Research highlights for review

  • This study examines the causality between insurance market density (IMD) and economic growth.

  • We use 19 Eurozone countries between 1980 and 2014.

  • The analysis has been done at individual country level and at Eurozone panel level.

  • The study finds an evidence of Granger causality between IMD and economic growth.

  • Results in the short run are mostly non-uniform with a few exceptions.

Background

Theoretical studies and empirical evidences have revealed that countries with well-developed financial systems experience faster and more stable long-run economic growth. Normally, a well-built financial marketFootnote 1 has a significant positive impact on total factor productivity, which translates into high long-run economic growth (see, inter alia, Haiss and Sumegi, 2008; King and Levine, 1993; Levine and Zervos, 1998; Levine et al., 2000). This holds true for all the sub-sectors of financial markets, such as banking sector, stock market, and insurance market. In this paper, we primarily focus on the relationship between insurance market and economic growth. The motivation for this study is based on two typical reasons. First, the coverage of insurance sector has gained less attention in the finance-growth literature, particularly in comparison to both banking sector and stock markets (see, inter alia, Lee et al., 2013a, 2013b). Second, with the process of financial liberalization and integration, we have witnessed an increasingly rapid growth in the insurance market activity during last few years, which raises the question of ‘whether insurance market activity promotes economic growth.’ This adds to the empirical evidence on resolving the controversial issue between insurance market development and economic growth (see, inter alia, Boon, 2005; Chang et al., 2014).

The relationship between insurance market activitiesFootnote 2 and economic growth has been broadly discussed in extant literature.Footnote 3 Most of these studies have argued that economic growth is characteristically determined by insurance market activities, with sufficient evidence presented to policymakers to this effect (see, inter alia, Arena 2006; Beck and Webb 2003; Chen et al. 2013; Lee et al. 2012; Hussels et al. 2005). However, in extant literature, the link between insurance market activities and economic growth has not been fully recognized, and most empirical results vary according to data and econometric tools (see, inter alia, Lee et al. 2013a, 2013b; Outreville 2013). There is no universally held view of the nature of causality between insurance market activities and economic growth (see, inter alia, Pradhan et al. 2017; Alhassan and Fiador 2014; Chang et al. 2014; Kugler and Ofoghi 2005; Ward and Zurbruegg 2000). Therefore, we investigate the causal nexus between the two in order to ascertain the actual fact; that is, “How do insurance market activities cause economic growth?” The focus of this study is on EurozoneFootnote 4 countries during the period of 1980-2014.

The remaining paper is outlined as follows. Insurance market activities and economic growth: The theoretical basis presents the theoretical basis of insurance market activities to growth. An outline of insurance market density in the eurozone countries outlines the trend of insurance market density. Empirical strategy deliberates the empirical strategy. Empirical results and discussion presents the empirical results and discussion thereof. Finally, we conclude in Conclusion.

Insurance market activities and economic growth: The theoretical basis

Like other financial services, such as banking and stock market activities, insurance market activities play a key role in economic growth (see, inter alia, Chang et al. 2014; Ghosh 2013; Garcia 2012; Webb et al. 2005a, 2005b; Lee et al. 2012; Adams et al. 2009; Li et al. 2007; Webb et al. 2005a, 2005b; Outreville 1996) Insurance market activities serve a number of valuable economic functions that are largely distinct from other types of financial intermediaries, such as banking and stock market activities. The insurance market activities- both as a provider of risk transfer and indemnification and as an institutional investor- may contribute to economic growth in the following ways: promoting financial stability, facilitating trade and commerce, mobilizing domestic savings, allowing different risks to be managed more efficiently, encouraging the accumulation of new capital, fostering a more efficient allocation of domestic capital, and helping to reduce or mitigate losses (see, inter alia, Pradhan et al. 2015a, 2015b; Liu et al. 2014; Lee et al. 2013a, 2013b; Billio et al. 2012; Guochen and Wei 2012; Haiss and Sumegi 2008; Skipper and Kwon 2007; Kugler and Ofoghi 2005; Ward and Zurbruegg 2000). Additionally, there may be different effects on economic growth from life and non-life insurance market activities given that these two types of insurance market activities protect the households and corporations from different kind of risks that affect the economic activity in different ways. Additionally, life insurance companies facilitate long-term investment, rather than short-term investment, as is the case of non-life insurance companies (see, inter alia, Arena 2008; Brainard 2008).

