Johannes Trüby, Moritz Paulus


International Journal of Energy Economics and Policy 

Vol. 5, No. 1, 2015, pp.54-68 

ISSN: 2146-4553 

www.econjournals.com 

 

Crude Oil Price Shocks and Stock Returns:  

Evidences from Turkish Stock Market under Global Liquidity Conditions 
 

Berna Aydogan 

Izmir University of Economics,  

Department of International Trade and Finance,  

Izmir, Turkey. Email: berna.okan@ieu.edu.tr 

 

Istemi Berk 

University of Cologne, Cologne Graduate School (CGS),  

Institute of Energy Economics (EWI), Germany. 

Email: istemi.berk@ewi.uni-koeln.de 

 

 

ABSTRACT: The purpose of this study is to investigate the impacts of crude oil price variations on 

the Turkish stock market returns. We have employed vector autoregression model using daily 

observations of Brent crude oil prices and Istanbul Stock Exchange National Index returns for the 

period between January 2, 1990 and November 1, 2011. We have also tested the relationship between 

oil prices and stock market returns under global liquidity conditions by incorporating a liquidity proxy 

variable, Chicago Board of Exchange’s S&P 500 market volatility index into the model. Variance 

decomposition test results suggest little empirical evidence that crude oil price shocks have been 

rationally evaluated in the Turkish stock market. Rather, it was global liquidity conditions that were 

found to account for the greatest amount of variation in stock market returns. 

 

Keywords: Oil Price Shocks; Stock Returns; Global Liquidity 

JEL Classifications: C58; G15; Q43; Q47 

 

 

1. Introduction 

Since the first oil crisis experienced in 1973, the impact of oil price changes on 

macroeconomic activity has been widely discussed by academic researchers, investors and policy 

makers. In this respect, the pioneering study of Hamilton (1983), which concludes that there is 

significant correlation between increase in crude oil prices and US recessions, has been accepted as the 

fundamental basis for the subsequent studies on the effects of crude oil price shocks on 

macroeconomic indicators such as GDP growth rate, inflation, and industrial activity
1
. According to 

these studies, the price of crude oil, which is the primary fuel of industrial activity, plays a significant 

role in shaping the countries’ economic and political developments, not only by directly affecting the 

aggregate indicators, but also by influencing companies’ operational costs, and thus their revenues. 

When the stock market is efficient, positive crude oil price shocks would negatively affect the cash 

flows and market values of companies, causing an immediate decline in the overall stock market 

returns.  

 Although there exists a major consensus in the literature that endogeneity is not an issue when 

analyzing the impacts of oil prices on stock markets of the countries apart from USA, some studies 

(e.g., Park and Ratti, 2008) suggest that there would, at least, be some sort of spillover from US or 

global financial markets to that of developed, mostly European, countries. It also seems plausible to 

consider this interrelationship when studying stock markets of emerging economies, which attract 

large amount of short-term capital movement from major economies. This paper extends the 

understanding on the issue of global spillover effects on the dynamic relationship between oil prices 

and stock market returns by employing data from one particular emerging economy, Turkey.  

                                                 

1
 Please see “Section 2. Literature Review” for corresponding studies. 



International Journal of Energy Economics and Policy, Vol. 5, No. 1, 2015, pp.54-68 

 

 

55 

 The purpose of this paper is to investigate the impacts of oil price shocks on the Turkish stock 

market for the period between January 1990 and November 2011 using the vector autoregression 

(VAR hereafter) model. A proxy variable capturing liquidity conditions in the global financial system 

is included into the analyses in order to examine the above-mentioned spillover effect. Since Turkey 

has limited domestic oil production and reserves, imports make up a significant portion of its oil 

consumption. Therefore, Turkish economy appears sensitive to oil price changes, similar to other 

developing and crude oil import-dependent countries. Moreover, over the last decades Turkish 

financial market, through a condense trade liberalization, has been attracting worldwide capital inflow. 

As of November 2011 foreign portfolio investments have been responsible for nearly 63% of total 

Turkish stock market capitalization.
2
 Thus Turkish stock market returns have become sensitive to the 

shocks created in international financial markets.  

 One more reason for including financial liquidity is that financial, more specifically futures, 

markets have been the other major crude oil market since the early 1990s. This was the result of 

increasing volume of crude oil future contracts traded, which exceeded global oil 

production/consumption during late 1980s
3
. Since then crude oil prices have been determined in a 

manner that accounts for the effects of decisions made by investors, speculators, hedgers, and large 

investment funds in the future markets, as well as physical market conditions. Analyzing these “non-

physical” market conditions, such as expectations about the market, global financial and economic 

indicators, would increase the possibility to shed some more light on the empirical variations in crude 

oil prices.  

 Therefore, a proxy for global financial liquidity will not only serve as an explanatory factor 

that influences stock market returns, but also be used to explain variations in oil prices. In the current 

study, the evidence of such tridimensional interaction, e.g. joint respond of stock returns and oil prices 

to liquidity, is investigated using the disentangling methodology proposed by Kilian and Park (2009). 

Understanding the impact of crude oil prices on Turkish stock market is potentially beneficial 

for investors, market participants, regulators and researchers, as it is likely to exhibit characteristics 

different from those observed in well-documented developed markets. Thus, our study explores an 

underexploited area of potentially valuable research in Turkey with a very comprehensive data set, 

ranging from January 1990 and November 2011. This relatively long time horizon has been divided 

into three sub-periods
4
 coinciding with specific oil price trends to allow testing of the performance of 

the Turkish stock market under different oil price regimes. Empirical results suggest that oil prices 

have significant impacts on Turkish stock market returns only during the third sub-period, during 

which crude oil prices represented extreme volatile structure. On the other hand, whenever the 

financial liquidity conditions are incorporated into the analyses, it is found out that liquidity is the 

most plausible explanation for the changes in both oil prices and stock market returns. 

The remainder of this paper is organized as follows. The next section provides relevant 

literature about the relationship between financial markets and oil price shocks. Section 3 outlines the 

econometric methodology concerning VAR analysis and disentangling. The data set and empirical 

results are presented in section 4. Finally, section 5 contains discussion of results and concluding 

remarks. 

 

2. Literature Review 

Since Hamilton (1983), a plethora of studies have analyzed the interrelation between 

macroeconomic activity and oil price changes, most of which demonstrated a negative correlation
5
. 

