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Covid-19 and Uncertainty Effects on Tunisian Stock Market Volatility: Insights from GJR-GARCH, Wavelet Coherence, and ARDL

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Emna Trabelsi^*

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Preprints on COVID-19 and SARS-CoV-2

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31 January 2024

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02 February 2024

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Abstract

This study rigorously investigates the impact of COVID-19 on the Tunisian stock market volatility. The investigation spans from January 2020 to December 2022, employing a GJR-GARCH model, bias-corrected wavelet analysis, and an ARDL approach. Specific variables related to health measures and government interventions are incorporated. The findings highlight that confirmed and death cases contribute significantly to the escalation in TUNINDEX volatility. Interestingly, certain indices related to government interventions exhibit no substantial impact on volatility, indicating a weak resilience of the Tunisian stock market amidst the challenges posed by COVID-19. However, the application of the bias-corrected wavelet analysis yields more nuanced outcomes in terms of correlations of volatility to the same metrics. Notably, the study recognizes the potential influence of uncertainties linked to the duration of lockdowns on financial market volatility. The positive and long-term impact on volatility of the US Equity Market uncertainty and VIX is evident through the Autoregressive Distributed Lag Model (ARDL), whereas economic policy uncertainty shows no significant impact. This indicates a potential vulnerability of the Tunisian stock market to future shocks, emphasizing the need for government efforts to instill investor confidence. This comprehensive exploration contributes to our understanding of the dynamics between the pandemic’ metrics, government interventions, and financial market stability. Our findings provide valuable insights for implementing risk management strategies amid the COVID‐19 crisis.

Keywords:

Subject: Business, Economics and Management - Finance

1. Introduction

The outbreak of the COVID-19 pandemic has triggered unprecedented challenges across global financial markets, with profound implications for economic systems and investment landscapes (see Lee et al., 2020; He et al., 2020; Ashraf, 2020; Okori and Lin, 2021; Mazur et al., 2021; Endri et al., 2021; Chowdhury et al., 2022). Among the affected regions, Tunisia has encountered distinctive dynamics in its stock market, marked by heightened volatility and fluctuations. This research endeavors to comprehensively examine the Impact of COVID-19 on the Tunisian stock market volatility through the lens of a GJR-GARCH model, Wavelet Coherence Analysis, and Autoregressive Distributed Lag Model (ARDL). The motivation behind this study stems from the critical need to understand and quantify the specificities of the financial repercussions experienced by Tunisia in the wake of the pandemic, shedding light on the relationships between key variables influencing market dynamics. The significance of this research lies in its potential to provide valuable insights for investors, policymakers, and financial analysts navigating during and the post-COVID economic recovery, facilitating informed decision-making in the Tunisian financial landscape.

Our research is distinguished by incorporating specific determinants related to the COVID-19 pandemic and aims to quantify their impact on the conditional volatility of TUNINDEX stock market return. It is also important to investigate the predictive power of uncertainty indicators for volatility in the Tunisian context while considering a very sensitive period of investigation. By doing so, we not only offer a thorough exploration of a burgeoning economy grappling with the pandemic but also contribute valuable insights, particularly in light of the scarce existing literature within the scope of our research goals.

The remainder of this paper is as follows. Section 2 reviews specific studies that relate the stock market volatility to the COVID-19 crisis. Section 3 presents data and materials to answer the research objective. The main findings are exposed in Section 4. Concluding remarks and policy implications of the results are displayed in Section 5 and Section 6, respectively.

