1 Introduction

Due to the recent financial crisis of 2007–2008, illiquidity research has gained importance,Footnote 1 as Crotty (2009) highlights that the crisis happens when investors run for liquidity and safety. Brunnermeier (2009) mentions that the crisis has led to the most severe financial predicament since the great depression. It had large repercussions on the real economy, indicating the significance of market liquidity on the economy. Liquid markets make new and existing investors more willing to invest in stocks which in turn make cost of capital cheaper for companies that seek capital in the financial markets. Cheaper cost of capital facilitates new investment which in turn helps increase GDP.

Nevertheless, along with liquidity, the price of oil is an important part of macroeconomic activity. Basher and Sadorsky (2006) highlight that countries’ demand for oil increases significantly due to urbanization and modernization, indicating that oil is considered the lifeblood of modern economies. Furthermore, similar to illiquidity, oil is also linked to the financial crisis as Taylor (2009) mentions that oil price increases have prolonged the crisis. Tverberg (2012) also suggests that if world oil supply should remain the same (low), then there is the possibility of a continuing financial crisis similar to the 2008–2009 recession. Low supply implies a higher oil price which can bring about higher inflation and consequent stagnation. Higher oil prices could also increase the cost of existing or new investment projects, rendering those unprofitable achieving a direct hit on the real economy (see Cuñado and de Gracia 2003, 2005).

Current research acknowledges the relationship between the two variables. Ratti and Vespignani (2013) find evidence that the cumulative impact of China’s liquidity (measured by money supply) on the real price of crude oil is large and statistically significant. Although both liquidity (Crotty 2009) and oil prices (Tverberg 2012) are related to present/past crises and economic growth, there is no research available that investigates the combined effect of the two variables.

Galariotis and Giouvris (2015) find evidence that market liquidity may contain some information for predicting the current and future state of the economy. We are looking into oil prices and illiquidity among other variables as antagonists using their framework. We include national foreign exchange rate (NFX) as part of our controlling variables because oil is usually priced in United States dollar (USD). Cunado and de Gracia (2005) highlight that the effect of oil on economic activity becomes more significant when oil is defined in local currencies. Authorities will also devalue the local currency in order to boost stagnating economies through increased exports (see Inman 2005 with reference to the devaluation of the Chinese Yuan). We also include the Baltic Dry index (BD), as it is commonly used as an indicator of economic activity reflecting on the global demand for raw materials (Bakshi et al. 2011). Higher global demand for raw materials implies an overall increase in productive activity and therefore GDP. Tett (2016) notes that price movements of the BD are almost as important as oil prices.

Although there are various studies on oil available, Wang et al. (2013) highlight that past studies seldom differentiate between oil-exporting countries and oil-importing countries. We undertake original research by covering ten countries grouped into five net oil-exporting countries (Norway, Canada, Denmark, Mexico, and Brazil) and five net oil-importing countries (Singapore, UK, Germany, Japan, and France). Our grouping is based on the latest data available on US Energy Information Administration and DataStream.

Overall, this paper contributes to the current literature of macroeconomics forecasting. Næs et al. (2011) mention that a larger cross section of stock markets should be investigated to test the predictive power of liquidity on the state of the economy. We expand this line of research by treating illiquidity and oil prices as antagonistic predictive variables along with other variables, focusing on ten countries. Four of those countries are new additions in comparison with Næs et al. (2011) and Galariotis and Giouvris (2015). We provide original results by analysing variables which have not been used before such as oil (OB), the Baltic Dry index (BD), and national foreign exchange (NFX), in addition to the illiquidity variables.Footnote 2 Moreover, by segregating our sample into net oil exporters and net oil importers, we will be able to investigate which predictive variables affect macroeconomic activityFootnote 3 of the two groups of countries. Finally, we also split our net oil-exporting countries into developed and emerging countries in order to further enhance our study.

The remainder of this paper is organized as follows. Section 2 presents the literature review, while Sect. 3 describes the data and variables. In Sect. 4, the methodology, empirical results, and analysis are discussed followed by our conclusion in Sect. 5.

2 Literature review

2.1 Predictive variables and the macroeconomy

Past literature such as Hamilton (1983)Footnote 4 appears to show that crude oil does impact the economy of countries (see also Hamilton 2011Footnote 5; Mork 1989). Cuñado and de Gracia (2003) who study fifteen European countries find evidence of oil price shocks affecting inflation and industrial production indexes. Furthermore, Cunado and De Gracia (2005) undertake similar research on six Asian countries and highlight that oil prices have a significant effect on both economic activity and price indexes.

Similarly, studies have emerged on the impact of liquidity on macroeconomic variables such as Næs et al. (2011) who mention that at least since World War II (WWII), market liquidity contains useful information for estimating the current and future state of the US and Norwegian economy. Galariotis and Giouvris (2015) expand this line of research by studying G7 countries, and they find evidence that market liquidity may contain some information for predicting the current and future state of the G7 economies.

In order to make this study broader, we have included the Baltic Dry index (BD)Footnote 6 due to its apparently close relationship with oil (Tett 2016). Moreover, Kilian (2009) introduces a new measure of monthly global real economic activity based on dry cargo bulk freight rate data that is used to disentangle demand and supply shocks in the global crude oil market.Footnote 7

Lin and Sim (2013) highlight that BD has become one of the most important indicators of the cost of shipping and an important barometer of the volume of worldwide trade and manufacturing activity. Although the predictive ability of BD has recently waned, BD still shows some potential. Bakshi et al. (2011) find evidence of positive association between a BD increase and growth on stock/commodity returns as well as in global economic activity by studying the industrial production of 20 countries. Furthermore, using daily data spanning from 1985 to 2012, Apergis and Payne (2013) show the predictive capacity of the BD for both financial assets and industrial production, whereby the relationship is found to be positive.

As mentioned earlier, we have included national foreign exchange (NFX) rate because oil is usually priced in USD and there appears to be a relationship between oil and NFX.Footnote 8 Basher et al. (2012) highlight that lower USD coincides with higher oil prices and vice versa.Footnote 9 Nevertheless, Lizardo and Mollick (2010) make different observations for oil exporters and importers which motivate us to include NFX rate in our study as we are exploring net oil exporters and importers.