                                                 

2
 Data from website of Istanbul Stock Exchange (IMKB): http://www.ise.org/Data/StocksData.aspx.

 

3
 Using data for global crude oil production/consumption from BP’s Statistical Review of World Energy 2011 

and for the volume of WTI crude oil futures contracts from NYMEX official website exact year can be derived 

as 1988. 
4
 Sub-period I: January 1990–November 2001; Sub-period II: November 2001–July 2008; Sub-period III: July 

2008–November 2011. Please see Section 4.1 for details of sub-periods. 
5
 Mork, 1989; Kahn and Hampton, 1990; Huntington, 1998; Brown and Yucel, 1999, 2002; Gao and Madlener, 

1999; Hamilton, 2003; Dickman and Holloway, 2004; Guo and Kliesen, 2005; Rogoff, 2006; Sill, 2007; Kilian, 

2008; and Oladosu, 2009. Moreover, a number of researchers have examined the role of crude oil prices in 



Crude Oil Price Shocks and Stock Returns: Evidences from Turkish Stock Market under Global Liquidity 

Conditions 

 

 56 

However, according to the studies on the relationship between oil prices and stock markets, oil price 

shocks influence various industries’ stock prices differently and the relationships between oil price 

shocks and financial markets are, for many countries, complex and ambiguous. A commonly held 

view is that an upward trend in oil price is beneficial for oil producing companies’ stock returns and 

oil exporting countries’ market activity, yet has an adverse effect on most of other sectors and oil 

importing countries. 

A firm-specific study by Al-Mudhaf and Goodwin (1993) investigated the returns from 29 oil 

companies listed on the NYSE and demonstrated a positive impact of oil price shocks on ex post 

returns for firms with significant assets in domestic oil production. Further, Haung et al. (1996) 

analyzed the relationship between daily oil future returns and US stock returns by employing an 

unrestricted vector autoregression (VAR) model and found evidence that oil futures clearly lead some 

individual oil company stock returns. Faff and Brailsford (1999) used market model to investigate 

several industry returns in the Australian stock market, finding significant positive oil price sensitivity 

of Australian oil and gas, and diversified resources industries. In contrast, industries such as paper and 

packaging, banks and transport appear to display significant negative sensitivity to oil price hikes. 

Sadorsky (2001) indicated that stock returns of Canadian oil and gas companies are positively 

sensitive to oil price increases. Boyer and Filion (2009) employed a multifactor framework to analyze 

the determinants of Canadian oil and gas stock returns, finding similar results to Sadorsky (2001). 

Although El-Sharif et al. (2005) demonstrated how the oil prices have significantly positive impacts 

on oil and gas returns in the UK, evidence for the oil price sensitivity existing in the non-oil and gas 

sectors is generally weak. In this context, Henriques and Sadorsky (2008) measured the sensitivity of 

the financial performance of alternative energy companies to changes in oil prices using VAR model 

in order to investigate the empirical relationship between alternative energy stock prices, technology 

stock prices, oil prices, and interest rates. They indicated that technology stock price and oil price each 

individually Granger causes the stock prices of alternative energy companies. More recently, 

Obernderfer (2009) analyzes the interrelationship between oil prices and European energy companies 

and finds both oil prices and oil price volatility negatively affects the stock prices of utility companies. 

Jones and Kaul (1996) examined whether the reaction of international stock markets to oil shocks 

could be justified by current and future changes in real cash flows, or changes in expected returns. 

They provided evidence that aggregate stock market returns in the US, Canada, Japan and the UK are 

negatively sensitive to the adverse impact of oil price shocks on the economies of these countries. 

Contradicting to Jones and Kaul (1996), Huang et al. (1996) found no evidence of a relationship 

between oil futures prices and aggregate stock returns using daily data from 1979 to 1990. However, 

Ciner (2001) challenged the findings of Huang et al. (1996), and argued for the need for further 

research to produce evidence from international equity markets to support the robustness of the results. 

He concluded that a statistically significant relationship exists between real stock returns and oil price 

futures, but that the connection is non-linear. Moreover, Huang et al. (2005) investigated the effect of 

oil price change and its volatility on economic activities in the US, Canada and Japan. They indicated 

that when exceeding a certain threshold, oil price change and volatility possess significant explanatory 

power for the outcome of economic variables such as industrial production and stock market returns.  

Theoretically, in oil exporting countries, stock market prices are expected to be positively affected by 

oil price changes through positive income and wealth effects. In an analysis of the effects of oil price 

shocks on stock markets in Norway, Bjørnland (2009) argued that higher oil prices represent an 

immediate transfer of wealth from oil importers to exporters, stating that the medium to long-term 

effects depend on how the governments of oil producing countries dispose of the additional income. If 

used to purchase goods and services at home, higher oil prices will generate a higher level of activity, 

and thus improve stock returns. In addition, Gjerde and Saettem (1999) demonstrated that stock 

returns have a positive and delayed response to changes in industrial production and that the stock 

market responds rationally to oil price changes in the Norwegian market.  

A negative association between oil price shocks and stock market returns in oil importing 

countries has been reported in several recent papers. Nandha and Faff (2008) examined global equity 

                                                                                                                                                         

monetary policy (e.g., Bernanke et al., 1997; Hamilton and Herrera, 2004) and impacts of oil prices on exchange 

rates (e.g., Chen and Chen, 2007; Coudert et al., 2008). 



International Journal of Energy Economics and Policy, Vol. 5, No. 1, 2015, pp.54-68 

 

 

57 

indices with 35 industrial sectors, showing that oil price rises have a negative impact on stock returns 

for all sectors except the mining, and oil and gas industries. O'Neill et al. (2008) found that oil price 

increases led to reduced stock returns in the US, the UK and France. In a study of the connection 

between oil price shocks and the stock market for the US and 13 European countries, Park and Ratti 

(2008) reported that oil price shocks had a negative impact on stock markets in US and many 

European countries, while the stock exchange of Norway showed a positive response to the rise in oil 

prices. These authors also provided evidence that stock markets in oil exporting countries are less 

affected by oil prices relative to oil importing countries. The results of Chiou and Lee’s (2009) study 

confirmed the existence of a negative and statistically significant impact of oil prices on stock returns. 

Their findings also provided support for the notion that oil shocks drive economic fluctuations, with 

the evidence indicating that with changes in oil price dynamics, oil price volatility shocks have an 

asymmetric effect on stock returns. Examining whether the endogenous character of oil price changes 

affect stock market returns in a sample of eight developed countries, Apergis and Miller (2009) found 

evidence that different oil market structural shocks play a significant role in explaining adjustments in 

international stock returns. Aloui and Jammazi’s (2009) study focused on two major crude oil markets, 

namely WTI and Brent, and three developed stock markets, namely France, UK and Japan and was 

based on the relationship between crude oil shocks and stock markets from December 1987 to January 

2007. The results indicated that the net oil price increase variable plays an important role in 

determining both the volatility of real returns and the probability of transition across regimes.  

