TX_1~AT/TX_2~AT


International Journal of Energy Economics and Policy | Vol 13 • Issue 2 • 2023526

International Journal of Energy Economics and 
Policy

ISSN: 2146-4553

available at http: www.econjournals.com

International Journal of Energy Economics and Policy, 2023, 13(2), 526-536.

Analysis of the effect of Energy Prices on Stock Indexes During 
the Epidemic Crisis

Shafa Guliyeva*

Azerbaijan State University of Economics (UNEC), Azerbaijan. *Email: shafa_guliyeva@unec.edu.az

Received: 15 December 2022 Accepted: 10 March 2023 DOI: https://doi.org/10.32479/ijeep.14052

ABSTRACT

Petroleum and natural gas, which are among the most used energy sources in the world, have a significant impact on financial markets and macroeconomic 
indicators as they are used as raw materials in many fields. For this reason, US, England, Japan, Russia, Turkey, Brazil, and India, as energy importers 
and developing countries, may be affected positively or negatively by changes in energy prices. The main purpose of this study is to examine the 
correlation between Brent oil, crude oil (WTI), and natural gas (NG) prices and Moscow Stock Exchange Index (RTSI), Borsa Istanbul Index (XU100), 
Bovespa Brazilian Stock Exchange Index (BVSP), Indian National Stock Exchange Nifty 50 Index (NSEI), Standard and Poor’s 500 Index (S and P 
500), London Stock Exchange (FTSE 100), and Тokyo Stock Exchange (N225). In the study, weekly data between February 16, 2020 and December 
26, 2021 were examined. Vector autoregressive (VAR) model was used to examine the correlation between the variables included in the analysis, and 
the direction of the correlation between the variables was determined by the Granger causality test. According to the results of the VAR model, Brent 
oil and crude oil prices have significant effects on the indices included in the analysis; however, natural gas price does not have a significant effect on 
indices, Brent oil, and crude oil prices. On the other hand, the results of the Granger causality test confirm the findings of the VAR analysis. Granger 
causality test results reveal that in Granger’s sense, only BVSP and NSEI are the cause of Brent oil price, RTSI, BVSP, NSEI, XU100, S and P 500, 
FTSE 100, and N225 are the cause of WTI, and WTI is the cause of NSEI.

Keywords: Brent Oil, Crude Oil, Natural Gas, Stock Market İndex, VAR Analysis, Granger Causality 
JEL Classifications: B26, C58, G14, G15, O16

1. INTRODUCTION

Stocks reflect enterprises’ potential profitability. Therefore, oil 
shocks’ influence on the stock market is a helpful economic 
indicator. Since asset prices reflect organisations’ future net 
earnings, it’s important to lessen the effects of present and future 
oil shocks on stocks and returns before they happen (Jones et al., 
2004 p. 13).

In the simplest sense, energy, which is the basis of life, is vital 
for the survival and development of humanity (Fouquet, 2011 
p. 1). With the mechanisation of production and the production 
of steam-powered machines, the need for energy has continuously 
increased, and economic growth and prosperity have become

more dependent on energy (Ghosh, 2002 p. 125). It is necessary 
to consume energy at a certain level in order to achieve rapid 
economic development (Özdemir, 2012 p. 61). Energy is one of 
the most important factors that directly or indirectly determines 
the production level, national and international competitiveness, 
budget balances, current account deficits, and economic growth 
levels of countries (Esen, 2013 p. 48, 49). In this respect, for the 
continuity of economic growth, it is important to provide timely, 
low-cost, high-quality, reliable energy sources (Bayraktutan 
et al., 2012 p. 30). Determining the factors affecting stock prices 
will enable the investor to make the right investment decisions. 
If the factors affecting the stock prices are determined correctly, 
the success of the investments to be made will be higher. Factors 
affecting stock prices are macroeconomic, enterprise-specific, and 

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



Guliyeva: Analysis of the effect of Energy Prices on Stock Indexes During the Epidemıc Crisis

International Journal of Energy Economics and Policy | Vol 13 • Issue 2 • 2023 527

other (Dizdarlar and Derindere, 2008 p. 113). Macroeconomic 
factors: interest rates, inflation, exchange rates, money supply, 
economic growth, industrial production index, gold prices, foreign 
trade balance, foreign portfolio investments, and energy price 
changes (Güngör and Yerdelen, 2015 p. 149). Microeconomic 
factors: Capital structure, profit distribution policies, corporate 
governance, intellectual capital, insider trading, and financial ratios 
(Demir, 2001 p. 110). Other factors are psychological factors, 
political factors, seasonal changes, and speculation (Kaya et al., 
2015 p. 167).

The effect of energy prices on national economies and financial 
markets varies depending on whether the country is an energy 
importer or exporter. Countries that import the majority of energy can 
be adversely affected by changes in energy prices. For this reason, 
the long and short-term correlations between energy prices (oil and 
natural gas) and stock market indices of four developing countries 
were examined in this study. In this direction, the study is important 
as it will help the investors who are present and who aim to invest in 
the Brent oil, Crude oil, and Natural Gas prices, and Moscow Stock 
Exchange Index, Borsa Istanbul Index, Bovespa Brazilian Stock 
Exchange Index, Indian National Stock Exchange Nifty 50 Index, 
Standard and Poor’s 500 Index, London Stock Exchange, and Тokyo 
Stock Exchange in the decision-making process.

The study consists of four parts. In the first part of the study, a 
literature review related to the studies on this subject was made. In 
other words, studies on the effects of volatility in energy resource 
prices on the stock market indices of developed and developing 
countries have been conducted. In the second part of the study, 
information is given about the definition of the variables to be 
analysed and the methods to be used in the analysis. In the third 
part of the study, the findings obtained as a result of the analysis of 
dependent and independent variables are included and interpreted. 
In the conclusion part, which constitutes the fourth chapter, a 
general evaluation of the study was made.

2. LITERATURE REVIEW

In this section, studies on energy price changes and stock market 
indices are discussed, and the results of the studies examined in 
this direction are presented. The number of academic studies is 
increasing day by day due to the importance of energy and the 
volatility of its prices.

Price fluctuations in one market can rapidly propagate other 
markets. In recent decades, there has been much research effort 
to study the relationship between gold, crude oil, and the stock 
markets (Gujarati, 2013; Jain and Biswal, 2016; Coronado et al., 
2018; Tursoy and Faisal, 2018; Shabbir and Kousar, 2020; Shaikh, 
2021), and discover evidence from developed or emerging markets 
yielding various results. (Samanta and Zadeh, 2012; Partalidou 
et al., 2016; Raza et al., 2016; Arfaoui and Rejeb, 2017; Wei and 
Guo, 2017; Karhan and Aydın, 2018; Pandey and Vipul, 2018; Alio 
et al., 2019; Singhal et al., 2019; Kumar et al., 2019; Majidli and 
Guliyev, 2020; Kumar et al., 2021; Kumau et al., 2020; Gherghina 
et al., 2020; Humbatova et al., 2020; Karakuş, 2021). Some of 
the empirical studies employed vector autoregressive model 

(VAR) (Ding et al., 2016; Chkili, 2022; Grabias, 2022; Nairobi 
et al., 2022; Kelesbayev et al., 2022). However, not a single 
study was able to explain the specific relationship between gold, 
crude oil, and the stock market (Uthumrat, 2022 p. 350-356.). In 
recent decades, there has been much research effort to study the 
relationship between the effect of energy prices on stock ındices 
in the period of COVID-19, and relationship between oil prices 
and stock ındustry ındex prices Akbulaev and Rahimli (2020). 
Suleymanli et al. (2020) Akbulaev et al. (2022).

Between 2001 and 2010, Managi and Okimoto (2013) used 
MarkovSwitching VAR (MS-VAR) analysis to detect the existence 
of a relationship between oil, energy company stocks, and interest 
in the United States. As a result of the analysis, they found a 
positive relationship between oil prices and stocks. Dhaoui and 
Khraief (2014) used the EGARCH method to examine whether 
the stock returns of the USA, Switzerland, France, Canada, 
England, Japan, Singapore, and Australia countries were affected 
by oil shocks between January 1991 and September 2013. As a 
result of the analysis, they found that returns were significantly 
affected, with decreased returns and increased volatility. They 
stated that this was due to the risk of an increase in oil prices and 
the uncertainty in the market.

Benkraiem et al. (2018) examined whether there is a relationship 
between S&P 500 monthly price data and oil and natural gas prices 
in the USA between January 1999 and September 2015 using the 
QARDL-ECM method. They discovered an unstable long-and 
short-term relationship as a result of the analysis, despite the fact 
that the amounts were insignificant, and emphasised that energy 
prices were the driving force for stock market returns.

Alsufyani and Sarmidi (2020) examined the relationship between 
commodity energy prices and the stock market in Saudi Arabia 
between the years 2007 and 2017 using the GARCH-X method. As 
a result of the analysis, they determined that energy prices did not 
affect the stock market and that there were other macroeconomic 
factors affecting the stock market.

