Asymmetric market efficiency of the Eurozone using the MF-DFA: a comparison between global financial crisis and COVID-19 era

Sajid Ali (Iqra University, Karachi, Pakistan)
Syed Ali Raza (Iqra University, Karachi, Pakistan)
Komal Akram Khan (Iqra University, Karachi, Pakistan)

European Journal of Management and Business Economics

ISSN: 2444-8451

Article publication date: 12 June 2023

1019

Abstract

Purpose

This research paper aims to explore asymmetric market efficiency of the 13 Euro countries, i.e. Austria, Belgium, Finland, France, Germany, Greece, Ireland, Italy, Netherland, Portugal, Slovakia, Slovenia and Spain, concerning the period before global financial crisis (GFC), after GFC and period of COVID-19 pandemic.

Design/methodology/approach

Multifractal detrended fluctuation analysis (MF-DFA) is applied to examine the persistence and anti-persistency. It also discusses the random walk behavior hypothesis of these 13 countries non-stationary time series. Additionally, generalized Hurst exponents are applied to estimate the relative efficiency between short- and long-run horizons and small and large fluctuations.

Findings

The current study results suggest that most countries' markets are multifractal and exhibit long-term persistence in the short and long run. Moreover, the results with respect to full sample confirm that Portugal is the most efficient country in short run and Austria is the least efficient country. However, in long run, Austria appeared to be highly efficient, and Slovakia is the least efficient. In the pre-GFC period, Greece is said to be the relatively most efficient market in the short run, whereas Austria is the most efficient market in the long run. In the case of Post-GFC, Netherland and Ireland are the most efficient markets in short and long run, respectively. Lastly, COVID-19 results indicate that Finland's stock market is the most efficient in short run. Whereas, in the long run, the high efficiency is illustrated by Germany. In contrast, the most affected stock market due to COVID-19 is Belgium.

Originality/value

This study will add value to the present knowledge on efficient market hypothesis (EMH) with the MF-DFA approach. Also, with the MF-DFA approach, potential investors will be capable of ranking the stock markets of Eurozone countries based on their efficiency in the period before and after GFC and then specifically in the period of COVID-19.

研究目的

本研究旨在探討13個歐元區國家在環球金融危機前後, 以及2019新型冠狀病毒病肆虐時期之不對稱市場效率; 這13個國家包括: 奧地利、比利時、芬蘭、法國、德國、希臘、愛爾蘭、義大利、荷蘭、葡萄牙、斯洛伐克、斯洛維尼亞和西班牙。

研究設計/方法/理念

研究人員使用多重分形去趨勢波動分析法、來探討持續性與反持續性。這分析法也用來討論正在研究中的13個國家的非平穩時間序列的隨機漫步假說; 而且, 廣義赫斯特指數被用來估算長期/短期投資與大/小波動之間的相對效率。

研究結果

研究結果間接表明了大部份國家的市場都是多重分形的; 而且, 它們無論以短期抑或以長期來審視觀察, 均能展示持久性。再者, 就整體樣本而言, 研究結果確認了在短期來看, 葡萄牙是效率最高的國家, 而奧地利則效率最低。唯以長期來審視觀察, 奧地利則似乎效率很高, 而效率最低的則是斯洛伐克。在環球金融危機爆發前, 就短期而言, 希臘被認為是相對效率最高的市場, 而長期而言, 效率最高的則是奧地利。至於在環球金融危機爆發後, 就短期而言, 荷蘭是效率最高的市場, 而就長期而言, 效率最高的則是愛爾蘭。最後, 2019新型冠狀病毒病的結果顯示, 就短期而言, 荷蘭的股票市場是效率最高的, 而長期而言, 德國則展示了其高效率性。而受疫情影響最大的股票市場則是比利時。

研究的原創性/價值

研究採用了多重分形去趨勢波動分析法、來探討股票市場的效率, 並以此分析法來討論有關國家的非平穩時間序列的隨機漫步假說, 這使我們對效率市場假說有進一步的認識; 就此而言, 本研究為有關的探討增添價值; 而且, 有意投資者在使用多重分形去趨勢波動分析法下, 能夠基於歐元區國家的股票市場在環球金融危機前後, 以及更明確地在2019新型冠狀病毒病肆虐時期的效率, 來把這些股票市場分等級。

關鍵詞

環球金融危機、2019新型冠狀病毒病、效率市場假說、多重分形去趨勢波動分析.

Keywords

Citation

Ali, S., Raza, S.A. and Khan, K.A. (2023), "Asymmetric market efficiency of the Eurozone using the MF-DFA: a comparison between global financial crisis and COVID-19 era", European Journal of Management and Business Economics, Vol. ahead-of-print No. ahead-of-print. https://doi.org/10.1108/EJMBE-04-2021-0116

Publisher

:

Emerald Publishing Limited

Copyright © 2023, Sajid Ali, Syed Ali Raza and Komal Akram Khan

License

Published in European Journal of Management and Business Economics. Published by Emerald Publishing Limited. This article is published under the Creative Commons Attribution (CC BY 4.0) licence. Anyone may reproduce, distribute, translate and create derivative works of this article (for both commercial and noncommercial purposes), subject to full attribution to the original publication and authors. The full terms of this licence may be seen at http://creativecommons.org/licences/by/4.0/legalcode


1. Introduction

The global financial crisis (GFC) and COVID-19 share uncertainty as a significant element after originating in one of the two leading economies (the USA in 2008 and China at the end of 2019). Moreover, both crises severely affect the stock markets, resulting in an economic downturn. Hence, there is a need to consider both situations collectively to analyze the efficiency of stock markets. Therefore, to explore the financial markets' efficiency, a new concept, the efficient market hypothesis (EMH), has been introduced; it has become the investor's favorite device to understand any financial market's quality and efficiency. According to Fama (1970), an efficient market (even in its weak form) is if prior information enclosed in price movements is entirely explained in the current prices. Therefore, it is challenging for investors to earn abnormal profits and predict prices based on past statistics. Further, if an efficient market exhibits random walk behavior, the new information is more likely to lessen or exaggerate the prices in an inefficient market, resulting in a severe impact on efficient resource allocation (Ali et al., 2018; Mensi et al., 2017).