More recently, Arouri and Nguyen (2010) used different empirical techniques namely, market model 

and the two-factor market and oil model, to test the causality between oil prices and twelve European 

sector indices listed on Dow-Jones for the period from January 1998 to November 2008. They found 

asymmetries in response of the different sector indices to oil price changes. Fan and Jahan-Parvar 

(2012), studying the interrelation between U.S. industry-level returns and oil prices, found no evidence 

that oil prices have significant predictive power for industry-level returns. Chortareas and Noikokyris 

(2014) has more recently investigated the effects of oil supply and demand shocks on U.S. dividend 

yield components, i.e. dividend growth, real interest rate, equity premium. Following disentangling 

methodology proposed by Kilian (2009) they showed that that although positive relationship between 

oil price increase and dividend yield is evident, the persistence of relationship is highly dependent on 

the driving force of the oil price increase.  

Jammazi and Aloui (2010) explore the impact of crude oil shocks on stock markets of three 

developed countries, UK, France and Japan, using a combined approach of wavelet analysis and 

Markov Switching Vector Autoregression. They evaluated the issue in two phases of stock markets 

and found that while oil shocks do not affect stock markets during recession phases, they have 

significant negative impact during expansion phases. While Jammazi (2012a) uses the same approach 

with Jammazi and Aloui (2010) to analyze the effect of crude oil shocks on stock market returns of 

USA, Canada, Germany, Japan and UK, Jammazi (2012b) uses a transformation of wavelet analysis 

with Haar A Trous decomposition to explore the interactions between crude oil price changes and 

stock returns of same five countries. The results of these studies reveal that both approaches are more 

accurate then the methodologies used in existing literature when the focus is to account for changing 

intensity of crude oil shocks over time. Reboredo and Rivero-Castro (2014) also used wavelet-based 

analysis to investigate the impacts of oil prices on different stock market indices, including S&P 500, 

Dow Jones Stoxx 600 and sectoral indices, and found positive interdependence especially during post 

credit crunch period. 

Contrary to the work done on developed markets, relatively little research has focused on the 

relationship between oil prices and stock markets of emerging – oil exporting or importing – 

economies. Hammoudeh and Aleisa (2004) examined the relationship between oil prices and stock 

prices for five members (Bahrain, Kuwait, Oman, Saudi Arabia, and the United Arab Emirates) of the 

Gulf Cooperation Council (GCC), all of which are net oil exporters, for the period 1994-2001, while 

Zarour (2006) investigated the same countries during 2001 to 2005. Hammoudeh and Aleisa’s findings 

suggested that most of these markets react to the movements of the oil futures price, with only Saudi 

Arabia having a bidirectional relationship. By analyzing the impulse response function, Zarour 

concluded that the sensitivity of these markets to shocks in oil prices has increased, with responses 

becoming more rapid after rises in prices. Arouri and Fouquau (2009) investigated the short-run 



Crude Oil Price Shocks and Stock Returns: Evidences from Turkish Stock Market under Global Liquidity 

Conditions 

 

 58 

relationships between oil prices and GCC stock markets. To examine the phenomena of stock markets’ 

occasional non-linear response to oil price shocks, they examined both linear and nonlinear 

relationships. Their findings pointed to a significant positive relation between oil prices and the stock 

index of Qatar, Oman and UAE, but for Bahrain, Kuwait and Saudi Arabia, they found no such 

influence. As another GCC study, Naifar and Al Dohaiman (2013) using Markov regime-switching 

model, found that the relationship between those markets and oil price volatility is dependent upon the 

regime.  

Employing an error correction representation of a VAR model, Papapetrou (2001) concluded 

that oil price is an important factor in explaining the stock price movements in Greece, and that a 

positive oil price shock tends to depress real stock returns. Maghyereh (2004) studied the relationship 

between oil prices changes and stock returns in 22 emerging markets, conducting VAR model from 

1998 to 2004, without finding any significant evidence that crude oil prices have an impact on stock 

index returns in these countries. In contrast to this conclusion, Basher and Sadorsky (2006), analyzing 

the impact of oil price changes on a large set of emerging stock market returns for the period 1992 to 

2005, proposed that emerging economies are less able to reduce oil consumption and thus are more 

energy intense, and more exposed to oil prices than more developed economies. Therefore, oil price 

changes are likely to have a greater impact on profits and stock prices in emerging economies. Cong et 

al. (2008) apply multivariate vector autoregression methodology to analyze the interactive relationship 

between oil price shocks and Chinese stock market activity. Authors find no evidence that oil price 

shocks have no significant effect on stock returns except for manufacturing index and some oil 

companies’. Similarly, Narayan and Narayan (2010) investigated the impact of oil prices on Vietnam’s 

stock prices and concluded that oil price have a positive and significant impact on stock prices. 

Finally, Soytaş and Oran (2011) examined the causality between oil prices and Turkish stock market 

(ISE-100) aggregate and electricity indices. They concluded that while oil prices do not Granger cause 

aggregate index, they have significant impact on electricity index.  

 

3. Methodology 

This study employs VAR approach in order to examine the dynamic interactions between oil 

price shocks and the Turkish stock index, and compare results, which take into account global 

financial liquidity conditions with those that do not. The VAR model introduced by Sims (1980), 

presents a multivariate framework that expresses each variable as a linear function of its own lagged 

value and lagged values of all the other variables in the system. The main advantage of this approach 

is the ability to capture the dynamic relationships among the economic variables of interest. The 

methodology treats all variables as jointly endogenous, and for proper estimation in a multivariate 

stable VAR system, all variables employed in the model must be stationary or I(0) process. Although 

there are many tests developed in the time-series econometrics to test for the presence of unit roots, 

two tests in particular the Augmented Dickey-Fuller (ADF hereafter) test (Dickey and Fuller, 1979, 

1981) and the Kwiatkowski, Phillips, Schmidt, and Shin (KPSS hereafter) test (Kwiatkowski et al., 

1992) have been employed to investigate the degree of integration of the variables used in the 

empirical analysis
6
.  

Case I: Simple Model 

Here, we start with a simple model, which takes the relationship between oil prices and 

Turkish stock market into account and neglects effect of global liquidity constraints. In this model we 

needed to transform oil prices into shock variables. Besides linear ones, some nonlinear 

transformations of oil prices have also been proposed in the literature
7
. Therefore, in order to achieve 

robust empirical results we have used both linear and nonlinear transformations of oil prices. Two 

types of variables for oil price shocks employed in this study are log return and scaled oil price 

increase (SOPI hereafter). The log return of oil prices, , is from  to  calculated as; 

                                        (1) 

                                                 

6
 Since all the variables included in the VAR methodolog are I(0) process, Vector Error Correction Model 

(VECM) was not conducted in this paper. 
7
 Mork, 1989; Lee et al., 1995; Hamilton, 1996. 



