TX_1~AT/TX_2~AT


International Journal of Energy Economics and Policy | Vol 11 • Issue 4 • 2021 121

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(4), 121-126.

Volatility Spillovers between Oil Prices and Stock Returns in 
Developing Countries

Khairulla Massadikov*

Department of Public Administration and Regional Development, Khoja Akhmet Yassawi International Kazakh-Turkish University, 
Turkestan/Kazakhstan. *Email: k.massadikov@ayu.edu.kz

Received: 25 January 2021 Accepted: 22 April 2021 DOI: https://doi.org/10.32479/ijeep.11117

ABSTRACT

Risk and uncertainty have always been an important issue for investors, researchers and policymakers. Thus, the explanation of the mechanism of 
spreading volatility between different markets has been the focus of attention by researchers. Determining the return and volatility interaction between 
oil prices and stock markets will be useful not only for pricing and hedging financial assets, but also for detecting and interpreting the reflection of 
the problems arising in the oil industry on the country’s economies. In this study, the VAR-GARCH model introduced by Ling and McAleer (2003) 
was used to determine the interaction between oil prices and stock markets in terms of return and volatility for developing countries (BRICS-T). The 
reason for choosing this model is to reveal whether the shocks and volatility in these markets have a transitional effect.

Keywords: Oil Price, Stock Return, Volatility Spillovers, VAR-GARCH Model 
JEL Classifications: G11, G15, Q4

1. INTRODUCTION

The oil markets in the world are known as the deepest markets 
in terms of the volume of transactions realized in terms of their 
positions. On the other hand, oil is the input material of most 
enterprises and factories. Therefore, any fluctuation in the oil 
markets affects the prices of the products produced and reflects 
on the stock markets. This means that there is a close relationship 
between capital markets and oil markets.

The share of oil in the total energy consumption in the world 
constitutes an undeniably large proportion. As of 2018 and 2019, 
33.2% and 33.05% of the total amount of energy consumed 
worldwide were met from petroleum resources, respectively 
(BP, 2020). In fact, the fact that approximately one third of the 
amount of energy consumed is met from petroleum resources is 
an indicator that industry, production and other sectors are largely 
dependent on oil. Therefore, the fluctuations in the prices of oil, 
which has an important role as the main input of most production 

sectors, due to various reasons will affect the rates of return of 
the relevant sectors and affect the market values. When viewed 
rationally, the reduction of GDP by oil shocks will cause economies 
to shrink and as a natural result of this, the economic balances 
will be broken by triggering the inflation rate. Therefore, changing 
macroeconomic variables will indirectly affect capital markets and 
stock markets throughout the country.

Studies investigating the relationship between oil price movements 
and macroeconomic variables are more frequently encountered 
in the literature. In studies investigating the relationship between 
oil prices and stock markets, it has been found that there is 
generally a positive relationship between oil markets and stock 
markets (Sadorsky, 1999; Sadorsky, 2001; El-Sharif et al., 2005; 
Lescaroux and Mignon, 2008; Bjornland, 2009; Mendoza and 
Vera, 2010; Wang et al., 2013; Hanif, 2020). In some other studies, 
the existence of a negative relationship between oil markets and 
stock markets has been advocated (Filis, 2010; Filis et al., 2011; 
Cunado and Gracia Perez, 2014). In recent years, studies arguing 

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Massadikov: Volatility Spillovers between Oil Prices and Stock Returns in Developing Countries

International Journal of Energy Economics and Policy | Vol 11 • Issue 4 • 2021122

that oil prices affect stock prices asymmetrically have increased 
(Tsai, 2015; Narayan and Gupta, 2015; Syzdykova, 2018; Mokni, 
2020; Chang, 2020; Chang et al., 2020).

When looking at the shocks and crises experienced in the oil 
market in recent years, it is seen that it has reached regional even 
global dimensions due to the contamination effect. The spreading 
mechanism of this effect, also known as the domino effect, has 
been a matter of curiosity. This has led to the investigation of 
issues such as the causes of volatility, its effect and the mechanism 
of spreading. In this study, the interaction between oil markets 
and stock markets is analyzed with the help of the VAR-GARCH 
model introduced by Ling and McAleer (2003). The reason for 
choosing this model is to reveal whether the shocks and volatility 
in these markets have a transitional effect. For this purpose, the 
relationship between the stock markets of developing countries 
and oil markets has been investigated.