The degree to which insurance market activities are pervasive in a country is believed to be largely a function of four factors. First, the affordabilityFootnote 5 of insurance; second, the amount of regulation imposed on the insurance industry by the host government; third, the amount of risk and uncertainty that the people in the society perceive in their lives; and fourth, the degree to which these individuals want to minimize these perceived risks by purchasing insurance rather than relying on the other mechanisms to hedge risks (see, inter alia, Pradhan et al. 2017; Lee et al. 2013a, 2013b; Park et al. 2002; Soo 1996).

At the empirical level, a large section of finance-growth work assesses the impact of the banking sector on economic growth. It shows that the banking sector development contributes to economic growth (see, inter alia, King and Levine 1993), and that there is a positive causal relationship between the two (see, inter alia, Levine 1999; Levine et al. 2000). Similarly, the impact of stock market on economic growth has been studied extensively, justifying the belief that stock market development contributes to economic growth (see, inter alia, Beck and Levine 2004; Caporale et al. 2004; Kar et al. 2011; Levine and Zervos 1998; Arena 2008). Nevertheless, the impact of the insurance market on economic growth has not been studied as extensively as the impacts of the banking sector and stock market.Footnote 6 In this context, our main task is to address the following. First, we examine the existence of cointegration between insurance market activities and economic growth; second, we observe the presence of long-run and short-run direction of causality between the two; and third, we distinguish the particular effectsFootnote 7 of life and non-life insurance activities on economic growth.

The literature indicates insurance market activities contribute to economic growth to a great extent (see, inter alia, Chen et al. 2012; Adams et al. 2009; Kugler and Ofoghi 2005). However, it is possible that insurance market activities are also equally exaggerated by economic growth. This means, in practice, insurance market activities and economic growth can Granger cause each other, and hence, there is a prospect of feedback relationship between the two. Overall, there are four possible hypotheses to signify the Granger causal relationship between insurance market activities and economic growth (Pradhan et al. 2017; Alhassan and Fiador 2014; Ward and Zurbruegg 2000).

First, the supply-leading hypothesis (SLH), which posits that insurance market activities are a necessary pre-condition to economic growth. Here, the Granger causality runs from insurance market activities to economic growth. The studies supporting SLH are Alhassan and Biekpe (2016), Pradhan et al. (2017, 2015), Alhassan and Fiador (2014), Chang et al. (2014), Lee et al. (2013a, 2013b), Guochen and Wei (2012), Lee (2011), Adams et al. (2009), Kugler and Ofoghi (2005), and Boon (2005).

Second, the demand-following hypothesis (DFH), which posits that Granger causality runs from economic growth to insurance market activities. The studies supporting DFH are Alhassan and Biekpe (2016), Pradhan et al. (2015a, 2015b), Chang et al. (2014), Ching et al. (2010), Guochen and Wei (2012), Lee (2011), Kugler and Ofoghi (2005), Beck and Webb (2003), and Ward and Zurbruegg (2000).

Third, the feedback hypothesis (FBH), which posits that economic growth and insurance market activities Granger cause each other. The studies supporting FBH are Alhassan and Biekpe (2016), Chang et al. (2014), Pradhan et al. (2014, 2015a, 2015b), Guochen and Wei (2012), Kugler and Ofoghi (2005), Ward and Zurbruegg (2000), and Beck and Webb (2003).

Fourth, the neutrality hypothesis (NLH), which posits that economic growth and insurance market activities do not Granger cause each other. The studies supporting NLH are Pradhan et al. (2015a, 2015b), Akinlo (2013), Chang et al. (2014), Chau et al. (2013), Guochen and Wei (2012), and Nejad and Kermani (2012).

