TX_1~AT/TX_2~AT


International Journal of Energy Economics and Policy | Vol 11 • Issue 2 • 2021 49

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(2), 49-56.

Examining the Relationship between Electricity Consumption, 
Financial Development and Economic Growth in ASEAN 
Countries: Evidence from a Bayesian Analysis

Canh Chi Hoang

Faculty of Business Administration, University of Finance - Marketing, Ho Chi Minh City, Vietnam. 
*Email: canhchihoang@ufm.edu.vn

Received: 21 September 2020 Accepted: 20 December 2020 DOI: https://doi.org/10.32479/ijeep.10642

ABSTRACT

The literature has suggested that financial development and electricity consumption are key determinants of economic growth. However, existing studies 
usually was applied the frequentist inference, which is an outdated estimator. By applying the Bayesian approach via the Metropolis-Hasting and Gibbs 
samplers as the MCMC methods, the study aims to re-examine the impact of financial development and electricity consumption on economic growth 
in ASEAN+6 countries from 1980 to 2016. The obtained outcome shows that the impact of both financial development and electricity consumption 
is strong and positive on economic growth. There is a uni-directional causality running from economic growth to energy consumption, supported the 
Conversation hypothesis. Based on the empirical result, several policy implications are suggested for emerging countries, ASEAN+6 nations, in particular.

Keywords: Financial Development, Energy Consumption, Economic Growth, Bayesian, ASEAN Countries 
JEL Classifications: F43, O13, O47, Q42, Q43

1. INTRODUCTION

Physical capital accumulation is a crucial factor contributing 
to economic growth (Romer, 1990; Stiglitz, 2000). Following 
the pioneering of Schumpeter (1912), majority of the economic 
researcher is persuaded that financial development allows foreign 
direct investment flows, encourages the investment of enterprises, 
reduces costs of loans, boost household consumption, and 
increase banking activities, less financial risks. The pressure of 
improving income per capita leads to pumping more money into 
the financial system by Government. The consequence of more 
money is a high-inflation situation, and the financial crisis of 2008 
provided practical evidence to re-examine the benefit of financial 
development to growth. Now, the notion “more money, more 
oversight” has been supported by many governments worldwide. 
However, a financial reduction is not good for economic growth. 
McKinnon (1974), Shaw (1974) argues that financial reduction 

leads to a fixed interest rate, decreasing banking activities, 
increasing the real exchange rate, reducing export, discourage 
the development of capital markets, and hurts economic growth.

Understanding and quantifying the relationship between energy 
consumption and economic growth is one of the hot topics for 
economics researchers and administrators. Energy is used as 
an input in the production, transportation, and consumption of 
nearly all goods or services (Ha and Ngoc, 2020; Long et al., 
2018; Stern, 2000). The linkage between energy consumption and 
economic growth has been well-studied by several researchers. 
Nevertheless, the conclusion of existing studies has failed to 
provide a consistent answer. For example, Tang (2009) investigates 
the connection between electricity consumption, income, foreign 
direct investment, and population in Malaysia from 1970 to 
2005. The obtained results by the ARDL approach shows that 
economic growth has a positive impact on electricity consumption, 

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



Hoang: Examining the Relationship between Electricity Consumption, Financial Development and Economic Growth in Asean Countries: Evidence from a Bayesian  Analysis

International Journal of Energy Economics and Policy | Vol 11 • Issue 2 • 202150

supported the Conversation hypothesis. However, Yoo (2005) 
used the cointegration and vector error correction model to 
analyzes the short- and long-run causality between electricity 
consumption and economic growth in Korea from 1970 to 2002. 
The empirical outcome reveals that there is bi-directional causality 
between economic growth and electricity, supported the Feedback 
hypothesis. Even using the panel data, the results of Chen et al. 
(2007) are mixed in ten newly industrializing and developing 
ASIAN countries. Accordingly, there is a uni-directional short-
run causality running from economic growth to electricity 
consumption and a bi-directional long-run causality between 
electricity consumption and economic growth if the panel data 
procedure is implemented.

The above mentioned previous studies indicate that the linkage 
between financial development, electricity consumption, and 
economic growth is an interesting topic, which is still the subject 
of an ongoing debate (Omri, 2014; Tiba and Omri, 2017). The main 
aim of this work is to inspect the impact of financial development, 
electricity consumption, and economic growth in ASEAN+6, 
including Indonesia, Malaysia, Philippines, Singapore, Thailand, 
Vietnam during the period 1980-2016. Our study is different from 
several previous studies in multiple points, as follows: First, to 
the best of our knowledge, the available studies analyzed in the 
case of ASEAN countries have drawn little attention. Second, 
most previous studies have been conducted in a linear framework 
and used the frequentist inference. In the study, we employed the 
Bayesian inference approach through the integrated Markov chain 
Monte-Carlo sampler to provide probabilistic interpretations of 
model uncertainty and varying effects of financial development 
and electricity consumption on economic growth. The advantage of 
Bayesian inference compared to frequentist inference is presented 
in Section 3. To our knowledge, the obtained result could be 
enrichment in existing economic literature and for the ASEAN+6 
countries in particular.