Chien et al. (2021) analysed the relationship between the 
COVID-19 pandemic, oil prices, US geopolitical risk index, 
stock market indices, and the Granger causality test in the USA, 
Europe, and China. As a result of the analysis, a 1% severity of the 
pandemic has caused a decrease of around 10% in the productivity 
index, 0.9% in oil demand, 0.67% in the stock market, 1.12% in 
GDP growth, and 0.65% in the electricity demand index. They 
found out why.

Çevik et al. (2020) investigated the relationship between oil 
prices and stock market returns between 1990 and 2017 using the 
EGARCH method. As a result of the analysis, they determined 
that oil prices significantly affect stock returns.

Özcan and Karter (2020) used the Bostrap Rolling Windov 
causality test to investigate the relationship between oil prices 
and the BIST100 index between 2001 and 2020. According to the 
analysis’ findings, there is causality from oil prices to the BIST100 
index in six periods and in three periods if oil prices from the 



Guliyeva: Analysis of the effect of Energy Prices on Stock Indexes During the Epidemıc Crisis

International Journal of Energy Economics and Policy | Vol 13 • Issue 2 • 2023528

BIST 100 are correct, and it would be beneficial for investors to 
monitor changes in oil prices.

Dursun and Ozcan (2019) constructed a panel data collection 
using 2005-2017 quarterly OECD data. A multiple structural 
break cointegration study demonstrated a long-term cointegration 
between electricity, natural gas, and oil price indices and OECD 
stock market indices. Energy prices and stock indexes move 
in the same way. Granfger’s causality research shows a link 
between stock market indices and oil and natural gas prices, but 
not electricity costs.

Kuzu (2019) analysed the spillover effects of exchange rates, 
government debt securities, and oil prices on the BIST 100 index, 
using the data from January 2, 2005, to May 31, 2018, and the 
EGARCH model. The results of the analysis showed that there 
is a significant average volatility spillover effect between the 
government debt securities and the stock market, and this effect 
is bidirectional.

Corbet et al. (2020) discussed sectoral volatility spillovers in terms 
of the COVID-19 outbreak, specific to energy companies. As a 
result, they found significant spillover effects from oil prices on 
renewable energy and coal prices.

Rakshit and Neog (2021) investigated the effects of volatility in 
exchange rates, oil prices, and COVID-19 cases on the returns and 
volatility of stock markets and found that the volatility in exchange 
rates had a negative effect on the returns of stock markets in Brazil, 
Chile, India, Mexico, and Russia. They are determined.

Wang et al. (2021) examined the volatility spillovers between 
stock markets, exchange rates, and oil prices and suggested that 
volatility spillovers peaked at the beginning of the COVID-19 
outbreak and then declined.

Hung and Vo (2021) focused on the spillover effects between the 
S&P 500 index, oil, and gold prices. They benefited from wavelet 
coherence and the Diebold-Yilmaz Index. As a result of their study, 
they determined that return spreads are more intense during the 
COVID-19 period.

Ajmi et al. (2021), using the BEKK-GARCH model, discussed 
the volatility spillovers between the US stock market, oil, and gold 
during the COVID-19 period and determined that the intensity of the 
spreads between the markets increased during the pandemic period.

Amar et al. (2021) investigated the spreads and co-movements 
between commodity and stock prices during the COVID-19 period. 
Using econometric methods such as the Dieboldnd co-movements 
between commodity and stock prices during the COVID-19 period. 
Using econometric methods such as the Diebold–Ylmaz Index, the 
researchers stated that the spreads between the markets included 
in the study changed according to time, and the highest spread 
levels were reached during the COVID-19 period.

Kök and Nazlolu (2022) analysed the study’s annual data for 
Brazil, Russia, India, China, South Africa, and Turkey using the 

stock market index, oil price, and international energy security 
risk index score covering the period of 1994-2018. As a result of 
the research, it has revealed the importance of financial markets 
in terms of energy security risk in the energy-finance relationship 
for BRICS-T countries.

In their study, Gül and Suyadal (2022) examined the dynamic 
interdependence relationships between 11 stock markets before and 
during the COVID-19 pandemic. The research findings show that 
the relationships between the stock markets have increased during 
the COVID-19 pandemic. When the literature is examined, the 
general opinion is that there is an interaction between energy prices 
and stock market indices, or from stock market indices to energy 
prices. For this reason, during the pandemic period of February 16, 
2020-December 26, 2021, which is thought to be an interaction in 
the research, Brent oil, crude oil (WTI), and natural gas (NG) prices, 
the Moscow Stock Exchange Index (RTSI), the Borsa Istanbul Index 
(XU100), and the Bovespa Brazilian Index The presence of the effect 
will be investigated in the Boston Stock Exchange Index (BVSP), 
Indian National Stock Exchange Nifty 50 Index (NSEI), Standard 
and Poor’s 500 Index (S and P 500), London Stock Exchange (FTSE 
100), and Tokyo Stock Exchange (N225) indices.

3. DATASET AND ECONOMETRIC METHOD

3.1. Dataset
In this study, the correlation between Brent oil, crude oil (WTI), 
and natural gas (NG) prices and the indicators of four important 
capital markets was examined. These four capital market indicators 
include RTSI-Moscow Stock Exchange Index, XU100-Borsa 
Istanbul Index, BVSP-Brazilian Stock Exchange Index, NSEI-
Indian Stock Exchange Index (in US dollars), S&P 500-Standard 
and Poor’s 500 Index, FTSE 100-London Stock Exchange, and 
N225-Тokyo Stock Exchange. To investigate the correlation 
between Brent oil, crude oil (WTI), and natural gas (NG) prices 
and RTSI-Moscow Stock Exchange Index, XU100-Borsa Istanbul 
Index, BVSP-Brazilian Stock Exchange Index, NSEI-Indian Stock 
Exchange Index, S&P 500-Standard and Poor’s 500 Index, FTSE 
100-London Stock Exchange, and N225-Тokyo Stock Exchange.
97-week data for the period of February 16, 2020-December 26,
2021, when large price fluctuations were observed in energy
prices, were used. Vector autoregressive model was used to
examine the correlation between the variables, and the direction
of the correlation between the variables was determined by the
Granger causality test. In this study, all analyzes were carried out
with the help of the EViews 12 software package. Table 1 presents
the coding and description of the data included in the analysis.

3.2. Methodology
This section describes the methods used to choose the right model 
in studying the correlation between energy prices and stock market 
indices. An ordinary time series analysis may be appropriate if all 
the variables are stationary; however, if they are not stationary, 
a cointegration analysis, vector error correction (VEC) model, 
or vector autoregressive (VAR) model may be the appropriate 
model to test this correlation. Therefore, this section begins with 
an explanation of stationarity tests. After the stationarity tests, the 
VAR model and the Granger causality test are explained.



Guliyeva: Analysis of the effect of Energy Prices on Stock Indexes During the Epidemıc Crisis

International Journal of Energy Economics and Policy | Vol 13 • Issue 2 • 2023 529

3.2.1. Stationarity tests
Stationarity is one of the most critical properties of time series 
data. With non-stationary series, it is possible to conclude the 
analysis with a “spurious regression.” On the other hand, having 
non-stationary data does not always mean that the correlation 
between these variables causes spurious regression. If the variables 
are cointegrated in their level form, the regression results will show 
their long-run equilibrium correlations.

There are several methods of testing whether the variables satisfy 
the stationarity condition. One of the methods of testing the 
stationarity of the said variables is the unit root test. The presence 
of a unit root in the variables proves that there is no stationarity. 
In this study, the Augmented Dickey-Fuller test, which is obtained 
from the Dickey-Fuller test, was used as a unit root test. The 
following three equations can be used in the traditional Dickey-
Fuller test (Syzdykova and Azretbergenova, 2021:50):

∆𝑦𝑡 = 𝛽1 * 𝑦𝑡  -  1 + 𝜀𝑡 

∆𝑦𝑡 = 𝛽0 + 𝛽1  * 𝑦𝑡 -  1 +  𝜀𝑡 

∆𝑦𝑡 = 𝛽0 + 𝛽1  * 𝑦𝑡 -  1 +  𝛽2 * 𝑇𝑟𝑒𝑛𝑑 + 𝜀𝑡 

In all three tests, the hypothesis is as follows:

H0 :  𝛽1 = 0 The variable has a unit root, the variable is not 
stationary.

H1 :  𝛽1  < 0 The variable has no unit root, the variable is stationary.