International Journal of Energy Economics and Policy, Vol. 5, No. 1, 2015, pp.54-68 

 

 

59 

where  denotes oil prices at time . The oil price shock variable is also calculated by the method of 

SOPI developed by Lee et al. (1995).  

                                       (2) 

where  is the residuals and  is the square root of the volatility ( ), which are derived from 

equation system (3), and  captures positive oil price shocks for the subjected date. For this 

specification, GARCH (p,q) model, which has been first proposed by Bollerslev (1986) and has 

become popular, particularly, due to its explanatory power for dependence in volatility, is estimated as 

follows: 

  

                                    (3) 

where  is white noise with .   

Furthermore, we have proposed a bivariate  system with daily return of Turkish stock 

index and two types of oil price change variable to analyze the variance decomposition structure. The 

model is written in the reduced form of structural VAR representation as follows: 

  

                                      (4) 

where  is the log-return of daily Turkish stock exchange index price, and  is the corresponding 

oil price shock variable, either  or .  

Case II: Incorporating Global Liquidity Conditions 

The dynamic system in equation (4) may lead to a conclusion that oil price shocks have 

significant impacts on stock returns, however this result may be biased if any variable, which affects 

both oil prices and stock returns in the long-run, is omitted. In order to avoid such a consequence, we 

should obtain a “purified” oil price shock variable, related only to the oil market itself. In order to 

obtain such purified oil market specific price shock variable we have employed disentangling 

methodology, proposed by Kilian and Park (2009). A proxy variable for global financial liquidity 

conditions, which is thought to be responsible for variations in oil prices besides physical oil market 

conditions, is incorporated into the analyses. Chicago Board of Options Exchange’s (CBOE hereafter) 

S&P 500 market volatility index, , is chosen as the proxy for global liquidity and its first 

difference, , is used
8
 in VAR framework:  

  

                                               (5) 

The first equation of this dynamic system allows to capture residuals, , which can be used 

as purified oil market specific shock variable. This residual series and  are, further, used in the 

VAR framework proposed below instead of oil price shock variable, , to examine their effects on 

Turkish stock index returns’ variance decomposition structure. The proposed dynamic system, hence, 

becomes a tri-variate VAR with a following representation: 

     

                     

                                                 

8
 First difference of CBOE’s volatility index , which is stationary, is used in the analyses since  is I(1) 

process. 



Crude Oil Price Shocks and Stock Returns: Evidences from Turkish Stock Market under Global Liquidity 

Conditions 

 

 60 

                                            (6) 

Variance decomposition analysis of this tri-variate VAR system will enlighten whether Turkish stock 

returns react to oil market specific shocks, or to shocks created in global markets due to the liquidity 

conditions. 

 

4. Data and Empirical Results 

4.1. Data  

The data of this study consists of daily observations of ICE’s Brent crude oil prices , log-

return of ISE-100 stock market index , and CBOE volatility index . The ‘National-100 

Index’ (ISE-100) is the main market indicator of the Turkish Stock Market. The data for Brent crude 

oil prices, ISE-100 index prices and VIX obtained from the US Energy Information Administration, 

the Matrix Database
9
 and CBOE’s official website, respectively. The data covers the period from 

January 2, 1990 to November 1, 2011, realizing a total of 5,194 observations. In order to examine 

stock market behavior under different oil price regimes, the data set is divided into three sub-periods. 

The first sub-period consists of 2833 observations, namely from January 2, 1990 to November 15, 

2001, where oil prices follow a comparatively stable and horizontal trend, ranging between 9 US 

Dollars per barrel ($/bbl hereafter) and 41 $/bbl. The second consists 1604 observations from 

November 16, 2001 to July 11, 2008, during when the crude oil market, as with other commodities, 

witnessed historical record prices after an upward trend reaching to approximately 145 $/bbl. During 

the third, from July 14, 2008 to November 1, 2011, with the credit crunch period, crude oil prices 

immediately fell from 145 $/bbl barrel to nearly 40 $/bbl, and then increased again to approximately 

125 $/bbl, representing high volatility, which led to extremely large positive and negative returns 

within a relatively short time period.  

The descriptive statistics for Brent crude oil returns , ISE-100 stock index returns , 

and first difference of CBOE’s S&P 500 market volatility index  series are provided in Table 

1. All three descriptive series display non-Gaussian characteristics with negative skewness for Brent 

crude oil returns and positive skewness for ISE-100 stock index returns, and CBOE’s market volatility 

index. Moreover, all series exhibit excessive kurtosis, a fairly common occurrence in high-frequency 

financial time series data, and suggest that the observed excessive kurtosis may be due to 

heteroskedasticity in the data, which may be captured with the GARCH models.  

 
Table 1. Descriptive Statistics of Sample Series 

 
   

Mean 0.0003 0.0015 0.0034 

Median 0.0008 0.0014 -0.0600 

Maximum 0.1813 0.2655 16.5400 

Minimum -0.3612 -0.2033 -17.3600 

Standard Deviation 0.0247 0.0290 1.5876 

Coefficient of Variation 82.33 19.33 466.94 

Skewness -0.7742 0.0469 0.6606 

Kurtosis 17.29 8.58 21.46 

Jarque-Bera Stat. 44736.01* 6745.03* 74148.06* 

# of observations 5193 5193 5193 

Notes: SD indicates standard deviation. Jarque-Bera normality test statistic has a chi-square distribution with 2 

degrees of freedom.* denotes statistical significance at 1% level.  

 

 

                                                 

9
 Matriks is a licensed data dissemination vendor located in Turkey. It provides data and information on global 

financial markets as well as selected macroeconomic indicators. 



International Journal of Energy Economics and Policy, Vol. 5, No. 1, 2015, pp.54-68 

 

 

61 

Excessive kurtosis would also explain the reasoning for high Jarque-Bera statistics, which 

reject the null hypothesis of normality for all return series. Values for coefficient of variation (CV) 

represent extreme and relatively high variance clustering around the mean of  and . The 

volatility index variable, by definition, captures variance of CBOE market; hence high CV is expected 

for . On the other hand high CV value for  suggests further analyzing the variance structure of 

oil returns.  
 

