Does the Interaction between ICT Diffusion and Economic Growth Reduce CO2 Emissions? An ARDL Approach

2.1 ICT-CO2 emissions

The first stream of existing literature provides a wide range of studies with mixed results on ICT and environmental quality. For the influence of ICT on CO2 emissions, it differs from a study to another and from a country to another. For instance, AñónHigón et al. [15] conclude that, in the short run, ICT worsen the environmental quality; however in the long run, it improves through controlling CO2 emissions. In addition, Tamazian et al. [16] argues that well-developed financial systems affect positively the economic growth which leads to improving the industrial pollution. Also, Lee and Brahmasrene [17], using a panel of ASEAN countries, suggest that ICT affect positively and significantly the economic growth and CO2 emission. Besides, Malmodin and Lunden [18] demonstrate that the relationship between ICT usage, carbon emissions, and electricity consumption is positive and significant.

However, the second stream conclude the negative relationship between CO2 and ICT. In fact, Ollo-López and Aramendía-Muneta [19] confirm that ICT helps to decrease CO2 emissions. Besides, Coroama et al. [20] found that the ICT reduce the CO2 emission, especially the greenhouse gasses (GHGs). Recently, using the pooled mean grouped (PMG) method, Salahuddin et al. [21] also revealed that Internet use has a significant long-run relationship with CO2 emission in OECD countries. More recently, analyze the nexus between ICT and CO2 emissions in the case of 44 sub-Saharan African countries employing GMM model. Conclude that ICT has a significant impact on CO2 emission; but, when the square of ICT increases, the level of pollution mitigates. Also, a study done by Salahuddin et al. [21] confirms that economic growth, financial development, and trade decrease the level of CO2 emission. Similarly, using a panel of 12 Asian countries, Lu [22] analyzes the impact of ICT, financial development, energy consumption, and economic growth on environmental quality. He shows that the use of ICT decreases CO2 emission; but economic growth, financial development, and energy consumption increase CO2 emission. A study by Hart [23] also highlighted a negative relationship between ICT and the overall quantity of carbon gas emitted. In addition, Ozcan and Apergis [10] and Lu [22] observed that ICT reduced carbon emissions. Malmodin and Lunden [24] also proved that ICT led to a decline in carbon emissions in the entertainment and media sectors globally during the period from 2010 to 2015.

However, others researches examine the impact of ICT on CO2 emissions and found a nonsignificant relationship between these variables. In fact, Amri et al. [25] found a nonsignificant impact of ICT on CO2 emissions in the case of Tunisia over the period 1975–2014. Gelenbe and Caseau [26] also revealed that the effect of ICT on carbon emissions is mixed. This effect is influenced by the economic sectors involved. Similarly, Al-Mulali et al. [27] conclude that ICT measured by the use of internet reduced CO2 emissions in developed nations, while the effect is insignificant in developing countries. Moreover, Zhang and Liu [28] conclude that ICT decreases the carbon emissions in the case of China over the period 2000–2010. This effect was found to be insignificant in the western region, while it was greater in the central region as well as in the eastern region.

2.2 CO2 emissions-economic growth

The second stream of existing literature provides empirical evidence on the relationship between economic growth and environmental quality. The context of economic growth in the region raises the question of the environment in the EKC hypothesis. This hypothesis stipulates that there is a positive relationship between income and CO2 emissions until an income threshold is reached, and after this level the correlation between these two variables becomes negative, i.e. when the income increases, CO2 emissions decrease. There are numerous studies testing for the causal link between carbon emissions and economic growth. In fact, Apergis and Payne [29], applying FMOL S model and Granger causality test in the case of six Central American countries, confirm the validity of environmental Kuznets curve (EKC). In addition, Pao and Tsai [30] aimed to explore the causal relationship between energy consumption, CO2 emission, foreign direct investment, and growth in the BRIC countries and Ukraine. The author found that exist a strong positive bi-directional causal relationship between these variables. Similarly, Narayan and Popp [31] aimed to explore the validity of the Environment Kuznets’s Curve (EKC) hypothesis for 93 countries over the period from 1980 to 2004. Narayan and Popp [31] confirmed the existence of the long-run relationship between energy consumption and real GDP. Dogan and Turkekul [32] arrived at the same conclusion, using Bounds cointegration model and Granger causality test in the case of USA. However, Katircioglu and Katircioglu [33] found no evidence to support the existence of the EKC in the case of Turkey. Similarly, in a study for Malaysia over the period 1980–2009, Ozturk and Al-Mulali [27] failed to confirm the validity of the EKC. Similarly, Al-Mulali et al. [27] and Shahbaz et al. [34] confirmed the no validity of the EKC hypothesis over the period 1981–2011 and 1976–2016, respectively. There are a large number of papers empirically examining the issues of the impact of ICT and economic on environmental quality using the tools of econometric analysis.