2. Literature review

Literature on the determinants of stock market volatility is abundant (see Binder and Merges, 2001; Mazzucato and Semmler, 2002; Nikmanesh and Nor, 2016; Hussain et al., 2019; Hewamana et al., 2022; Biu and Kusuma, 2023; Dhingra et al., 2023; etc.). We particularly focus on research that relates stock market volatility to the COVID-19 crisis. Li et al. (2022) established a link between COVID-19 fear and stock market volatility, emphasizing its significance for portfolio diversification. Findings suggest that COVID-19 fear is a primary driver of public attention and stock market fluctuations, with associated impacts on both stock returns and GDP during the pandemic. Gao et al. (2022) used the quantile-on-quantile approach to compare the impact of COVID-19 new cases on U.S. and Chinese stock market volatility, revealing COVID-19 as the primary driver in the U.S. with implications for monetary policy and market stability amid the global spread of the virus. Kusumahadi and Permanan (2021) examined the global impact of COVID-19 on stock return volatility in 15 countries and identified structural changes preceding the onset of COVID-19, suggesting the positive influence of the virus on return volatility, though the effect size is modest. Uddin et al. (2021) emphasized the importance of leveraging economic factors such as capitalism, monetary policy, and financial development in policymaking to address global stock market volatility and prevent potential financial crises. Bora and Basistha (2021) compared the stock return volatility performance of India pre and during the COVID-19 crisis and documented a higher volatility due to the pandemic effect. According to Baek et al. (2020), COVID-19 news significantly influences US stock market volatility, with a notable negativity bias, and industry-wise changes in systematic risk. Yousef (2020) used regression analysis and GARCH models to show that the COVID-19 pandemic, daily new cases, and growth rate of daily new cases significantly increased volatility across all G7 stock indices. The same view is shared by Izzeldin et al. (2021). Through GARCH modeling, Chaudhary et al. (2020) found a negative mean return during the COVID period, with heightened volatility, suggesting a bearish trend in the top 10 countries according to GDP. The global COVID-19 fear index seems to have a pronounced effect on the volatility of 19 emerging stock markets (see Sadiq et al., 2021). Papadamou et al. (2020) highlighted that increased anxiety regarding COVID-19 contagion on Google correlates with heightened risk aversion in stock markets, especially in Europe. The volatility in stock prices caused by COVID-19 affects abnormal returns, prompting investors to implement risk management strategies amid uncertainty, while also creating potential speculative opportunities in an inefficient market (En-dri et al., 2021). Lúcio and Caiado (2022) observed that amid the COVID-19 outbreak, all S&P 500 industries, except Internet and Direct Marketing Retail, witnessed a substantial rise in volatility, leading to a convergence in time-varying variance among them.

Studies on the effect of COVID-19 on stock return volatility in the Tunisian context are very recent. Using GARCH models, Akinlaso et al. (2022) detected high persistence in both Tunisia’s Islamic and conventional stock markets, with the conventional index negatively influencing Islamic stocks during the pandemic. Jeribi et al. (2015) and Fakhfekh et al. (2023) revealed increased volatility persistence in all Tunisian sectorial stock market indices post-COVID-19, with certain sectors showing significant asymmetric effects.

3. Data and Methodology

3.1. Data

We collect daily data on TUNINDEX returns amid the COVID-19 pandemic. The period spans from January 2d, 2020 to December, 30^th 2022, making a total of 755 observations, omitting nontrading days. Since the objective is to analyze the impact of the sanitary crisis on the Tunisian stock return volatility, we gather data on the number of cases (total, new, and death) and on the government intervention to limit the spread of the virus (see Table 1 for details).

Table 1. Data definitions.

Variable	Symbol	Definition	Source
TUNINDEX	tun	The daily closing price of the Tunisian market index	https://www.investing.com/indices/tunindex-historical-data
Total cases	total_cases	Cumulative number of the confirmed cases due to COVID-19	Our World in Data https://ourworldindata.org/coronavirus/country/tunisia
Total deaths	total_death	Cumulative number of the confirmed death cases due to COVID-19
New cases	new_cases	Total number of the new confirmed cases due to COVID-19
New deaths	new_death	Total number of new confirmed death cases due to COVID-19
Rate of confirmed cases	cases_rate	News cases/Total cases	Calculus
Rate of deaths	death_rate	Death cases/Total deaths	Calculus
Stringency index	stringency_index	Ranges from 0 to 100, where higher values indicate stricter government policies and restrictions in response to the COVID-19 pandemic.	Oxford COVID-19 Government Response Tracker (OxCGRT) https://github.com/OxCGRT/covid-policy-dataset
Containment health index	containement_health_index	Typically ranges from 0 to 100, where higher values indicate better virus containment.
Economic policy index	economic_policy_index	Ranges from 0 to 100, where higher values indicate a more accommodative economic policy stance and lower values indicate a more restrictive stance.
Government response index	government_response_index	Ranges between 0 and 100. A higher score means a better country’s response to the pandemic.
WTI crude oil price	wti_price	Crude oil price (United States)	Energy Information Administration database https://www.eia.gov/dnav/pet/pet_pri_spt_s1_d.htm
School closing	s1	Sub-indicator 1 of the stringency index	Oxford COVID-19 Government Response Tracker (OxCGRT) https://github.com/OxCGRT/covid-policy-dataset
Workplace closing	s2	Sub-indicator 2 of the stringency index
Cancel public events	s3	Sub-indicator 3 of the stringency index
Restrictions on public gatherings	s4	Subindicator 4 of the stringency index
Closures of public transport	s5	Sub-indicator 5 of the stringency index
Stay-at-home requirements	s6	Sub-indicator 6 of the stringency index
Restrictions on internal movements	s7	Subindicator 7 of the stringency index
International travel control	s8	Sub-indicator 8 of the stringency index
Public information gatherings	s9	Subindicator 9 of the stringency index

Source: The Author.