2.2 Causality

Past literature appears to show that the four predictive variables impact the economy of countries. Nevertheless, we believe that there may also be an inverse relationship whereby economic growth influences our predictive variables.

With reference to oil, as economies develop, it is expected that the energy consumption of those economies will increase resulting in a higher demand for oil causing oil price to increase. Al-Iriani (2006) finds a unidirectional causality running from GDP to energy consumption by studying six Gulf Cooperation Council (GCC)Footnote 10 countries. Similarly, Mehrara (2007) also shows a unidirectional strong causality running from economic growth to energy consumption for eleven oil-exporting countries.

Furthermore, Clements and Fry (2008) highlight that commodity-exporting countries through their exchange rate can have an impact on commodity prices. This situation can arise if a country is a large producer of a commodity or if a group of commodity-exporting countries have the combined market power to influence the world prices of commodities. This can relate to oil as well. In fact, Clements and Fry (2008) give examples of Saudi Arabia which has the ability to influence oil prices. Moreover, Saudi Arabia is part of OPEC (Organization of Petroleum Exporting Countries), a group of oil-exporting countries, which have the combined market power to influence oil prices. Kaufmann et al. (2004) actually find evidence that OPECFootnote 11 Granger causes real oil prices, but there is no inverse relationship (or causality).

There are also studies that find bidirectional causality such as Oh and Lee (2004). They find a long-run bidirectional relationship between energy and GDP by studying Korea from 1970 to 1999. Even though Soytas and Sari (2003) obtain mixed results for their sample countries, they find bidirectional causality for Argentina. Thus, the overall literature appears to suggest the possibility of bidirectional relationship between oil and economic growth.

Similarly, past literature appears to show that there is a potential two-way relationship between illiquidity and macroeconomic variables. Fujimoto (2004) notes that macroeconomic fundamentals seem to be significant determinants of liquidity, while Næs et al. (2011) highlight an inverse relationship for the same country. Meanwhile, Pereira and Zhang (2010) do find a bidirectional relationship, but their study involves stock market and liquidity. Galariotis and Giouvris (2015) do find evidence that there is a two-way causality between macroeconomic indicators and liquidity variables for the six countries in their sample, but it is more consistent for global liquidity, whereas Lim and Giouvris (2016) obtain similar results for national liquidity.

The Baltic Dry index (BD) also appears to have the ability to predict economic growth (Bakshi et al. 2011). Nevertheless, there also seems to be an inverse relationship between macroeconomic variables and BD as well. Klovland (2002) shows that cycles in economic activity are major determinants of the short-run behavior of shipping freight rates in the years between 1850 and World War I. Moreover, since Apergis and Payne (2013) indicate that there is a relationship between commodities and BD, a change in demand for commodities should have an effect on BD as well. For example, an increased demand for commodities will eventually affect BD. Bloch et al. (2012) mention that China’s demand for coal is surging because of China’s strong economic growth. Hence, there is potentially a two-way relationship between BD and economic growth. In fact, Bloch et al. (2012) find that there is bidirectional causality between coal consumption and GDP using demand-side analysis. Thus, since coal is part of BD, it should be expected that economic growth may also affect BD. Overall, there is potentially a two-way causality between the Baltic Dry index and the macroeconomy.

Finally, past literature appears to show that national foreign exchange (NFX) can influence economic activity. Cunado and De Gracia (2005) highlight that the impact of oil price shocks on economic activity becomes more significant when shocks are defined in national currencies. However, we believe that economic growth can also affect NFX rate. Inman (2015) highlights that the main reason that China devalued the Yuan is due to its flagging economy. This was also reported by Ryan and Farrer (2015), indicating that the state of the economy of a country can also impact NFX rate. Therefore, the possibility of a two-way relationship between the NFX rate and economic growth is present.

2.3 Net oil-exporting countries versus net oil-importing countries

We believe that the degree to which oil is important to a specific country’s economy may result in this specific country to react differently to oil price movements. For instance, a country that is less dependent on oil is expected to react less to any movement in oil prices.

Earlier research tends to focus on the US economy, an oil importer, and the results show that there is a significant increase in the price of crude petroleum prior to recession periods (Hamilton 1983). However, an oil exporter is expected to benefit from an oil price increase, as shown by Saudi Arabia’s willingness to cut oil production in order to improve revenue and their economy (Sheppard et al. 2016). Wang et al. (2013) mention that the influence of oil price shocks on the national economies of oil-exporting countries can be different from those of oil-importing countries. Oil price increases may bring positive effects on the national economies of oil-exporting countries.

Mork et al. (1994) obtain results which show that Norway, an oil-exporting country, benefits significantly from oil price increases. Moreover, Mork et al. (1994) highlight that Norway seems to be hurt by oil price declines but less significantly. Mork et al. (1994) mention that if the domestic oil sector is large enough relative to the size of the economy, a country’s net oil-exporting position appears to influence the oil price GDP correlation substantially. Nevertheless, UK,Footnote 12 another oil-exporting country in their research, exhibits similar results to oil-importing countries such as USA, Germany, France, and Japan.

Cunado and De Gracia (2005) find that Malaysia’s oil priceeconomy relationship seems to be less significant compared to other five Asian economies, as Malaysia is the only oil-exporting country in their sample. Cunado and De Gracia (2005) stress that more research is required to draw conclusions, but their results seem to suggest that there are different responses between oil exporters and oil importers.

Moreover, Wang et al. (2013) highlight the different reaction between oil-exporting and oil-importing countries, as positive aggregate and precautionary demand oil shocks are shown to result in a higher degree of co-movement among the stock markets in oil-exporting countries but not in oil-importing countries. Engemann et al. (2014) highlight that apparently the most energy-intensive US states are the ones that respond only to negative oil price shocks.

Overall, it seems that the classification of whether a country is an oil exporter or importer is important when undertaking research in this area. However, past studies seldom differentiate between oil-exporting countries and oil-importing countries, which is also highlighted by Wang et al. (2013). If they do differentiate between oil-importing/exporting countries, their focus is on the relationship between oil price shocks and stock markets instead of macroeconomic activity. This indicates the importance of this study.