Figure  1. Brent Crude Oil Prices, Returns and Tail Distribution with QQ-Plot  

1990 1995 2000 2005 2010

50

100

150
Price 

1990 1995 2000 2005 2010

-0.25

0.00

Return 

-0.3 -0.2 -0.1 0.0 0.1 0.2

10

20

Density

Return 

-0.3 -0.2 -0.1 0.0 0.1 0.2

-0.25

0.00

Distribution

Return 

-0.075 -0.05 -0.025 0 0.025 0.05 0.075

-0.25

0.00

QQ plot

Return ´ normal 

 
Note: The Brent crude oil price, daily returns, daily returns density and QQ-plot against the normal 

distribution. The time period is from 02.01.1990 – 01.11.2011 

 

Volatility clustering is immediately evident from the graphs of daily oil returns, which 

suggests the presence of heteroskedasticity (Figure 1). The density graphs and the QQ-plot against the 

normal distribution show that return distribution exhibits fat tails, which the QQ-plots reveal are not 

symmetric. Oil prices show the greatest volatility and excess kurtosis, and the corresponding returns 

are positively skewed. This short but important preliminary descriptive and graphical analysis of the 

series indicates that the chosen statistical model should take into account the volatility clustering, fat 

tails and skewness features of the returns. 

4.2 Empirical Results 

Before investigating the impacts of oil price shocks on the stock market, we proceed to 

examine the stochastic properties of the series considered in the model by analyzing their order of 

integration on the basis of a series of unit root tests. Specifically, the Augmented Dickey-Fuller (ADF) 

and Kwiatkowski-Phillips-Schmidt-Shin (KPSS) tests are performed for the three sub-periods and the 

findings, summarized in Table 2, indicate that the first differences of all series are stationary, I(1) for 

all periods, allowing us to model the dynamic interactions with VAR model.  

 

 

 



Crude Oil Price Shocks and Stock Returns: Evidences from Turkish Stock Market under Global Liquidity 

Conditions 

 

 62 

Table 2. Unit Root Test Results
10

  

  Level  First Difference 

  ADF KPSS  ADF KPSS 

Brent Crude 

Oil 

Sub-Period I -2.760 0.603*  -17.905* 0.038 

Sub-Period II 0.272 0.429*  -38.524* 0.137*** 

Sub-Period III -5.120* 0.338*  -27.608* 0.289* 

Whole Period -2.852 1.341*  -11.308* 0.022 

ISE-100 

Sub-Period I -2.129 0.976*  -13.685* 0.035 

Sub-Period II -1.531 0.297*  -40.282* 0.136*** 

Sub-Period III -1.227* 0.407*  -12.278* 0.143*** 

Whole Period -2.157 1.434*  -14.754* 0.035 

VIX 

 

Sub-Period I -4.181* 0.901*  -19.364* 0.018 

Sub-Period II -2.002 0.802*  -17.837* 0.041 

Sub-Period III -2.726 0.277*  -8.907* 0.053 

Whole Period -5.046* 0.273*  -13.629* 0.014 

*,** and *** indicate the statistical significance at 1%, 5% and 10% level, respectively. 

 

As represented in equation system (4), VAR analysis is conducted on two types of oil price 

shock variables. In order to estimate  type shock variable, volatility of Brent crude oil returns is 

modeled with AR(1)-GARCH(1,1)
11

 specification and the test results are indicated in Table 3. All of 

the parameter estimates of the AR(1)-GARCH(1,1) model are found to be highly statistically 

significant. The persistence in volatility as measured by sum of  and  in GARCH model is closer 

to unity for each period. As shown in Table 3, the estimated  coefficient in the conditional variance 

equation is considerably larger than  coefficient. The implication is that the volatility is more 

sensitive to the previous forecast of volatility in the market place.  

 
Table 3. GARCH Variance Estimation Results 

 
     

Sub-period I 0.0001 0.0765* 0.0000* 0.8926* 0.1032* 

Sub-period II 0.0016* -0.0220 0.0000* 0.8620* 0.0400* 

Sub-period III 0.0009 0.0013 0.0000** 0.9328* 0.0600* 

Whole Period 0.0005** 0.0328** 0.0000* 0.9154* 0.0747* 

*,** and *** indicate the significance at 1%, 5% and 10% confidence level respectively. 

 

To check the performance of our model, ARCH-LM specification test was conducted on the 

normalized residuals, and there should be no ARCH effect left in the normalized residuals. Table 4 

reports ARCH-LM test results for all three sub-periods. The results indicate that no serial dependence 

persists left in squared residuals of Brent crude oil returns after volatility modeling for sub-periods I 

and III, and also for the whole period. Although test statistics for sub-period II rejects the null 

hypothesis of “no serial dependence between squared residuals”, it is statistically significant only at 

the 10% level of significance. Hence, the results suggest that AR(1)-GARCH(1,1) model is reasonably 

well specified to capture the ARCH effects.  

 

 

                                                 

10 
Note that null hypothesis (H0: unit root exists in time series) for ADF test is the alternative hypothesis (HA) 

for KPSS test. 
11 

Different AR(q)-GARCH(p,q) models were initially fitted to the data and compared on the basis of the Akaike 

and Schwarz Information Criteria (AIC and SIC) from which a AR(1)-GARCH(1,1) model was deemed most 

appropriate for modeling. The test results were not reported but they are available upon request from the authors. 



International Journal of Energy Economics and Policy, Vol. 5, No. 1, 2015, pp.54-68 

 

 

63 

Table 4. ARCH-LM Test Results 

 Constant Term Squared Residuals F-Statistics LM-Statistics 

Sub-period I 1.003 (0.0000) -0.004 (0.8280) 0.0472 (0.8280) 0.0473 (0.8279) 

Sub-period II 1.037 (0.0000) -0.041 (0.0986) 2.7306 (0.0986)* 2.7293 (0.0985)* 

Sub-period III 1.013 (0.0000) -0.010 (0.7773) 0.0801 (0.7773) 0.0803 (0.7769) 

Whole Period 1.006 (0.0000) -0.0072 (0.6026) 0.2712 (0.6026) 0.2712 (0.6025) 

Note: The numbers in parenthesis are p-values. * denotes rejection of null hypothesis at 10%. 

 

 Since the volatility modeling has significantly succeeded in capturing the oil prices variance 

to a significant degree, the GARCH model and derived residual terms were further used in equation 

(2) to calculate  data. Then we employed VAR framework as in equation system in (4) with 

ISE-100 daily returns and two of the oil price shock variables, log returns ( ) and , separately 

for each period. The results of Wald test for block significance and generalized variance 

decomposition of ISE-100 due to the oil price shocks are summarized in Table 5 and Table 6 

respectively. According to the block-significance test results, oil prices found to have a statistically 

significant impact on stock returns only during the last sub-sample period. Yet the impact is rather 

small as represented in variance decomposition results. 