The rest of the study is organized as follows: Section 2 focuses on 
present the literature and the existing studies. Section 3 describes 
the model, data, and methodology. The obtained outputs are 
shown in section 4, while section 5 provides a conclusion and 
policy implication.

2. LITERATURE REVIEW

2.1. Financial Development and Economic Growth
The role of the financial development and financial system is 
a vital one for any economy. The pioneering of Schumpeter 
(1912) found that a developed financial system boost investment 
activities, increase transparency between lenders and borrowers, 
reduces costs of credits, and leads to beneficial for economic 
growth. Schumpeter (1912) stated that most of the enterprises need 
credit in order to buy material, machinery, and paying salaries. 
In simple capital markets, the bank becomes the producer of this 
commodity. Thus, the banking system plays the most critical 
channel, where intermediating financial activities are supported 
and enhance growth. Consistent with this view, McKinnon (1974) 
and Shaw (1974) devote to financial liberalization. They pointed 
out that the Government should not strictly control interest rates 

because it will reduce the return rate of financial assets. Besides, 
it encourages people/enterprises to invest in non-financial assets 
(e.g., gold, real estate) and generates back financial markets. 
Indeed, Bretschger and Steger (2004) showed two channels that 
financial development affects on economic growth, including (i) 
the scale-effect channel; (ii) the factor-reallocation effect channel. 
Accordingly, they confirmed that the efficiency banking system 
is the vital factor for economic development due to its role in 
mobilizing and allocating saving and the funding of economic 
activity investment.

Regarding empirical studies, King and Levine (1993) found that 
the development of the financial sector is robustly related to per 
capita GDP growth, and it positively enhances the accumulation of 
physical capital. Likewise, Ben Jedidia et al. (2014) used the ARDL 
approach to analyze the connection between financial development 
and economic growth in Tunisia from 1973 to 2008. The obtained 
result shows that domestic credit to the private sector positively 
affects economic growth, and financial development is a driver 
of long term economic growth. The positive impact of financial 
development on economic growth is supported by the study of 
Liang and Teng (2006), Komal and Abbas (2015), Salahuddin and 
Gow (2016). Another study by Alsamara et al. (2018) examines 
the impact of financial development and trade openness on the 
real GDP per capita in Turkey during the period 1960-2014. The 
empirical result from the ARDL approach with structural break 
reveals that both the trade openness and financial development 
have a positive impact on per capita real GDP. Accordingly, a 1% 
increase in money supply to GDP ratio leads to a 0.36% increase in 
real GDP per capita. Using the non-linear framework, Masten et  al. 
(2008), Law and Singh (2014) found that the impact of financial 
development was depended on the critical threshold, exceed this 
critical threshold, the more money is not good for economic growth.

Goldsmith (1969) was the first to work a positive correlation 
between economic growth and financial development in his 35 
countries sample. Abid et al. (2016) used a multivariate vector 
autoregressive model to inspect the linkage between financial 
development (measured by the stock market return) and economic 
growth in ten MENA (the Middle East and North Africa) countries. 
The result provides evidence that the GDP growth response to 
Qatar GDP growth shock is statistically significant for all countries, 
while the stock market response to Morocco stock market shock is 
insignificant in Qatar, Saudi Arabia, and UAE. The positive impact 
of financial development on economic growth is confirmed by 
the study of Ibrahim and Alagidede (2018). Applying the system 
GMM method, Ibrahim and Alagidede (2018) found that financial 
development supports economic growth. The extent of finance 
helps growth depends crucially on the simultaneous growth of real 
and financial sectors in 29 sub-Saharan African countries over the 
period 1980-2014. Greenwood and Jovanovic (1990) explained 
that individuals or enterprises have many opportunities to invest 
in several projects. The developed financial system, as mentioned 
by Schumpeter (1912) must mobilize and allocate saving capital 
flows into projects, which have high productivity or output. That 
means stock market allocates these capital flows into priority 
sectors, which have the highest return rate, and generates several 
optimal stock lists. Greenwood and Jovanovic (1990) pointed out 



Hoang: Examining the Relationship between Electricity Consumption, Financial Development and Economic Growth in Asean Countries: Evidence from a Bayesian  Analysis

International Journal of Energy Economics and Policy | Vol 11 • Issue 2 • 2021 51

that if individual or enterprises select an optimal stock list, which 
leads to beneficial for economic growth.