3 Data and variables

3.1 Data

We have chosen ten (10) countries for our data sample expanding from January 1998 to December 2015. Using the most recent data obtained from the US Energy Information Administration (EIA) website, we have equally segregated our countries into five (5) net oil-exporting countries and five (5) net oil-importing countries. The net oil-exporting countries are Norway, Canada, Denmark, Mexico, and Brazil, while the net oil-importing countries are Singapore, UK, Germany, Japan, and France. The countries and periods are selected based on the availability of financial markets and economic data of the respective countries. Unfortunately, due to limited data availability, we are unable to include any members of the OPEC. Please refer to Table 1 for more information.

Table 1 Details of the ten (10) countries in our sample

3.2 Macroeconomic, market, and illiquidity data

We use the constituents of stock indexes of our chosen ten (10) countries to calculate market data such as our illiquidity measure. The indexes that we chose are Oslo All Share index (Norway), TSX Composite index (Canada), OMXC index (Denmark), IPC index (Mexico), Bovespa index (Brazil), STI index (Singapore), FTSE All Share index (UK), Prime All Share index (Germany), Nikkei 225 (Japan) and SBF120 index (France).

Gross domestic product (GDP) is used to determine economic growth. For financial variables (FV) and as control variables, we use the risk-free rate (RF), standard deviation or market volatility (SD), excess market returns (XS), and dividend yield (DY). Risk-free rate (RF) is the quarterly risk-free rate of the respective countries,Footnote 13 while standard deviation or market volatility (SD) is the standard deviation of daily average returns for all stocks over each quarter. Dividend yield (DY) is calculated as the cross-sectional quarterly average for all stocks of the respective countries. Excess market returns (XS) are the cross-sectional average returns for all stocks of the respective countries in excess of the risk-free rate of the respective countries also over each quarter. Unfortunately, due to the limited number of stocks available for certain countries, certain financial variables that are used by Galariotis and Giouvris (2015) are not available for us such as size premium (SMB) and value premium (HML).

Our five (5) predictive variables are national foreign exchange (NFX), national illiquidity (NAM), global illiquidity (GAM), crude oil Brent (OB), and the Baltic Dry index (BD). National foreign exchange (NFX) is the specific country’s currency foreign exchangeFootnote 14relative to USD, and hence an increase in value will signify that USD has strengthened, while the respective country’s currency has weakened. For instance, an increase in the GBP/USD value means that GBP has weakened, while USD has strengthened. The opposite scenario will be observed if the NFX value reduces. We include NFX because the crude oil Brent (OB) is normally priced in USD and Cunado and De Gracia’s (2005) study of six (6) Asian countries suggests that the significant effect of oil price shocks on macroeconomic variables becomes more significant when oil prices are defined in local currencies.

Different illiquidity measures capture different aspects of liquidity (Goyenko et al. (2009)). There are various measures available such as Bid-Ask spread (Amihud and Mendelson 1986) and High-Low Spread (Corwin and Schultz 2012). Amihud et al. (2005) mention that there is hardly a single liquidity measure that can capture all aspects of estimating the effect of liquidity on asset prices. We have decided to choose the Amihud illiquidity measure (Amihud 2002). The reason we made this decision is because it is a recognizable measure which has been extensively used in the past literature and it is simple to calculate.

Our Amihud illiquidity measure is calculated for each stock, s, in all countries for every quarter as follows:

$$ {\text{Amihud}}_{\text{sq}} = \frac{1}{q}\mathop \sum \limits_{t}^{{}} \frac{{1{,}000{,}000 \times \left| {{\text{return}}_{t} } \right|}}{{{\text{price}}_{t} \times {\text{volume}}_{t} }} $$
(1)

where t is each trading day.

We believe that using one illiquidity measure is sufficient because we will be considering two aspects of illiquidity, namely national and global illiquidity for all the countries in our sample. National illiquidity (NAM) is simply the cross-sectional average of Amihud illiquidity measure for all stocks of the respective countries in our sample. Global illiquidity (GAM) is created using the equally weighted average of the Amihud illiquidity measure across all stocks for the nine (9) countries, with the exception of the stocks belonging to a specific country nominated for the analysis. This is similar to Brockman et al.’s (2009) and Galariotis and Giouvris’s (2015) technique. For instance, the global illiquidity (GAM) measure used in the UK regressions is the equally weighted average of all sample stocks of the nine (9) countries, with the exception of stocks that are part of the UK FTSE All Share index.

Oil is based on the crude oil Brent prices (OB), and we chose to use it because at the point of our data collection, crude oil Brent (OB) is considered as the most widely used oil reference (Kurt 2015). In comparison with other benchmarks such as the WTI (West Texas Intermediate), around two-thirds of global crude contracts use crude oil Brent (Kurt 2015).

Lastly, the Baltic Dry index (BD) is an index that tracks the cost of shipping commodities, such as coal, iron ore, steel, cement, and grain, around the world (Apergis and Payne 2013). Thus, it can be an indicator of global demand for raw materials as well as a predictor of growth in global economic activity (Bakshi et al. 2011). Moreover, BD appears to be closely related to oil. Tett (2016) remarks that the behavior of the BD is almost as dramatic as oil prices when viewing the global economy.

We use daily data to calculate our quarterly variables except for GDP which is available only quarterly. Before the calculation of the illiquidity measures and construction of the portfolios, the sample is initially scrutinized for any unsuitable data to avoid biased results. All the data used in this paper are obtained from DataStream, Bloomberg, the World Bank website, and the US Energy Information Administration (EIA) website.

3.3 Details of countries and variables

Table 1 provides more information of our chosen ten (10) countries, which is constructed using the most recently available data of the year 2012, obtained from the US EIA website. The table reports the “oil exports” and “oil imports” of the countries in our sample as well as the “net oil exports (imports)”, which is merely the difference of oil exports and imports. Using the net oil exports, the ten (10) countries are then segregated into five (5) net oil-exporting countries and net oil-importing countries, respectively. The net oil exporters are Norway, Canada, Denmark, Mexico, and Brazil, while net oil importers consist of Singapore, UK, Germany, Japan, and France. The table also reports the “annual oil revenue (expenditure) to GDP ratios” of the countries, which are calculated using Wang et al.’s (2013) framework. The “annual revenue (expenditure)” of a country’s net oil exports (imports) is calculated using the following formula:

$$ {\text{Annual}}\;{\text{revenue}}\,\left( {\text{expenditure}} \right)\;{\text{of}}\;{\text{a}}\;{\text{country's}}\;{\text{net}}\;{\text{oil}}\;{\text{exports}}\,\left( {\text{imports}} \right) = {\text{Daily}}\;{\text{oil}}\;{\text{exports}}\,\left( {\text{imports}} \right) \times {\text{number}}\;{\text{of}}\;{\text{days}}\;{\text{in}}\;{\text{a}}\;{\text{year}} \times {\text{the}}\;{\text{annual}}\;{\text{average}}\;{\text{oil}}\;{\text{price}} $$
(2)

where the annual average oil price of USD112.02 is the average price per barrel for crude oil Brent in the year 2012 obtained from DataStream and the number of days in the year 2012 is 366 days because it is a leap year.