2.3 Interaction between ICT and GDP-CO2 emissions

Studies on interaction between ICT and economic growth-environmental quality nexus is still limited. In this context, Danish et al. [14], using an AMG estimations models over the period 1990–2015, conclude that ICT and GDP stimulate the CO2 emissions. However, the interaction between GDP and ICT mitigates the level of pollution in emerging countries. Similarly, Tsaurai and Chimbo [11] examine the impact of ICT on CO2 emissions using different analysis methods (FMOLS, DOLS, fixed effects, and random effects) in emerging economies. He explores that ICT increase carbon emissions. But he concludes that the interaction between ICT and economic growth, in first hand, and the interaction between ICT and financial development, in second hand, reduce the carbon emissions.

4.1 Data, model and hypotheses

The empirical investigation aims to examine the role of ICT in reducing the impact of GDP on CO2 emissions using an ARDL model in the case of Tunisia and Morocco over the period 1980–2018. To do this, we will estimate, on first hand, the direct impact of GDP on CO2 emissions. Therefore, the representation of our models is illustrated:

Where i represents each country in the panel and t indicates the time period; CO2 refers to the CO2 emissions; GDP is the GDP per capita growth (annual %); X refers to the explanatory variables that are: inf is the Consumer price index (2010 = 100); find is the Domestic credit to private sector (% of GDP); trade is the sum of Imports of goods and services (% of GDP) and Exports of goods and services (% of GDP); invst is the Gross fixed capital formation (% of GDP).

The expected sign of GDP is positive because economic growth accelerates the level of pollution while the level of CO2 emissions increases (Danish et al. [14]). The expected sign of ∝1 should be positive. This is essential because with the increase in GDP, people consume more goods; more industries develop so the level of CO2 emissions increases.

On second hand, we will estimate the direct impact of ICT on CO2 emissions. So, in order to study the nature of the relationship between ICT and CO2 emissions, we include ICT proxies, namely, mcs is the Mobile cellular subscriptions (per 100 people); fbs is the Fixed broadband subscriptions (per 100 people); fts Fixed telephone subscriptions (per 100 people); internet is the Individuals using the Internet (% of population).

Finally, we study the impact of the interaction between ICT and economic growth on ameliorating the environmental quality. So, we will introduce each time the interaction between GDP and one of the measures of ICT. The inclusion of these interactions allows us to examine whether growing economies are increasing the use of ICTs in different sectors to expand economic activities. We then try to examine whether the increased use of ICTs with growing economic growth positively or negatively affects environmental quality.

So, the representation of the models is illustrated:

Hypotheses

1. GDP has a destructive effect on environmental quality; in other words, GDP has a positive impact on CO2 emissions.

2. ICT moderates the adverse effect of GDP on environmental quality.

4.2 Methodology

In order to empirically examine whether ICT and economic growth have an effect on CO2 emissions in Morocco and Tunisia, and whether the interaction between ICT and economic growth affects the environmental quality, we applied an Autoregressive Distributed Lag (ARDL) model. This approach is proposed by and subsequently it was modified by introducing the bounds testing approaches. This technique is effective for many reasons. Firstly, it examines the short- and long-term relationships between the different variables that do not have the same order of integration. Secondly, it can solve the problems associated with autocorrelation and omitted variables. Finally, this approach can be useful for a small sample size application.