 
Table 5. Block Exogeneity Wald Test Results for System in (4) 

 Implied Coefficient Restrictions  
-stat 

 
-stat 

Sub-period I , for  1.8095 1.5544 

Sub-period II 
 

1.3681 1.8308 

Sub-period III 
 

6.5633* 10.1163* 

Whole Period , for  4.3473 6.7199 

Note: AIC determines the lag-length for VAR model as 5 for the first sub-period, 1 for the second sub-period, 1 

for the third sub-period and 6 for whole period. *, ** and *** indicate the significance at 1%, 5% and 10% 

confidence level respectively. 

 

Table 6. Generalized Decomposition of Variance of ISE-100 in Response to Oil Price Shock Variables 

Days after 

Impulse 

Sub-period I Sub-period II Sub-period III Whole Period 

        

1 0.0000 0.0000 0.0000 0.0000 0.0000 0.0000 0.0000 0.0000 

2 0.0344 0.0258 0.0854 0.1144 0.8094 1.2432 0.0148 0.0011 

5 0.0486 0.0522 0.0861 0.1147 0.8098 1.2433 0.0148 0.0234 

10 0.0553 0.0593 0.0861 0.1147 0.8098 1.2433 0.0148 0.1322 

 

Moreover, in order to include global financial liquidity conditions into the analyses, VAR 

methodology between Brent crude oil prices and CBOE’s S&P 500 volatility index (Eq. 6) was used 

to capture the variance decomposition, which is provided in Table 7. Although the block-significance 

test results
12

 imply a unidirectional lead-lag relation between first difference of VIX and crude oil 

returns for all three sub-periods, it is only during the third sub-period that shocks from VIX create a 

comparatively higher variance on crude oil returns. On the other hand, regardless of the magnitude of 

the effect of global financial liquidity condition on variance of crude oil prices, it would still be 

                                                 

12
 According to the Block Exogeneity Wald Test, there exists a significant unidirectional causality from first 

difference of VIX to log-returns of Brent crude oil prices at 1% level for all three sub-periods. 



Crude Oil Price Shocks and Stock Returns: Evidences from Turkish Stock Market under Global Liquidity 

Conditions 

 

 64 

considered possible to be able to capture residuals for oil returns that will be used as oil market 

specific price shocks purified of global liquidity constraints. 

 
Table 7. Generalized Decomposition of Variance of Brent Crude Oil Returns in Response to Global 

Financial Liquidity 

Days after 

Impulse 
Sub-period I Sub-period II Sub-period III Whole Period 

1 0.0000 0.0000 0.0000 0.0000 

2 0.0912 0.6183 1.9680 0.1580 

5 0.3545 0.6482 2.6108 0.2253 

10 0.6819 0.6487 3.8427 0.3578 

Note: AIC determines the lag-length as 7 for the first sub-period, 4 for the second sub-period, 1 for the third sub-

period and 7 for the whole period. 

 

Once oil market specific shock, , and financial liquidity shock, , are captured by the 

disentangling methodology, they are considered as two separate variables, along with stock prices in 

the VAR framework. Therefore, we have also used this multivariate framework to investigate the 

interrelationship between ISE-100 returns, oil price shocks and global financial liquidity shocks for the 

whole periods. The results, which are provided in Table 8, imply that the global liquidity statistically 

increases the variance of ISE. 

 
Table 8. Block Exogeneity Wald Test Results for System in (6) 

 
Implied Coefficient 

Restrictions 
 

-stat 

Implied Coefficient 

Restrictions 
 

-stat 

Sub-period I , for  24.4151* , for  4.2867 

Sub-period II 
 

34.1651* 
 

1.4218 

Sub-period III 
 

95.7573* 
 

3.1124*** 

Whole Period , for  85.0101* , for  6.0041 

Note: AIC determines the lag-length as 6 for the first sub-period, 1 for the second sub-period, 1 for the third sub-

period and 6 for the whole period. *,** and *** indicate the significance at 1%, 5% and 10% confidence level 

respectively. 

 

Table 9. Generalized Decomposition of Variance of ISE-100 in Response to Oil Price Shock with Global 

Financial Liquidity 

Days after 

Impulse 

Sub-period I Sub-period II Sub-period III Whole Period 

        

1 0.0000 0.0000 0.0000 0.0000 0.0000 0.0000 0.0000 0.0000 

2 0.6894 0.0052 2.0763 0.0874 10.0515 1.7774 0.1153 0.0415 

5 0.7595 0.0259 2.1237 0.0897 10.3609 1.7871 0.1797 0.0884 

10 0.9007 0.1582 2.1237 0.0897 10.3609 1.7871 0.2186 0.1542 

 

According to the results from variance decomposition analyses, provided in Tables 6 and 9, 

three deductions can be made. First of all, the contribution of oil price shocks to the Turkish stock 

market is greater in the third sub-period than that of the first and second. This is an expected result 

such that, since oil prices move in a considerably more volatile manner in the third sub-period they 

create a higher impact on the ISE-100 returns. Secondly, the impact on variance decomposition starts 

with the second day of the impulse and dies out immediately without changing the structure of the 

trend of ISE-100. This may be the result of a non-linear relationship between oil prices and stock 

market returns, as proposed by prior researches (e.g. Arouri and Fouquau, 2009; Jawadi et al, 2010). 

Finally, the liquidity shock variable seems to be a considerable source of volatility for ISE-100 returns 



International Journal of Energy Economics and Policy, Vol. 5, No. 1, 2015, pp.54-68 

 

 

65 

during the third sub-sample period, contributing more than 10%. This means that liquidity shocks, 

rather than crude oil prices, are the primary factor in stock market movements.  

 

5. Discussions and Concluding Remarks  

In this paper, we have investigated the impacts of crude oil price variations on the Turkish 

stock market using structural vector autoregression (VAR) model for the period between January 2, 

1990 and November 1, 2011. ISE-100 index is used as a proxy for the performance of the Turkish 

stock market. The interactions between oil prices and ISE-100 have been analyzed by dividing this 

long time horizon into three sub-periods in order to test the response of Turkish stock market during 

different oil price regimes.  

The empirical results suggest that the oil price changes significantly and rationally affect the 

Turkish stock market activity during only the third sub-period, which begins after the credit-crunch of 

2008. Moreover, when the global financial liquidity conditions have been incorporated into the model, 

CBOE’s market volatility index (VIX), which is used as an indicator for global financial liquidity, has 

been found to significantly affect both oil prices and ISE-100 returns. In this trivariate VAR analysis 

results also suggest that the most significant impacts of global liquidity shocks on stock market returns 

occur in the third sub-period.  