Table 8 presents a brief summary of the relationship between insurance market activities and economic growth (see Appendix A). The aim of our study is to validate these four claims in the 19 Eurozone countries. This kind of analysis has received less attention in the literature. This study adds to the scant literature on the insurance-growth nexus by finding an answer to the question, “Are insurance market activities in Eurozone countries “supply-leading,”demand-following,” or “feedback?””

An outline of insurance market density in the Eurozone countries

As emphasized above, insurance market activities and economic growth are broadly inter-related, in the process of economic development (Pradhan et al., 2014). There are two diverse ways to address the relationship between insurance market activities and economic growth. First, the regional disparity between insurance market activities and economic growth; and second, the causal relationship between the two. This paper deals with both the issues for the 19 Eurozone countries during the period from 1980 to 2014.

This section discusses the brief profile of Eurozone countries (see Appendix B), an outline of insurance market activities in these countries, and conventional facts on the insurance markets covered in this study. The highlights of this issue will give a theoretical evidence to examine the empirical relationship between insurance market activities and economic growth in these selected countries.

It may be noted that, like banking and stock market activities, the coverage of insurance market activities is extensively wide. There are many insurance market activities that can exhibit the coverage and status of insurance market. At large, there are two important insurance market activities that exemplify the status of insurance market. These are insurance market density (IMD) and insurance market penetration (IMP). Both are again projected in three different ways, namely life insurance, non-life insurance, and total insurance (both life and non-life). This paper precisely confines its analysis to IMDFootnote 8 activities and their causal link with economic growth in the studied Eurozone countries.

Characteristically, we intend to examine the trend and regionalization of IMD activities in the Eurozone. We highlight here three activities of IMD, namely life insurance density (LID), non-life insurance density (NID), and total insurance (both life and non-life) density (TID). A detailed discussion of these variables is available in Appendix C (see Table 9). We use annual data of these variables for both regional disparity discussion and Granger causality investigation. These were obtained from the World Development Indicators of the World Bank and Sigma Economic & Research Consulting of Switzerland.

The study first examines the trend of insurance market activities before studying the Granger causal relationship with economic growth. We present the trend of these activities in four different time periods from 1980 to 2014. These time periods are: Period 1— 1980 to 2000, Period 2— 2001 to 2007, Period 3— 2008 to 2014, and Period 4— 1980 to 2014. These four categorizations have been made with reference to the global financial crisis in the year 2007-2008. The idea is to know the trend of insurance market before and after the global financial crisis, and how the deviation of this market behaves with respect to its overall average from 1980 to 2014. We choose this particular time period on the basis of data availability in the archives.

This study presents the salient facts of three IMD activities across the 19 Eurozone countries. These countries are Austria, Belgium, Cyprus, Estonia, Finland, France, Germany, Greece, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, the Netherlands, Portugal, Slovakia, Slovenia, and Spain.

First, the level of life insurance density (LID) is moderately high in comparison to non-life insurance density (NID). This is true for most of the Eurozone countries.

Second, the volume of LID is relatively high in Finland, Ireland, France, and Luxembourg, while it is proportionally low in Latvia, Lithuania, Estonia, and Slovakia. This is true for all the the four time periods.

Third, the volume of NID is considerably high in the Netherlands, Luxembourg, Germany, and Austria, while it is relatively low in Lithuania, Latvia, Estonia, and Slovakia. This is again true for all the four time periods.

Fourth, the volume of TID has great intensity in the Netherlands, Finland, Ireland, Luxembourg, and Belgium, while it is low in Lithuania, Latvia, Estonia, and Slovakia. This is significantly true for all the time periods.

Fifth, the insurance density values are substantially low for Lithuania, Latvia, Estonia, and Slovakia for all the three cases and all the time periods.

Sixth, for all the three insurance density indicators, the Netherlands, Ireland, and Luxembourg record the highest values in all the four time periods.

To summarize, insurance market density (for LID, NID, and TID) is considerably low in Lithuania, Latvia, Estonia, and Slovakia, while it is relatively high in the Netherlands, Ireland and Luxembourg. Furthermore, the extent of regional disparity measured through coefficient of variation has been declining in the Eurozone countries, which is reflected across all periods (P1-P4). The figures are not reported here in order to conserve space.