The EMH has a significant role in financial literacy in understanding financial markets' behavior and performance. As per the EMH theory presented by “Fama (1970), 1998”, any sensible investor can forecast market efficiency with a given market's share price index information. It further stated that if the asset price rapidly shows variation due to the current relevant market information or the asset price is market sensitive, such a market is called a weak-form efficient market. It is not easy for investors to procure abnormal profit in a given situation because of asset price fluctuation, and no one can predict market price and condition. So, the validity of EMH suggests that it is the primary key to predicting such probable gain. There are three significant well-known market situations depending on the market behavior: bear, standard and bull markets. In a stock market, no one can predict the investor's behavior. However, in the other two bear and bull markets, investors' behavior can easily be examined as either aggressive “Greed” or defensive “Fear.” In these risky situations, investors can make irrational decisions due to herding behavior, resulting in a variation in stock prices and economic features (Baker and Wurgler, 2006). Many global and regional black swan events have recently distressed the global markets. In discussed techniques, market crashes can occur directly, while the rise in the stock price over a long time confirms asymmetric effects in stock markets (Ni et al., 2015).

Share price indices measure the variation in the stock's value; it states the investor's return on their investment and expresses the variation in the market capitalization. The stock market is a complicated and dynamic structure sensitive to various internal and external variables (Boubaker and Raza, 2017). Exchange institutes and investors are the primary sources of internal influences. Further, external factors that make stock market vulnerable are policies and changes by the governments (Raza and Jawaid, 2014). Also, some crucial events play a major role in affecting stock markets (Mensi et al., 2022). Several researchers have inspected the influence of important events, such as crises, on the stock market's efficiency (Anagnostidis et al., 2016; Mensi et al., 2017; Tiwari et al., 2018). Managi and Okimoto (2013) declared that abrupt “big” shocks, like GFC of 2008, generate structural changes in financial and commodities markets that might result in asymmetric impacts on market efficiency, volatility spillovers and portfolio allocations. Hence, it stimulates the importance of exploring the GFC and COVID-19 effects on the efficiency of these markets. Therefore, in this study, the EMH concept is tested on 13 Eurozone countries with the support of MF-DFA recommended by Kantelhardt et al. (2002). The roles of GFC and COVID-19 have been investigated to reflect these countries' stock markets' efficiency by using share price indices data. That is a more flexible and efficient approach than other approaches of analyzing the multifractal (long-term persistent) features of time series having non-stationary properties (Mensi et al., 2017; Bouoiyour et al., 2018).

We have divided the contribution of current study into multiple roles; first of all, this study will add value to the present knowledge on EMH via the estimation of the MF-DFA approach. As the name implies, MF-DFA is based upon the combination of the following two procedures, i.e. “multifractal methods (MF) and detrended fluctuation analysis (DFA).” Mandelbrot et al. (1997) considered the MF method a monofractal approach. Conversely, Chen et al. (2002) state that DFA is useful in assessing noisy time series and non-stationary long-term correlations, hence, said to detect monofractal scaling technique. Horvatic et al. (2011) claim that the MF-DFA approach expands Kantelhardt et al. (2002) DFA method. In this way, it assists in exploring stochastic process's multifractal spectrum for a financial time series (Raza et al., 2021). Some other benefits are: “removal of the monofractal and multifractal behavior of the financial data, assessment of volatility's long-run correlations, degree of time-varying efficiency, and predictability of financial series.” Furthermore, this method provides a valid multifractal classification of non-stationary multifractal financial time series. Such attributes of MF-DFA are said to be more interesting than other econometrics approaches. In present research, MF-DFA contributes to the information concerning range memory, random walk behavior, degree of persistency and Eurozone's market efficiency. Secondly, the application of the MF-DFA approach will make potential investors capable enough to rank the stock markets of these Eurozone countries based on their efficiency in the following periods: full sample, pre and post-GFC and period of COVID-19. Thirdly, 13 European countries for the analysis have been targeted. However, prior research by Cao et al. (2013) is based on a similar approach, but a point of difference is the selected country. Moreover, prior authors employed MFDFA in analyzing Shenzhen and Shanghai stock markets concerning asymmetric multifractal scaling behavior.

2. Literature review

The literature includes various studies which have explored the efficiency of different markets through MF-DFA. For instance, research conducted by (Tiwari et al., 2018) focused on eight developed countries for investigating their efficiency. The authors employed “the MF-DFA approach” and observed that most markets were highly efficient in the long run. Furthermore, Rizvi et al. (2014) claimed that progressive markets are highly efficient; hence, less efficient are the Islamic states' markets. Different results were found by Ali et al. (2018) that Islamic markets are found to be more efficient than conventional ones after using the MF-DFA method. Arshad et al. (2016) selected the “Organization for Islamic Conference (OIC)” countries and explained that complete efficiency is different across the OIC based on the MF-DFA approach. Stakić et al. (2016) examined that the stock market is inefficient after using daily return data from 2006 to 2013. Anagnostidis et al. (2016) revealed a significant mean-reverting behavior established after the crisis, and markets are near to random walk behavior before crises.