Before the data are further analyzed, it is necessary to demonstrate the stationarity of all variables. In fact, in order to arrive at robust empirical results, all estimated variables should be non-unit root. In this case, we use four unit root tests Augmented Dickey-Fuller (ADF), Phillips-Perron (PP 1988), Dickey-Fuller GLS (DF-GLS), and KPSS (Kwiatkowski-Phillips-Schmidt-Shin) unit root; whose critical threshold is 5%, and with a null hypothesis (H0) of non stationarity of the variable. The ARDL bounds test is based on the assumption that the variables are I(0) or I(1). So we use the unit root tests in order to make sure that the variables are not I(2) because if variables are I(2), we cannot interpret the values of Fi statistics provided by.

The next step is to test the presence of cointegrating relationships among the variables. To do this, we use the bounds test that is mainly based on the joint Fi statistics whose asymptotic distribution is non-standard under the null hypothesis of no cointegration. Once cointegration was established, we estimate the long- and short-run relationship between ICT, economic growth, and CO2 emissions using ARDL model. In order to obtain the dynamic parameters in the short run, we estimate a correction error model associated with long-run estimates (Odhiambo [35]). The short-run causal effect was represented by Fi statistics on explanatory variables, while the t statistic on the lagged error correction coefficient represents the causal relationship in the long run.

Finally, we examine the causal relationship between ICT, economic growth, and CO2 emissions using Toda-Yamamoto Granger causality test. This method is based on the estimation of augmented VAR model (k + dmax) where k is the optimal time lag on the first VAR model and dmax is the maximum integrated order on system’s variables (VAR model). To do so, it is necessary, firstly, to determine the integration order for each series using AIC and SC criteria. If the integration order is different we get the maximum (dmax) and we create a VAR model (VAR (k + dmax)) on series levels regardless of integration order that we found. However, if we have the same integration order, we continue on cointegration test using Johansen methodology.

5.1 The direct effect of ICT and GDP on environmental quality

First, we will select the required number of lags of dependent variable and the regressors by applying the information criteria such as Criterion (HQ). Second, the estimation of the model should be carried out based on the number of lags.

According to the results obtained from the AIC and HQ information criteria, one lag is the optimum number to be incorporated in the analysis.

To examine the direct impact of ICT and GDP on CO2 emissions both in Tunisia and in Morocco, we will estimate Eqs. (1) and (2). So, we will find for each country five regressions. In the four first regressions, we examine the direct effect of ICT on carbon emissions, so, we will introduce each time one of the four measures of ICT in Eq. (1). In the last regression, we will introduce in Eq. (2) the variable GDP in order to examine the direct impact of GDP on environmental quality.

To test the cointegration of variables, the ARDL bounds test was used. This test was used to check the long-term relationship among the study series. Table 2 indicates the results of F-statistics which is applied to decide the cointegration. The calculated F-statistics value is greater than the upper bounds value at 10% and 5% level of significance that indicates that cointegration exists among the study variables, in both Tunisia and Morocco for all our models.

This section consists of describing the short-term estimators and presenting an error correction model corresponding to the established cointegration or the long-term equilibriums. The notion CointEq (−1) defines the delayed residue originating from our long-term equilibrium equation. The negative sign of its estimated coefficient and its significance for both countries thus confirm the presence of an error correction tool. The coefficient of the cointegration equation explains the order in which the variable CO2 will be mobilized towards the long-term target.

Findings presented in Table 4 confirm that ECT is negative and significant which proves that there is a cointegration relationship between the variables of the model. In fact, a negative sign of ECT is essential for a stable error correction mechanism.

With regard to the GDP variable, the short-run results presented in Table 4 demonstrate that the coefficient of the present value of the GDP is significant and positive in both Tunisia and Morocco. That is means that economic growth was found to have increased the quantity of CO2 emissions in the case of Tunisia and Morocco. The positive impact of GDP on CO2 emissions can be explained, essentially, by the fact that when economic growth improves, the use of energy increases. So the increase in CO2 emissions is mainly due to the combustion of petroleum, coal, and natural gas for energy purposes. Also, the environmental quality can be deteriorated by certain industrial processes namely the production of cement, the manufacture of clothing, the alcohol factories, etc. Then, the increase in the number of economic activities has a detrimental effect on the environmental quality.