These typical IMD trends are more or less similar to economic growth trend represented by per capita gross domestic product, and are considerably true for most of the Eurozone countries. In other words, like IMD, the level of economic growthFootnote 9 is typically high in like group of countries like the Netherlands, Ireland, and Finland and moderately low in other similar group of countries like Lithuania, Latvia, Estonia, and Slovakia. This, hypothetically, signals that IMD and per capita economic growth have a link and can cause each other in the process of economic development. In the subsequent section, we empirically authenticate this claim in the context of the 19 Eurozone countries, both at individual country level and at the panel level.

Empirical strategy

This study uses Granger causality test to recognize the evidence of the relationship between insurance market density and economic growth using the Eurozone countries over the period of 1980 to 2014. The period is chosen on the basis of the data availability of insurance market activities (IMA). We use complete archived IMA data available at the time of study, and specifically deploy this particular period (1980-2014) for Granger causality test because of its larger sample size. We propose the following two hypotheses to be tested:

H 1A, B : Insurance market density in any year Granger-causes economic growth, leading to the occurrence of supply-leading hypothesis of insurance-growth nexus.

H 2A, B : Economic growth in any year Granger-causes insurance market density, leading to the occurrence of demand-following hypothesis of insurance-growth nexus.

On the empirical front, we deploy per capita gross domestic product (GDPFootnote 10), and three IMD indicatorsFootnote 11 to validate the above two hypotheses (H 1A, B and H 2A, B ).

Annual data of these variables (GDP, LID, NID, and TID) were obtained from the World Development Indicators of the World Bank and Sigma Economic & Research Consulting of Switzerland. The summary statistics of these variablesFootnote 12 for each country are presented in Table 1.

Table 1 Descriptive Statistics of Variables

The study uses the following models to identify the long-run and short-run causal relationships between insurance market density and economic growth.

$$ Economic\kern0.5em {Growth}_{it}={\alpha}_{it}+{\beta}_{1i} Insurance\kern0.5em Market\kern0.5em {Density}_{it}+{\varepsilon}_{it} $$
(1)

where,

i = 1 , 2 … N represents an individual country in the Eurozone panel;

t = 1 , 2 .… T refers to the time period (1980 − 2014); and.

ε it is an independent and normally distributed random error with zero mean and a finite heterogeneous variance (σ i 2).

Other variations of eq. (1) are also allowed to change the dependent variable from economic growth to insurance market density. When we look for individual country analysis, the subscript ‘i’ is removed from eq. (1). The parameter β 1i represents the long-run elasticity estimates of economic growth with respect to insurance market density.Footnote 13 The task was to estimate the parameters in eq. (1) and conduct panel tests on the causal nexus between the two variables. It is guessed that β 1i  > 0, which suggests that an increase in insurance market density is likely to cause an increase in economic growth. We can also guess the presence of reverse causality by interchanging the position of insurance market density and economic growth in Eq. (1). In other words, we look forward to recognize the feasibility of feedback relationship (i.e., the bidirectional causality) between insurance market density and economic growth.

The Granger causality test (Granger, 1988) is deployed here to detect the direction of causality (bidirectional/ unidirectional/ neutrality) between insurance market density and economic growth. We deploy the following regression models to observe the direction of causality between insurance market density and economic growth.

Model 1: For individual country analysis

$$ {\displaystyle \begin{array}{l}\left[\begin{array}{l}\varDelta Economic\kern0.5em {Growth}_t\\ {}\varDelta Insurance\kern0.5em Market\kern0.5em {Density}_t\end{array}\right]=\left[\begin{array}{l}{\mu}_{1 INS}\\ {}{\mu}_{2 INS}\end{array}\right]+\\ {}\sum \limits_{k=1}^p\left[\begin{array}{l}{\delta}_{11 INS1k}(L){\delta}_{12k}(L)\\ {}{\delta}_{21 INS1k}(L){\delta}_{22k}(L)\end{array}\right]\left[\begin{array}{l}\varDelta Economic\kern0.5em {Growth}_{t-k}\\ {}\varDelta Insurance\kern0.5em Market\kern0.5em {Density}_{t-k}\end{array}\right]+\left[\begin{array}{l}{\eta}_{1 INS}{ECT}_{1t-1}\\ {}{\eta}_{2 INS}{ECT}_{2t-1}\end{array}\right]+\left[\begin{array}{l}{\xi}_{1 INS t}\\ {}{\xi}_{2 INS t}\end{array}\right]\end{array}} $$
(2)