Rizvi and Arshad (2017) claimed that Japanese stock markets were most efficient during the global crisis period. Moreover, Dow Jones Islamic stock index sectors were targeted by Mensi et al. (2017) for testing these markets' efficiency and multifractality. For this purpose, the authors employed MF-DFA. The results indicate that in the long term, efficiency is higher and time-varying. Cao et al. (2013) targeted China for the examination of stock markets' uptrend and downtrend multifractality. Thus, the authors used asymmetric MF-DFA. The analysis reveals that uptrends have stronger multifractality than downtrends. In the literature, some studies are available that used the same method in the cryptocurrency, gold, green bonds and conventional bond markets. Such as, Al-Yahyaee et al. (2018) emphasize Bitcoin, gold, currency (USD index) and world stock markets' long memory and efficiency. Authors found that long memory and multifractality are present in all investigated return series, and these features are more prominent in the Bitcoin market than in other traditional markets. Likewise, green and conventional bond markets' efficiency was studied by (Naeem et al., 2021). The authors divided the analysis into two periods, i.e. pre and during the pandemic of COVID-19. Hence, to meet this goal, the authors employed the approach of MF-DFA.

Literature consists of several studies that inspect the impact of GFC on market efficiency. For instance, the research investigated 15 emerging European stock markets for their efficiency (Smith, 2012). The results exhibit a severe influence of GFC on the stock markets' efficiency. Kumar and Deo (2013) emphasize the effects of GFC (pre and during crisis) on twenty international financial indices using MF-DFA. It was disclosed that some indices hold significant discrepancies in multifractal degrees in both periods. Majumder (2012) in the context of US and BRICS markets, reveals that before the period of GFC, the US market was highly efficient than others but became inefficient after the crisis. Finally, Mensi et al. (2017) considered Islamic stock markets to test the effect of GFC. They employed the MF-DFA approach to examine the efficiency of these markets in the short and long run and concluded that after GFC, most of the markets' efficiency was weakened.

Further, Adu et al. (2015) targeted the BRICS countries' stock returns and concluded that China and India's stock markets do not depend on the unit of measurement; on the contrary, Brazil and South Africa's market prediction is dependent on the unit of measurement. Sensoy et al. (2015) explored that conventional equity markets are found to be highly efficient than Islamic equity markets. GFC and the succeeding Eurozone sovereign debt crisis underline the higher level of dependency among markets and reveal a degree of asymmetry that exists internally and among markets.

3. Methodology

The share price indices data from June 1994 to August 2022 is used to examine the efficiency of the markets of 13 Euro area countries. The research further divided the full sample into pre-GFC post-GFC and COVID-19 periods.

3.1 Multifractal detrended fluctuation analysis

The two most used methods in the literature are MF-DFA and MF-DCC, but MF-DFA is the most effective and better approach (Shahzad et al., 2017). To detect the scaling behavior that has multifractal features in non-stationary time series, MF-DFA is a better technique. In addition, this method delivers evidence on the long-term memory, level of persistency and efficiency of stock markets. Previously rescaled range analysis “R/S” was used to analyze the long-range correlation behavior of non-stationary time series. However, MF-DFA is a better tool than rescaled range analysis because it avoids the miscalculation of correlation. Furthermore, to analyze the persistence, anti-persistency in the series (mean-reverting process) and random walk behavior, MF-DFA is a better method.

The MF-DFA approach developed by Kantelhardt et al. (2002) is applied to examine Eurozone countries' market efficiency. MF-DFA is comprised of five steps as follows.

Let “{Xt,t = 1, ….,N}” be a time series.

  • Step1. Define the profile

(1)Ykkt=1[xix¯],k=1,,N,
Where x represents the average of the entire time series.
  • Step2. Divide the profile “yi” into “Nsf (N/s)” non-overlapping segment windows of equal length s.

  • Step 3. Compute the local trend for each of the two N’s by the least-squares fit of the series and calculate variance:

(2)F2(s,v)=1ssi=1{y[(v1)s+i]yv(i)}2

For “v = 1,2, ….,Ns,” and

(3)F2(s,v)=1ssi=1{y[N(vNs)s+i]yv(i)}2

For v = Ns +1, …,2Ns.

  • Step 4. The “qth order fluctuation function “Fq(s)” is determined by averaging all segments.

(4)Fq(S)={12Ns2Nsv=1[F2(s,v)]q2}1q
  • Step 5. Define the scaling behavior of fluctuation functions by analyzing log-log plots “Fq(s)” versus s for each level of “q.”

If there is a correlation between the series “xi” in the long term, then “Fq(s)” increases for large values of s, according to power law:

(5)Fq(S)Sh(q)

In general, “h(q)” the exponent describes the criteria for whether the time series is monofractal or multifractal; if “h(q)” is not dependent on q, time series is monfractal otherwise multifractal when “h(q)” is dependent on “q,” meaning that the small variation “(q < 0)” and large variation “(q > 0)” of scaling behavior is different. Where “h(q)” is a generalized Hurst exponent, when in the case of stationary series, “h (2)” is the same as the well-known Hurst exponent(H). To examine the correlation in the time series, the scaling exponent “h (2)” is used when “h (2) = 0.5”. It explains that series are not correlated and follow a random walk process when “0.5< h (2) <1” indicates long-term persistence series (long-memory), and “0< h (2) >0.5” shows anti-persistence series (mean-reverting process).

