stands a lot to benefit from making use of 
hydro-electricity. Not only is hydropower sustainable, but it 
is also eco-friendly and relatively cheaper than some other 
sustainable sources of energy such as solar energy. All of the 
factors hampering the efficient and effective production of 
hydro-electric energy must be reviewed in details and mitigated 
so that Nigeria could reap the benefits of the hydro-electricity. 
For alternative and nuclear energy, since it provides immense 
benefit and would help to cater for the growing energy needs of the 
Nigerian population, the Nigerian government and all concerned 
stakeholders should develop the country’s infant nuclear industry 
so as to ensure its availability at an affordable price. The results 
show that the contribution of Net official development assistance 
received to economic growth in Nigeria is positive. The reason 
for this may be because this source of financing is monitored 
by the donor countries or organisations. However, despite the 
positive contribution of net official development assistance 
received to economic growth, great care must be taken when 
dealing with it as some economists have argued that dependence 
on foreign financing could hamper the growth and development 
in developing countries.

It is also seen that both taxes and external debt contribute negatively 
to economic growth in Nigeria. The negative contribution of tax 
to economic growth may stem from cases of tax avoidance and 
tax evasion. With high taxes, people are encouraged to alter their 

financial books and take advantage of loopholes in tax laws. 
Some people evade taxes altogether. In order to reduce cases of 
tax avoidance and tax evasion, taxes levied should not be above 
the ability and willingness of the taxpayers. In addition, the 
government should operate an effective taxation system that would 
ensure proper remittance of collected tax funds to the government 
so that tax benefits are reaped by both the public and the private 
sectors. Tax laws should also be made clear and the process should 
be transparent.

It is revealed that the contribution of external debt to economic 
growth in Nigeria is negative. The reason for this may be as a 
result of the negative effect of a debt burden. Since debts would 
have to be paid back, they are shifted to the citizens in the form of 
higher taxes. In turn, higher taxes, as the results have shown, lead 
to a negative effect on economic growth. It is recommended that 
loans should be taken only after proper and careful consideration 
by economic experts. Funds borrowed should also be used to 
embark on projects that have a high return or on projects that help 
to facilitate economic activities.

This study has thus been able to achieve its set objectives by 
establishing the existence of a long-run relationship amongst the 
variables of interest. From the results obtained from the study, it 
is possible for Nigeria to be able to achieve the 7th Sustainable 
Development Goal (Affordable and Clean Energy) before the 
SDGs timeline elapses in the next 12 years by 2030. This would 
be made possible if all stakeholders get involved in the sustainable 
energy movement.

REFERENCES

Akinlo, A.E. (2008), Energy consumption and economic growth: Evidence 
from 11 Sub-Sahara African countries. Energy Economics, 30(5), 
2391-2400.

Alege, P.O., Oye, Q.E., Adu, O.O., Amu, B., Owolabi, T. (2017), Carbon 
emissions and the business cycle in Nigeria. International Journal of 
Energy Economics and Policy, 7(5), 1-8.

Al-Mulali, U., Fereidouni, H.G., Lee, J.Y. (2014), Electricity consumption 
from renewable and non-renewable sources and economic 
growth: Evidence from Latin-American countries. Renewable and 
Sustainable Energy Reviews, 30, 290-298.

Charles, A. (2014), How is 100% Renewable Energy Possible for Nigeria? 
Global Energy Network Institute. United States: Global Energy 
Network Institute.

Chirambo, D. (2016), Addressing the renewable energy financing gap 
in Africa to promote universal energy access: Integrated renewable 
energy financing in Malawi. Renewable and Sustainable Energy 
Reviews, 62, 793-803.

Chirambo, D. (2018), Towards the achievement of SDG 7 in Sub-Saharan 
Africa: Creating synergies between power Africa, sustainable energy 
for all and climate finance in-order to achieve universal energy 
access before 2030. Renewable and Sustainable Energy Reviews, 
94, 600-608.

Gershon, O., Ezenwa, N.E., Osabohien, R. (2019), Implications of oil 
price shocks on net oil-importing African countries. Heliyon, 5(8), 
e02208.

Iwayemi, A. (2012), Energy Resources and Development in Nigeria. 
NAEE/IAEE 4th Annual International Conference. Available from: 
http://www.naee.org.



Onabote, et al.: Energy Sustainability, Energy Financing and Economic Growth in Nigeria

International Journal of Energy Economics and Policy | Vol 11 • Issue 1 • 2021 439

Jebli, M.B., Youssef, S.B. (2014), Economic Growth, Combustible 
Renewables and Waste Consumption and Emissions in North Africa. 
Germany: Munich Personal RePEc Archive.

Johansen, S. (1991), Estimation and hypothesis testing of cointegration 
vectors in gaussian vector autoregressive models. Econometrica, 
59(6), 1551-1580.

Maji, I.K. (2015), Does clean energy contribute to economic growth? 
Evidence from Nigeria. Energy Reports, 1, 145-150.

Matthew, O., Osabohien, R., Fasina, F., Fasina, A. (2018), Greenhouse 
gas emissions and health outcomes in Nigeria: Empirical insight 
from ARDL technique. International Journal of Energy Economics 
and Policy, 8(3), 43-50.

Matthew, O.M., Miebaka-Ogan, T., Popoola, O., Olawande, T., Osabohien, 
R., Urhie, E., Ogunbiyi, T. (2019), Electricity consumption, 
government expenditure and sustainable development in Nigeria: A 
co-integration approach. International Journal of Energy Economics 
and Policy, 9(4), 74-80.

Mitic, P., Ivanovic, O.M., Zdravkovic, A. (2017), A co-integration 
analysis of real GDP and CO2 emissions in transitional economies. 
Sustainability, 9, 1-18.

Onakoya, A.B., Onakoya, A.O., Jimi-Salami, O.A., Odedairo, B.O. 

(2013), Energy consumption and Nigerian economic growth: An 
emprical analysis. European Scientific Journal, 9(4), 25-40.

Oyedepo, S.O. (2012), On energy for sustainable development in Nigeria. 
Renewable and Sustainable Energy Reviews, 16, 2583-2598.

Pao, H.T., Li, Y.Y., Fu, H.C. (2014), Clean energy, non-clean energy, and 
economic growth in the MIST countries. Energy Policy, 67, 932-942.

Shiu, A., Lam, P.L. (2004), Electricity consumption and economic growth 
in China. Energy Policy, 32(1), 47-54.

Silva, S., Soares, I., Pinho, C. (2012), The impact of renewable energy 
sources on economic growth and CO2 emissions-a SVAR approach. 
European Research Studies, 15, 133-144.

Simsek, H.A., Simsek, N. (2013), Recent incentives for renewable energy 
in Turkey. Energy Policy, 63, 521-530.

Troster, V., Shahbaz, M., Uddin, G.S. (2018), Renewable Energy, Oil 
Prices, and Economic Activity: A Granger-causality in Quantiles 
Analysis. Germany: Munich Personal RePEc Archive.

WCED. (1987), Our Common Future. World Commission on 
Environment and Development. World Commission on Environment 
and Development. Oxford: Oxford University Press.

World Bank. (2019). World Development Indicators. Washington, DC: 
World Bank.