However, some administrators and economics researchers are not 
advocating for financial development. Edwards (2001), Okada 
(2013) argues that the overload of financial development leads to 
an increase in inflation, which harms economic growth in the long-
run. Emerging markets have a low financial institution, and should 
be highly susceptible to the volatility of the global financial market, 
which is especially severe for countries with an open capital account. 
Demetriades and Hussein (1996) used the VAR model to examines 
the influence of financial development on economic growth in 16 
countries. The obtained result reveals that the money supply is the 
danger of economic growth. Likewise, Rousseau and Vuthipadadorn 
(2005) found that financial development has a dampening effect on 
investment and growth in ten ASIAN countries. Similarly, Ono (2017) 
found that there is no causality from money supply to economic 
growth in the case of Russia during the period of 2009-2014.

2.2. Energy Consumption and Economic Growth
In developing countries, administrators and economic researchers 
have advocated analysis of the linkage between energy 
consumption and economic growth with the expectation that 
energy production and energy consumption are key determinants 
of economic growth. In fact, energy is a necessary input of 
economic activities, such as transportation, production (Abosedra 
et al., 2009; Chandran et al., 2010; Golam and Nazrul, 2011; 
Ngoc, 2019; Zhang et al., 2017). The energy-growth nexus has 
been well-studied in the energy economics literature. However, 
the available studies have failed to provide a consistent answer 
(Ha and Ngoc, 2020; Tiba and Omri, 2017), and it is still the 
subject of an ongoing policy debate. There are four hypotheses 
found by existing works about the relationship between energy 
consumption and economic growth, including the “Conversation,” 
the “Growth,” the “Feedback” and the “Neutrality” hypothesis.

Supporting the Feedback hypothesis, based on the Cobb-Douglas 
production function, Hamdi et al. (2014) inspect the linkages 
between electricity consumption, foreign direct investment, capital, 
and economic growth from 1980Q1 to 2010Q4 for the Kingdom 
of Bahrain. The empirical result from the ARDL bounds testing 
and VECM causality shows that there exist a positive impact 
and bi-directional causality between electricity consumption 
and economic growth. Likewise, Ibrahiem (2015) analyzes the 
relationship between renewable electricity consumption, foreign 
direct investment, and economic growth in Egypt from 1980 to 
2011. The existence of cointegration among the examined variable 
is found by the ARDL bounds testing, and the Granger causal test 
identifies the bi-directional causality between economic growth 
and renewable electricity consumption. The positive influence of 
electricity consumption on economic growth is confirmed by the 
study of Tang (2009) for Malaysia, Long et al. (2018) for Vietnam, 
or Zhang et al. (2017) for China’s economy.

About the growth hypothesis, Golam and Nazrul (2011) discover 
the connection between per capita electricity consumption and 
per capita GDP in the case of Bangladesh from 1971 to 2008. The 
obtained outcome reveals mixed results. Accordingly, there is a 

uni-directional causality in the short-run, a bi-directional causality 
between per capita electricity consumption and per capita GDP 
in the long-run. Another study by Acaravci (2010) explores the 
short- and long-run causality between electricity consumption 
and economic growth in Turkey from 1968 to 2005. The VECM 
Granger causality shows that there is a uni-directional causality 
running from electricity consumption to economic growth.

The conversation hypothesis was found by the pioneering study of 
Kraft and Kraft (1978). They examine the impact of economic growth 
on electricity consumption in the United States over the period 1947-
1974. The Granger causality provides that there is a uni-directional 
causality running from economic growth to electricity consumption. 
Likewise, Balcilar et al. (2019) used the Maki cointegration to inspect 
the linkage between electricity consumption, real gross domestic 
product, and carbon dioxide emissions in Pakistan. A uni-directional 
causality running from economic growth to electricity consumption 
was found by the Toda-Yamamoto causality test, which supported 
the Conversation hypothesis.

Some studies found the neutrality hypothesis. Ghosh (2009) does 
not found the interaction between electricity supply, employment, 
and real GDP for India. Similarly, Payne (2009) applied the Toda-
Yamamoto causality tests. The obtained result shows that the 
absence of Granger-causality between renewable or non-renewable 
energy consumption and real GDP in the case of the United States 
from 1949 to 2006, which supports the neutrality hypothesis.

The impact of financial development and energy consumption on 
economic growth has been studied by several previous works, such 
as Kahouli (2017), Rafindadi and Ozturk (2016), Burakov Burakov 
and Freidin (2017), and Mahi et al. (2019). However, the conclusion 
of these studies is not consistent, even ambiguous. To explain the 
different above-mentioned conclusion, Apergis and Payne (2010) point 
out that the interaction between energy consumption and economic 
growth nexus is depended on the level of national development. In 
poor countries, economic activities based on natural extraction (e.g., 
planting, fishing). Thus, the demand for energy is low, and the energy 
consumption does not enhance economic growth. However, it is not 
true in developing or developed countries. The pressure improving 
income per capita leads to many projects or policies were issued by 
the Government, which requires more energy as a driving force of 
production of goods or services. So, energy production and energy 
consumption is an essential factor for development.