4. Empirical results

4.1 Preliminary analysis

Descriptive statistics are explained in Table 1. The results depict that the Jarque-Bera time series of all countries is not normally distributed, indicating the properties of high-pitched peaks and fat-tailed distributions. Furthermore, Augmented Dickey and Fuller's (1979) analysis indicates that all series are stationary at a 1% level of significance. Skewness and Kurtosis results of all series show asymmetry and leptokurtic series.

4.2 Multifractal detrended fluctuation analysis (MF-DFA)

The share price indices' fractal properties are explained by a log-log plot on the length scale and the order of fluctuation effect. A scaling range is vital to decide a linear behavior, as it axes on both lower and upper limits. The current study scaling behavior of the given share price indices is exhibited in Figure 1(a–m). It is clear from these figures that the local slope of these 13 countries' plots changes with crossover time scale (logs*) = 3.3 in the case of overall data of all 13 countries, but in this study, we are also analyzing the effect of the GFC, in case of before GFC the crossover time scale for all countries is logs* = 3.9 except in case of Austria, Belgium, France and Germany where crossover time scale logs* = 3.7, but after GFC the crossover time scale for all countries is same that is logs* = 3.3. The crossover point varies at a different time of scale because of the unlike properties of time series. This is the case of two different time scales of stock markets one is the short-run component when s* < s, and the other is the case of the long-run component when s* > s; the MF-DFA approach is used to stud these two-time scales of the stock market of selected 13 Eurozone countries. The q-order Hurst exponent graphs of all 13 countries exhibit proof of multifractality in the time series of these selected countries as h(q) vary with the variation in (q), and there is a decreasing trend in the case of this sample size. The multifractal spectrum graph shows the large arc for the multifractal time series and the small for the monofractal time series. This graph also calculates the amplitude of the fractal spectrum as it is the difference between hqmaxi and hqmini; in our case, Slovakia has the most massive multifractal strength (0.45), and Greece the least multifractal strength (0.31).

4.2.1 Discussion of full sample results

Output Table 2 represents the slopes of generalized Hurst exponents h(q). The upper bound for q is 5, and the lower bound for q is −5 for large fluctuations q > 0 and small fluctuations q < 0. Moreover, h(q) is not constant and dependent on q, showing that all 13 countries' share price indices have multifractal properties. h(q) explains the scaling behavior of these countries with small and large fluctuations. Further, h(q) for q < 0 is higher than h(q) for q > 0. This scaling behavior is explained by the stock markets of these 13 countries, estimating long-memory features better in short-term fluctuations than in long-term fluctuations. All h(q) is more significant than 0.5 in both small and large fluctuation, i.e. “q < 0 (q > 0),” which shows long-term persistence in stock markets of all selected countries. At q = −5, Austria is the most constant stock market in the short run, with the series' highest h(q) value (4.021). Greece, in the long run, is chiefly the persistent market with the highest h(q) value (1.019) of the series, and as the h(q) value in both cases exceeds 0.5, both countries are showing more substantial long-term persistence in the short run. To predict the long-term or large fluctuation, we focused on q = 2, clearly showing deviation from random walk behavior as all h(q) values are different from 0.5; the same is the case; in the long run, all countries series show long-term persistence as all h(q) are more significant than 0.5. The results of prior literature (Mensi et al., 2019) and (Sensoy and Tabak, 2015) depict similar results. According to Sensoy and Tabak (2015), the literary discourse on random walk behavior has shown negative autocorrelations in the long term. Consequently, in the long run, stock market returns are mean-reverting. Further, in previous studies, it has been found that all series exhibit multifractality; hence, if we compare short and long fluctuations, it is revealed that multifractality is more prominent in short fluctuations than long. It is concluded that investors can predict their future returns based on MF-DFA results, as in our study, most of the countries' markets are presenting long-term persistence. It implies that these markets will be positive in the future if, currently, their returns are complimentary. However, it is also dependent on countries' economic conditions.

4.2.2 Discussion of GFC and COVID-19 results

In Table 3 at q = −5, all countries show long-term persistence in the short and long run. Austria has the largest (q) value, the most persistent in the short run, and Portugal has the highest h(q) value, the most persistent in the long run. However, in case of large fluctuation when q = 2, all countries have long term persistence except Austria and Slovenia; both countries are mean-reverting or anti-persistence in the long term as h(q) < 0.5, which shows that future returns of these two markets are capable of returning to a long-term mean. In the case of Austria and Slovenia, their market scaling behavior is anti-persistence. These results align with past studies' results (Smith, 2012; Sensoy and Tabak, 2015). The findings of Smith (2012) claimed that in the case of the following stock markets “Croatian, Hungarian, Polish, Portuguese, Slovakian, and UK,” GFC is highly linked with return predictability. Moreover, the following stock markets “Greece, Latvia, Romania, Russia, and Turkey” observe a minor influence of crisis on weak-form efficiency. Authors also claim that the efficiency of “Croatia, Estonia, Slovenia, and Portugal markets” has deteriorated badly because of the crisis.