3.2.2. Vector autoregressive model
The possibility of endogeneity can bias traditional multilinear 
model estimates. At this point, the vector autoregressive (VAR) 
model is a suitable model designed to deal with endogeneity 
problems. In the VAR model, all variables are considered 
endogenous and their effects on each other are taken into account. 
In these models, an equation is created for each variable. In these 
equations, each variable becomes the dependent variable, and the 
lagged values of the dependent variable and the lagged values of 
the independent variables are added to the equation. In the end, 
there will be as many equations as the number of variables. Thus, 
the effect of each variable on other variables can be tested. The 
VAR model will use the following systems of equations for the 
two variables (Syzdykova and Azretbergenova, 2021: 50):

Y a Y Xt i t
i

m

i t i t
i

m

� � � ��
�

�
�

� �0 1
1 1

� � � (1)

X a Y Xt i t
i

m

i t i t
i

m

� � � ��
�

�
�

� �0 1
1 1

� � � (2)

VAR analysis requires determining the optimal lag length. In the 
above equations, m refers to the optimal lag. Depending on the 
information criteria, the appropriate lag length is selected. The 
information criteria used in this study are Likelihood Ratio (LR), 
Final Prediction Error (FPE), Hannan-Quinn (HQ), Schwarz 
(SIC), Akaike (AIC). The lower the information criteria of the 
model, the more appropriate the lag length used in that model. 

However, information criteria alone are not sufficient to decide the 
optimal lag length. Serial correlation is a very critical problem in 
VAR analysis, as the VAR model includes the lagged value of the 
dependent variable. Therefore, before determining the optimal lag, 
model results with that lag should be tested for serial correlation. 
The appropriate lag length can only be chosen after it has been 
found that the error terms are not serially related.

3.2.3. Vector error correction model, VECM
After proving the existence of a long-term relationship between 
the series, it is necessary to show the short-term movements of 
the variables that are related in the long-term. The short-term 
analysis of the VAR model is done with the vector error correction 
mechanism. The error correction model allows one to distinguish 
between the long-term equilibrium between the variables and the 
short-term dynamics and determine the short-term dynamics. For 
this purpose, an error correction term reflecting the adjustment 
to the long-term equilibrium is added between the explanatory 
variables by taking the first-order differences of the non-stationary 
variables (Lebe and Akbaş, 2014:67).

If there is a cointegration relationship between the variables, 
short- and long-term causal relationships can be examined in terms 
of VECM. Within the scope of this model, even if the series are 
not stationary, the causality relationship between the variables is 
questioned without any difference, so information loss about the 
series is prevented. If the series consisting of X and Y variables are 
assumed to be dependent variables, respectively, VECM models 
can be expressed with the help of equations (3) and (4) below 
(Turan, 2018: 205).

� � � � � � � ��
�

� �
�

� �lnY a X Y VECTt i t
i

k

i t t t
i

k

1 1

1

1 1 1 1

1

� � � �  (3)

� � � � � � � ��
�

� �
�

� �ln X a X Y VECTt i t
i

k

i t t t
i

k

2 2 1

1

2 1 1 2

1

� � � �  (4)

In equations (3) and (4), k represents the optimal delay length, and 
VECT represents the error correction term. The coefficient in front 
of the VECT term indicates the vector error correction coefficient 
and expresses the speed of adaptation of the post-shock imbalances 
to the equilibrium level over time. If the VECT coefficient is 
negative, between 0 and 1, and is statistically significant, it will be 
understood that the established VECM model is correct and the long-
term causal relationship between the variables is valid. Diagnostic 
analysis based on several tests is required to determine whether the 
established VECM model is robust. The diagnostic tests mentioned 
above include autocorrelation, varying variance, and normality 
tests. The existence of serial correlation between the residuals of 
the model established up to a certain lag length is examined by an 
autocorrelation test. The autocorrelation test is based on the LM test 
statistic. If the probability value for all delay values is greater than 
5%, it can be concluded that there is no autocorrelation. This shows 
that the model is a good one. Another method used to measure the 
robustness of the model is the variable variance test.

The changing variance test is based on the Chi-Square test statistic. 
If the probability of the Chi-square test statistic calculated for the 



Guliyeva: Analysis of the effect of Energy Prices on Stock Indexes During the Epidemıc Crisis

International Journal of Energy Economics and Policy | Vol 13 • Issue 2 • 2023530

model is greater than 1%, it is understood that there is no problem 
of varying variance. Finally, the established VECM model’s 
residues should follow the multivariate normal distribution (Mert 
and alar, 2019: 273). The normality test is based on the Jarque-
Bera test statistic. If the probability of the Jarque-Bera test statistic 
is greater than 1%, it is understood that the model satisfies the 
normality condition. As a result, in a well-established VECM 
model, the VECT coefficient should be negative, between 0 and 
1, statistically significant, there should be no autocorrelation and 
varying variance problems in terms of the residuals of the model, 
and the residuals of the model should be in accordance with the 
normal distribution (Tayyar, 2021: 273-274).

Although the cointegration relationship shows long-term 
relationships between the variables, it does not indicate whether 
the variables used are internal or external. In terms of establishing 
the VECM model, it is very important whether the variables 
are internal or external (Salam & Yldrm, 2014: 203). For this 
reason, the equation accuracy of the model can be determined 
by applying the weak externality test to each series. The weak 
externality test is based on the Chi-square test statistic. By giving 
a constraint to the related variable, its connection with other series 
is eliminated in the cointegration relationship. If the chi-square 
probability value of the variable is less than 1% or 5%, it is 
understood that the relevant variable is an endogenous variable 
(Tayyar, 2021: 273-274).

3.2.4. Granger causality test
The significant side in regression analysis is the dependence of 
one variable on other variables. However, this does not always 
mean that there is causality between these variables. In other 
words, causality or the direction of the effect cannot be proved 
by the existence of a correlation between the variables (Gujarati, 
2013: 652).

The Granger causality test consists of estimating the following 
regression systems (Syzdykova and Azretbergenova, 2021: 51):

Y Y a Xt i t
i

m

i t i i
i

m

� � ��
�

�
�

� �� �1
1 0

 (5)

Y Y Xt i t i
i

m

i t i i
i

n

� � ��
�

�
�

� �� � �
1 0

(6)

Using these models, the Granger Causality test reveals not only 
the significance of the correlation between variables but also the 
direction of the correlation between these variables.

4. EMPIRICAL RESULTS

To determine whether there is a multicollinearity problem between 
the variables used in the study, first of all, the correlation between 
the variables is examined. Table 2 below shows the correlation 
matrix between independent variables.

4.1. Unit Root Test
To test the stationarity in the data, study incorporated the 
Augmented Dicky-Fuller Test. The results statistics are as follows:

As seen in Table 2, according to the above test statistics, all 
variables are non-stationary at level. As we can see, Brent has a 
t-statistic of −8.65 with a P-value near zero at the first difference
level. This means that the study cannot proceed with regression
with the variable BRENT’s first difference. NG have a −10.31
value of the t-statistic, which is also highly significant and shows
the first differential is better. Like these two, our variable WTI is
also stationary at the first difference. As per the above results, all
variables based on stock market indices are also significant with
respect to the first difference.

4.2. Descriptive Statistics
In this study, the data have been described with the help of 
descriptive analysis. As we know, the variables incorporated into 
the study have a unit root problem at level; therefore, the data were 
initially converted into the first differential for further analysis. 
Descriptive statistics explain the mean, median, maximum, 
minimum, standard deviation, skewness, and kurtosis of the data. 
But the main thing that is explained is the Jarque-Bera statistic. 
It shows the normality of the data. As per the below results, all 
variables’ data are normally distributed because the probability 
values of the Jarque-Bera statistic were significant.

Sampling periods and descriptive statistics regarding sampling 
are given in Table 3. According to the price averages, Bovespa 
Brazilian Stock Exchange Index (BVSP) has negative averages 
with a score of −91.32990 and London Stock Exchange with a 
score of −0.199794 on the basis of the sample period. That is, it has 
a higher negative return in terms of returns than other countries. 
Тokyo Stock Exchange (N225) 55.72134 and Indian National 
Stock Exchange Nifty 50 Index (NSEI) 54,36289, with the highest 
average, has higher returns for the sample period compared 
to other countries. Standard and Poor’s 500 Index (S&P 500) 
14.84536 and Borsa Istanbul Index (XU100) 7.106804 averages 

Table 1: Dataset information
Variable Description
BRENT Brent oil futures
WTI Crude oil WTI futures
NG Natural gas futures
RTSI RTSI (IRTS) moscow-moscow stock exchange ındex
BIST100 BIST 100 (XU100) ıstanbul-borsa ıstanbul ındex
BVSPO Bovespa (BVSP)-bovespa brazilian stock exchange ındex
NSEI Nifty 50 (NSEI)-Indian national stock exchange
SP500 S&P 500 (SPX)-Standard and poor’s 500 ındex
FTSE100 FTSE 100 (FTSE)-London stock exchange
N225 Nikkei 225 (N225)-Тokyo stock exchange

Table 2: Augmented Dickey‑Fuller test statistic
Variable t-statistic P‑value Stationary level
BRENT −8.654948 0.0000 1st difference
NG −10.31618 0.0000 1st difference
WTI −8.035219 0.0000 1st difference
RTSI −9.658492 0.0000 1st difference
BIST100 −8.523583 0.0000 1st difference
BVSPO −8.816050 0.0000 1st difference
NSEI −7.163876 0.0000 1st difference
SP500 −11.71144 0.0001 1st difference
FTSE100 −10.83087 0.0000 1st difference
N225 −7.723180 0.0000 1st difference



Guliyeva: Analysis of the effect of Energy Prices on Stock Indexes During the Epidemıc Crisis

International Journal of Energy Economics and Policy | Vol 13 • Issue 2 • 2023 531

are seen to have medium returns. Moscow Stock Exchange Index 
(RTSI) 0.732474, crude oil (WTI) 0.225052, Brent oil (BRENT) 
0.198763 and Natural Gas (NG) 0.018814 averages seem to have 
the lowest returns.