2. LITERATURE REVIEW

Studies examining the relationship between oil price and stock 
markets on the basis of country or country groups differ from each 
other in terms of their results. In the literature, concepts such as 
interaction, transmission, propagation, and pass-through are used 
to express the relationship between cross markets. 

Malik and Hammoudeh (2007) reported the existence of volatility 
and shock interaction between the oil market (WTI) and the stock 
market of the USA and three different Gulf countries (Bahrain, 
Kuwait and Saudi Arabia) with data for the period between 
February 14, 1994 and December 25, 2001. They researched it 
with the GARCH model. The authors found evidence that there 
is a significant relationship between the oil market and the second 
moment of the US stock market, and that there is a volatility 
interaction from the oil market to the stock market in Bahrain, 
Kuwait and Saudi Arabia in all circumstances. In addition, the 
researchers, stating that there is volatility interaction from the 
Saudi Arabian stock market to the oil market, state that the news 
and shocks in the US stock market affect the stock market volatility 
of the Gulf countries.

Driesprong et al. (2008), using daily data for the period between 
October 1973 and April 2003, examined the interaction between 
the stock market returns of developed and developing countries and 
oil prices with the GARCH model. The researchers stated that if 
oil prices increase compared to the previous month, stock market 
returns tend to decrease, and if oil prices decrease, stock market 
returns tend to increase, because investors react to information 
about the oil price. Howewer they found that an increase in oil 
prices would greatly reduce stock market returns in the upcoming 
period. The findings obtained show that oil prices allow us to make 
predictions for stock market returns, and this prediction is more 
meaningful and powerful for developed country stock markets.

Constantinos et al. (2010) investigated the yield interaction 
between the Greek stock market and oil prices with the VAR 
model and the volatility interaction with the EGARCH model. 
The authors identified a positive and statistically significant 

causal effect from oil price returns and oil price volatility to stock 
market returns. Also, it is determined that there is a bidirectional 
causality relationship between stock market returns and stock 
market volatility.

Chang et al. (2013), using CCC-GARCH, DCC-GARCH, 
VARMA-GARCH and VARMA-AGARCH models, investigated 
the conditional correlation and volatility interaction between spot, 
futures and forward oil returns and FTSE 100, NYSE, Dow Jones 
and S&P 500 index returns. The researchers, based on the daily 
data of January 1998 - November 2009, found that the conditional 
correlation estimated for returns between markets according to 
the CCC model is low and not statistically significant, and the 
conditional correlation estimated in the DCC model is significant. 
Although the VARMA-GARCH and VARMA-AGARCH models 
provide less information about the volatility interaction between 
markets; The asymmetric effect of equally sized positive and 
negative Shocks on conditional variance shows that the VARMA-
AGARCH model is a more effective model.

Hamma et al. (2014) examined the relationship between oil prices 
(WTI and Brent) and the Tunisian Stock Exchange (Tunindex) 
industry indices and the volatility interaction with multivariate 
GARCH models (BEKK, VEC, CCC-GARCH). They aimed to 
determine the rate of protection and the best prevention strategy. 
As a result of the analysis, they determined that there is a one-
way relationship from the petroleum market to the Tunisian Stock 
Exchange, that the sector’s stock returns are affected by the stock 
market volatility and the oil markets, and the BEKK-GARCH 
method is the most effective method to minimize the risk of the 
portfolio of oil and stocks. 

Gomes and Chaibi (2014) examined the shock and volatility 
interaction between 21 frontier markets and oil prices using the 
bivariate BEKK-GARCH(1,1) model. The authors used weekly 
returns from February 8, 2008 to February 1, 2013, as a result they 
found a significant shock and volatility spread between oil prices 
and some markets. Moreover, this spillover effect is bi-directional 
for some markets.