Table 4 portrays that at q = −5 in the short-term fluctuation, Slovakia is the most persistent country in both the short and long run. At q = 2 in the case of long-term fluctuation, most of the countries are showing long term persistency having h(q) > 0.5 except Belgium, Finland, France, Germany, Ireland and Italy. While the Netherlands is showing short-term persistence in both the short and long run as h(q) is less than 0.5, these countries' market returns will be negative in the future if it is currently positive. Only two countries' markets show anti-persistent or malicious autocorrelation behavior; after the GFC, seven countries' markets exhibit anti-persistent autocorrelation. These markets' anti-persistent behavior makes it easier for investors to predict the stock return and earn the abnormal profit (Tiwari et al., 2017). A study by Hasan and Mohammad (2015) revealed that during the post-crisis era, a decline was observed in multifractality indices of all markets, with the exception of the Malaysian market. Another research by Anagnostidis et al. (2016) claimed that after GFC, anti-persistent behavior had been observed in Spain and France's stock price movements. Also, scholars observed improvement in the post-crisis period instead of the availability of significant mean-reverting patterns. In contrast, across the sample period, Germany, Netherlands, Greece and Italy were considered to be weak-form efficient.

The outcomes of the COVID-19 period are illustrated in Table 5. We identified that at q = −5, Belgium has the largest (q) value, the most persistent in the short and long run. Nevertheless, at q = 2 in the case of long-term fluctuation, most of the countries are showing long term persistency having h(q) > 0.5 except Austria, Belgium and Ireland, presenting short-term persistence in the long run. While France is showing short-term persistence in the short run as h(q) is less than 0.5, these countries' market returns will be negative in the future if it is currently positive. Hence, results confirm that in COVID-19 period, the stocks of Belgium and France are most fluctuating. The results are in line with the findings of Abuzayed et al. (2021) and Khattak et al. (2021). The prior studies also claim that in the times of COVID-19, Belgium, the UK and France are the most incremental systemic risk receivers. Hence, the stock markets are adversely exposed to the emergence of the deadly coronavirus. Due to COVID-19, the GDP of Belgium declined by 6.3% in 2020. The economic failure because of COVID-19 outbreak is the greatest yearly GDP decline ever observed in Belgium after Second World War. This is significantly larger than the drop observed during the GFC. At that time, GDP declined by a “mere” 2% in 2009 after having risen by 0.4% in 2008. Further, Sami and Abdallah (2021) claims that stock market returns are highly volatile. Also, as per the statistics, the most crucial stock of France, i.e. CAC 40, witnessed a fall of 37% from its highest value. In a nutshell, the stock markets of Belgium and France witnessed a downturn.

4.2.3 Ranking efficient markets

The next step in MF-DFA is to rank the efficient markets based on the market deficiency measure (MDM) score .

Table 6 illustrates country's rank based on the efficiency of the market both in the short run and in the long run. The most efficient market has an MDM value equal to zero, while the less efficient market has a higher MDM value (Mensi et al., 2017). According to the MDM ranking, Portugal is the most efficient market, with the lowest MDM value (1.277), and Austria, with the highest MDM value (2.3838), is the most inefficient market in the short and long run. Austria is the most efficient market after having the lowest MDM value (0.5689), and Slovakia is the most inefficient market in the long run, with the highest MDM value (0.899).

According to the given output of MDM ranking before the GFC of 2007–2008, Greece is the most efficient market with the lowest MDM value (0.847) in the short run. On the other hand, Austria is the most efficient market in the long run after having the lowest MDM value (0.5499). In GFC, the Netherlands is the most efficient market having the lowest MDM value (0.744), and Ireland is the most efficient market in the long run based on MDM value (0.4452). Simultaneously, Austria and Slovakia are the most inefficient markets before and after GFC, both in the short and long run. In COVID-19, Finland is the most efficient market as MDM value is (1.3071) in the short run. The second most efficient is Germany (1.4245). Conversely, in long run, the most efficient market is Germany (0.5512) which is followed by Austria with an MDM value of (0.5783). However, in the short run, Belgium (4.4943) and France (2.8755) are appeared to be the least efficient. Likewise, the least efficiency is exhibited by Belgium (1.5974) in long run. Also, the results depict that the stock markets of Belgium and France are highly fluctuating, making markets inefficient in the short and long run. Finally, we suggest that the investors should invest in the markets with the lowest MDM value to earn abnormal profit as these stock returns are predictable.

5. Conclusion

This research explores asymmetric market efficiency of the 13 Euro countries concerning the period before GFC, after GFC and the period of COVID-19 by employing MF-DFA. Further, it aims to explore the efficiency of markets based on MDM scores. The findings suggest that efficiency in these markets varies over time. It implies that all markets possess multifractal properties. These markets are not deteriorating efficiently over time, and all markets reject the hypothesis of random walk behavior. Further, developed economies' market behavior is more toward stability, but emerging economies' behavior is less stable. This study's implication is for investors to earn abnormal profits and help predict the future returns of anti-persistent markets. It will assist these countries' economies in the implementation of relevant regulations on stock markets. It is crucial to have in-depth knowledge about stock indices, and in which particular sector the development of speculative bubbles is more likely to appear. Eurozone markets play a major role in crisis; hence, a comprehensive understanding of their behavior is necessary. More importantly, it is suggested that policymakers should start enforcing laws and legislation to improve the efficiency of these markets and strengthen local and international investors' confidence in them.

The results indicate that only two countries' markets show anti-persistent or negative autocorrelation behavior; after GFC, seven countries' markets exhibit anti-persistent autocorrelation. These markets' anti-persistent behavior provides ease to investors to predict the stock return and earn abnormal profit. Based on the MDM ranking, it is concluded that Portugal is the most attractive market and Austria is the least attractive market in terms of future return in the short run. However, Austria is the most favorable market for investors in the long run, and Slovakia is the least efficient market.