The overall results suggest that the global financial liquidity conditions are the most plausible 

explanation for the changes in Turkish stock market returns. Although there exists some evidence that 

purified oil price shocks still have an impact on stock market returns, this effect is smaller and less 

significant than the liquidity constraints. This is an expected result provided that Turkish stock market, 

through widespread trade liberalization, has been attracting worldwide capital inflow, which makes it 

more vulnerable to shocks created in global financial markets. 

This study can be extended by obtaining a comparable firm-based dataset and by analyzing the 

behavior of each firm after oil price shocks. The empirical findings will prove to be extremely useful 

information to investors who need to understand the effect of oil price changes on certain stocks across 

industries, as well as for the managers of certain firms who require deeper insight into the 

effectiveness of hedging policies, which are affected by oil price changes. 

 

Acknowledgements 

The authors would like to thank to Prof. Felix Höffler, Prof. Oleg Badunenko, Prof. Adnan Kasman 

and the participants in the IAEE’s 33
rd

 International Conference for their helpful comments as well as 

to Simon Mumford for critically editing the manuscript.  

 

References 

Al-Mudhaf, A., Goodwin, T.H. (1993), Oil shocks and oil stocks: evidence from the 1970s. Applied 

Economics, 25(2), 181-190. 

Aloui, C., Jammazi, R. (2009). The effects of crude oil shocks on stock market shifts behaviour: A 

regime switching approach. Energy Economics, 31(5), 789-799. 

Apergis, N., Miller, S.M. (2009). Do structural oil-market shocks affect stock prices?. Energy 

Economics, 31(4), 569-575. 

Arouri, M.E.H., Fouquau, J. (2009). On the short-term influence of oil price changes on stock markets 

in GCC countries: linear and nonlinear analysis. Economics Bulletin, 29(2), 795-804. 

Arouri, M.E.H., Nguyen, D.K. (2010). Oil prices, stock markets and portfolio investment: Evidence 

from sector analysis in Europe over the last decade. Energy Policy, 38(8), 4528-4539. 

Basher, S.A., Sadorsky, P. (2006). Oil price risk and emerging stock markets. Global Finance Journal, 

17 (2), 224–251. 

Bernanke, B.S., Gertler, M., Watson, M. (1997). Systematic monetary policy and the effects of oil 

price shocks. Brookings Papers on Economic Activity, 1, 91-157.  

Bjørnland, H. (2009). Oil price shocks and stock market booms in an oil exporting country. Scottish 

Journal of Political Economy, 56(2), 232-254 

Bollerslev, T. (1986). Generalized autoregressive conditional heteroscedasticity. Journal of 

Econometrics, 31(3), 307-327. 



Crude Oil Price Shocks and Stock Returns: Evidences from Turkish Stock Market under Global Liquidity 

Conditions 

 

 66 

Boyer, M.M., Filion, D. (2009). Common and fundamental factors in stock returns of Canadian oil 

and gas companies. Energy Economics, 29(3), 428-453. 

Brown, S.P.A., Yucel M.K. (1999). Oil prices and U.S. aggregate economic activity: a question of 

neutrality.  Economic and Financial Review, 2nd Quarter, Federal Reserve Bank of Dallas, 16-

23. 

Brown, S.P.A., Yucel M.K. (2002). Energy prices and aggregate economic activity: an interpretative 

survey. Quarterly Review of Economics and Finance, 42(2), 193-208. 

Chen, S.S., Chen H.C. (2007). Oil prices and real exchange rates. Energy Economics, 29(3), 390-404. 

Chiou, J.S., Lee, Y.H. (2009). Jump dynamics and volatility: Oil and the stock markets. Energy, 34(6), 

788-796. 

Chortareas, G., Noikokyris, E. (2014). Oil Shocks, Stock Market Prices, and the US Dividend Yield 

Decomposition. International Review of Economics & Finance, 29, 639-649. 

Ciner, C. (2001). Energy shocks and financial Markets: Nonlinear linkages. Studies in Nonlinear 

Dynamics and Econometrics Quarterly Journal, 5(3), 203-212. 

Cong, R.G., Wei, Y.M., Jiao, J.L., Fan, Y. (2008). Relationship between oil price shocks and stock 

market: An empirical analysis from China. Energy Policy, 36(9), 3544-3553. 

Coudert, V., Mignon, V., Penot, A. (2008). Oil price and dollar. Energy Studies Review 15(2), 48-65 

Dickey, D., Fuller, W. (1979). Distribution of the Estimators for autoregressive time series with a unit 

root. Journal of the American Statistical Association, 74(366), 427-431. 

Dickey, D., Fuller, W. (1981). Likelihood ratio statistics for autoregressive time series with a unit 

root. Econometrica, 49(4), 1057-1071. 

Dickman, A., Holloway J. (2004). Oil market developments and macroeconomic implications. 

Bulletin, October 2004, Reserve Bank of Australia.  

El-Sharif, I., Brown, D., Burton, B., Nixon, B., Russell, A. (2005). Evidence on the nature and extent 

of the relationship between oil prices and equity values in the UK. Energy Economics, 27(6), 

819-830. 

Faff, R.W., Brailsford J.T. (1999). Oil price risk and the Australian stock market. Journal of Energy 

Finance and Development, 4(1), 69-87. 

Fan, Q., Jahan-Parvar, M.R. (2012). US industry-level returns and oil prices. International Review of 

Economics & Finance, 22(1), 112-128. 

Gao, W., Madlener, R. (1999). Oil price shocks and macroeconomic performance. HIS Newsletter, 8, 

1, 3. 

Gjerde, Ø., Sættem , F. (1999). Causal relations among stock returns and macroeconomic variables in 

a small, open economy. Journal of International Financial Markets, Institutions and Money, 

9(1), 61-74. 

Guo, H., Kliesen, K.L. (2005). Oil price volatility and U.S. macroeconomic activity. Review, Federal 

Reserve Bank of St. Louis, 84(6), 669-683. 

Hamilton, J.D. (1983). Oil and macroeconomy since World War II. The Journal of Political Economy, 

91(2), 228-248. 

Hamilton, J. D. (1996). This is what happened to the oil price-macroeconomy relationship. Journal of 

Monetary Economics, 38 (2), 215-220. 

Hamilton, J.D. (2003). What is an oil shock?. Journal of Econometrics, 113(2), 363-398. 