Of course, the above-mentioned studies do not adequately 
represent all previous studies on financial development-energy 
consumption-growth nexus. Nevertheless, this review showed 
that most of the available studies use frequentist inference. No 
studies apply Bayesian inference. It is a methodology gap, which 
this work want to address.

3. RESEARCH MODEL AND 
METHODOLOGY

The main aim of this study is to investigate the impact of financial 
development and electricity consumption on economic growth 



Hoang: Examining the Relationship between Electricity Consumption, Financial Development and Economic Growth in Asean Countries: Evidence from a Bayesian  Analysis

International Journal of Energy Economics and Policy | Vol 11 • Issue 2 • 202152

in ASEAN+6 countries from 1980 to 2016, so the model is 
preliminarily set as follows:

 

LnGDP LnEC LnFI
Ln EC FI UB

i t i i t i t

i t

, , ,

,

. .

. ( . ) .

� � � �

� �

� � � �

� �
0 1 2

3 4 ii t i te, ,�  (1)

where, i is the country (1,…, N: including Indonesia, Malaysia, 
Philippines, Singapore, Thailand, Vietnam, respectively), t is 
time (1,…, T: from 1980 to 2016). υi are random intercepts, 
e(i,t) is an error. In Eq.1, LnFI variables is the logarithm of 
financial development (measured by M2 money supply, units: 
million U.S. dollar), LnEC variable is the logarithm of the 
electricity consumption per capita, unit: kWh/year), Ln(EC.FI) 
is the interaction variable (= LnEC*LnFI), and UB is the rate 
of urbanization (unit: percentage), which plays as the control 
variable in the model. Annual data is collected from the IMF and 
the World Bank. The dependent variable is LnGDP per capita 
(at the fixed price 2010, unit: U.S. dollar). This work used the 
Bayesian inference, which has several advantages outperforms 
the Frequentist inference, as follows:
First, Bayesian analysis is based on the Bayes rule and the posterior 
distribution results from updating the prior knowledge about model 
parameters with evidence from the observed data. The Bayesian 
analysis rests on Bayes’ theorem of probability theory:

  p y
p y p
p y

( )
( ). ( )

( )
�

� �
�  (2)

where, θ stands for a set of unknown parameters, y represents a 
marginal distribution of data, p(θ) denotes the prior distribution 
of the parameters θ (pre-existing information such as expert 
opinion, theory, or other external resources), p(y|θ) is a likelihood 
distribution, p(y) is the marginal distribution of y, and p(y|θ) denotes 
the posterior distribution, which is the probability of the parameters 
θ conditional on the data x. Equation (2) may be expressed as:

 p y p y p( ) ( ) ( )� � ��  (3)

where, ∝ implies “proportional to.” The posterior is proportional 
to the prior multiplied by the likelihood.

Second, the frequentist inference assumes that all parameters 
are considered unknown but fixed quantities, while Bayesian 
inference allows all parameters are random quantities and thus 
can incorporate prior knowledge. Hence, Bayesian analysis yields 
an entire probability distribution of a parameter, while frequentist 
results are point estimates. Also, the Bayesian paradigm allows 
for probability statements, such as a variable is likely or unlikely 
to impact on another, or the true value of a parameter falls into 
a certain interval with a pre-specified probability (Bernardo and 
Smith, 1994; Thompson, 2012).

Because our data sample size is sufficiently large, noninformative 
priors are enough for our model specification. For comparison 
purposes, we also specify informative priors for the model 
parameters. Accordingly, we conduct five posterior simulations. 
A sensitivity analysis to prior choice will be performed through 
a Bayes factor test and a model test. We assume to have models 
Mj parameterized by vectors θj,j=1,2,…r. By applying Bayes’s 
theorem, we calculate the posterior model probabilities:

  p M y
p y M p M

p yj
j j

( )
( ) ( )

( )
=   (4)

Since it is challenging to calculate p(y), a popular practice is to 
compare two models, for example, Mj and Mk via posterior odds 
ratio:

 PO
p M y
p M y

p y M p M

p y M p Mj k
j

k

j j

k k
,

( )

( )

( ) ( )

( ) ( )
= =   (5)

If all models are equally plausible, that is p(Mj)=1/r, the posterior 
odds ratio is transformed into the Bayes factor, which is simply 
ratios of marginal likelihoods (Jeffreys, 1962).

  BF
p y M

p y Mj k
j

k
,

( )

( )
=  (6)

The detailed process of estimation is acted through three steps, 
as follows:
First, we use the fixed-effect model (FEM) and the random-effect 
model (REM) to provide a general view of the influence of financial 
development and electricity consumption on economic growth.

Second, we apply the Bayesian approach via the Metropolis-
Hasting and Gibbs samplers as the MCMC methods to estimate 
the impact of financial development and electricity consumption 
on economic growth.

Finally, we use Dumitrescu and Hurlin (2012) test to check the 
causality between energy consumption and economic growth.