Descriptive statistics of the above variables are displayed in Table 2. The TUNINDEX exhibits a mean return of 0.000150, indicating a generally modest performance. Figure 1 illustrates a compelling narrative of diminishing returns in TUNINDEX, particularly during the challenging times of the COVID-19 era. The total number of COVID-19 cases and deaths, with means of 551,839.1 and 16,432.85 respectively, reflects the significant impact of the pandemic on public health. The stringency index, with a mean of 49.03363, suggests varying degrees of government measures. Interestingly, the containment health index, economic support index, and government response index do not seem to strongly influence market volatility. The skewness values, particularly for TUNINDEX, indicate a negatively skewed distribution, and the kurtosis values suggest heavy tails in the distribution.

Table 2. Descriptive statistics of the variables.

	RETURN_TUN	TOTAL_CASES	TOTAL_DEATHS	STRINGENCY_INDEX	S1	S2	S3	S4	S5	S6	S7	S8	S9	CONTAINMENT_HEALTH_INDEX	ECONOMIC_SUPPORT_INDEX	GOVERNMENT_RESPONSE_INDEX	WTI_OIL_RETURN
Mean	0.000150	551839.1	16432.85	49.03363	1.034043	1.144681	1.597163	3.262411	0.307801	0.808511	0.639716	1.876596	1.846809	50.28391	46.84397	49.85403	0.001816
Median	0.000339	603981.0	21941.00	45.31000	1.000000	1.000000	2.000000	4.000000	0.000000	0.000000	0.000000	2.000000	2.000000	49.96000	50.00000	48.80000	0.002294
Maximum	0.018974	1147571.	29284.00	90.74000	3.000000	3.000000	2.000000	4.000000	2.000000	2.000000	2.000000	4.000000	2.000000	77.74000	75.00000	77.40000	0.425832
Minimum	-0.041859	1.000000	3.000000	0.000000	0.000000	0.000000	0.000000	0.000000	0.000000	0.000000	0.000000	0.000000	0.000000	0.000000	0.000000	0.000000	-0.281382
Std. Dev.	0.004802	444625.6	11959.82	21.88917	1.017728	0.804146	0.757157	1.546832	0.603267	0.967621	0.918936	1.122006	0.490616	18.04488	25.69635	17.32935	0.045112
Skewness	-2.203420	0.060338	-0.263656	-0.119352	0.546806	0.438110	-1.480724	-1.632203	1.799000	0.390066	0.772150	0.298314	-3.148689	-1.074264	-0.287851	-1.055407	1.353766
Kurtosis	20.12168	1.393214	1.331061	2.671155	2.097217	2.843062	3.384040	3.672980	4.993379	1.183648	1.632938	2.231494	11.52594	4.109855	1.785051	4.541901	29.12992
Jarque-Bera	9181.807	72.04800	83.47809	4.850368	59.07326	23.27648	261.9562	326.3342	497.0006	114.7899	124.9530	27.80539	3300.243	171.7835	53.09627	200.7193	20271.78
Probability	0.000000	0.000000	0.000000	0.088462	0.000000	0.000009	0.000000	0.000000	0.000000	0.000000	0.000000	0.000001	0.000000	0.000000	0.000000	0.000000	0.000000
Sum	0.105709	3.68E+08	10747083	34568.71	729.0000	807.0000	1126.000	2300.000	217.0000	570.0000	451.0000	1323.000	1302.000	35450.16	33025.00	35147.09	1.280245
Sum Sq. Dev.	0.016235	1.31E+14	9.34E+10	337311.6	729.1830	455.2426	403.5943	1684.454	256.2071	659.1489	594.4879	886.2638	169.4553	229234.8	464852.8	211415.7	1.432724
Observations	705	666	654	705	705	705	705	705	705	705	705	705	705	705	705	705	705

Source: The Author.

Figure 1. Evolution of TUNINDEX stock return (02/01/2020-30/12/2022). Source: The Author.