Since we are investigating the Baltic Dry index, we have also included information for “liner shipping connectivity index” because it captures how well countries are connected to global shipping networks and it is computed by the United Nations Conference on Trade and Development (UNCTAD). Other information that we include in the table is the countries’ “exports, imports and net exports for goods and services (as a percentage of GDP)” as well as “GDP per capita” and “MSCI market classification”. With the exception of MSCI market classification, all the information is obtained from the World Bank website and it is more updated in comparison with our oil information, as we manage to obtain information as of 2015. The MSCI market classification categorizes the countries in our sample as either developed or emerging markets/countries as of 2016, and it is obtained directly from MSCI website.

Table 1 shows that Canada is a major net oil-exporting country, whereas Germany is the main net oil importer. The “annual oil revenue to GDP ratio” appears to be the highest for Norway, while Singapore’s “annual oil expenditure to GDP ratio” is the highest in comparison with the other countries’. The table also shows that only Mexico and Brazil are classified as emerging markets/countries by MSCI, while Singapore is the highest net exporter of goods and services as a percentage of GDP. Interestingly, the liner shipping connectivity index for the five (5) net oil-importing countries is higher in comparison with the five (5) net oil exporters with Singapore having the highest index value.

In Table 2, panel A shows descriptive statistics (mean, median, standard deviation, maximum, and minimum) of the GDP for the ten (10) countries, while panel B exhibits descriptive statistics for crude oil Brent (OB) and the Baltic Dry index (BD). In panel C of Table 2, we present descriptive statistics of the national foreign exchange (NFX) rate of the ten (10) countries relative to the USD. The last two (2) panels (panel D and panel E, respectively) exhibit descriptive statistics of the two (2) liquidity measures, namely national (NAM) and global illiquidity (GAM).

Table 2 Descriptive statistics of the chosen variables of the ten (10) countries in our sample

4 Methodology, empirical results, and analysis

4.1 Predictive variables and business cycles

Figures 1, 2, 3, and 4 exhibit time series for the four out of the five (5) predictive variables in our research in relation to recession periods. Our five (5) predictive variables consist of national illiquidity (NAM), global illiquidity (GAM), national foreign exchange (NFX), oil (OB), and the Baltic Dry index (BD). We define a period as a recession period when there is negative GDP growth for at least two consecutive quarters. The grey columns capture negative growth for at least 2 terms. If the negative GDP growth is for one term only, then there will be NO grey columns in the graph even though there is a spike before.Footnote 15

Fig. 1
figure 1

Business cycles and national illiquidity based on the Amihud illiquidity measure. The figure shows time series plots of the national illiquidity based on Amihud illiquidity measure (NAM) for all the countries in our sample, which are represented by the black lines. Shaded grey columns are recession periods, and a recession period is identified as a period for which there is negative GDP growth for at least two consecutive terms. Sample range: Q1 1998 to Q4 2015, 72 quarterly observations. All data are obtained from DataStream, Bloomberg, World Bank, and the US Energy Information Administration (EIA) website

Fig. 2
figure 2

Business cycles and global illiquidity based on the Amihud illiquidity measure. The figure shows time series plots of the global illiquidity based on Amihud illiquidity measure (GAM) for all the countries in our sample, which are represented by the black lines. Global illiquidity is constructed as in Brockman et al. (2009) and Galariotis and Giouvris (2015) whereby global illiquidity is created by combining all countries except the country nominated for the test. Shaded grey columns are recession periods, and a recession period is identified as a period for which there is negative GDP growth for at least two consecutive terms. Sample range: Q1 1998 to Q4 2015, 72 quarterly observations. All data are obtained from DataStream, Bloomberg, World Bank, and the US Energy Information Administration (EIA) website

Fig. 3
figure 3

Business cycles and crude oil Brent price. The figure shows time series plots of the crude oil Brent price, which are represented by the black lines. Shaded grey columns are recession periods, and a recession period is identified as a period for which there is negative GDP growth for at least two consecutive terms. Sample range: Q1 1998 to Q4 2015, 72 quarterly observations. All data are obtained from DataStream, Bloomberg, World Bank, and the US Energy Information Administration (EIA) website

Fig. 4
figure 4

Business cycles and Baltic Dry index. The figure shows time series plots of the Baltic Dry index, which are represented by the black lines. Shaded grey columns are recession periods, and a recession period is identified as a period for which there is negative GDP growth for at least two consecutive terms. Sample range: Q1 1998 to Q4 2015, 72 quarterly observations. All data are obtained from DataStream, Bloomberg, World Bank, and the US Energy Information Administration (EIA) website

The figures reveal that the countries in our sample have different recession periods and those periods do not last the same. Figure 1 shows that national illiquidity (NAM) is able to predict recessions for all net oil exporters, as NAM increases before the recession. For some net oil exporters such as Norway, Canada, and Brazil this relationship is very clear. Among net oil importers, Singapore, UK, and Germany show the strongest relationship between illiquidity and subsequent recessions. At this point some of the readers might say that there are spikes which are not followed by recessions (grey columns). This is because those recessions last only for a term and are not captured by grey columns as it is the norm in the literature. If there is a grey column, then this is preceded by an increase in illiquidity. The correct way to read the graphs that follow is to identify the grey columns first and then check whether the grey columns are preceded by spikes in illiquidity and not the other way around. To identify the spikes first and then check whether a grey column follows is not the right way because negative growth could occur just for a single term which by definition is NOT captured by a grey column.