Hamilton J.D., Herrera A.M. (2004). Oil shocks and aggregate macroeconomic behavior: The role of 

monetary policy. Journal of Money, Credit and Banking, 36(2), 265-286.  

Hammoudeh S., Aleisa E. (2004). Dynamic relationships among GCC stock markets and NYMEX oil 

futures. Contemporary Economic Policy, 22(2), 250-269. 

Henriques, I., Sadorsky, P., 2008. Oil prices and the stock prices of alternative energy companies. 

Energy Economics, 30(3), 998-1010. 

Huang, R.D., Masulis, R.W., Stoll, H.R. (1996). Energy shocks and financial markets. Journal of 

Futures Markets, 16(1), 1-27. 

Huang, B., Hwang, M.J., Hsiao-Ping, P. (2005). The asymmetry of the impact of oil price shocks on 

economic activities: an application of the multivariate threshold model. Energy Economics, 

27(3), 455-476. 



International Journal of Energy Economics and Policy, Vol. 5, No. 1, 2015, pp.54-68 

 

 

67 

Huntington, H.G. (1998). Crude oil prices and U.S. economic performance: Where does the 

asymmetry reside? Energy Journal, 19(4), 107-132. 

Jammazi, R., Aloui, C. (2010). Wavelet decomposition and regime shifts: Assessing the effects of 

crude oil shocks on stock market returns. Energy Policy, 38(8), 4528-4539. 

Jammazi, R. (2012a). Oil Shock transmission to stock market returns: Wavelet-multivariate Markov 

switching GARCH approach. Energy, 37(1), 430-454. 

Jammazi, R. (2012b). Cross dynamic of oil-stock interactions: A redundant wavelet analysis. Energy, 

44 (1), 750-777. 

Jawadi, F., Arouri, M.E.H., Bellalah, M. (2010). Nonlinear linkages between oil and stock markets in 

developed and emerging countries. International Journal of Business 15(1), 19-31. 

Jones, C.M., Kaul, G. (1996). Oil and the stock markets. The Journal of Finance, 51(2), 463-491. 

Kahn, G.A., Hampton, R. (1990). Possible monetary policy responses to the Iraqi oil shock. Economic 

Review, Federal Reserve Bank of Kansas City, 19-32. 

Kilian, L. (2008). The economic effects of energy price shock. Journal of Economic Literature, 46(4), 

871-909. 

Kilian L. (2009). Not all oil price shocks are alike: Disentangling demand and supply shocks in the 

crude oil market. The American Economic Review, 99(3), 1053-1069. 

Kilian, L., Park, C. (2009). The impact of oil price shocks on the U.S. stock market. International 

Economic Review, 50(4), 1267-1287. 

Kwiatkowski, D., Phillips, P.C.B., Schmidt, P., Shin, Y. (1992). Testing the null hypothesis of 

stationarity against the alternative of a unit root. Journal of Econometrics, 54(1-3), 159-178. 

Lee, K., Ni, S., Ratti, R.A. (1995). Oil shocks and the macroeconomy: The Role of Price Variability. 

The Energy Journal, 16(4), 39-56. 

Maghyereh, A. (2004). Oil price shocks and emerging stock markets: a generalized VAR approach. 

International Journal of Applied Econometrics and Quantitative Studies, 1(2), 27-40. 

Mork, K.A. (1989). Oil and the macroeconomy when prices go up and down: An extension of 

Hamilton's results. The Journal of Political Economy 97(3), 740-744. 

Naifar, N., Al Dohaiman, M.S. (2013). Nonlinear analysis among crude oil prices, stock markets' 

return and macroeconomic variables. International Review of Economics & Finance, 27, 416-

431.  

Nandha, M., Faff, R. (2008). Does oil move equity prices? A global view. Energy Economics, 30(3), 

986-997. 

Narayan, P.K., Narayan, S. (2010). Modelling the impact of oil prices on Vietnam’s stock prices. 

Applied Energy, 87(1), 356-361. 

Obernfender, U. (2009). Energy prices, volatility, and the stock market: Evidence from the Eurozone. 

Energy Policy, 37(12), 5787-5795. 

Oladosu, G. (2009). Identifying the oil price-macroeconomy relationship: An empirical mode 

decomposition analysis of US data. Energy Policy, 37(12), 5417-5426. 

O'Neill, T.J., Penm, J., Terrell, R.D. (2008). The role of higher oil prices: a case of major developed 

countries. Research in Finance, 24, 287-299. 

Papapetrou E. (2001). Oil price shocks, stock market, economic activity and employment in Greece. 

Energy Economics, 23(5), 511-532. 

Park, J., Ratti, R.A. (2008). Oil price shocks and stock markets in the U.S. and 13 European countries. 

Energy Economics, 30(5), 2587-2608. 

Reboredo, J.C., Rivera-Castro, M.A. (2014). Wavelet–based evidence of the impact of oil prices on 

stock returns. International Review of Economics & Finance, 29, 145-176  

Rogoff, K. (2006). Oil and the global economy. Manuscript. Harvard University. Available at: 

http://www.nes.ru/publicpresentations/Papers/Oil%20and%20the%20Global%20Economy_Rog

off__v2.pdf 

Sadorsky, P. (2001). Risk factors in stock returns of Canadian oil and gas companies. Energy 

Economics, 23(1), 17-28.  

Sill, K. (2007). The macroeconomics of oil shocks. Federal Reserve Bank of Philadelphia Business 

Review, Q1, 21-31. 

Sims, C.A. (1980). Macroeconomics and reality. Econometrica, 48(1), 1-48. 

http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6V84-4D5KY1S-1&_user=4366190&_coverDate=11%2F30%2F2004&_rdoc=1&_fmt=high&_orig=search&_sort=d&_docanchor=&view=c&_searchStrId=1240497409&_rerunOrigin=google&_acct=C000063020&_version=1&_urlVersion=0&_userid=4366190&md5=ebe181a6aa9625add0fc52c50245af44#bbib8#bbib8


Crude Oil Price Shocks and Stock Returns: Evidences from Turkish Stock Market under Global Liquidity 

Conditions 

 

 68 

Soytaş, U., Oran, A. (2011). Volatility spillover from world oil spot markets to aggregate and 

electricity stock index returns in Turkey. Applied Energy, 88(1), 354-360. 

Zarour, B.A. (2006). Wild oil prices, but brave stock markets! The case of GCC stock markets. 

Operational Research: An International Journal, 6(2), 145-162. 

 


	Crude Oil Price Shocks and Stock Returns:
	Evidences from Turkish Stock Market under Global Liquidity Conditions