3.2. Methodology

The assessment of volatility has mandated the application of models within the Autoregressive Conditional Heteroskedasticity (ARCH) framework in the realm of financial literature. Originating with the seminal ARCH model introduced by Engle (1982), subsequent advancements have been made, encompassing the development of models such as Generalized ARCH (GARCH), GARCH-in-mean, Quadratic GARCH, and Threshold GARCH, among others.

The stock return is calculated following previous related literature using this formula:

R_{t} = L n (\frac{P_{t}}{P_{t - 1}})

where

P_{t} a n d P_{t - 1}

are the stock market indices of the Tunisian Stock Exchange at times t and t-1, respectively. Ln is the natural logarithm.

The logarithm transformation serves as a technique to induce stationarity in variables by mitigating trends and seasonality within time series data. Consequently, Augmented Dickey-Fuller (ADF) and Phillips-Perron (PP) tests are conducted to verify the attainment of stationarity in the level of returns. The associated results are available in Table 3.

The autoregressive (AR) (p) or autoregressive moving average (ARMA) (p, q) structures are commonly integrated as explanatory elements within the conditional mean equation of Generalized Autoregressive Conditional Heteroskedasticity (GARCH) models for the dependent variable. Following Insaidoo et al. (2021), an advantageous feature of the GARCH model lies in its adaptability to include explanatory variables and dummy variables in both the conditional mean and variance equations, thereby accommodating the specific objectives of the study. Hence, we incorporate each of the COVID-19 variables and the government intervention controls in both the mean equation and the variance equation, separately to capture the effect of the pandemic on the Tunisian stock return and volatility. Our econometric modeling is essentially based on Fakhfekh et al. (2023). However, we distinguish from their study by including specific controls related to the sanitary crisis instead of separating pre-crisis and during-crisis periods. Thus, we estimate the following GARCH family models.

Table 3. Results of ARCH/GARCH family models for the TUNINDEX volatility and oil volatility.

Panel A: Stock return volatility
Model	ARCH(1), constant	ARCH(1), AR(1)	ARCH(1), MA(1)	ARCH(1), ARMA(1,1)	GARCH(1,1), constant	GARCH(1,1), AR(1)	GARCH(1,1), MA(1)	GARCH(1,1), ARMA(1,1)
AIC	-8.248105	-8.283928	-8.274759	-8.281654	-8.332585	-8.376225	-8.365392	-8.378094
SC	-8.229721	-8.259390	-8.250246	-8.250982	-8.308073	-8.345553	-8.334751	-8.341287
Model	EGARCH(1,1), constant	EGARCH(1,1), AR(1)	EGARCH(1,1), MA(1)	EGARCH(1,1), ARMA(1,1)	TGARCH(1,1), constant	TGARCH(1,1), AR(1)	TGARCH(1,1), MA(1)	TGARCH(1,1), ARMA(1,1)
AIC	-8.323690	-8.369747	-8.358517	-8.369772	-8.330636	-8.374358	-8.363444	-8.376183
SC	-8.293050	-8.332940	-8.321748	-8.326830	-8.299996	-8.337551	-8.326675	-8.333242
Panel B: WTI oil volatility
Model	ARCH(1), constant	ARCH(1), AR(1)	ARCH(1), MA(1)	ARCH(1), ARMA(1,1)	GARCH(1,1), constant	GARCH(1,1), AR(1)	GARCH(1,1), MA(1)	GARCH(1,1), ARMA(1,1)
AIC	-3.856832	-3.990224	-4.003052	-4.000366	-4.272393	-4.269562	-4.269562	-4.257070
SC	-3.837436	-3.964362	-3.977190	-3.968039	-4.246531	-4.237234	-4.237235	-4.231253
	EGARCH(1,1), constant	EGARCH(1,1), AR(1)	EGARCH(1,1), MA(1)	EGARCH(1,1), ARMA(1,1)	TGARCH(1,1), constant	TGARCH(1,1), AR(1)	TGARCH(1,1), MA(1)	TGARCH(1,1), ARMA(1,1)
AIC	-4.278102	-4.275790	-4.275864	-3.344925	-4.292975	-4.290166	-4.290171	-4.287428
SC	-4.245774	-4.236997	-4.237071	-3.299666	-4.260648	-4.251373	-4.251377	-4.242170

Source: The Author.