Khalfaoui et al. (2015) investigated the volatility interaction 
between oil prices and the stock markets of G-7 countries (USA, 
Germany, France, England, Italy, Japan and Canada) with daily 
data for the period between 2 June 2003 and 7 February 2012. The 
authors have obtained strong evidence that volatility changes over 
time for markets examined with the BEKK-GARCH model. They 
determined that oil prices and stock market prices were directly 
affected by their own news and volatility, and indirectly by other 
market price volatility.

Ewing and Malik (2016) studied the volatility interaction between 
oil prices and US stock market prices using univariate and bivariate 
GARCH models, including structural breaks, in their study based 
on daily data for the period between 1 July 1996 and 30 June 2013. 
According to the research findings; When the structural breaks 
in the variance in the model are ignored, the researchers stated 
that there is no volatility interaction between oil prices and the 
US stock market, and after the structural breaks were calculated 



Massadikov: Volatility Spillovers between Oil Prices and Stock Returns in Developing Countries

International Journal of Energy Economics and Policy | Vol 11 • Issue 4 • 2021 123

in the model, they found a strong volatility interaction between 
the two markets.

Yu et al. (2020) investigated the volatility interaction between the 
crude oil market (WTI) and the US and Chinese stock markets 
with data for the 1991-2016 period. In the study in which VAR-
BEKK-GARCH method was used; It has been determined that 
the oil market triggered rapid and continuous fluctuations in 
market dependencies, which emerged most sharply after the 
2008 Financial Crisis and showed the increasing interdependence 
between oil and stock markets.

Sarwar et al. (2020) analyzed the volatility spread between 
oil prices and the stock exchanges of Karachi, Shanghai and 
Bombay using the bivariate BEKK-GARCH model with data for 
the period 1997-2014. The study looks at the role of spreading 
volatility in different economic scenarios by dividing it into pre 
and post-crisis periods. According to the results of the study, there 
is no significant difference between the spread between oil prices 
and stock markets, and the spread before and after the crisis. On 
the other hand, the estimated results vary according to the data 
frequencies used (daily, weekly and monthly).

3. DATA SET AND METHODOLOGY

3.1. Data
Different indices are used for oil prices at the international level. In 
this study, European brent spot prices are used for crude oil prices 
per barrel. Representing the developing countries in the study; 
Brazil (iBovespa), Russia (MICEX), India (SENSEX), China 
(Shanghai), South Africa (JALSH) and Turkey (BIST 100) have 
been selected exchanges. The data of the stock market indices of 
the countries were obtained from the Bloomberg database and the 
oil price data from the US Energy Information Agency. Between 
January 2010 and December 2019, logarithmic return series were 
created based on monthly data and analyzes were carried out using 
Eviews and Stata package programs.

3.2. Method: Bivariate VAR (1) - GARCH (1,1) Model
The model introduced by Ling and McAleer (2003) has some 
important advantages over traditional multivariate GARCH 
models. In the implementation of this model, there is less 
complexity in calculation and estimation compared to other 
volatility pass-through models. It also follows a very flexible 
process in explaining the mutual conditional effects and volatility 
pass-through between different series. In particular, the VAR 
(1) - MGARCH (1.1) model has recently confirmed its power in 
revealing the mutual volatility pass-through between different 
markets.

Based on the VAR (1) - MGARCH (1,1) model regarding the basic 
stock market index returns of developing countries included in the 
study and oil price returns, the conditional average equation has 
the following properties for each series:

 

1
1/2                 

t t t

t t t

R R

H

µ φ ε

ε η
−= + +


=  

(1)

Where, R r rt t
stock

t
oil= ( , )' , �rt

stock  ve rt
oil  denote stock and oil price 

index return vectors, respectively. In the conditional mean 
equation, ϕ representing the coefficients consists of a 2X2 

dimensional diagonal matrix �
�

�
�
�

�
�

�

�
�

1

2

0

0
.

� � �t t
stock

t
oil� ( , )' , �εt

stock  and εt
oil  shows the error terms vector 

obtained from the conditional average equations of sub-stock 
market index returns and oil price index returns, respectively. 
� � �t t

stock
t
oil� ( , )'  denotes the random errors vector showing an 

independent and homogeneous distribution (i, i, d).