4. EMPIRICAL RESULTS

4.1. Descriptive Statistic
In two past decades, the ASEAN+6 countries, including Indonesia, 
Malaysia, Philippine, Singapore, Thailand, and Vietnam, have 
changed rapidly in most socio-economic fields. Rapid growth leads 
to a change in the structure of the economy. The industry sector is 
focused on investing by the Government. Also, urbanization leads to 
a great demand for energy. Acknowledge that financial development 
and energy consumption are actively contributing to growth in these 
countries. The descriptive statistic of all variables is shown in Table 1.

4.2. Model Comparison
This subsection compares five posterior regression models, where 
the respective Gaussian prior distributions specified are N(0,1), 
N(0,10), N(0,100), N(0,1000), and N(0,10000).

The results of the model comparison are presented in Tables 2 and 3. 
In general, the less the DIC value, the more the log(ML) and 
log(BF) estimate, the better a model fits the data. P(My) shows 
the posterior model probability. Consequently, model 1 is the best.

Table 1: The descriptive statistic of all variables
Variables Mean Maximum Minimum Std. error
LnGDP 8.128 10.885 5.735 1.234
LnEC 6.763 9.088 3.832 1.358
LnFI 2.573 4.275 -1.472 0.725
LnECFI 17.301 31.028 -11.528 4.734
UB 50.26 100 19.25 25.56



Hoang: Examining the Relationship between Electricity Consumption, Financial Development and Economic Growth in Asean Countries: Evidence from a Bayesian  Analysis

International Journal of Energy Economics and Policy | Vol 11 • Issue 2 • 2021 53

4.3. MCMC Convergence Test
In the application of an MCMC method, a convergence check is 
needed before proceeding to inference. Once chain convergence is 
established, the model parameters have converged to equilibrium 
values. To avoid pseudo convergence, in this study, we simulate 
three MCMC chains and verify whether the results satisfy the 
convergence rule. This is because pseudo convergence takes place 
when the chains have seemingly converged, but indeed, they 
explored only a portion of the domain of a posterior distribution. 
As demonstrated in Table 4, the maximum Gelman-Rubin statistic 
Rc of 1.0001 is close to 1.1, indicating MCMC convergence.

The model summary reports the rate of acceptance and algorithm 
efficiency as initial indicators of MCMC convergence. The 
acceptance rate is the number of proposals accepted in the total 
proposals, whereas algorithm efficiency is the mixing properties of 
MCMC sampling. Concerning the chosen model 2, the acceptance 
rate of 0.84 is larger than the minimum level of 0.1, whereas 
average efficiency is equivalent to 0.35, which is more than the 
acceptable level of 0.01. This implies that the obtained results 
from Bayesian multilevel regression are reliable.

Additionally, it is useful to conduct a graphical inspection. For 
this, CUSUM plots as an accessible tool are applied. As shown in 
Figure 1, the CUSUM plots of the parameters corresponding to 
three chains are jagged, not smooth, running across the X-axis. So 
MCMC chains for the model parameters are well-mixed, which 
is a sign of sequence convergence.

4.4. FEM, REM and Bayesian Estimation
The estimation of the Eq.1 by frequentist and Bayesian inference 
is presented in Table 5. The obtained outcome from FEM and 
REM model shows that there is a positive impact of electricity 
consumption on economic growth. Accordingly, a 1% increase 
in electricity consumption leads to 0.747% increase in economic 
growth. Besides, financial development is helpful to economic 
growth (P_value = 0.000). A 1% increase in financial development 
leads to 0.629% increase in economic growth.

With the Bayesian inference, the result in the lower section of 
Table 5 reveals that both the influence of electricity consumption 
and financial development is beneficial for economic growth. With 
a probability of mean between 0.7 and 1, electricity consumption 
and financial development exert a powerfully positive effect 
on economic growth. The 95% credible intervals also point to 
similar results. Thus, we can confirm that the value of 0.7951 of 
the coefficient for LnEC belongs to the interval [0.6587, 0.9315] 
with a 95% probability. Similar interpretations can be made for 
the remaining parameters of the model. With a probability of mean 

Table 2: Bayesian information criteria
Model Gaussian distribution DIC log(ML) log(BF)
1 N(0,1) 103.8528 −75.6626
2 N(0,10) 104.0392 −79.5551 -3.8924
3 N(0,100) 104.0978 −85.1067 -9.4441
4 N(0,1000) 104.1043 −90.8425 −15.1799
5 N(0,10000) 104.1050 −96.5969 −20.9342

Table 3: Bayesian model tests
Model Gaussian distribution log(ML) P(M) P(My)
1 N(0,1) −75.6626 0.2000 0.9799
2 N(0,10) −79.5551 0.2000 0.0200
3 N(0,100) −85.1067 0.2000 0.0001
4 N(0,1000) −90.8425 0.2000 0.0000
5 N(0,10000) −96.5969 0.2000 0.0000