The null and alternative hypotheses are to test the following:

$$ {\displaystyle \begin{array}{cc}\hfill {H}_0:{\delta}_{12k=0}; and\ {\eta}_{1k}= 0\hfill & \hfill \kern5em for\ k=1,\dots, p\hfill \\ {}\hfill {H}_A:{d}_{12k\#0}; and\ {\eta}_{1k}\# 0\hfill & \hfill \kern5.4em for\ k=1,\dots, p\hfill \end{array}} $$
$$ {\displaystyle \begin{array}{cc}\hfill {H}_0:{\delta}_{21k=0}; and\ {\eta}_{2k}=0\hfill & \hfill \kern4.8em for\ k=1,\dots, p\hfill \\ {}\hfill {H}_A:{\delta}_{21k\#0}; and\ {\eta}_{2k}\#0\hfill & \hfill \kern5.3em for\ k=1,\dots, p\hfill \end{array}} $$

where, ECTFootnote 14 is error correction term, which is derived from the long-run cointegration equation; and.

ε it is an independent and normally distributed random error with a zero mean and a finite heterogeneous variance (σ i 2).

Model 2: For panel data analysis

$$ {\displaystyle \begin{array}{l}\left[\begin{array}{l}\varDelta Economic\kern0.5em {Growth}_{it}\\ {}\varDelta Insurance\kern0.5em Market\kern0.5em {Density}_{it}\end{array}\right]=\left[\begin{array}{l}{\mu}_{1 INSj}\\ {}{\mu}_{2 INSj}\end{array}\right]+\\ {}\sum \limits_{k=1}^p\left[\begin{array}{l}{\delta}_{11 INSi k}(L){\delta}_{12 ik}(L)\\ {}{\delta}_{21 INSi k}(L){\delta}_{22 ik}(L)\end{array}\right]\left[\begin{array}{l}\varDelta Economic\kern0.5em {Growth}_{it-k}\\ {}\varDelta Insurance\kern0.5em Market\kern0.5em {Density}_{it-k}\end{array}\right]+\left[\begin{array}{l}{\eta}_{1 INSi}{ECT}_{1 it-1}\\ {}{\eta}_{2 INSi}{ECT}_{2 it-1}\end{array}\right]+\left[\begin{array}{l}{\xi}_{1 INSi t}\\ {}{\xi}_{2 INSi t}\end{array}\right]\end{array}} $$
(3)

The null and alternative hypotheses are to test the following:

$$ {\displaystyle \begin{array}{cc}\hfill {H}_0:{\delta}_{12 ik=0}; and\ {\eta}_{1 ik}= 0\hfill & \hfill for\ k=1,\dots, p\hfill \\ {}\hfill {H}_A:{\delta}_{12 ik\#0}; and\ {\eta}_{1 ik}\# 0\hfill & \hfill for\ k=1,\dots, p\hfill \end{array}} $$
$$ {\displaystyle \begin{array}{cc}\hfill {H}_0:{\delta}_{21 ik=0}; and\ {\eta}_{2 ik}= 0\hfill & \hfill for\ k=1,\dots, p\hfill \\ {}\hfill {H}_A:{\delta}_{21 ik\#0}; and\ {\eta}_{2 ik}\# 0\hfill & \hfill for\ k=1,\dots, p\hfill \end{array}} $$

where, i = 1, 2, 3,…., N represents a country in the panel; and t = 1, 2, 3,…., T represents a year in the panel.