 H
H H

H H
t

t
stock

t
stock oil

t
stock oil

t
oil

�
�

�
�
�

�

�
�
�

�

�

forms the conditional variance matrix of stock and oil returns. 
Based on the above definitions, rt

stock  and rt
oil  equations are as 

follows:

 

r

r

rt
stock

t
oil

stock

oil
t
st�

�
�
�

�

�
�
�
�
�

�
�
�

�

�
�
�
�
�

�
�

�

�
�

��

�

�
�

1

2

10

0

oock

t
oil

t
stock

t
oil

t
stock

t
oil

r

r

r

�

�

�
�
�

�

�
�
�
�
�

�
�
�

�

�
�
�

�

�
�
�

�

�

1

�

�

��
�
�
�

�
�
�

�

�
�
�
�
�

�
�
�

�

�
�
�
��

�

�

�

�

�

�stock

oil
t
stock

t
oil

t
stocr

r
1 1

2 1

kk

t
oil�

�

�
�
�

�

�
�
�

 (2)

From the simplification of the above matrices, the conditional 
average equations of stock and oil price returns are obtained as 
follows:

 
r r

r r
t
stock stock

t
stock

t
stock

t
oil oil

t
oil

t
o

� � �

� � �
�

�

� � �

� � �
1 1

2 1
iil

�
�
�

��
 (3)

Also, when coefficient matrices for variance equations are defined 
as:

 

2 2
1 2

2 2
2 1

2 2
1 2

2 2
2 1

  
stock stock

t stock stock t
oil oil

t oil oil t

stock stock

oil oil

r r
A and B

r r

α α

α α

β β

β β

    
 = =   
        

 
 
 
   

(4)

ht
stock , �ht

oil  and ht
stock oil−  equations can be obtained as follows:

( )
( )

2
2 2 2 11 2

2 2 2 2
2 1 1

2 2
1 2 1

2 2
2 1 1

2

2

stockstock tt stock stock stock
oil oilt oil oil oil t

stock
stock stock t

oil
oil oil t

stock
t stock

oil
t oil

h c

h c

h

h

h c

h c

εα α

α α ε

β β

β β

−

−

−

−

 
      

= +      
           

 
  

+  
    

 
= 

  

( ) ( )
( ) ( )

2 22 2
1 1 2 1

2 22 2
2 1 1 1

2 2
1 1 2 1

2 2
2 1 1 1

 

 

stock oil
stock t stock t

stock oil
oil t oil t

stock oil
stock t stock t

stock oil
oil t oil t

h h

h h

α ε α ε

α ε α ε

β β

β β

− −

− −

− −

− −

 +   
+   

     +
 

 +
+ 

+    (5)



Massadikov: Volatility Spillovers between Oil Prices and Stock Returns in Developing Countries

International Journal of Energy Economics and Policy | Vol 11 • Issue 4 • 2021124

From the simplification of the above matrices, the conditional 
equations of variance of stock sectors and oil price returns are 
obtained as follows:

 

( ) ( )2 22 2 21 1 2 1
2 2

1 1 2 1

stock stock oil
t stock stock t stock t

stock oil
stock t oil t

h c

h h

α ε α ε

β β

− −

− −

= + × + ×

+ × + ×  (6)

 

( ) ( )2 22 2 21 1 2 1
2 2

2 1 1 1

oil oil stock
t oil oil t oil t

stock oil
oil t oil t

h c

h h

α ε α ε

β β

− −

− −

= + × + ×

+ × + ×  (7)

As can be seen in (6) and (7), the quadratic inclusion of all 
coefficients in the variance equations provides the positivity of 
the equations. It is assumed here that negative and positive shocks 
of equal magnitude have the same effects on conditional variances. 
Depending on the time, volatilities in stock and oil markets for 
period t are directly affected by the delays of their shocks 

� �t
stock

t
stock

� �� � � ��
��

�
��

1

2

1

2

,  and indirectly by the lagged shocks of each 

other. In addition, the volatilities in the said markets are affected 
by both their own volatility ( ht

stock
−1  ve ht

oil
−1 ) and reciprocal lagged 

volatility. Therefore, this model has a more advantageous position 
in analyzing possible volatilities in terms of dynamic shocks and 
volatilities in the market.