Since the high standard deviation, which is another important 
definitional indicator, indicates an increase in volatility, it is seen 
that this indicator is ranked from high risk to low risk in Brazil, 
Japan, England, India, the USA, Russia, and Turkey on the basis of 

the stock market index. In terms of risk score, it is seen that Russia’s 
score is at the highest level of volatility. In addition, Jarque Bera 
test statistics obtained from Skewness and Kurtosis statistics show 
that all series have normal distributions except for the Turkey and 
Russia data. According to the standard deviation indicators, it is 
ranked from the ones with both high volatility and high risk to the 
least. It would be important to state that Brent oil (3.304206), crude 
oil (3.266174), and natural gas (0.247618), which are the main 
energy sources known for their sudden price increases or decreases 
especially during economic, financial, war, and epidemic crises, 
have the lowest risk with their standard deviations.

4.3. Correlation Analysis
Table 4 presents the correlation analysis result table. In this section, 
we discuss the correlation analysis of our data. BRENT is strongly 
correlated with the RTS Index, and both are directly related to 

Table 3: Descriptive statistics based on first difference of variables
Variable DBRENT DNG DWTI DRTSI DBIST100 DBVSPO DNSEI DSP500 DFTSE100 DN225
Mean 0.198763 0.018814 0.225052 0.732474 7.106804 −91.32990 54.36289 14.84536 −0.199794 55.72134
Median 0.430000 0.032000 0.470000 7.110000 13.60000 −73.00000 133.6500 28.20000 4.560000 74.22000
Maximum 9.180000 0.519000 6.830000 111.6800 134.0000 8144.000 1289.650 301.2000 427.1600 2836.600
Minimum −11.42000 −1.315000 −9.550000 −266.2700 −193.1900 −15609.00 −1209.750 −406.1000 −1096.440 −3318.700
SD 3.304206 0.247618 3.266174 59.19468 52.85827 4073.209 393.8338 105.2938 205.0327 825.2497
Skewness −0.522792 −1.760721 −0.823189 −1.425213 −0.982526 −1.104221 −0.385984 −1.084831 −1.945342 −0.488255
Kurtosis 4.310279 10.82018 3.900287 7.728323 5.359342 5.906119 4.503449 6.959664 12.51440 6.152467
Jarque-Bera 11.35740 297.2880 14.23102 123.1979 38.10452 53.84610 11.54419 82.39493 427.0472 44.02029
Probability 0.003418 0.000000 0.000812 0.000000 0.000000 0.000000 0.003113 0.000000 0.000000 0.000000
Sum 19.28000 1.825000 21.83000 71.05000 689.3600 −8859.000 5273.200 1440.000 −19.38000 5404.970
Sum Sq. Dev. 1048.107 5.886197 1024.117 336384.9 268223.7 1.59E+09 14890088 1064332. 4035689. 65379557
Observations 97 97 97 97 97 97 97 97 97 97

Table 4: Correlation matrix
Variable DBRENT DNG DWTI DRTSI DBIST100 DBVSPO DNSEI DSP500 DFTSE100 DN225
DBRENT 1
DNG 0.0846 1
DWTI 0.9441 0.0693 1
DRTSI 0.6361 −0.0062 0.6232 1
DBIST100 0.2192 −0.1701 0.2364 0.4135 1
DBVSPO 0.5062 0.0268 0.4814 0.6253 0.4933 1
DNSEI 0.4144 0.0649 0.4130 0.6263 0.4595 0.6848 1
DSP500 0.4935 0.1347 0.4913 0.5912 0.4179 0.7290 0.6660 1
DFTSE100 0.5490 −0.0562 0.5128 0.7642 0.5018 0.7086 0.6060 0.7519 1
DN225 0.3487 0.0964 0.3386 0.5932 0.4083 0.6141 0.6300 0.6679 0.7124 1

Table 5: Variance inflation factors (VIF ındex)
Variables 
and VIF

Coefficient Uncentered Centered

Variable Variance VIF VIF
C 22.12289 1.010313 NA
DBRENT 18.74304 9.282673 9.248857
DNG 363.8313 1.014153 1.008271
DWTI 19.13658 9.271177 9.226914

Table 6: Unrestricted cointegration rank test (trace)
Hypothesized Eigenvalue Trace 

Statistic
0.05 Critical 

value
Prob.**

No. of CE (s)
None* 0.558555 307.7303 239.2354 0.0000
At most 1* 0.525815 229.2308 197.3709 0.0005
At most 2 0.311269 157.5997 159.5297 0.0634
At most 3 0.299913 121.8009 125.6154 0.0835
At most 4 0.283212 87.57202 95.75366 0.1600
At most 5 0.208537 55.60644 69.81889 0.3940
At most 6 0.135120 33.15470 47.85613 0.5483
At most 7 0.107538 19.21894 29.79707 0.4773
At most 8 0.082449 8.296846 15.49471 0.4342
At most 9 0.000379 0.036365 3.841466 0.8487
Trace test indicates 2 cointegrating eqn (s) at the 0.05 level. *Denotes rejection of the 
hypothesis at the 0.05 level. **MacKinnon-Haug-Michelis (1999) P-values

Table 7: Unrestricted cointegration rank test (maximum 
eigenvalue)
Hypothesized Eigenvalue Max‑Eigen 

Statistic
0.05 Critical 

value
Prob.**

No. of CE (s)
None* 0.558555 78.49944 64.50472 0.0014
At most 1* 0.525815 71.63115 58.43354 0.0016
At most 2 0.311269 35.79878 52.36261 0.7520
At most 3 0.299913 34.22885 46.23142 0.5099
At most 4 0.283212 31.96558 40.07757 0.3049
At most 5 0.208537 22.45174 33.87687 0.5727
At most 6 0.135120 13.93576 27.58434 0.8270
At most 7 0.107538 10.92210 21.13162 0.6551
At most 8 0.082449 8.260481 14.26460 0.3528
At most 9 0.000379 0.036365 3.841466 0.8487
Max-eigenvalue test indicates 2 cointegrating eqn (s) at the 0.05 level. *Denotes rejection 
of the hypothesis at the 0.05 level. **MacKinnon-haug-michelis (1999) P-values



Guliyeva: Analysis of the effect of Energy Prices on Stock Indexes During the Epidemıc Crisis

International Journal of Energy Economics and Policy | Vol 13 • Issue 2 • 2023532

each other. BRENT is also moderately directly proportional to 
BVSPO, NSEI, SP500, FTSE500, and N225, but only weakly 
correlated with BIST100.

NG has a very weak association with some indices. NG has no 
significant association with RTSI, BVSPO, NSEI, FTSE100, or 
N225, but the variable has a weakly significant association with 
BIST100 and SP500. The NG index has a direct relationship with 
the SP500 index and an inverse relationship with the BIST100 
index. WTI has a strong and positive relationship with RTSI. 
WTI is positively related to the BIST100, BVSPO, NSEI, SP500, 
FTSE100, and N225 indices. WTI is weakly related to the BIST100 

index, and its relationship with the other 5 indices is moderate. But 
here the question is: does there exist any statistically significant 
association between these oil prices and market indices? To test 
this phenomenon, the study will analyse the data using the VAR 
and VEC models.