3.2.1. ARCH

The ARCH model characterizes the variance of a time series, particularly in situations involving dynamic and potentially volatile variance. It was introduced by Engle (1982). While ARCH models can potentially depict a slowly escalating variance trend over time, their primary application lies in scenarios featuring brief episodes of heightened variation. It is worth noting that situations involving a gradual increase in both variance and mean level may be more effectively addressed by transforming the variable.

The mean equation is written as follows:

R_{t} = α + \sum_{i = 1}^{p} β_{i} R_{t - i} + \sum_{i = 1}^{q} θ_{i} ε_{t - i} + ε_{t}

The choice between AR(1), MA(1), and ARMA(1,1) is made based on the conventional information criteria (Aikake, Schwarz) for which the value is minimized.

Our estimations show that AR(1) is the preferred one.

The conditional variance equation is defined as:

σ_{t}^{2} = a_{0} + \sum_{i = 1}^{p} a_{i} ε_{t - i}^{2}

where

a_{0} > 0, a_{i} > 0

. This model is known as the linear ARCH(p). In financial data analysis, the model captures the phenomenon of volatility clustering, wherein significant (insignificant) price changes tend to be succeeded by other substantial (moderate) price changes, but with an unpredictable direction. To streamline the model and guarantee a consistently diminishing impact of more distant shocks, a makeshift linearly declining lag structure was frequently enforced in many early applications of the model (see Bollerslev et al., 1992; Bollerslev and Mikkelsen, 1996).

3.2.2. GARCH

Bollerslev’s GARCH model (1986) is the most widely used model for estimating volatility. volatility. GARCH models have had great success in the literature due to their simple specification and ease of interpretation.

The conditional variance equation is defined as:

σ_{t}^{2} = a_{0} + \sum_{i = 1}^{p} a_{i} ε_{t - i}^{2} + \sum_{j = 1}^{q} b_{j} σ_{t - j}^{2}

where

a_{0} > 0, a_{i} > 0, b_{j} > 0

. For a GARCH(1,1), the constraint

a_{1} + b_{1}

< 1 implies that the unconditional variance of the ε yield series is finite and that the conditional variance

σ_{t}^{2}

evolves. It also provides the necessary and sufficient for the stochastic process

σ_{t}

; t ∈ Z to be a unique process strictly stationary with E(

σ_{t}^{2}

) < ∞.

Two key properties can be noted from the above equation. First, a high value of

ε_{t - 1}^{2}

σ_{t - 1}^{2}

gives rise to a high value of

σ_{t}^{2}

and this generates the volatility clustering that is common in time series. Second, the tail distribution is thicker than that of a normal distribution (see Mestiri, 2022).

3.2.4. EGARCH

This model is suggested by Nelson (1991) to account for leverage effects. It is an asymmetric Exponential GARCH specification that distinguishes between “good” and “bad” news on volatility.

The conditional volatility equation is given by:

L n σ_{t}^{2} = a_{0} + \sum_{i = 1}^{p} a_{i} \frac{|ε_{t - i}| + δ_{i} ε_{t - i}}{σ_{t - i}} + \sum_{j = 1}^{q} b_{j} L n σ_{t - j}^{2}

If there is "good" news,

ε_{t - i} > 0

and the total effect is given by

(1 + δ_{i}) ε_{t - i}

. If there is "bad" news,

ε_{t - i} < 0

, and the total effect is given by

(1 - δ_{i}) ε_{t - i}

. “Bad” news is likely to have a more pronounced impact on volatility and

δ_{i}

is expected to be negative.

3.2.5. GJR-GARCH

Another version of an asymmetric GARCH model with leverage effects is the Threshold GARCH specification, called also GJR-GARCH. The conditional volatility is given by:

σ_{t}^{2} = a_{0} + \sum_{i = 1}^{p} a_{i} ε_{t - i}^{2} + \sum_{i = 1}^{p} γ_{i} S_{t - i} ε_{t - i}^{2} + \sum_{j = 1}^{q} b_{j} σ_{t - j}^{2}

With

S_{t - i} = \{\begin{matrix} 1 i f ε_{t - i} < 0 \\ 0 i f ε_{t - i} > 0 \end{matrix}

When

ε_{t - i} > 0

, the total effect is given by

a_{i} ε_{t - i}^{2}

. If

ε_{t - i} < 0

, the total effect is given by

(a_{i} + γ_{i}) ε_{t - i}^{2}

. The coefficient

γ_{i}

is expected to be positive so that “bad” news has a larger impact on volatility.