Figure 2 results are more consistent, as global illiquidity (GAM) increases prior to the recession period for the majority of the countries. At this stage we need to remind the readers how GAM is constructed. It is based on illiquidity of all countries in the sample except the country whose recession(s) we are trying to predict. As you understand maybe there is a liquidity crisis in all other countries but not in the one under investigation. By construction global illiquidity would be a weaker indicator since the liquidity of the country under consideration is excluded. Having said that, for all periods which are identified as recessions (2 + terms of consecutive negative GDP growth) by the grey columns, global illiquidity increases beforehand even though it is a weaker indicator by construction as we explained above. Japan presents contradictory results for 2011–2012 and France for 2012, but these are the only incidents.

With reference to oil (OB), Fig. 3 shows that all five (5) net oil-importing countries go into recession immediately after an increase in oil price (OB) during the big financial crisis (concentrate on the thickest grey column, which aligns perfectly for all graphs for all countries) which is consistent with past studies such as Hamilton (1983). Net oil exporters go into recession after an oil price decrease. The only exception is Denmark whose recession is concurrent with the oil price decrease. This is actually expected for net oil exporters as a decrease in oil price is considered detrimental for such countries and is consistent to Mork et al. (1994) who finds that Norway, a net oil exporter, reacts differently to the oil-importing countries in their sample. Among net oil exporters, Denmark is the only country that reacts differently to oil (OB) during the crisis. Table 1 shows that Denmark exports the smallest amount of crude oil and has the second lowest “annual oil revenue to GDP ratio”, indicating that probably the economy of Denmark may not be too dependent on oil. Following the big financial crisis, it takes a number of years before the price of oil bounces back to pre-crisis level and as you can see from the graphs there are periods (see Japan) which are identified as recession periods and the price increase does capture the recession. Japan suffers another recession before France and Germany. The graphs are stacked on top of each other, and the grey columns (which indicate recession) almost align perfectly. In the case of Japan the price index does capture the recession(s) that follow the big crisis, but in the other 2 countries there is no recession as it is defined in the literature. The needs of each country for oil are different so that it is not possible for the price index to predict recessions at the same point in time for all countries. Japan suffers more recessions than Germany and France because it may have more need for oil. In addition, governments take action to prevent a recession and some governments are better than other. So the fact that in some cases there are spikes even though there is no grey column (recession), could be because some governments are better than other at preventing recessions. Also keep in mind that the recession could be just for a single term which by default does not appear in the graphs. In addition, France and Germany are EU members and there is more coordination to tackle with recessions. Japan is not. We believe that the case of Japan, Germany, and France clearly illustrates this point. In Japan the index does capture a recession as indicated by the grey column, but in France and Germany there is no recession because maybe it was too small to be recorded and appear in the graph. We think that in this particular case the index is doing a very good job.Footnote 16

Figure 4 shows that for net oil importers, a decrease in Baltic Dry is almost concurrent with the crisis. Baltic Dry starts from a high point and decreases during the crisis. See for example the thickest grey columns for Singapore, UK, Germany, Japan and France. The graphs for those countries are stacked on top of each other, and the biggest recession/thickest grey columns almost align perfectly. In all those occasions the BD reaches peak before and declines during the recession. The same happens in Denmark and Mexico even though they are oil exporters. This is the case for 7 countries out of 10 countries in the sample for the biggest worldwide recession. For shorter (less severe) recessions the index might not work so well, but at least for the big recession it is very consistent. For net oil exporters, Baltic Dry seems to predate the crisis for a very short period of time (see Brazil, Mexico, and Canada). In the case of Denmark, the decrease is concurrent with the crisis, while in the case of Norway, Baltic Dry actually increases before the crisis. Bakshi et al. (2011) highlight that increases in the Baltic Dry index growth rate could predict increases in economic growth, concurring with strengthening commodity prices and rising stock markets. Rothfeder (2016) reports that BD predicted IndyMac’s bankruptcy during the financial crisis of 2007–2008. Overall, the index is capable of capturing big recession(s) but may fail on shorter less severe recessions. In addition, the index may peak and then decline during a recession, but this is not captured in the graph by a grey column because it lasts for less than a term.

The main points from the analysis above are as follows:

  1. 1.

    In comparison with national illiquidity (NAM), global illiquidity (GAM) shows more consistent results since during the financial crisis, GAM is able to predict recessions for the majority of countries.

  2. 2.

    With reference to oil (OB), all five (5) net oil-importing countries go into recession immediately after an increase in oil price during the financial crisis, while it is observed that oil price actually decreases prior to recessions for net oil exporters (with the exception of Denmark), which is expected.

  3. 3.

    The Baltic Dry index (BD) is concurrent to the recession for net oil importers, while it decreases for net oil exporters (with the exception of Norway) prior to recessions, indicating that it may actually be a good proxy for oil.

Moreover, it appears that oil may have a stronger effect on economic growth relative to BD. Further analysis will follow to investigate this issue.

4.2 Correlations

Correlations in Table 3 use only raw data before any differencing and orthogonalization. The correlation analysis in Table 3 shows the relationship between our variables for all countries in our sample. Panel A to panel E show the correlation results for net oil exporters. The correlation results for net oil importers are presented in panel F to panel J. We will initially look at the relationship between gross domestic product (GDP) and financial variables (FV),Footnote 17 followed by the relationship between GDP and the predictive variables inclusive of national foreign exchange (NFX), national illiquidity (NAM), global illiquidity (GAM), crude oil Brent (OB) and the Baltic Dry index (BD).Footnote 18 Our correlation tables also present relationships between financial variables and predictive variables as well as correlations among predictive variables themselves.Footnote 19 If the reader wishes to avoid the discussion that follows, the reader can skip to the last paragraph where everything is summarized in just 4 points.

Table 3 Correlations of the chosen variables for all ten (10) countries

Similar to Galariotis and Giouvris (2015), it appears that standard deviation (SD) (or market volatility) and dividend yield (DY) are negative and significantly correlated to GDP for most countries, with the exception of Norway and Canada. Six (6) countries have excess market returns (XS) that are positively correlated to GDP, signifying that as excess market returns increase GDP also improves. The risk-free rate (RF) shows less consistent results, as only two (2) countries are found to be negatively correlated to GDP. The negative correlation between the risk-free rate and GDP is expected since as the interest rate falls, investment increases and this brings about an increase in GDP.