4.4. Testing for Multicollinearity
Before starting any regression analysis, the study tested the model 
for multicollinearity. To study the multicollinearity, we used the 
Variance Inflation Factors (VIF) index. There are different schools 
of thought about the VIF value for multicollinearity, but we go with 
the common thought. If the VIF value is <10, it means there is no 

Table 8: Lag order selection criteria
VAR lag order selection criteria Endogenous variables: BRENT NG WTI RTSI BIST100 BVSPO NSEI SP500 FTSE100 N225

Lag LogL LR FPE AIC SC HQ
0 −5187.958 NA 5.63e+36 112.9991 113.2732 113.1097
1 −4428.898 1336.606 3.41e+30 98.67170 101.6869* 99.88865*
2 −4331.945 149.6444 3.91e+30 98.73794 104.4942 101.0612
3 −4251.102 107.2056 7.19e+30 99.15439 107.6517 102.5840
4 −4107.397 159.3249 4.14e+30 98.20428 109.4427 102.7402
5 −3952.995 137.6189 2.64e+30 97.02164 111.0011 102.6639
6 −3762.423 128.4289* 1.35e+30* 95.05268* 111.7732 101.8012
*Indicates lag order selected by the criterion

Table 9: Vector autoregressive model results
Statistics output 
and variable

BRENT NG WTI RTSI BIST100 BVSPO NSEI SP500 FTSE100 N225

R-squared 0.974097 0.966539 0.974198 0.950041 0.962341 0.943222 0.985518 0.976600 0.912345 0.959774
Adj.R-squared 0.971085 0.962648 0.971197 0.944232 0.957961 0.936619 0.983834 0.973879 0.902152 0.955096
Sum sq. resids 728.0609 4.095312 764.0154 266391.1 224751.2 1.19E+09 11454324 879950.0 2651285. 51874394
S.E. equation 2.909609 0.218220 2.980587 55.65582 51.12129 3719.447 364.9518 101.1532 175.5816 776.6535
F-statistic 323.4107 248.4133 324.7030 163.5404 219.7621 142.8661 585.2272 358.9180 89.51166 205.1904
Log likelihood −235.3972 15.85907 −237.7351 −521.6605 −513.4169 −929.2684 −704.0766 −579.6131 −633.1055 −777.3338
Akaike AIC 5.080355 −0.100187 5.128558 10.98269 10.81272 19.38698 14.74385 12.17759 13.28053 16.25431
Schwarz SC 5.372332 0.191791 5.420536 11.27467 11.10470 19.67896 15.03583 12.46957 13.57250 16.54628
Mean dependent 56.83412 2.994773 53.79763 1421.877 1334.686 107003.3 13704.27 3784.499 6554.477 25907.04
SD dependent 17.11099 1.129110 17.56248 235.6765 249.3321 14774.08 2870.317 625.8690 561.3112 3665.099
Determinant resid covariance (dof adj.): 4.36E+30, Determinant resid covariance: 1.31E+30, Log likelihood: −4739.625, Akaike information criterion: 99.99228, Schwarz criterion: 102.9121

Table 10: Vector error correction model results
Error 
correction:

D 
(BRENT)

D (NG) D (WTI) D (RTSI) D 
(BIST100)

D 
(BVSPO)

D (NSEI) D (SP500) D 
(FTSE100)

D (N225)

CointEq1 −0.496842 −0.046765 −0.365810 0.518457 1.944733 −110.2825 26.32373 −8.674123 −16.02876 −78.99497
(0.15420) (0.01119) (0.15609) (2.90900) (2.59037) (199.883) (19.1680) (5.09822) (9.94251) (39.7440)

(−3.22210) (−4.18104) (−2.34363) (0.17823) (0.75075) (−0.55174) (1.37331) (−1.70140) (−1.61215) (−1.98759)
C 0.198763 0.018814 0.225052 0.732474 7.106804 −91.32990 54.36289 14.84536 −0.199794 55.72134

(0.32021) (0.02323) (0.32413) (6.04085) (5.37918) (415.078) (39.8045) (10.5870) (20.6467) (82.5327)
(0.62073) (0.81003) (0.69432) (0.12125) (1.32117) (−0.22003) (1.36575) (1.40223) (−0.00968) (0.67514)

R-squared 0.098517 0.155413 0.054657 0.000334 0.005898 0.003194 0.019466 0.029570 0.026629 0.039924
Adj. 
R-squared

0.089028 0.146523 0.044706 −0.010189 −0.004566 −0.007299 0.009145 0.019355 0.016383 0.029818

Sum sq. resids 944.8505 4.971403 968.1426 336272.5 266641.7 1.59E+09 14600237 1032859. 3928220. 62769323
S.E. equation 3.153695 0.228759 3.192331 59.49547 52.97881 4088.046 392.0290 104.2698 203.3462 812.8528
F-statistic 10.38191 17.48106 5.492586 0.031764 0.563633 0.304412 1.885989 2.894772 2.599012 3.950532
Log 
likelihood

−248.0384 6.456891 −249.2195 −532.9589 −521.7061 −943.2614 −715.8461 −587.3839 −652.1729 −786.5799

Akaike AIC 5.155430 −0.091895 5.179783 11.03008 10.79806 19.48992 14.80095 12.15224 13.48810 16.25938
Schwarz SC 5.208517 −0.038808 5.232869 11.08317 10.85115 19.54301 14.85404 12.20533 13.54119 16.31247
Mean 
dependent

0.198763 0.018814 0.225052 0.732474 7.106804 −91.32990 54.36289 14.84536 −0.199794 55.72134

SD dependent 3.304206 0.247618 3.266174 59.19468 52.85827 4073.209 393.8338 105.2938 205.0327 825.2497
Determinant resid covariance (dof adj.): 1.30E+31, Determinant resid covariance: 1.06E+31, Log likelihood: −4840.948, Akaike information criterion: 100.4319, Schwarz criterion: 101.2282



Guliyeva: Analysis of the effect of Energy Prices on Stock Indexes During the Epidemıc Crisis

International Journal of Energy Economics and Policy | Vol 13 • Issue 2 • 2023 533

issue of multicollinearity, but if the VIF value is higher than10, it 
means multicollinearity exists.

As seen in Table 5, the above results are based on the ordinary least 
squares method. In the above analysis, first the study regresses 
the model by taking any one index as a dependent variable and 
BRENT, NG, and WTI as independent variables. The ordinary 
least squares method was used to detect the VIF index values for 
regressors. The VIF values indicate that all our variables are free 
from the issue of multicollinearity.

4.5. Testing for Cointegration
Before going for VAR or VECM, the study tested the data for 
cointegration equations. The below results are based on Johnson’s 
cointegration test. The cointegration test will reveal whether or not 
there are any cointegrated equations. If any cointegrated equation 
exists, it means that the data follow a long-term trend, and we can 
regress the vector error correction model. As we already tested the 
data for unit root and unit root exists in the data, it is better to use VAR 
models with lag selections to eliminate the issue of unit root. As per 
the below analysis, at most two cointegrating equations can be studied 
with the help of Johnson’s cointegration test. Therefore, we will use 
both VAR and VECM methods to test the relationship between oil 
market prices and stock market indices (As seen in Tables 6 and 7).

4.6. Vector Autoregressive Model (VARM)
This work is based on studying the relationship between crude oil, 
natural gas, and petroleum products using seven different stock 
market indices. The study uses VAR and VECM methods to test the 
relationship between oil prices and indices. In this section, we will 
discuss the lag selection criteria and vector autoregressive analysis.

As seen in Table 8, as per the above analysis, there are different 
criteria to select the lanes. These lag selection criteria are LR, 
FPE, AIC, SC, and HQ. LR, FPE, and AIC criteria explain that the 
lag selection should be six or higher, but in this study, our data is 
based on limited observations; therefore, we consider the SC and 
HQ criteria for lag selection. We can accept one lag based on the 
above analysis. In VAR, we will do analysis with lag 1, and for 
VECM, we will use lag min 1, e.g., zero lags (Table 9).

As seen in Table 9, as per the above analysis, the Brent oils are 
positively related, with the RTS index having a P-value near 
zero. It means we can conclude the results as the brent is highly 
significantly related with RTS index at 0.01 level of significance. 
Moreover, the relationship between these variables is positive. 
Natural gas and crude oil are also positively related to the RTS 
index, with both being significant at the 0.01 level. The association 
between Brent oil, crude oil, and natural gas with the BIST100 
index is also highly significant and directly proportional to this 
index. The P-value of these three regressors is significant at 
the 0.01 level. Brent oil, crude oil, and natural gas variables all 
have a positive relationship with the BVSPO index. As per the 
above results, these variables are also highly significant for the 
NSE index, SP500, FTSE 100, and N225, as the P-values of all 
regressors were almost zero. As a result, we can conclude that all 
of the regressors are statistically significant at the 0.01 level and 
have a positive association.

4.7. Vector Error Correction Model (VECM)
After performing the analysis with the VAR method, the study 
incorporated VECM as a robustness analysis because there is 
cointegration, which indicates that a long-term trend is applicable. 
To test the model under long-term trends, the study uses VECM. 
Below are results based on a vector error correction model (Table 10).

As per the above analysis, Brent oil is significantly associated 
with market indices at the 0.05 level of significance. The equation 
based on Brent oil can explain 9.85% of the total population. The 
overall significance of the model is good, with an F-statistics value 
of 10.38. Natural gas is also significant at the 0.05 level, and the 
model based on natural gas can explain 15.54% of the population. 
The second model based on natural gas has overall significance 
with an F-statistic value of 17.48. Moreover, the model based on 
crude oil is significant only at a 0.1 level. As per the two analyses, 
the VAR and VECM explain the significant association between 
Brent oil, crude oil, and natural gas with stock market indices.