Table 4: Gelman-rubin convergence diagnostic
Max gelman-rubin Rc=1.000142 
<Convergence rule (=1.1)

Rc value

Dependent variable: LnGDP 
LnEC 1.000142
LnFI 1.00009
LnECFI 1.000076
UB 1.00008
Intercept 1.00013
var 0.999963

Table 5: FEM, REM and Bayesian simulation results
Variables Coefficient P_value Coefficient P_value

FEM result REM result
LnEC 0.8324 0.000 0.7461 0.000
LnFI 0.5715 0.000 0.6298 0.000
LnECFI −0.0824 0.000 -0.0891 0.000
UB −0.009 0.000 0.0054 0.021
Intercept 2.916 0.000 2.7009 0.000
F-test F-statistic=254.24 (P_value = 0.000)
Hausman test F-statistic=467.59 (P_value = 0.000)
Variables Mean Bayesian result

Std. Dev. MCSE Probability of mean>0 Equal-tailed (95% Cred. Interval)
Dependent variable: LnGDP

LnEC 0.7951 0.0691 0.0004 1 (0.6587, 0.9315)
LnFI 1.0226 0.1652 0.0009 1 (0.6983, 1.3473)
LnECFI -0.1469 0.0230 0.0001 1* (−0.1919, −0.1019)
UB 0.0251 0.0016 0.0000 1 (0.0221, 0.0280)
Intercept 1.3753 0.4849 0.0028 0.99 (0.4216, 2.3275)

* is probability of mean < 0



Hoang: Examining the Relationship between Electricity Consumption, Financial Development and Economic Growth in Asean Countries: Evidence from a Bayesian  Analysis

International Journal of Energy Economics and Policy | Vol 11 • Issue 2 • 202154

is one, we can state that urbanization is a good contribution to 
economic growth in examined countries.

4.5. The Causality Test
Finally, the study used Dumitrescu and Hurlin (2012) test to 
examine the causality relationship between energy consumption 
and economic growth. Both the W-bar and Z-bar statistic test 
presented in Table 6 provides evidence in favor of the rejection 
of the null hypothesis (P_value < 0.05). This result implies that 
there is a uni-directional causality running from economic growth 
to energy consumption in examined countries, which supported 
the Conversation hypothesis.

5. DISCUSSION

The empirical result shows that the impact of financial 
development and electricity consumption on economic growth is 
beneficial. These results are in line with the conclusion by Ben 
Jedidia et al. (2014) for Tunisia, Sarkar et al. (2019) for Malaysia, 
Glasure and Lee (1997) for South Korea and Singapore, or Long 
et al. (2018); Ngoc (2019); Nguyen and Ngoc (2020) for Vietnam. 
Physical capital accumulation and a developed financial system 
will enhance economic growth through the process of mobilizing 
and allocating the saving capital flows into projects, which have 
high productivity or output. All six countries in our sample are 
developing or developed countries, so the demand for production, 
distribution, or household consumption is rapid growth. According 
to the forecasting of the International Energy Agency, the energy 
demand is growing by 1.4% per year until 2035. This is valid for 
both emerging or developed countries.

6. CONCLUSION

The study applies the Bayesian approach via the Metropolis-
Hasting and Gibbs samplers as the MCMC methods to investigate 
the impact of financial development and electricity consumption 
on economic growth in ASEAN+6 countries over the period 1980 
to 2016. Five simulations are conducted with Gaussian prior 
distributions ranging from (0,1) to (0,10000). As shown by model 
comparison results via a Bayes factor and a model test, the model 
with a noninformative, namely, N(0,1) prior fits the best. According 
to the estimation results, we claim in view of the probability that 
both electricity consumption and financial development strongly 
and positively affects economic growth.

Based on the empirical results, some policy implications are 
suggested, as detailed:

Firstly, electricity consumption is beneficial for growth, so the 
Government should intend to expand energy supply through the 
development of renewable or green energies, such as solar, wind, 
biofuels, and geothermal power.

Secondly, financial development will drive economic growth if 
the country has a transparent and efficient financial system. Thus, 
the rate of the money supply should be calculated corresponding 
to the rate of growth. A deficiency in the money supply will result 
in a decrease in economic growth, negatively impacting other 
economic activities.

REFERENCES

Abid, F., Bahloul, S., Mroua, M. (2016), Financial development and 
economic growth in MENA countries. Journal of Policy Modeling, 
38(6), 1099-1117.

Abosedra, S., Dah, A., Ghosh, S. (2009), Electricity consumption and 
economic growth, the case of Lebanon. Applied Energy, 86(4), 
429-432.

Figure 1: CUSUM plots of model parameters

Table 6: Results of the causality test
Null hypothesis: No causality W-bar Z-bar P-value
LnEC does not granger cause LnGDP 1.9879 1.711  0.087
LnGDP does not granger cause LnEC 4.6660 6.3549  0.000



Hoang: Examining the Relationship between Electricity Consumption, Financial Development and Economic Growth in Asean Countries: Evidence from a Bayesian  Analysis

International Journal of Energy Economics and Policy | Vol 11 • Issue 2 • 2021 55

Acaravci, A. (2010), Structural breaks, electricity consumption and 
economic growth: Evidence from Turkey. Romanian Journal of 
Economic Forecasting, 2, 140-154.