It is not surprising that there is a strong negative relationship between ICT diffusion and environmental quality, in the short-run model. In fact, the coefficients of each measure of ICT (fbs, fts, internet, and mcs) are significant and positive, implying that fts, fbs, internet, and mcs negatively influence the Moroccan and Tunisian environmental quality. It means that the ICT diffusion increases the CO2 emissions. Concerning the variable find, we note that both present and first delayed value have positive effects on carbon emissions of the two countries.

Besides, the findings presented in Table 4 confirm that in the short run, the openness deteriorates the Moroccan and Tunisian environmental quality. In fact, the coefficient of the variable open is positive and significant in all models.

As apparent in Table 4, the coefficient of the variable inf is negative and significant in all models in short run. Therefore, inflation ameliorates the environmental quality in both countries. This negative relationship between carbon emissions and inf can be explained by the fact that when prices increases, energy consumption decreases; as a result the CO2 emissions decrease. Also, we can see that the first delayed value of inf affect negatively the Tunisian CO2 emissions in the first model when we introduce the variable fts as a measure of ICT.

Finally, the variable invst has not an impact on environmental quality in both countries. In fact the coefficient of this variable is insignificant, except, in the case of Tunisia, when we introduce the variable internet in our model invst affects positively and significantly the CO2 emissions. That is means that invst deteriorates the Tunisian environmental quality. The positive relationship between CO2 emissions and invst can be explained, especially, by the fact that invst increases energy consumption that deteriorates the environmental quality.

We can deduce from Table 3 that there is substantial evidence that the variables ICT and GDP have long-run effects on CO2 emissions. Therefore, we will examine the long-run direct impact of ICT and GDP on CO2 emissions for both countries. So, we will find for each country five regressions.

Findings presented in Table 4 confirm that in the long term all explanatory variables have the same signs of the coefficients in both countries. Similarly the GDP and ICT conserve the same sign in the short run. In other words, in the long run, the economic growth and the ICT diffusion deteriorate the environmental quality in both countries. In fact the coefficient of the variables fbs, fts, internet, mcs, and GDP are positive and significant, so when ICT and GDP increase, the CO2 emissions increase.

5.2 The effect of the interaction between ICT and GDP on environmental quality

To examine the role of the interaction between ICT diffusion and economic growth on enhancing the environmental quality, we will estimate in this section Eq. (3) where we will introduce in our model the variable (GDP*ICT). Because the ICT is measured by four measures (fbs, fts, internet and mcs), we will find for each country four regressions.

The ARDL bounds test results are presented in Table 5 which demonstrates that the calculated F-statistics value is greater than the upper bounds value at 10% and 5% level of significance that indicates that cointegration exists among the study variables, both in Tunisia and Morocco for all our models.

Findings presented in Table 6 resume the ARDL short-run relationship between the dependent variable and the explanatory variables. It is necessary to note that the sign of ECTt-1 is as we expected. It is negative and statistically significant. Then, we can conclude that there is a cointegration relationship between the variables of the model.

Findings presented in Table 7 show that in the short run, the coefficient of the variable of the interaction between ICT and economic growth is positive and significant. The positive relationship running from the interaction between ICT and economic growth toward carbon emissions signifies that economic growth is a channel through which ICT enhances the environmental quality in both countries. The result collaborates with the findings of Khan et al. [9] and Danish et al. [14]. So, we can conclude that in the short term, the Moroccan and Tunisian economic growths were found to be a channel through ICT to improve the environmental quality.

Similarly, in the long run, the impact of the interaction between economic growth and technology on CO2 emissions was found to be positive and significant in all models where ICT is measured by fbs, fts, internet, and mcs. These results confirm that, also, in the long term, economic growth increased ICT’s ability to improve the environmental quality in both countries.

5.3 Toda and Yamamoto granger causality test results

The next step is to examine the directions and causality between the variables for the cross-check of our findings using the Toda and Yamamoto Granger causality test. The results of this test are presented in Table 8. Based on the objective of this paper, we are going to be concerned about the results of the relationship between GDP, CO2 emission, and ICT. As we could see from Table 8, there is bidirectional causality between CO2 emissions and economic growth; however, there is a unidirectional causality running from each measure of ICT (FTS, FBS, MCS, and INTERNET) to CO2 without feedback.