4.8. Granger Causality Test
After performing the analysis with VAR and VECM, the study also 
tested the causal relationship between the indicators. The results 
presented below are based on the Granger Causality Test, which 
was run in EViews. As per the below results, the BIST100 index has 
a positively significant causal relationship with Brent oil at a 0.05 
level of significance. Moreover, the NSE index positively causes the 
Brent oil price, and the SP500 index also has a causal association 
with Brent oil prices. Both causal relationships are significant.

According to the Granger causality test results shown in Table 11, 
while the natural gas price is not the cause of Brent Oil (P-values 
higher than 1%, 5%, and 10%, “0.0151”), it is seen that Brent 
Petroleum Natural Gas is the cause (P < 10%, “0.0954”). Similarly, 
while natural gas prices are not the cause of crude oil prices 
(P > 1%, 5%, and 10%, “0.2121”), crude oil prices are the cause 
of less (P < 10%, “0.0757”). While the price of crude oil is the 
cause of Brent oil (P < 10%, “0.0630”), it is seen that Brent oil 
is not the cause of crude oil (P-value is higher than 1%, 5%, and 
10%, “0.5811”).

When Table 12 is examined, it is seen that while the RTSI index 
belonging to the country with oil resources is the cause of Brent 
Petroleum (P < 10%, “0.0762”), Brent Petroleum is not the 
cause of the RTSI index (P-value higher than 1%, 5%, and 10% 
“0.22029”). While BIST100 index is the reason for Brent Oil 
(P < 5%, “0.0495”), Brent Oil is not the reason for BIST100 
index (P-value is higher than 1%, 5%, and 10%, “0.6705”). It is 
seen that the BVSPO index is not the cause of Brent Oil (P-value 

Table 11: Granger causality test of the relationship 
between energy prices
Null hypothesis F‑statistic Prob.
NG→BRENT 2.20787 0.1407
BRENT→NG 2.83783 0.0954
NG→WTI 1.57869 0.2121
WTI→NG 3.22541 0.0757
WTI→BRENT 3.54082 0.0630
BRENT→WTI 0.30653 0.5811



Guliyeva: Analysis of the effect of Energy Prices on Stock Indexes During the Epidemıc Crisis

International Journal of Energy Economics and Policy | Vol 13 • Issue 2 • 2023534

higher than 5%, “0.2193”), and Brent Oil is not the cause of the 
BVSPO index (P-value higher than 1%, 5%, and 10%, “0.6859”). 
While the NSEI index is the strongest cause of Brent Oil (P < 1%, 
“0.0002”), Brent Oil is not the cause of the NSEI index (P-value is 
higher than 1%, 5%, and 10%, “0.8028”). While the SP500 index 
belonging to the country that owns the oil resources is the strong 
cause of the Brent Petroleum (P < 1%, “0.0006”), it is seen that 
the Brent Petroleum is not the cause of the SP500 index (P-value 
higher than 1%, 5%, and 10%, “0.7242”). Likewise, it is seen that 
the FTSE100 and N225 indices, Brent Oil, and Brent Oil are not 
the cause of the FTSE100 and N225 indices (P-values higher than 
1%, 5%, and 10%). “FTSE100: 0.9730, Brent: 8.E-05, N225: 6.E-
05, Brent: 0.4661,” for example.

As seen in Table 13, the P-value of the test statistics for the RTSI 
belonging to the country with natural gas resources is 0.0496, which 
is <5% significance level. The RTSI index is the cause of the natural 
gas price. The P-value of the test statistics for natural gas is 0.0089, 
which is <1% significance level. Therefore, the null hypothesis that 
natural gas and RTSI are the causes is accepted. While it is not the 
reason for the natural gas price of the BIST100 index of the natural 
gas-importing country (P-value higher than 1%, 5%, and 10%, 
“0.5798”), it is seen that the natural gas price is the reason for the 
BIST100 index (P < 1%, “0.0090”). While the BVSPO index is 
the cause of the natural gas price (P < 10%, “0.0995”), the natural 

gas price is not the cause of the BVSPO index (P-value is higher 
than 1%, 5%, and 10%, “0.9890”). While the NSEI index is the 
reason for the natural gas price (P < 10%, “0.0692”), the natural 
gas price is not the reason for the NSEI index (P-value is higher 
than 1%, 5%, and 10%, “0.1949”). While the SP500 index is the 
reason for the natural gas price (P < 10%, “0.0825”), the natural 
gas price is not the reason for the SP500 index (P-value is higher 
than 1%, 5%, and 10%, “0.6007”). While it is not the reason for 
the natural gas price of the FTSE 100 index (P-value higher than 
1%, 5%, and 10%, “0.3432”), it is seen that the natural gas price is 
not the reason for the SP 500 index (P < 1%, “0.0011”). It is seen 
that the N225 index is not the cause of the natural gas price, and 
the natural gas price is not the cause of the N225 index (P-values 
higher than 1%, 5%, and 10% “0.2868” and “0.4417”).

Examining Table 14, the RTSI index is the cause of the WTI price 
(P < 10%, 0.0979). However, it seems that the WTI price is not 
the cause of the RTSI index (P-value higher than 1%, 5%, and 
10%, “0.1750”). It is the reason for the WTI price of the BIST100 
index (P < 10%, “0.0710”). It seems that the WTI price is not 
the cause of the BIST100 index (P-value higher than 1%, 5%, 
and 10%, “0.6714”). It is seen that the WTI price of the BVSPO 
index (P-value higher than %, 5%, and 10%, “0.2092”) and WTI 
are not the cause of the BVSPO index (P-value higher than 1%, 
5%, and 10%, “0.7885”). While the NSEI index is the cause of 
the WTI price (P < 1%, “0.0011”), it is seen that the WTI price 
is not the cause of the NSEI index (P-value higher than 1%, 5%, 
and 10%, “0.9949). The strong reason for the WTI price of the 
SP500 index belongs to the country that owns this oil resource 
(P < 1%, or “0.0016”). However, it seems that the WTI price is 
not the cause of the SP500 index (P-value higher than 1%, 5%, 
and 10%, “0.8309”). Why does the WTI price of the FTSE 100 
index change? (The P-value is higher than 1%, 5%, and 10% 
(“0.7918”). The WTI price appears to be the strong cause of the 
FTSE 100 index (P < 1%, “0.0001”), while the N225 index is the 
strong cause of the WTI price (P < 1%, “0.0020”). It seems that 
the WTI price is not the cause of the N225 index (P-value higher 
than 1%, 5%, and 10%, “0.5798”).

As a result, it can be said that the Granger causality test results 
confirmed the findings of the VAR analysis during the COVID-19 
pandemic.

Table 12: Granger causality test of the relationship 
between brent oil prices and stock indices
Null hypothesis F‑statistic Prob.
RTSI→BRENT 3.21441 0.0762
BRENT→RTSI 1.64452 0.2029
BIST100→BRENT 3.96073 0.0495
BRENT→BIST100 0.18219 0.6705
BVSPO→BRENT 1.52897 0.2193
BRENT→BVSPO 0.16460 0.6859
NSEI→BRENT 15.5201 0.0002
BRENT→NSEI 0.06270 0.8028
SP500→BRENT 12.4966 0.0006
BRENT→SP500 0.12524 0.7242
FTSE100→BRENT 0.00115 0.9730
BRENT→FTSE100 17.1354 8.E-05
N225→BRENT 17.7753 6.E-05
BRENT→N225 0.53568 0.4661

Table 13: Granger causality test of the relationship 
between natural gas and stock market indices
Null hypothesis F‑statistic Prob.
RTSI→NG 3.95474 0.0496
NG→RTSI 7.13336 0.0089
BIST100→NG 0.30864 0.5798
NG→BIST100 7.11022 0.0090
BVSPO→NG 2.76849 0.0995
NG→BVSPO 0.00019 0.9890
NSEI→NG 3.37802 0.0692
NG→NSEI 1.70467 0.1949
SP500→NG 3.08032 0.0825
NG→SP500 0.27576 0.6007
FTSE100→NG 0.90765 0.3432
NG→FTSE100 11.2688 0.0011
N225→NG 1.14776 0.2868
NG→N225 0.59700 0.4417

Table 14: Granger causality test of the relationship 
between crude oil prices and stock indices
Null hypothesis F‑statistic Prob.
RTSI→WTI 2.79530 0.0979
WTI→RTSI 1.86729 0.1750
BIST100→WTI 3.33554 0.0710
WTI→BIST100 0.18107 0.6714
BVSPO→WTI 1.59909 0.2092
WTI→BVSPO 0.07240 0.7885
NSEI→WTI 11.2549 0.0011
WTI→NSEI 4.1E-05 0.9949
SP500→WTI 10.5796 0.0016
WTI→SP500 0.04587 0.8309
FTSE100→WTI 0.07007 0.7918
WTI→FTSE100 16.5976 0.0001
N225→WTI 15.5635 0.0002
WTI→N225 0.30872 0.5798



Guliyeva: Analysis of the effect of Energy Prices on Stock Indexes During the Epidemıc Crisis

International Journal of Energy Economics and Policy | Vol 13 • Issue 2 • 2023 535

5. CONCLUSION

The relationship between energy and capital market indicators is 
very important for investors as it can affect their diversification 
decisions. In this study, the correlation between Brent oil, crude 
oil, and natural gas prices and Moscow Stock Exchange Index, 
Borsa Istanbul Index, Bovespa Index, Indian Stock Exchange 
Index, Standard and Poor’s 500 Index, London Stock Exchange, 
and Тokyo Stock Exchange has been studied. In the study, weekly 
data between 16.02.2020 and 26.12.2021 were examined. Vector 
autoregressive model was used and the direction of the correlation 
between variables was determined by the Granger causality test.