In order to guarantee stationarity in VAR (1) - bivariate GARCH 
(1,1) model, the roots of the I AL BL2 0� � �  equation must remain 
outside the unit circle. Here L is the polynomial delay value and I2 
is the 2 × 2 dimensional unit matrix. In this model, ρ is taken as the 
constant conditional correlation independent of time. Therefore, 
taking into account ρ, it is possible to explain the conditional common 
variance between these bilateral markets as follows:

 h h ht
stock oil

t
stock

t
oil� � � ��  (8)

Although the constant conditional correlation assumption is 
seen as a restrictive assumption under changing economic 

conditions, the statistical properties for the dynamic conditional 
correlation for the VAR-MGARCH model have not yet been 
analyzed theoretically. However, it has been emphasized in 
previous studies that this model is a possible model in terms 
of providing the permanence of long-term fluctuations and 
the transmission of volatility and shock between oil and stock 
markets included in the study. The parameters of the bivariate 
VAR (1) -GARCH model used as the basic model are estimated 
by the quasi-maximum likelihood method. The Quasi-maximum 
likelihood method is a robust method against all kinds of 
deviation and convergence problems in normality conditions 
(Ling and McAleer, 2003).

4. RESULTS

In this study, which investigates the shock and volatility spread 
between oil markets and stock markets in developing countries, 
first some basic statistics are included. First of all, descriptive 
statistics and correlation table of the variables were presented 
and then the stationarity of the variables was examined with the 
unit root test.

From the descriptive statistics in Table 1, it is seen that the average 
return of Brent oil is higher than all other developing countries 
except Brazil. However, it also appears to be even more risky. For 
this reason, those who will invest in this market should closely 
monitor the variables that affect oil prices, the policies followed 
and the existence of the markets it is affected by. In addition, 
whether the riskiness in oil markets spreads to stock markets or 
not is important for stock investors.

Looking at the correlation relationship in Table 2; compared 
to other countries, it is seen that a high correlation between 
the India-Brazil-Turkey and Turkey. In addition, it is seen that 
the country with high correlation with the oil price is Russia, 
followed by Brazil. After basic statistics, we will look at the 
stationarity of variables. It is important that the variables are 
stationary in order to avoid spurious regression in the models 

Table 1: Descriptive statistics
Brent Brazil Russia India China South Africa Turkey

Mean −0.045130 −0.162836 −0.089348 0.147743 −0.050594 0.087180 −0.163553
Median 0.473759 −0.114509 −0.205055 0.269789 −0.024328 −0.077921 0.000000
Maximum 8.511181 11.50221 8.289696 7.643441 7.667250 6.001519 7.311989
Minimum −11.57025 −10.27799 −10.82758 −7.128142 −11.72918 −7.919362 −7.489669
SD 3.457602 3.745150 3.189083 2.680377 2.922102 2.566163 3.505569
Skewness −0.797760 −0.040906 −0.345481 −0.091206 −0.480121 −0.188313 −0.176999
Kurtosis 4.464080 3.677143 4.338015 3.222459 5.410388 3.054474 2.447288

Table 2: Correlation matrix
Brent Brazil Russia India China South Africa Turkey

Brent 1 0.3198 0.4674 0.1534 0.1918 0.1160 0.1116
Brazil 0.3198 1 0.6148 0.5512 0.3377 0.4473 0.4773
Russia 0.4674 0.6148 1 0.4174 0.2566 0.4039 0.3911
India 0.1534 0.5512 0.4174 1 0.2131 0.3989 0.4935
China 0.1918 0.3377 0.2566 0.2131 1 0.0751 0.2577
South Africa 0.1160 0.4473 0.4039 0.3989 0.0751 1 0.4172
Turkey 0.1116 0.4773 0.3911 0.4935 0.2577 0.4172 1