This study follows the AICFootnote 15 statistic to decide the optimum lag length of these two models. Equally, the inclusion of ECT (in both Model 1 and Model 2) exclusively depends upon the condition of order of integration and the cointegrating relationship between insurance market density and economic growth. Hence, the first requirement is to check the order of integration and cointegration between the two (IMDFootnote 16 and GDP). Therefore, we first deploy unit root test and cointegration test, both at the individual country as well as at the panel level, to ascertain the order of integration and the presence of cointegrating relationship between insurance market density and economic growth.

The ADFFootnote 17 unit root test is used for individual country analysis, while the LLCFootnote 18 panel unit root test is used for the panel setting. In the same way, Johansen Maximum Likelihood cointegration test (Johansen, 1988) is deployed for individual country analysis, while Johansen Fisher panel cointegration test is deployed for the panel setting. The details of these two tests (Johansen and Fisher/ Maddala) are not discussed here due to space constraints and can be made available on request. Additionally, it can be noted that the evidences of cointegration and causality in the panel setting may be sensitive to the assumption of cross-sectional dependence. Hence, we deployed Pesaran (2004) test of cross sectional dependence (CD) to all the four variables. However, CD-statistics do not give any significant results. The results of these statistics are not reported in order to conserve space.

Empirical results and discussion

This section begins with the stationarity issue of variables, namely GDP, LID, NID, and TID, and their cointegrating relationships.Footnote 19 First, by using the unit root tests (ADF test for individual country and LLC test for panel setting), we reject the null hypothesis of unit root at the first difference, but not for the levels (see Table 2). This indicates that insurance market density (LID, NID and TID) and economic growth (GDP) are non-stationary at the level data, but are stationary at the first difference. This is true for all the Eurozone countries, both at the individual country and at the panel setting. This suggests that insurance market development (LID, NID, and TID) and economic growth are integrated of order one [i.e., I (1)], which opens the possibility of cointegration between the two.

Table 2 Results of Unit Root Test

In the next step, using cointegration test (Johansen Maximum Likelihood cointegration test for individual country and Johansen and Fisher/ Maddala cointegration for panel settings), we find that IMD and GDP are cointegrated, suggesting the existence of long run relationship between insurance market density and economic growth. This finding is consistent with the findings of several earlier studies (see, inter alia, Petkovski and Jordan 2014; Pradhan et al. 2017). However, cointegration between GDP and IMD does not exist in some Eurozone countries. These exceptions are Cyprus, Finland, Greece, Latvia, Lithuania, Malta, Slovakia, and Slovenia (see Table 3). A summary of these findings has been highlighted in Table 4.

Table 3 Results of Cointegration Test
Table 4 Summary of Cointegration Test Results

The next step is to determine the direction of causality between insurance market density and per capita economic growth. The Granger causality test, based on vector error correction model (VECMFootnote 20), was deployed to test the direction of Granger causality between insurance market density and per capita economic growth. The estimated results of this section are reported in Tables 5, 6 and 7. Table 5 reports both short-run and long-run estimatesFootnote 21 of VECM/VARM, while Tables 6 and 7 report the summary of short-run Granger causality results.

Table 5 Results of Test from the Vector Error Correction Model for Long-Run Causality
Table 6 Granger Causality Test Results for the Short run
Table 7 Summary of Granger Causality Test Results

Table 5 reports the presence of a long-run equilibrium relationship between insurance market density and economic growth, while Tables 6 and 7 report the short-run Granger causality between the two. The analysis is based on three individual indicators of insurance market density (such as LID, NID, and TID) and economic growth. With respect to long-run equilibrium relationship, we find the presence in a few situations and absence in other situations. This is true while studying Granger causality from insurance market density (LID/NID/TID) to per capita economic growth, and vice versa. On the other hand, we have an experience of divergence in the context of short-run Granger causality between insurance market density and economic growth. The results of this section are presented below.