Alsamara, M., Mrabet, Z., Barkat, K., Elafif, M. (2018), The Impacts of 
trade and financial developments on economic growth in Turkey: 
ARDL approach with structural break. Emerging Markets Finance 
and Trade, 55(8), 1671-1680.

Apergis, N., Payne, J.E. (2010), Energy consumption and growth in South 
America: Evidence from a panel error correction model. Energy 
Economics, 32(6), 1421-1426.

Balcilar, M., Bekun, F.V., Uzuner, G. (2019), Revisiting the economic 
growth and electricity consumption nexus in Pakistan. Environmental 
Science and Pollution Research, 26(12), 12158-12170.

Ben Jedidia, K., Boujelbène, T., Helali, K. (2014), Financial development 
and economic growth: New evidence from Tunisia. Journal of Policy 
Modeling, 36(5), 883-898.

Bernardo, J.M., Smith, A.F.M. (1994), Bayesian Theory. Hoboken: John 
Wiley & Sons, Inc.

Bretschger, L., Steger, T.M. (2004), The dynamics of economic 
integration: Theory and policy. International Economics and 
Economic Policy, 1(2-3), 119-134.

Burakov, D., Freidin, M. (2017), Financial development, economic 
growth and renewable energy consumption in Russia: A vector error 
correction approach. International Journal of Energy Economics and 
Policy, 7(6), 39-47.

Chandran, V.G.R., Sharma, S., Madhavan, K. (2010), Electricity 
consumption-growth nexus: The case of Malaysia. Energy Policy, 
38(1), 606-612.

Chen, S.T., Kuo, H.I., Chen, C.C. (2007), The relationship between GDP 
and electricity consumption in 10 Asian countries. Energy Policy, 
35(4), 2611-2621.

Demetriades, P.O., Hussein, K.A. (1996), Does financial development 
cause economic growth? Time-series evidence from 16 countries. 
Journal of Development Economics, 51(2), 387-411.

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

Edwards, S. (2001), Capital Mobility and Economic Performance: Are 
Emerging Economies Different? NBER Working Paper No. 8076. 
Available from: https://www.nber.org/papers/w8076.

Ghosh, S. (2009), Electricity supply, employment and real GDP in India: 
Evidence from cointegration and Granger-causality tests. Energy 
Policy, 37(8), 2926-2929.

Glasure, Y.U., Lee, A.R. (1997), Cointegration, error-correction, and the 
relationship between GDP and energy: The case of South Korea and 
Singapore. Resource and Energy Economics, 20, 17-25.

Golam, A.M., Nazrul, I.A.K. (2011), Electricity consumption and 
economic growth nexus in Bangladesh: Revisited evidences. Energy 
Policy, 39(10), 6145-6150.

Goldsmith, R.W. (1969), Financial Structure and Development. New 
Haven: Yale University Press.

Greenwood, J., Jovanovic, B. (1990), Financial development, growth, 
and the distribution of income. Journal of Political Economy, 98(5), 
1076-1107.

Ha, N.M., Ngoc, B.H. (2020), Revisiting the relationship between energy 
consumption and economic growth nexus in Vietnam: New evidence 
by asymmetric ARDL cointegration. Applied Economics Letters, 
2020, 1789543.

Hamdi, H., Sbia, R., Shahbaz, M. (2014), The nexus between electricity 
consumption and economic growth in Bahrain. Economic Modelling, 
38, 227-237.

Ibrahiem, D.M. (2015), Renewable electricity consumption, foreign direct 
investment and economic growth in Egypt: An ARDL approach. 
Procedia Economics and Finance, 30, 313-323.

Ibrahim, M., Alagidede, P. (2018), Effect of financial development on 
economic growth in sub-Saharan Africa. Journal of Policy Modeling, 
40(6), 1104-1125.

Jeffreys, H. (1962), Theory of probability. Geophysical Journal 
International, 6(4), 555-558.

Kahouli, B. (2017), The short and long run causality relationship among 
economic growth, energy consumption and financial development: 
Evidence from South Mediterranean countries (SMCs). Energy 
Economics, 68, 19-30.

King, R.G., Levine, R. (1993), Finance, entrepreneurship and growth: 
Theory and evidence. Journal of Monetary Economics, 32(3), 
513-542.

Komal, R., Abbas, F. (2015), Linking financial development, economic 
growth and energy consumption in Pakistan. Renewable and 
Sustainable Energy Reviews, 44, 211-220.

Kraft, J., Kraft, A. (1978), On the Relationship between energy and GNP. 
The Journal of Energy and Development, 3(2), 401-403.