Massadikov: Volatility Spillovers between Oil Prices and Stock Returns in Developing Countries

International Journal of Energy Economics and Policy | Vol 11 • Issue 4 • 2021 125

Table 4: VAR (1) - GARCH (1,1) estimation results
Brazil Russia India China South Africa Turkey

Oil Stock Oil Stock Oil Stock Oil Stock Oil Stock Oil Stock
Conditional mean equation

Constant 0.1329* −0.1287 0.0719 0.1870* 0.2009 −0.0531 0.1034* 0.0310 0.1309* 0.0305 0.1397* 0.2401
Oil (1) 0.0290 0.1520* 0.0345 0.0230 0.3029* −0.2034* −0.0021 −0.2043* 0.1506* 0.1303* 0.0213* −0.1423*
Stock (1) 0.0530 0.1540* 0.0512 0.0408 0.0912 0.2620* −0.0231 0.0523 0.0941 0.2175* 0.0031 0.1321*

Conditional variance equation
Constant 0.2095* 0.3213* 0.3003* 0.1601* 2.1390 2.1094 0.0902* 0.0029 0.0690* 0.0421* 0.0312* 0.0897**
( )t
stock
−1

2 0.0021 0.4023* 0.0456 0.3045* −0.2032 0.4560* 0.0901* 0.1306* 0.0612 0.1590 0.0201 0.1009*

( )t
oil
−1

2 0.3098* −0.0071 0.3349** −0.1025 0.0233 −0.0677 0.0204* 0.0713* 0.0897** 0.0926* 0.1020* −0.0876*

�t
stock
�1 )

0.1087 0.5023* 0.0032 0.6710* −0.2787 0.4054 −0.7307 0.6087* 0.6012 0.7634* 0.1200 0.7891**

( )�t
oil
�1

0.6256* 0.2304** 0.6341* −0.0765 0.9680 0.0987 0.9267* 1.1230 0.8529* −0.0207 0.8321* 0.2709*

JB 72.90* 83.05* 45.09* 125.02 52.90* 150.50* 80.34* 90.80* 40.30* 90.24* 60.50* 95.07*
LB-Q (10) 6.5 12.04 10.93 15.05 12.50 8.01 7.8 6.40 20.33* 16.19 6.90 10.02
LBQ2 (10) 7.01 13.90 9.91 11.08 8.05 5.90 8.03 18.07 14.84 10.91 7.90 12.76
Log likelihood −5090.401 −5502.03 −5003.40 −3605.56 −4802.76 −5809.36
Akaike 7.9030 8.9035 8.0105 -8.0701 -8.2071 7.9020
CCC 0.1505* 0.0780* 0.0906* 0.1590 0.1302 0.1401**
CCC: Constant Conditional Correlation Coefficient, LB: Ljung-Box, JB: Jarque-Bera, (*,**) indicates the rejection of the zero hypothesis at 1%, 5% significance level, respectively

Table 3: Unit root test results
ADF unit root test PP unit root test

Intercept Trend and 
intercept

Intercept Trend and 
intercept

Brent −8.453586* −8.420041* −8.251997* −8.211873*
Brazil −11.05401* −11.05208* −11.06099* −11.06110*
Russia −10.38852* −10.34535* −10.62113* −10.57288*
India −10.28590* −10.27440* −12.30450* −12.27718*
China −9.162510* −9.116206* −9.071232* −9.022504*
South Africa −13.94756* −13.91233* −14.15977* −14.12797*
Turkey −9.677585* −9.657140* −9.717914* −9.681629*
Test critical values

1% level −3.486551 −4.037668 −3.486551 −4.037668
5% level −2.886074 −3.448348 −2.886074 −3.448348
10% level −2.579931 −3.149326 −2.579931 −3.149326

*Is statistically significant at 99% confidence level

used in the study. Misleading results are obtained when 
experimental analysis is performed between non-stationary series 
(Syzdykova et al., 2021). For this reason, Augmented Dickey-
Fuller (ADF) and Phillips-Perron (PP) tests were applied to test 
stationarity in the study.