Case 1: Between life insurance density and per capita economic growth

For Belgium, Cyprus, Estonia, Finland, Latvia, Lithuania, Luxembourg, Malta, the Netherlands, and Portugal, there is a unidirectional causality from life insurance market density (LID) to economic growth (GDP) [LID = > GDP]. This supports the supply-leading hypothesis (SLH 1) of insurance market-growth nexus (see column 5 of Table 6). This finding is consistent with the findings of earlier studies by Alhassan and Biekpe (2016), Pradhan et al. (2017), Alhassan and Fiador (2014), Webb et al. (2005a), Chang et al. (2014), Guochen and Wei (2012), Lee (2011), Arena (2008), Kugler and Ofoghi (2005), and Catalan et al. (2000). For, Germany, Greece, Slovakia, and Slovenia, we find the presence of unidirectional causality from economic growth to life insurance density [GDP = > LID]. This supports the demand-following hypothesis (DFH 1) of insurance market-growth nexus. This finding is consistent with the findings of earlier studies by Alhassan and Biekpe (2016), Pradhan et al. (2015a, 2015b), Chang et al. (2014), Guochen and Wei (2012), Lee (2011), Ching et al. (2010), and Catalan et al. (2000). Furthermore, for Ireland, Italy, and the European Zone panel, there is a bidirectional causality between life insurance density and economic growth (LID <= > GDP]. This supports the feedback hypothesis (FBH 1) of insurance market-growth nexus.Footnote 22 This finding is consistent with the findings of earlier studies by Alhassan and Biekpe (2016), Pradhan et al. (2015a, 2015b), Chang et al. (2014), Guochen and Wei (2012), and Kugler and Ofoghi (2005).

Case 2: Between non-life insurance density and per capita economic growth

For Cyprus, France, Lithuania, Luxembourg, the Netherlands, and Slovenia, there is a unidirectional causality from non-life insurance market density (NID) to economic growth [NID = > GDP], offering support to the supply-leading hypothesis (SLH 2) of insurance market-growth nexus. This finding is consistent with the findings of earlier studies by Alhassan and Biekpe (2016), Pradhan et al. (2017), Alhassan and Fiador (2014), Chang et al. (2014), Guochen and Wei (2012), Lee (2011), Arena (2008), Kugler and Ofoghi (2005), Webb et al. (2005a), and Catalan et al. (2000). For, Austria, Germany, Greece, Ireland, Italy, Malta, Portugal, and Slovakia, we find the presence of unidirectional causality from economic growth to non-life insurance density [GDP = > NID], lending support the demand-following hypothesis (DFH 2) of insurance market-growth nexus. This finding is consistent with the findings of earlier studies by Alhassan and Biekpe (2016), Pradhan et al. (2015a, 2015b), Chang et al. (2014), Guochen and Wei (2012), Lee (2011), and Catalan et al. (2000). Furthermore, for Estonia, Finland, Latvia, Spain, and the European Zone panel, there is a bidirectional causality between non-life insurance density and economic growth (NID < => GDP], testifying the presence of feedback hypothesis (FBH 2) of insurance market-growth nexus. This finding is consistent with the findings of earlier studies by Alhassan and Biekpe (2016), Pradhan et al. (2015a, 2015b), and Chang et al. (2014).

Case 3: Between total insurance density and per capita economic growth

For Belgium, Cyprus, Estonia, France, Luxembourg, Portugal, and Slovenia, there is a unidirectional causality from total insurance market density (TID) to economic growth [TID = > GDP], lending support to the supply-leading hypothesis (SLH 3) of insurance market-growth nexus. This finding is consistent with the findings of earlier studies by Alhassan and Biekpe (2016), Pradhan et al. (2017), Alhassan and Fiador (2014), Chang et al. (2014), Guochen and Wei (2012), Nejad and Kermani (2012); Kugler and Ofoghi (2005), Boon (2005), and Ward and Zurbruegg (2000). For, Germany, Greece, Malta, and Spain, we find the presence of unidirectional causality from economic growth to total life insurance density [GDP = > TID], thus supporting the demand-following hypothesis (DFH 3) of insurance market-growth nexus. This finding is consistent with the findings of earlier studies by Alhassan and Biekpe (2016), Pradhan et al. (2015a, 2015b), Chang et al. (2014), and Guochen and Wei (2012). Additionally, for Finland, Ireland, Italy, Latvia, Lithuania, the Netherlands, Slovakia, and the European Zone panel, there is a bidirectional causality between total insurance density and economic growth (TID < => GDP], supporting the feedback hypothesis (FBH 3) of insurance market-growth nexus. This finding is consistent with the findings of earlier studies by Alhassan and Biekpe (2016), and Pradhan et al. (2015a, 2015b).