Law, S.H., Singh, N. (2014), Does too much finance harm economic 
growth? Journal of Banking and Finance, 41, 36-44.

Liang, Q., Teng, J.Z. (2006), Financial development and economic growth: 
Evidence from China. China Economic Review, 17(4), 395-411.

Long, P.D., Ngoc, B.H., My, D.T.H. (2018), The relationship between 
foreign direct investment, electricity consumption and economic 
growth in Vietnam. International Journal of Energy Economics and 
Policy, 8(3), 267-274.

Mahi, M., Phoong, S.W., Ismail, I., Isa, C.R. (2019), Energy-finance-
growth nexus in ASEAN-5 countries: An ARDL bounds test 
approach. Sustainability, 12(1), 1-16.

Masten, A.B., Coricelli, F., Masten, I. (2008), Non-linear growth effects 
of financial development: Does financial integration matter? Journal 
of International Money and Finance, 27(2), 295-313.

McKinnon, R.I. (1974), Money and capital in economic development. 
The Economic Journal, 84(334), 422-423.

Ngoc, B.H. (2019), Energy consumption and economic growth nexus in 
Vietnam: An ARDL approach. In beyond traditional probabilistic 
methods in economics. In: Kreinovich, V., Thach, N., Trung, N., 
van Thanh, D., editors. Beyond Traditional Probabilistic Methods in 
Economics. ECONVN 2019. Studies in Computational Intelligence. 
Vol. 809. Cham: Springer. p311-322.

Nguyen, H.M., Ngoc, B.H. (2020), Energy consumption-economic 
growth nexus in Vietnam: An ARDL approach with a structural 
break. The Journal of Asian Finance, Economics and Business, 
7(1), 101-110.

Okada, K. (2013), The interaction effects of financial openness 
and institutions on international capital flows. Journal of 
Macroeconomics, 35, 31-143.

Omri, A. (2014), An international literature survey on energy-economic 
growth nexus: Evidence from country-specific studies. Renewable 
and Sustainable Energy Reviews, 38, 951-959.

Ono, S. (2017), Financial development and economic growth nexus in 
Russia. Russian Journal of Economics, 3(3), 321-332.

Payne, J.E. (2009), On the dynamics of energy consumption and output 
in the US. Applied Energy, 86(4), 575-577.

Rafindadi, A.A., Ozturk, I. (2016), Effects of financial development, 
economic growth and trade on electricity consumption: Evidence 
from post-Fukushima Japan. Renewable and Sustainable Energy 
Reviews, 54, 1073-1084.

Romer, P.M. (1990), Endogenous technological change. Journal of 
Political Economy, 95(5), 71-102.

Rousseau, P.L., Vuthipadadorn, D. (2005), Finance, investment, and 
growth: Time series evidence from 10 Asian economies. Journal of 
Macroeconomics, 27(1), 87-106.

Salahuddin, M., Gow, J. (2016), The effects of internet usage, financial 



Hoang: Examining the Relationship between Electricity Consumption, Financial Development and Economic Growth in Asean Countries: Evidence from a Bayesian  Analysis

International Journal of Energy Economics and Policy | Vol 11 • Issue 2 • 202156

development and trade openness on economic growth in South 
Africa: A time series analysis. Telematics and Informatics, 33(4), 
1141-1154.

Sarkar, M.S.K., Al-Amin, A.Q., Mustapa, S.I., Ahsan, M.R. (2019), 
Energy consumption, CO2 emission and economic growth: Empirical 
evidence for Malaysia. International Journal of Environment and 
Sustainable Development, 18(3), 318-334.

Schumpeter, J.A. (1912), The Theory of Economic Development: Harvard 
Economic Studies.

Shaw, E.S. (1974), Financial deepening in economic development. The 
Journal of Finance, 29(4), 1345-1348.

Stern, D.I. (2000), A multivariate cointegration analysis of the role of 
energy in the US macroeconomy. Energy Economics, 22, 267-283.

Stiglitz, J.E. (2000), Capital market liberalization, economic growth, and 

instability. World Development, 28(6), 1075-1086.
Tang, C.F. (2009), Electricity consumption, income, foreign direct 

investment, and population in Malaysia. Journal of Economic 
Studies, 36(4), 371-382.

Thompson, S.K. (2012), Sampling. 3rd ed. Hoboken, New Jersey: John 
Wiley & Sons. Inc.

Tiba, S., Omri, A. (2017), Literature survey on the relationships between 
energy, environment and economic growth. Renewable and 
Sustainable Energy Reviews, 69, 1129-1146.

Yoo, S.H. (2005), Electricity consumption and economic growth: 
Evidence from Korea. Energy Policy, 33(12), 1627-1632.

Zhang, C., Zhou, K., Yang, S., Shao, Z. (2017), On electricity consumption 
and economic growth in China. Renewable and Sustainable Energy 
Reviews, 76, 353-368.