Brent oil prices also have a positive causal relationship with 
the FTSE 100 index and the N225 index. The causal impact is 
significant at a level of 0.05. Natural gas has a positive effect on 
the RTS Index and is significant at both the 0.05 and 0.01 levels. 
Natural gas also has a positive effect on the BIST100 index and is 
significant at the 0.05 level. The causal association between natural 
gas and the FTSE 100 index is also positively significant. These 
results are also similar to our previous VAR and VECM analyses. 
The NSE index, SP500 index, and N225 index positively cause 
the price of crude oil, as these variables are significant at the 0.01 
level of significance. Finally, crude oil has a positive influence on 
the FTSE 100 index, which is statistically significant at the 0.01 
level. In line with all the above analyses, e.g., correlation, VAR, 
VECM, and Granger Causality Analysis, there was a significant 
association studied between Brent Oil, Crude Oil, and Natural 
Gas Prices with Stock Market Indices.

As a result of the analysis, in summary (i) causality in the price 
of Brent oil and crude oil natural gas, crude oil Brent oil price 
at 10% accuracy level; (ii) causality to brent oil price of Russia, 
Turkey, India and USA stock market indexes; the causality of the 
Brent oil price only to the Turkish Stock Exchange; (iii) causality 
to natural gas from the Russian, Brazilian, Indian, and US stock 
exchanges; Causality from natural gas to stock market indices in 
Russia, Turkey, and England; (iv) Causal to Crude Oil from stock 
market indices of Russia, Turkey, India, USA and Japan; It can 
be said that there is only one causal link between crude oil and 
the British Stock Exchange Index. There is a causal relationship 
between stock markets and energy prices. As a result of this study, 
it shows that oil and natural gas, which are the main energy sources, 
and capital market investors should follow both the oil and natural 
gas price changes and the movements in the stock market indices 
during the pandemic crisis periods as well as during the economic 
and financial crisis periods. Although the results provided valuable 
information about the relationships between stock market indices 
and oil and gas prices, it would be useful to analyze normal periods 
and compare the results with the findings in this study.

REFERENCES

Ajmi, H., Arfaoui, N., Saci, K. (2020), Volatility transmission across 
international markets amid COVID-19 pandemic. Studies in 
Economics and Finance, 38(5), 926-945.

Akbulaev, N., Mammadli, E., Bayramli, G. (2022), The effect of energy 
prices on stock indices in the period of COVID-19: Evidence from 

Russia, Turkey, Brazil, and India. International Journal of Energy 
Economics and Policy, 12(3), 262-269.

Akbulaev, N., Rahimli, E. (2020), Statistical analysis of the relationship 
between oil prices and industry index prices. International Journal 
of Energy Economics and Policy, 10(2), 324-331.

Alio, F.C., Okolo, V.O., Egbo, O.P., Ezeaku, H.C. (2019), Energy prices 
and the Nigerian stock market. International Journal of Energy 
Economics and Policy, 9(6), 33-37.

Alsufyani, M., Sarmidi, T. (2020), The inter-relationship between 
commodity energy prices and stock market volatility in Saudi-Arabia. 
Journal of Nusantara Studies (JONUS), 5(1), 270-293.

Amar, A.B., Belaid, F., Youssef, A.B., Chiao, B., Guesmi, K. (2021), 
The unprecedented reaction of equity and commodity markets to 
COVID-19. Finance Research Letters, 38, 101853.

Arfaoui, M., Rejeb, A.B. (2017), Oil, gold, US dollar and stock market 
interdependencies: A global analytical insight. European Journal of 
Management and Business Economics, 26(3), 278-293.

Bayraktutan, Y., Uçak, S., & Bicil, İ.M. (2012). Yükselen piyasalarda 
elektrik tüketimi büyüme ilişkisi: Nedensellik analizi. Çukurova 
Üniversitesi Sosyal Bilimler Enstitüsü Dergisi, 21(1), 241-254.

Benkraiem, R., Lahiani, A., Miloudi, A., Shahbaz, M. (2018), New insights 
into the US stock market reactions to energy price shocks. Journal of 
International Financial Markets, Institutions and Money, 56, 169-187.

Çevik, N.K., Cevik, E.I., Dibooglu, S. (2020), Oil prices, stock market 
returns and volatility spillovers: Evidence from Turkey. Journal of 
Policy Modeling, 42(3), 597-614.

Chien, F.S., Sadiq, M., Kamran, H.W., Nawaz, M.A., Hussain, M.S., 
Raza, M. (2021), Co-movement of energy prices and stock market 
return: Environmental wavelet nexus of COVID-19 pandemic from 
the USA, Europe, and China. Environmental Science and Pollution 
Research, 28, 32359-32373.

Chkili, W. (2022), The links between gold, oil prices and islamic stock 
markets in a regime switching environment. Eurasian Economic 
Review, 12, 169-186.

Corbet, S., Goodell, J.W., Günay, S. (2020), Co-movements and spillovers 
of oil and renewable firms under extreme conditions: New evidence 
from negative WTI prices during COVID-19. Energy Economics, 
92, 104978.

Coronado, S., Rodriguez, R.J., Rojas, O. (2018), An empirical analysis 
of the relationships between crude oil, gold and stock markets. The 
Energy Journal, 39, 193-208.

Demir, Y. (2001), Hisse senedi fiyatını etkileyen işletme düzeyindeki 
faktörler ve mali sektör üzerine İMKB’de bir uygulama. Süleyman 
Demirel Üniversitesi İktisadi ve İdari Bilimler Fakültesi Dergisi, 
6(2), 109-130.

Dhaoui, A., Naceur, K. (2014), Empirical Linkage Between Oil Price and 
Stock Market Returns and Volatility: Evidence from International 
Developed Markets. Economics Discussion Papers. p1-30.

Ding, Z., Liu, Z., Zhang, Y., Long, R. (2016), The contagion effect of 
international crude oil price fluctuations on Chinese stock market 
investor sentiment. Applied Energy, 187, 27-36.

Dizdarlar, H.I., Derindere, S. (2008), Hisse senedi endeksini etkileyen 
faktörler: İMKB 100 endeksini etkileyen makroekonomik göstergeler 
üzerine bir araştırma. Yönetim Dergisi, 19(61), 113-124.

Dursun, A., Özcan, M. (2019), Enerji fiyat değişimleri ile borsa endeksleri 
arasındaki ilişki: OECD ülkeleri üzerine bir uygulama. Muhasebe 
ve Finansman Dergisi, 82, 177-198.

Esen, Ö. (2013), Sürdürülebilir Büyüme Bağlaminda Türkiye’nin Enerji 
Açiği Sorunu: 2012-2020 Dönemi Enerji Açiği Projeksiyonu 
(Yayımlanmamış Doktora Tezi). Erzurum: Atatürk Üniversitesi 
Sosyal Bilimler Enstitüsü İktisat Anabilim Dali.

Fouquet, R. (2011), A Brief History of Energy. United Kingdom: Edward 
Elgar Publications.

Fuat, L., Yusuf, A. (2014), Türkiye’nin konut talebinin analizi: 1970-2011. 



Guliyeva: Analysis of the effect of Energy Prices on Stock Indexes During the Epidemıc Crisis

International Journal of Energy Economics and Policy | Vol 13 • Issue 2 • 2023536

Atatürk Üniversitesi İktisadi ve İdari Bilimler Dergisi, 28(1), 57-83.
Gherghina, Ș.C., Armeanu, D.Ș., Joldeș, C.C. (2020), Stock market 

reactions to Covid-19 pandemic outbreak: Quantitative evidence 
from ARDL bounds tests and Granger causality analysis. International 
Journal of Environmental Research and Public Health, 17(18), 6729.