According to the results of the before-GFC period, Greece is the most favorable market, and again Austria is the least significant market for future returns in the short run. Whereas, in the long run, Austria is the most efficient market for investors in terms of their efficiency, and Slovakia is the least preferred market for investors before the GFC of 2007–2008. After GFC, the MDM ranking tells a different story, as the Netherlands is the most significant market in the short run, and Ireland is the most efficient in the long run from an investing point of view. However, Austria and Slovakia are still the least efficient markets in the short and long run, consistently before and after the financial crisis.

During the period of COVID-19, the discovered results are surprising and different from the full sample and GFC pre and post-periods. As per the outcomes of Generalized Hurst exponents during COVID-19 sample for short and long term components and market efficiency, the most fluctuating stocks are of Belgium and France in long and short run. Most importantly, Belgium's stock markets appear to be highly fluctuating, hence, making the market least efficient in short and long run. Moreover, France is also the second least efficient market in short run. Conversely, the most efficient market in the times of COVID-19 is Finland and Germany in the short and long run, respectively. The reason for the sudden change in the results is the robust role of COVID-19.

These vibrant market conditions of 13 countries can be defined in bear markets, such as markets with low growth opportunities and bull markets having high growth opportunities, and regular markets with stable conditions. These market conditions are persistent. Our study results can divide these 13 countries into different segments, as we have incorporated the crucial role of the GFC and COVID-19 in the stock markets of 13 Eurozone countries. Countries showing long-term persistence can be viewed as regular markets or bull markets, and countries showing anti-persistent behavior can be viewed as bear markets. However, again, it also depends on the country's economic condition, and the occurrence of any black swan event that may alter the condition, such as an outbreak of coronavirus, has affected the global markets adversely. Although it started in China gradually, unfortunately, it has spread worldwide and upset the world economy.

6. Future recommendations

We recommend the scholars: (1) to conduct a comparative study by considering the data of different economies. For instance, comparison between China–USA, BRICS countries, developed-developing economies, European-Asian countries and Islamic countries. It will provide a novel idea of how different economies respond to GFC and COVID-19 with respect to EMH and MF-DFA. (2) We considered the overall stock markets of Eurozones; however, each market responds differently during crises like GFC and COVID-19. Hence, it is suggested to consider a specific stock market for in-depth analysis—for instance, the health, hospitality, tourism and telecommunication sectors.

Figures

(a–m) Scaling behavior of the given share price indices

Figure 1.

(a–m) Scaling behavior of the given share price indices

Descriptive statistics and results of unit root test

Mean MaximumMinimumStd. DevSkewnessKurtosisJ-BADF test
Austria0.00140.00430.0672−0.17310.0217−2.164116.98802751.45***−11.19***
Belgium0.00150.00430.0477−0.11820.0179−1.29518.9892546.42***−11.00***
Finland0.00240.00510.1136−0.11130.0277−0.36895.074062.18***−11.35***
France0.00170.00450.0478−0.08780.0191−0.95735.4128121.75***−11.43***
Germany0.00160.00460.0566−0.10160.0208−1.06725.9614171.01***−11.27***
Greece0.00000.00070.1315−0.13410.0331−0.03574.288321.36***−11.15***
Ireland0.00190.00510.0625−0.13810.0218−1.45158.9053555.68***−11.11***
Italy0.00080.00230.0730−0.09850.0227−0.52055.115871.35***−11.62***
Netherland0.00160.00510.0550−0.13230.0202−1.53899.6807694.34***−11.73***
Portugal0.00190.00250.0584−0.09590.0205−0.53244.917561.73***−13.83***
Slovakia0.00040.00010.0897−0.14180.0221−0.38589.8899616.84***−15.22***
Slovenia0.00680.00171.6809−0.08980.098815.8637269.3924923.92***−23.12***
Spain0.00150.00250.0595−0.07610.0210−0.47004.156628.50***−11.30***

Note(s): J-B = Jarque-Bera test of Normality, ADF = augmented Dickey and Fuller (1979) test and KPSS = Kwiatkowski et al. (1992) test of stationary. *** denotes the rejection of null hypothesis at the 1%”

Source(s): Authors' Estimation, Table 1 by authors

Generalized Hurst exponents of full sample for short and long term components from −5 to 5

CountryAustriaBelgiumFinlandFranceGermanyGreeceIreland
Order of qShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-term
−54.0210.7383.0430.9692.6780.9021.9850.9241.9390.8991.6761.0192.6080.990
−43.8960.7262.8230.9572.4710.8891.8810.9032.0030.8811.6040.9932.4680.968
−33.6020.7152.4860.9422.1660.8731.7410.8782.0350.8601.5150.9602.2360.944
−22.9650.7042.0160.9241.7630.8531.5630.8491.9450.8331.4010.9181.9000.915
−12.0180.6971.5200.8991.3820.8261.3550.8161.6760.8011.2650.8671.5130.884
01.3840.6871.1630.8641.1810.7861.1580.7781.3380.7611.1320.8081.1810.846
11.1150.6520.9640.8151.1440.7381.0360.7381.1120.7161.0390.7470.9710.800
20.9830.5740.8680.7531.1870.6930.9910.6981.0160.6710.9970.6890.8780.740
30.9120.4840.8310.6861.2510.6550.9820.6620.9780.6310.9930.6380.8560.674
40.8720.4110.8260.6271.3070.6260.9820.6310.9550.5991.0080.5960.8620.617
50.8480.3610.8340.5791.3490.6030.9820.6050.9370.5721.0300.5620.8730.572
CountryItalyNetherlandPortugalSlovakiaSloveniaSpain
Order of qShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-term
−52.9840.9472.4940.9651.7540.9673.6991.0763.5320.9172.9130.896
−42.8190.9232.3360.9451.6850.9443.4691.0543.3560.8922.7890.875
−32.5580.8942.1220.9231.5720.9173.0731.0263.0360.8642.5670.851
−22.1470.8591.8390.8981.3990.8822.3840.9902.4570.8332.1900.824
−11.6000.8171.4980.8691.1990.8411.6140.9471.6310.7991.6980.793
01.1680.7711.1980.8301.0310.7941.2720.8981.0610.7561.2830.758
10.9700.7231.0320.7790.9180.7441.1090.8500.8380.6991.0500.718
20.8750.6750.9720.7160.8640.6940.9680.8080.7310.6320.9390.677
30.7950.6310.9440.6540.8540.6490.8480.7730.6460.5720.8830.639
40.7150.5930.9120.6020.8680.6110.7590.7440.5690.5270.8510.606
50.6440.5600.8750.5600.8910.5800.6990.7210.5010.4950.8320.578