Correlations between GDP and the predictive variables show that out of the five (5) predictive variables, illiquidity variables appear to be more strongly correlated to GDP. Between national (NAM) and global illiquidity (GAM), the latter seems to be more important as six (6) countries out of 10 exhibit significant correlations to GDP, while for national illiquidity (NAM) only four (4) countries show correlations. As expected, the two (2) illiquidity variables consistently show negative correlations to GDP, indicating that GDP increases with a decrease in illiquidity (or increase in market liquidity).

Correlations are less noticeable for the other three predictive variables. The Baltic Dry index (BD) and foreign exchange (NFX) show no significant correlations with GDP. (Only 2 countries out of 10 appear to show significant values.) In relation to crude oil Brent (OB), only the GDP of UK and France show significant negative correlations to oil as expected since they are oil importers.

Overall, the main message from this section is that

  1. 1.

    Financial variables have stronger correlations to GDP in comparison with predictive variables. Standard deviation (SD) appears to relate to GDP of most countries.

  2. 2.

    Among the predictive variables, global illiquidity (GAM) is found to have the strongest relationship with countries’ GDP, while the Baltic Dry index (BD) and crude oil Brent (OB) are found to be less correlated to GDP.

  3. 3.

    Financial variables and predictive variables appear to show some significant correlations to each other.

  4. 4.

    Oil (OB) is found to be positively correlated to BD, and this somehow justifies some researchers’ usage of the BD to estimate oil demand.

Finally (and this justifies why it is important to present correlations between all variables), significant correlations between financial and predictive variables used in the same regression(s), necessitate orthogonalization.

4.3 In sample prediction of economic growth

4.3.1 Stationarity and orthogonalization

In this section, we test the data for stationarity before conducting any further analysis, as non-stationaryFootnote 20 data will result in potentially unreliable and biased outcomes. We conduct six (6) stationarity tests, namely the augmented Dickey–Fuller (ADF) test, GLS detrended Dickey–Fuller (DFGLS) test, Phillips–Perron (PP) test, Kwiatkowski, Phillips, Schmidt and Shin (KPSS) test, Elliot, Rothenberg and stock point optimal (ERS) test and the Ng and Perron (NP) test on all the variables, and if the variable examined satisfies at least four (4) of the stationarity tests, we consider the variable as stationary.Footnote 21 The variables have been differenced to become stationary if the variable is deemed non-stationary. The variables that have been differenced have a D in brackets at the back of the name of the variable in the tables.Footnote 22

The correlation analysis also shows that most independent variables are correlated to each other, signifying the possibility of biased results due to multicollinearity. Thus, in order to avoid multicollinearity, we have also orthogonalized all the relevant variables using the same technique utilized by Brockman et al. (2009) and Galariotis and Giouvris (2015). For example, in order to orthogonalize the explanatory variables X1, X2, and X3, we run the following regressions: X1 = c + X2 + X3 + residualsX1 and X2 = c + X3 + residualsX2. From those 2 regressions we obtain: residualsX1 and residualsX2. By running those 2 regressions, we remove the effects of X2 and X3 from X1 and the effect of X3 from X2. X3 remains as it is. This means that residualsX1, residuals X2, and X3 are independent from each other and their correlations are zero. Multicollinearity is not an issue. Then, we use residualsX1, residualsX2 and X3 in order to explain Y. The regression we use to explain Y is as follows: Y = c + residualsX1 + residualsX2 + X3 + error term.Footnote 23

4.3.2 Predicting economic growth using individual variables

We estimate the following model to assess the predictive ability of our independent variables:

$$ Y_{t + 1} = \alpha + \beta^{{\prime }} FV_{t} + \gamma^{{\prime }} X_{t} + \varepsilon_{t + 1} $$
(3)

where Yt+1 is the realized growth of our macroeconomic variable, GDP, one quarter ahead (t + 1); FVt are the control variables at contemporaneous quarter t and contain the following financial variables (FV): the risk-free rate (RF), standard deviation, or market volatility (SD), excess market returns (XS), dividend yield (DY), at least one lag of the dependent variable (GDP), and more lags of the GDP if autocorrelation remains in the residuals. Xt contains the following predictive variables: national foreign exchange (NFX), national illiquidity (NAM), global illiquidity (GAM), crude oil Brent (OB), and Baltic Dry index (BD). \( \beta^{\prime} \) and \( \gamma^{{\prime }} \) are the vector of coefficient estimates for the financial variables (or control variables) and predictive variables, respectively, and ε is the error term.

In Table 4, we run six different regression models in order to identify the contribution of our predictive variables to economic growth. The first regression model includes one lag of the dependent variable and financial variables only. The following five regression models use the same variables as the first regression model, but we add one predictive variable at a time. This is repeated for all countries. Table 4 shows that only France requires an additional lag of the dependent variable (GDP), as initially there is an autocorrelation in the residuals. We have reported both regressions in panels J and K, respectively.

Table 4 In sample prediction of economic growth using individual predictive variables for all ten (10) countries

Our first regression model which includes only financial variables shows that excess market returns (XS) is the most relevant variable as it is positive and significant for six (6) countries, namely Norway, Denmark, Mexico, Brazil, Singapore, and France. Standard deviation (SD), dividend yield (DY), and the risk-free rate (RF) are less important.

We will now investigate the effect of our predictive variables, adding one at a time. By adding national foreign exchange (NFX), only Brazil shows a significant result. Global illiquidity (GAM) is less important in comparison with national illiquidity (NAM), as only two (2) countries’ GDP is predicted by GAM, while four (4) countries’ economic growth can be predicted by NAM.

Interestingly, crude oil Brent (OB) appears to be the most significant variable as the economic growth of nine (9) countries is positively predicted by it. Only UK, a net oil importer is not affected by OB. All the countries that are affected exhibit a positive coefficient, signifying that as oil price increases, the GDP of those countries also increases. Moreover, Mexico displays the highest positive coefficient, which is not surprising, as Mexico is a net oil exporter. However, for net oil importers we expect the opposite results whereby an oil price decrease will increase GDP of those countries as they will be able to import oil cheaper for the development of their economy. Table 4 provides contradictory results for oil (OB), but Mork et al. (1994) do find evidence that USA and Canada are positively related to a decrease in oil price even though the two (2) countries are oil importer and potentialFootnote 24 oil exporter, respectively. However, we will investigate this further in the next section when we include all variables.