We have also studied the relationship between insurance market activities and economic growth at the multivariate level by deploying three additional variables, such as finical depth,Footnote 23 government consumption expenditure, and young dependency population. Here, we observe six cases, depending upon the deployment of three insurance market activities (life insurance density, non-life insurance density and total insurance density), and two financial depth indicators. The results of this section are reported in Appendix D (see Tables 10-11). The findings of this multivariate analysis are more or less similar to the findings of bivariate analysis. In the long-run, we find economic growth tends to converge to its long-run equilibrium path in response to changes in insurance market activities and three macroeconomic indicators.Footnote 24 This is relatively true for all these six cases considered. However, in the short-run, we find both bidirectional and unidirectional Granger causality between economic growth, insurance market activities, financial depth, government consumption expenditure, and young dependency of population among our panel of countries.

Conclusions

This study explored the nexus between the insurance market and economic growth for the Eurozone countries using time series data from 1980 to 2014. The focal message from our study for both policymakers and researchers is that implications drawn from research on per capita economic growth that excludes the dynamic interrelation of these two variables will be imperfect. It is the conjoined back-and-forth relationship between insurance market and economic growth, that is, the stand point of our study and directs future research in this field.

Our study finds mixed evidence on the interrelationship between insurance market density and economic growth in the Eurozone countries, both at the individual country level and at the panel setting. On some occasions, insurance market density leads to economic growth, lending support to supply-leading hypothesis of insurance market-growth nexus. On other occasions, economic growth leads to insurance market density, providing support to demand-following hypothesis of insurance market-growth nexus. For countries that support the supply-leading hypothesis, we could argue that insurance market activities are fully developed in those countries, and hence, contribute to economic growth. However, in countries that support the demand-following hypothesis, we may argue that insurance market activities in these countries, even though growing during this period, are either deficient or have impacted economic growth indirectly, possibly through other financial indicators like banks and stock markets. The latter part is, in fact, beyond the scope of this study. There are also situations, where insurance market density and economic growth are interdependent on each other, offering support to the feedback hypothesis of insurance market-growth nexus. In addition, there are also cases, where insurance market density and economic growth are independent of each other, lending support to the neutrality hypothesis of insurance-growth nexus. These findings are on the lines of Chang et al.Footnote 25 (2014), Guochen and WeiFootnote 26 (2012), and Pradhan et al.Footnote 27 (2015a, 2015b).

Finally, the study suggests that in order to promote per capita economic growth, attention must be paid to policies that promote the insurance market. This requires an efficient allocation of financial resources combined with wide-ranging movement in the insurance market. Furthermore, establishing a well-developed financial system, particularly with reference to the insurance market, can facilitate further investment and easier means of raising capital to support economic development. Given the possibility of reverse causality or bi-directional causality on some occasions, policies that increase economic growth (such as steps to increase investment) would be desirable to bring insurance market development. Therefore, it is recommended that the government be proactive if it aims to develop the insurance market and integrate it with economic growth.

No doubt, in the globalization era, many developing countries have recognized the importance of financial market development for high economic growth. Accordingly, there has been a change of strategy to refine their financial system. Earlier studies mostly focused on both banking and stock markets and their link with economic growth to stimulate the financial development. However, there is now a need to concentrate on the insurance market by eliminating some of the hindrances in the insurance market-growth nexus, such as tax and regulatory framework, and drive towards more insurance market activities.

To summarize, government must be attentive in its attempts to bring stable financial environment in order to promote the link between insurance market and economic growth. This study is restricted to insurance market density only, and particularly in a bivariate framework of insurance-market growth nexus. It is also one of the major limitations of this empirical investigation. Future studies can include insurance market penetration and other relevant variables, like interest rates or other financial indicators, to gain better inference of the link between the insurance market and economic growth.