Source(s): Authors' Estimation, Table 2 by authors

Generalized Hurst exponents of before the GFC sample for short and long term components from −5 to 5

CountryAustriaBelgiumFinlandFranceGermanyGreeceIreland
Order of qShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-term
−53.2020.7531.5090.7821.6470.9991.1430.9511.3190.9170.8940.8631.7200.878
−43.0060.7361.4880.7751.5370.9551.1040.9281.3590.9000.8830.8521.6680.854
−32.6820.7171.4380.7671.3780.8941.0630.8981.3950.8790.8740.8411.5720.823
−22.1710.6931.3440.7571.1720.8181.0220.8611.3860.8510.8630.8261.4070.786
−11.5890.6631.2060.7420.9840.7430.9770.8191.2760.8110.8440.8011.1810.742
01.2240.6201.0660.7180.8870.6940.9290.7741.0940.7590.8220.7590.9730.690
10.9890.5630.9580.6830.8460.6720.8920.7300.9580.7010.8030.7010.8200.632
20.7780.4940.8820.6390.8130.6560.8650.6910.8880.6500.7930.6420.7120.571
30.6020.4240.8310.5940.7820.6380.8440.6590.8450.6090.7940.5930.6330.511
40.4830.3630.7970.5550.7550.6170.8280.6350.8100.5790.7990.5560.5720.459
50.4120.3150.7750.5230.7340.5980.8150.6160.7820.5570.8010.5280.5210.417
CountryItalyNetherlandPortugalSlovakiaSloveniaSpain
Order of qShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-term
−51.6280.9862.0020.8281.8161.0101.4451.0042.3680.8372.0890.829
−41.5660.9651.8700.8231.7500.9941.4070.9592.2570.8091.9560.799
−31.4730.9411.6850.8151.6230.9751.3500.9022.0700.7761.7680.766
−21.3350.9141.4470.8011.3960.9501.2650.8401.7340.7371.5150.734
−11.1360.8821.1920.7771.1190.9141.1490.7871.2030.6871.2210.704
00.9200.8430.9890.7400.9170.8631.0200.7480.8020.6200.9620.675
10.7650.7950.8610.6920.7790.7970.8990.7220.6660.5370.7790.644
20.6540.7420.7780.6430.6870.7230.7910.7010.6170.4480.6400.608
30.5620.6910.7210.6030.6270.6560.6960.6810.5800.3680.5200.571
40.4870.6480.6840.5710.5870.6020.6190.6600.5410.3060.4170.536
50.4270.6130.6570.5460.5590.5600.5600.6400.5040.2600.3340.505

Source(s): Authors' Estimation, Table 3 by authors

Generalized Hurst exponents of after the GFC sample for short and long term components from −5 to 5

CountryAustriaBelgiumFinlandFranceGermanyGreeceIreland
Order of qShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-term
−53.5300.8552.6950.7232.4550.6891.6570.7412.0750.7751.4640.8501.9710.686
−43.4180.8372.5820.7062.2460.6731.5650.7221.9350.7511.4790.8371.8670.665
−33.2070.8142.3760.6851.9440.6531.4440.6951.7400.7211.5020.8211.7110.639
−22.7570.7872.0000.6571.5500.6281.2960.6591.4780.6791.5020.8021.4890.605
−11.9290.7521.4520.6211.1750.5971.1390.6101.1770.6231.4160.7771.2230.563
01.2560.7040.9960.5760.9360.5620.9930.5500.9260.5491.2590.7470.9700.509
11.0060.6380.7390.5230.7850.5240.8550.4870.7680.4681.1210.7130.7620.442
20.9100.5620.5830.4660.6390.4870.7230.4320.6690.3921.0370.6750.6000.364
30.8720.4900.4690.4120.4830.4550.6050.3880.5950.3331.0040.6390.4770.289
40.8660.4320.3770.3670.3390.4270.5090.3560.5390.2891.0040.6070.3860.225
50.8750.3890.3020.3310.2210.4050.4340.3320.4970.2571.0230.5800.3160.176
CountryItalyNetherlandPortugalSlovakiaSloveniaSpain
Order of qShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-term
−53.1430.8471.4780.8031.3950.8404.0641.0492.6550.8183.0000.908
−42.9620.8181.4050.7781.3290.8183.8321.0252.4970.8082.8340.878
−32.6490.7811.2990.7461.2450.7923.4430.9932.2180.7952.5590.840
−22.1240.7331.1470.7051.1520.7602.7780.9521.7690.7802.1270.793
−11.4970.6750.9610.6521.0680.7231.9100.9001.2550.7571.6000.736
01.0970.6080.7800.5860.9980.6811.2630.8370.9380.7121.1880.673
10.8740.5380.6130.5150.9300.6360.8290.7680.8290.6280.9570.610
20.6630.4710.4320.4500.8540.5920.5520.7010.8080.5080.8270.552
30.4260.4150.2460.3990.7770.5520.4010.6420.7850.3940.7350.502
40.2050.3700.0830.3610.7070.5190.3200.5950.7460.3070.6610.461
50.0310.335−0.0470.3330.6500.4910.2710.5590.7070.2470.6020.427