The Baltic Dry index (BD) is found to be significant for three (3) countries, namely Canada, UK, and France. The negative coefficients indicate that as BD increases, the economy of the three (3) countries shrinks. We notice that the three (3) countries’ “net exports of goods and services (% of GDP)” is negative and one way to explain this, is that as the BD increases (which indicates an increase in demand for raw materials as well as the price for those materials) this results in more expensive imports which could lead to a GDP decline through the balance of trade.

The last panel L shows the summary of each country’s adjusted R2 after the addition of the individual predictive variables (one at a time) to our initial regression model which consists of the dependent variable (one lag or two lags) and financial variables only. National foreign exchange (NFX) provides extra explanatory power over the financial variables for three (3) countries only. In relation to illiquidity, national illiquidity (NAM) provides greater explanatory power for four (4) countries over financial variables compared to global illiquidity (GAM) which provides greater explanatory power for three (3) countries only.Footnote 25 Surprisingly, GAM and not NAM provide extra explanatory power in the case of Germany even though both illiquidity variables are significant.

As expected, oil (OB) exhibits the greatest explanatory power over financial variables, as there is improvement in nine (9) countries with the exception of UK. In the case of Japan, the addition of oil brings the highest improvement in explanatory power over financial variables. This may be due to Japan being a net importing country with the second highest “Annual oil expenditure to GDP ratio” after Singapore. Moreover, Japan is the only country that does not export any oil. Similar to NFX, the inclusion of the Baltic Dry index (BD) provides extra explanatory power for only three (3) countries. The highest improvement is observed in the case of the UK, which is consistent to our earlier regression findings.

The main message from the first set of regressionsFootnote 26 is that:

  1. 1.

    Excess market returns (XS) is the best predictor among financial variables, while NFX is the least important predictive variable.Footnote 27

  2. 2.

    Among predictive variables, oil (OB) appears to be the best predictor as it is significant in nine (9) countries.

  3. 3.

    Between illiquidity variables, national illiquidity (NAM) is found to be superior in comparison with global illiquidity (GAM).

4.3.3 Predicting economic growth using all variables

Instead of adding one predictive variable at a time, we will now use a regression modelFootnote 28 which incorporates all variables and is shown in Table 5.

Table 5 In sample prediction of the macroeconomic variable with all variables for the ten (10) countries

Table 5 shows that the effects of the risk-free rate (see Norway and Denmark), standard deviation (see Norway, and Germany) and dividend yield (see Japan) are reinforced since we obtain more significant coefficients. There are no changes for excess market returns (XS) since the same six (6) countries exhibit positive coefficients.

In relation to the predictive variables, national foreign exchange (NFX) remains negative and significant only for Brazil, confirming that Brazil benefits from their cheaper imports.

The effect of illiquidity appears to be more important than before (see NAM for Norway and GAM for Canada and Mexico). National liquidity (NAM) has more significant results compared to global illiquidity (GAM). The GDP of four (4) countries is correctly predicted by NAM and GAM, respectively. Thus, similar to Galariotis and Giouvris (2015), this shows that market illiquidity does contain some information for estimating the current and future state of the economy of certain countries in our sample.

The GDP of the nine (9) countries (except the UK) is still predicted by oil (OB) even after including all predictive variables. The coefficients are positive which is not expected for net oil importers.Footnote 29 Probable reasons for the positive coefficients are that (1) oil importers hedge their positions, (2) their need for oil is reduced, or (3) their net position could change from importer to exporter. In relation to switching positions (from importer to exporter or vice versa), Mork et al. (1994) do find evidence that countries with different characteristics, namely USA and Canada,Footnote 30 can have a similar reaction to oil (OB).

The Baltic Dry index (BD) still predicts the GDP of three (3) countries even after including all variables. However, the composition of the three (3) countries actually changes. Brazil’s GDP is now significantly affected by BD, while the GDP of Canada is not affected by the BD.

Panel B presents a summary of explanatory power for all countries in the sample by looking at the adjusted R2 of the combined predictive variables over financial variables. After including all predictive variables into the regression, surprisingly results for two (2) countries, namely Singapore and Norway, do not show any improvement.Footnote 31 Predictive variables for Germany show the greatest explanatory power over financial variables, as the adjusted R2 increases by more than 200%.

Overall, the results show that when including all variables, oil (OB) is able to predict economic growth for most countries in our sample, while excess market returns (XS) is the best predictor among financial variables (FV). Regarding national and global illiquidity there are changes in the number of countries affected. National illiquidity (NAM) is significant for five (5) countries’ GDP, and global illiquidity (GAM) is significant for four (4) countries’ GDP. The Baltic Dry index (BD) has a positive effect on Brazil’s GDP after the inclusion of all variables. With regard to explanatory power, Germany shows the highest improvement, while Norway and Singapore are the only two (2) countries that do not show any improvement after including all predictive variables. The main message one should keep in mind from all those regressions is that oil (OB) has greater explanatory power in comparison with other predictive variables such as BD and the illiquidity variables.

4.3.4 Summary of the average adjusted R 2

Table 6 presents the grand average of adjusted R2. The first line shows the results when all countries are included. National foreign exchange (NFX) does not show any extra explanatory power over financial variables (FV). Global illiquidity (GAM) has extra explanatory power over national illiquidity (NAM) and the Baltic Dry index (BD). BD has more explanatory power in comparison with NAM. Nevertheless, the extra explanatory power of the three (3) variables dwarves by the extra explanatory power of oil (OB), signifying the importance of oil (OB) for predicting economic growth.

Table 6 Summary of the average adjusted R2 of the ten (10) countries as a group (all countries, net oil exporters and net oil importers)

So far our study shows the importance of oil (OB) for the countries in our sample. In order to research this further, we have categorized the ten (10) countries into net oil exporters and net oil importers. To recap, net oil exporters are: Norway, Canada, Denmark, Mexico, and Brazil, while net oil importers are: Singapore, UK, Germany, Japan and France.

The adjusted R2 for net oil exporters (line 2) shows that NFX now has extra explanatory power over financial variables, but BD does not have extra explanatory power. In terms of illiquidity variables, GAM remains superior in comparison with NAM. Nonetheless, oil (OB) outperforms all other predictive variables. For net oil importers (line 3), results are similar whereby oil (OB) provides superior explanatory power. By comparing the three groups, it appears that oil (OB) is more important for net oil exporters as the explanatory power is higher in comparison with the other two groups, consistent with Wang et al. (2013).