Ghosh, S. (2002), Electricity consumption and economic growth in India. 
Energy Policy, 30(2), 125-129.

Grabias, I.P. (2022), Interdependence between WTI crude oil prices and 
the us equity market. International Journal of Energy Economics 
and Policy, 12(2), 226-232.

Gujarati, D. (2013), Basic Econometrics. 5th ed. United States of America: 
TataMcGraw-Hill Education Pvt. Ltd.

Gül, Y., Suyadal, M. (2022), COVID-19’un pay piyasaları arasındaki 
getiri ve volatilite yayılımlarına etkisi. Pamukkale Üniversitesi 
Sosyal Bilimler Enstitüsü Dergisi, 50, 350-368.

Güngör, B., Yerdelen, K.C. (2015), Dinamik panel veri analizi ile hisse 
senedi fiyatını etkileyen faktörlerin belirlenmesi. KAÜ İİBF Dergisi, 
6(9), 149-168.

Humbatova, S.I., Ahmadov, F.S., Seyfullayev, I.Z., Hajiyev, N.G.O. 
(2020), The relationship between electricity consumption and 
economic growth: Evidence from Azerbaijan. International Journal 
of Energy Economics and Policy, 10(1), 436-455.

Hung, N.T., Vo, X.V. (2021), Directional spillover effects and time-
frequency nexus between oil, gold and stock markets: Evidence 
from pre and during COVID-19 outbreak. International Review of 
Financial Analysis, 76, 101730.

Jain, A., Biswal, P.C. (2016), Dynamic linkages among oil price, gold 
price, exchange rate, and stock market in India. Resources Policy, 
49, 179-185.

Jones, D. W., Leiby, P. N., and Paik, I. K. (2004). Oil price shocks and 
the macroeconomy: what has been learned since 1996. The Energy 
Journal, 25(2).

Karakuş, R. (2021), Petrol ve doğalgaz fiyatları ile hisse senedi fiyatları 
ilişkisi: BİST sinai sektöründe ampirik bir araştırma. İşletme 
Araştırmaları Dergisi, 13(3), 2072-2083.

Karhan, G., Aydın, H.İ. (2018), Petrol fiyatlari, kur ve hisse senedi 
getirileri üzerine bir araştırma. Akademik Araştırmalar ve Çalışmalar 
Dergisi,10(19), 405-413.

Kaya, V., Çömlekçi, İ., Kara, O. (2015), Hisse senedi getirilerini etkileyen 
makroekonomik değişkenler 2002-2012 Türkiye örneği. Dumlupınar 
Üniversitesi Sosyal Bilimler Dergisi, 35, 167-176.

Kelesbayev, D., Myrzabekkyzy, K., Bolganbayev, A., Baimaganbetov, S. 
(2022), The impact of oil prices on the stock market and real exchange 
rate: The case of Kazakhstan. International Journal of Energy 
Economics and Policy, 12(1), 163-168.

Kumar, S., Choudhary, S., Singh, G., Singhal, S. (2021), Crude oil, gold, 
natural gas, exchange rate and indian stock market: Evidence from the 
asymmetric nonlinear ARDL model. Resources Policy, 73, 102194.

Kumar, S., Pradhan, A., Tiwari, A., Kang, S.H. (2019), Correlations and 
volatility spillovers between oil, natural gas, and stock prices in 
India. Resources Policy, 62, 282-291.

Kök, D. & Nazlıoğlu, E. H. (2022). Enerji Arz Güvenliği, Petrol Fiyatları 
ve Pay Piyasalarında Nedensellik İlişkisi: BRICS-T Örneği . 
Ekonomi Politika ve Finans Araştırmaları Dergisi, 7 (1), 220-237.

Kuzu, S. (2019), Devlet iç borçlanma senetleri, döviz, petrol piyasalarının 
hisse senedi piyasası üzerine ortalama ve oynaklık yayilma etkileri. 
Bingöl Üniversitesi Sosyal Bilimler Enstitüsü Dergisi, 9(17), 443-461.

Majidli, F., Guliyev, H. (2020), How oil price and exchange rate affect 
non-oil GDP of the oil-rich country-Azerbaijan? International Journal 
of Energy Economics and Policy, 10(5), 123-130.

Managi, S., Okimoto, T. (2013), Does the price of oil interact with 
clean energy prices in the stock market? Japan and the World 
Economy, 27, 1-9.

Mert, M., Çağlar, A.E. (2019), Eviews ve Gauss Uygulamalı Zaman 
Serileri Analizi. 1. Baskı. Ankara: Detay Yayıncılık.

Nairobi, N., Ambya, A., Russel, E., Paujiah, S., Pratama, D.N., 
Wamiliana, W., Usman, M. (2022), Analysis of data inflation energy 
and gasoline price by vector autoregressive model. International 
Journal of Energy Economics and Policy, 12(2), 120-126.

Özdemir, A. (2012), Küreselleşme Sürecinde Anahtar Rol: Enerji 
Politikaları. Ankara: Asomedya.

Özcan, G., & Karter, Ç. (2020). Türkiye’de Petrol Fiyatları ve Hisse 
Senedi Fiyatları Arasındaki Nedensellik İlişkisi: Boostrap Rolling 
Window Yaklaşımı. Pamukkale Journal of Eurasian Socioeconomic 
Studies, 7(2), 105-114.

Pandey, V., Vipul, V. (2018), Volatility spillover from crude oil and gold to 
brics equity markets. Journal of Economic Studies, 45(2), 426-440.

Partalidou, X., Kiohos, A., Giannarakis, G., Sariannidis, N. (2016), The 
impact of gold, bond, currency, metals and oil markets on the USA 
stock market. International Journal of Energy Economics and Policy, 
6(1), 76-81.

Rakshit, B., Neog, Y. (2021), Effects of COVID-19 pandemic on stock 
market returns and volatilities: Evidence from selected emerging 
economies. Studies in Economics and Finance, 39, 549-571.

Raza, N., Shahzad, S.J.H., Tiwari, A.K. (2016), Asymmetric impact of 
gold, oil prices and their volatilities on stock prices of emerging 
markets. Resources Policy, 49, 290-301.

Sağlam, B.B., Yıldırım, K. (2014), Doğrudan yabancı yatırımlar 
ve ücretler: Türkiye ekonomisi için bir uygulama. Hacettepe 
Üniversitesi İİBF Dergisi, 32(1), 191-209.

Samanta, S.K., Zadeh, A.H.M. (2012), Co-movements of oil, gold, the 
U.S dollar, and stocks. Modern Economy, 3, 111-117.

Shabbir, A., Kousar, S., Batool, S.A. (2020), Impact of gold and oil prices 
on the stock market in Pakistan. Journal of Economics, Finance and 
Administrative Science, 25(50), 279-294.

Shaikh, I. (2021), On the relation between pandemic disease outbreak 
news and crude oil, gold, gold mining, silver and energy markets. 
Resources Policy, 72, 102025.

Singhal, S., Choudhary, S., Biswal, P.C. (2019), Return and volatility 
linkages among international crude oil price, gold price, exchange 
rate and stock markets: Evidence from Mexico. Resources Policy, 
60, 255-261.

Suleymanli, J.E., Rahimli, E.M., Akbulaev, N.N. (2020), The causality 
analysis of the effect of oil and natural gas prices on Ukraine stock 
ındex. International Journal of Energy Economics and Policy, 
10(4), 108-114.

Syzdykova, A. & Azretbergenova, G. (2021). Bıtcoın Fiyatının Altın ve 
Ham Petrol Fiyatları İle İlişkisinin Analizi . In Traders International 
Trade Academic Journal, 4(1), 43-58.

Tayyar, A.E. (2021), Elektrik üretimi-ekonomik büyüme-çevre kirliliği: 
Türkiye için VECM analizi. Sosyoekonomi, 29(47), 267-284.

Turan, Z. (2018), Türkiye’de tarımsal mal ticaretinin ve hayvancılığın 
ekonomik büyüme üzerindeki etkisi (1990-2014). International 
Journal of Disciplines Economics and Administrative Sciences 
Studies, 4(8), 200-209.

Tursoy, T., Faisal, F. (2018), The impact of gold and crude oil prices on 
stock market in Turkey: Empirical evidences from ardl bounds test 
and combined cointegration. Resources Policy, 55, 49-54.

Uthumrat, W. (2022), Dynamic relationship between the return of gold, 
crude oil, and the stock exchange of Thailand based on a vector 
autoregressive model. International Journal of Energy Economics 
and Policy, 12(4), 350-356.

Wang, D., Li, P., Huang, L. (2021), Time-frequency volatility spillovers 
between major international financial markets during the COVID-19 
pandemic. Finance Research Letters, 46, 102244.

Wei, Y., Guo, X. (2017), Oil price shocks and China’s stock market. 
Energy, 140, 185-197.