In Table 3, it is seen from the ADF and PP unit root test results that 
all return series are stable at level value and 99% reliability level. 
The results of the VAR (1) - GARCH (1,1) model that will measure 
the impact of shock and volatility spillover between oil markets 
and stock markets after stabilization are presented in Table 4.

Table 4 shows the results of VAR (1) -GARCH (1,1) estimates 
made for developing countries. Looking at the average equation 
results, it is seen that the lagged value of oil returns has an effect 
on the stock market indices of all countries except Russia. This 
effect Brazil and South Africa while creating a positive impact on 
stock index returns, India, China and Turkey constitute a negative 
impact on stock market index returns. That increase in the return of 
oil to China, Turkey and India while decreasing returns in the stock 
market, causing an increase in yields in Brazil and South Africa 
markets. The obvious conclusion from this is that the increase in 

oil returns in oil-importing developing countries has a negative 
effect. In Turkey, South Africa, Brazil and India, equity returns 
are affected by both self-and oil returns. The impact of oil returns 
in Turkey and India is seen to be greater than the impact of stock 
returns. The impact of stock returns in South Africa is greater than 
the impact of oil returns. In China, however, it seems that only oil 
returns have an effect on stock returns.

In the conditional variance equation, when the persistence degree 
of short term shocks is examined, it is seen that the permanence 
degree of short term oil shocks in Russia (0.3349) and the degree 
of permanence of stock shocks (0.3045) is higher. Stock shocks 
are more effective in all other countries. While the persistence of 
short-term oil shocks is low in South Africa and China, this effect 
is stronger in other countries.

According to the shock and volatility pass-through results, the 
shock pass-through from the stock market to the oil markets was 
determined only in China. A shock that will occur in the stock 
markets of other countries has no significant effect on the oil 
markets. South of shocks in the oil market in Africa, China, and 
Russia were identified significant effect on Turkey. Oil markets, 
volatility when the stock market right pass-through only examined 
were found to be a positive influence in Turkey and Brazil.

In the conditional variance equation, it is seen that the ARCH and 
GARCH coefficients are significant in all countries except India. In 
these countries, it is observed that the previous period shock and 
volatility had a strong impact on both the stock and oil markets 
in the current period. Past shocks are changing the volatility 
of developing countries more rapidly. Looking at the GARCH 
coefficients, it is seen that the volatility in the past period has a 
strong effect on the current period in all countries except India. 
It is seen that the fixed conditional correlation coefficients are 
significant in all countries. This indicates the relationship between 
oil markets and stock markets. However, the coefficients obtained 
are generally small values.



Massadikov: Volatility Spillovers between Oil Prices and Stock Returns in Developing Countries

International Journal of Energy Economics and Policy | Vol 11 • Issue 4 • 2021126

5. CONCLUSION

According to the findings of the study, the significant effect of 
oil markets on the stock markets of countries except Russia was 
determined. It has been found to have a positive effect for Brazil 
and South Africa and a negative effect for other countries. The 
negative impact in these countries is an indicator of the countries’ 
dependence on oil. Although there is no significant relationship 
in the Russian market, it is thought that the spillover effect of oil 
shocks in the Russian market may also affect this market indirectly, 
though not directly.

It is seen that oil shocks have a significant effect on the stock 
markets of other countries except India and Brazil. Looking at 
the volatility spread, no spread from stock markets to oil could be 
detected. Turkey and Brazil on the other hand the stock market has 
seen the oil market is right to spread. When the fixed conditional 
correlation coefficients are examined, it is seen that it is significant 
in all countries. Since the coefficients are not very large, it can be 
said that they are not the most important determinant of the stock 
markets, but one of the important factors.

Addressing the volatility phenomenon against oil prices on the 
basis of sectors will provide important advantages in presenting 
different perspectives. Such studies will provide opportunities for 
investors to create more effective portfolios, as they will provide 
an opportunity for effective diversification at the international 
level. In other words, in this case, the sub-sectors will present a 
more Transparent perspective for researchers and investors by 
demonstrating their direct reactions to oil Shocks according to their 
structural characteristics. This will provide additional information 
on building effective portfolios.

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