The best-fit model is chosen based on Akaike (AIC) and Schwarz (SC) information criteria for which the value is minimized.

According to Bera and Higgins (1993), the most applied financial work shows that GARCH (1,1) provides a flexible and parsimonious approximation of the conditional variance dynamics and is capable of representing the majority of financial series. Therefore, p=1 and q=1 are applied for all GARCH family models to be estimated.

Before estimating ARCH-type models, we need to test for the presence of ARCH(q) effects. We rely on the Lagrange Multiplier (LM) test. We reject the null hypothesis of no ARCH effects (F-statistic=342.0031, p-value=0.000; Obs*R²=235.6154, p-value=0.000).

To know what a combination of variables is to be included in the regression we provide the pairwise correlation matrix (see supplemental file for details).

4. Results and discussion

4.1. Impact of COVID-19 announcements and government intervention on TUNINDEX stock return volatility

Table 3 shows that GJR-GARCH is the preferred one as the conventional information criteria exhibit the lowest values. To examine the impact of COVID-19 announcements and the government intervention variables, we regress the conditional stock return variance that results from the GJR-GARCH(1,1), AR(1) model on the variables of interest and a set of controls (see Ibrahim et al., 2020; Bakry et al., 2022):

{V O L}_{t} = α + β_{1} {C R}_{t} + β_{2} {D R}_{t} + β_{2} {G I I}_{t} + β_{1} {O i l_V O L}_{t} + μ_{t}

where CR: cases_rate, DR: death_rate, GRI: Government intervention index (this includes stringency_index, containment_health_index, economic_support_index, government_response_index, and subindicators of the stringency index (s1 to s9), Oil_Vol: Conditional WTI oil volatility from GJR-GARCH(1,1) with a constant.

To handle the multicollinearity issue, we include the government intervention indicators separately. Further, we control for autocorrelation and heteroscedasticity by estimating the equation with the Newey-West method. Results are available in Table 4 and Table 5. We re-estimate the variants of the equations while skipping for the cases_rate variable. All results duplicate mostly the ones in Table 4 and Table 5, except that death_rate becomes statistically significant (see Table 6 and Table 7).

According to Kamal and Wohar (2023), "Considering global market integration (Solnik, 1974) and to remove misspecification error, [..]. We also lagged the independent variables by one period to examine the slow response of the market. Slow response supports the underreaction hypothesis, which suggests investors adjust slowly to new information.". We replicate the output while considering the variables of interest and controls lagged with one period (see Table 8, Table 9, Table 10 and Table 11).

The observed incidence of confirmed cases and mortality rates exhibit a positive association with heightened volatility in the TUNINDEX in addition to the WTI conditional volatility. Moreover, there exists a positive correlation between the stringency index and volatility in the Tunisian stock market. Conversely, the indices about containment health economic support and government response do not manifest a discernible impact on market volatility. Those observations can be attributed to increased uncertainty and economic impacts. Rising cases make investors cautious, leading to market fluctuations. Stringent government measures, reflected in the stringency index, also correlate positively with market volatility, indicating economic repercussions. However, indices related to health economic support and government response show no significant impact on volatility, suggesting that other factors may be more influential in shaping the Tunisian stock market.

Table 4. Effect of COVID-19 announcements and government intervention on TUNINDEX volatility.

Eq Name:	EQ01	EQ02	EQ03	EQ04
C	0.000011	0.000011	0.000011	0.000011
	[10.9061]***	[11.0044]***	[11.6222]***	[11.3206]***
CASES_RATE	0.000359	0.000358	0.000389	0.000366
	[3.3678]***	[3.3480]***	[3.2211]***	[3.2644]***
DEATH_RATE	0.000049	0.000053	0.000010	0.000037
	[0.7213]	[0.7701]	[0.1111]	[0.4705]
CONDVAR_WTI	0.001224	0.001220	0.001185	0.001219
	[2.3954]**	[2.3831]**	[2.3961]**	[2.3998]**
DSTRINGENCYINDEX	0.000001
	[0.9286]
DCONTAINMENTHEALTHINDEX		0.000001
		[0.7738]
DECONOMICSUPPORTINDEX			0.000001
			[1.2960]
DGOVERNMENTRESPONSEINDEX				0.000001
				[0.9220]
Observations:	654	654	654	654
R-squared:	0.4811	0.4794	0.4907	0.4823
F-statistic:	150.4010	149.4343	156.3274	151.1775
Prob(F-stat):	0.0000	0.0000	0.0000	0.0000