Source(s): Authors' Estimation, Table 4 by authors

Generalized Hurst exponents of during COVID-19 sample for short and long term components from −5 to 5

CountryAustriaBelgiumFinlandFranceGermanyGreeceIreland
Order of qShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-term
−54.1870.5818.9773.334.7751.2535.5011.1681.4830.9152.7560.4762.3621.072
−44.1110.4638.7913.2184.6731.1895.3981.1361.4910.9112.7070.4932.3511.069
−33.9710.3178.4463.0244.4971.0865.1521.0991.5360.9282.6180.552.3381.044
−23.6980.1637.7012.6844.1380.924.4651.0591.6860.9892.4040.742.3140.97
−13.1530.0445.8622.1353.380.8032.7841.0162.0681.1121.8061.2162.2410.822
02.2340.0123.041.432.4411.010.9810.9662.4541.1991.0341.4972.0490.626
11.3100.0911.4290.7871.8870.9570.4320.9052.2721.0380.9591.1181.7060.471
20.7580.2560.6840.3561.5630.5770.4010.8331.8820.6881.020.8551.3090.384
30.4590.4480.3510.2121.330.230.390.7531.5720.3871.0250.7970.9880.304
40.2830.620.1980.1231.1580.1220.3530.6751.3580.1911.0080.8260.7640.217
50.1700.7510.1180.1031.0330.0920.3120.6031.2110.0690.9670.880.6130.137
CountryItalyNetherlandPortugalSlovakiaSloveniaSpain
Order of qShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-termShort-termLong-term
−54.0511.3783.4471.4983.0061.3153.8112.1073.6572.6243.452.107
−43.9041.3473.3511.4572.9121.2893.682.0553.5362.623.322.055
−33.6821.3223.2071.4112.7791.2753.4841.9933.3582.6073.1221.993
−23.3321.3212.9781.372.61.2963.21.9343.1072.5742.8051.934
−12.791.3392.61.332.3811.3442.8411.8742.7922.4732.3111.874
02.0841.2712.0471.2142.1321.32.4941.7372.4772.1951.6961.737
11.3771.031.4190.9531.8621.0712.2251.4662.2121.7111.141.466
20.8180.6940.8780.6151.6010.7362.0311.1272.0041.1950.7311.127
30.4570.3970.5090.3261.3880.4351.890.8321.8440.8060.4630.832
40.2520.1890.2880.131.2350.221.7890.6191.7270.5480.3050.619
50.140.0520.1590.0061.130.0771.7180.4761.6430.3770.2130.476

Source(s): Authors' Estimation, Table 5 by authors

MF-DFA rankings for short and long-term components

Short-termLong-term
RankingCountryMDMRankingCountryMDM
Full sample period
1Portugal1.2771Austria0.5689
2Greece1.3062Slovenia0.710
3France1.43143Germany0.7399
4Germany1.47894Spain0.740
5Netherland1.6245Finland0.7572
6Ireland1.66496Italy0.758
7Italy1.7677France0.7668
8Spain1.8208Netherland0.774
9Belgium1.82489Portugal0.778
10Finland1.889210Belgium0.792
11Slovenia1.96211Ireland0.7924
12Slovakia2.11412Greece0.7944
13Austria2.383813Slovakia0.899
Before the GFC
1Greece0.8471Austria0.5499
2France0.9662Slovenia0.557
3Slovakia1.0133Ireland0.6562
4Italy1.0274Belgium0.6648
5Germany1.08455Spain0.667
6Ireland1.11956Netherland0.697
7Belgium1.14287Greece0.7042
8Finland1.14618Germany0.7399
9Portugal1.1689France0.7812
10Spain1.18610Finland0.786
11Netherland1.27711Portugal0.798
12Slovenia1.39912Italy0.807
13Austria1.744413Slovakia0.896
After the GFC
1Netherland0.7441Ireland0.4452
2Portugal1.0182Germany0.5202
3France1.03693Belgium0.5366
4Ireland1.12644France0.5389
5Germany1.23725Finland0.55
6Greece1.24146Slovenia0.558
7Finland1.29267Netherland0.569
8Belgium1.47968Italy0.594
9Italy1.5849Austria0.6345
10Slovenia1.62210Portugal0.669
11Spain1.74811Spain0.669
12Slovakia2.07612Greece0.7222
13Austria2.142113Slovakia0.810
COVID-19 period
1Finland1.30711Germany0.5512
2Germany1.42452Austria0.5783
3Ireland1.55783Finland0.6053
4Spain1.81234Ireland0.6429
5Netherland1.81935Greece0.6665
6Greece1.85396Portugal0.7545
7Portugal2.07367Italy0.768
8Italy2.07798Netherland0.7937
9Austria2.19689France0.9052
10Slovenia2.631410Spain1.3369
11Slovakia2.734811Slovakia1.3369
12France2.875512Slovenia1.5838
13Belgium4.494313Belgium1.5974

Source(s): Authors' Estimation, Table 6 by authors

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Corresponding author

Sajid Ali can be contacted at: sajidalikk@live.com

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