The Baltic Dry index (BD) is found to be more important for net oil importers probably since the countries are more focused on trading goods and services rather than oil (OB).

With reference to illiquidity, global illiquidity (GAM) seems to be more important for net oil exporters, while for net oil importers, national illiquidity (NAM) appears to be more important. National foreign exchange (NFX) also provides greater explanatory power for net oil exporters relative to net oil importers, implying that NFX may be important for them for trading oil. Being an emerging country may play a role as well. Brazil is the only country that displays significant results for NFX.

Here, we summarize all our findings from the analysis above and draw general conclusions condensed in four points:

  1. 1.

    Both illiquidity variables are able to provide greater explanatory power in comparison with financial variables, but the global illiquidity (GAM) variable is apparently superior.Footnote 32

  2. 2.

    The Baltic Dry index (BD) also provides some explanatory power, while national foreign exchange (NFX)Footnote 33 is the only variable that does not provide any additional explanatory power when all countries are included.

  3. 3.

    It can be unanimously stated that oil (OB) is the most important predictive variable,Footnote 34 as it provides the greatest explanatory power, especially for net oil exporters, and

  4. 4.

    BD appears to be more important for net oil importers.

The results obtained (in this stage) from adding all variables together in a single regression for each country are similar to the results obtained from adding one variable at a time in multiple regressions (previous stage). They confirm the suitability and importance of the chosen predictive variables.

4.4 Causality

So far our research has focused on the relationship and the effect of predictive variables on GDP. However, there is a possibility of an inverse relationship that is GDP may cause the predictive variables or even a two-way relationship. For instance, in relation to illiquidity, Fujimoto (2004) who studies the US market finds evidence that macroeconomic fundamentals are significant determinants of liquidity, while for oil (OB), Sheppard et al. (2016) report that due to big oil-producing countries going into recession, OPEC led by Saudi Arabia decided to cut oil production to help the oil market recover, signifying that there is a possibility for oil prices (OB) to be affected by GDP. With respect to national foreign exchange (NFX), Inman (2015) highlights that the main reason that China devalued its currency is due to its weakening economy, while for the Baltic Dry index (BD), Bloch et al. (2012) mention that due to China’s strong economic growth, China’s demand for coal is surging, and since coal is part of BD, it is expected that economic growth may also affect BD.

Furthermore, there is also evidence of a two-way or bidirectional relationship between the chosen predictive variables and macroeconomics. Galariotis and Giouvris (2015) find a two-way causality between global liquidity and macroeconomic variables in their study of G7 countries, while Bloch et al. (2012) find bidirectional causality between coal consumption and GDP, as coal is one of the raw materials captured by BD.

4.4.1 Causality results for all countries, net oil exporters and net oil importers

In Table 7, we use Galariotis and Giouvris (2015) methodology to investigate the possibility of an inverse or a two-way relationship between our predictive variables and GDP. Similarly, we use two causality tests, namely the “standard pairwise Granger causality panel data test” and the Dumitrescu–Hurlin (D–H) panel data test”. However, unlike them, we have two further panels of countries, namely net oil exporters (panel B) and net oil importers (panel C), in addition to the panel data involving all countries (panel A). We report the F test, and probability/p value (in parenthesis) for the standard pairwise Granger causality panel data test and the W-stat, Z bar and probability/p value (in parenthesis) for the DumitrescuHurlin (DH) panel data test. The null hypotheses for the standard pairwise Granger causality panel data test are that our predictive variables do not Granger cause GDP and GDP does not Granger cause our respective predictive variables. For the DumitrescuHurlin (DH) panel data test, the null hypothesis is that our predictive variables do not homogeneously cause GDP and then we test the null hypothesis that GDP does not homogeneously cause our predictive variables.

Table 7 Granger causality tests (panel data of all countries, net oil exporters and net oil importers)

Panel A in Table 7 reports causality results between our predictive variables and macroeconomic variable for all ten (10) countries in our sample. The panel shows that there are no interactions between national foreign exchange (NFX) and the macroeconomic variable (GDP). Both illiquidity variables appear to cause GDP based on D–H panel data test for national illiquidity (NAM) and standard Granger causality panel data test for global illiquidity (GAM). However, GDP also Granger causes GAM signifying a two-way causality for GAM, which is close to the findings of Galariotis and Giouvris (2015).

A two-way relationship can also be observed for the Baltic Dry index (Table 7, panel A, lines 9–10) according to both standard Granger and D–H tests which is close to the bidirectional evidence that Bloch et al. (2012) find between coal consumption and GDP. Oil (OB) also shows a two-way causality. Oil (OB) causes GDP (D–H test), while GDP Granger causes oil (standard Granger test). The main message from causality tests considering all countries is that there is a two-way causality for all variables except foreign exchange and GDP.

Next we will look into causality results for net oil-exporting countries in panel B of Table 7. Panel B shows that GDP Granger causes NFX. There are no interactions between national illiquidity (NAM) and GDP as previously observed when using all countries. Moreover, for net oil exporters, GDP does not homogenously cause global illiquidity (GAM) based on D–H test, but the two-way relationship between GAM and GDP remains according to the standard Granger test. In comparison with all countries, oil (OB) and the Baltic Dry index (BD) relationship with GDP remains the same, as there is still a two-way causality. The main message from causality tests considering oil-exporting countries only is that the two-way causality observed previously for all countries remains the same with minor changes. In addition, GDP Granger causes NFX.

Panel C in Table 7 shows causality tests for net oil-importing countries which consist of Singapore, UK, Germany, Japan, and France. Similar to net oil exporters, GDP of net oil importers also causes NFX according to DH test. Surprisingly, there is no interaction between national illiquidity (NAM) and GDP for net oil importers. Global illiquidity (GAM) still appears to have a two-way relationship with GDP, but it is slightly weaker compared to all countries and net oil exporters. Furthermore, there is no more a two-way causality for both oil (OB) and the Baltic Dry index (BD). GDP still Granger causes oil (OB), while BD Granger causes GDP (both tests) but not the other way around.

Our findings are summarized in four points:

  1. 1.

    GDP is found to cause national foreign exchange (NFX) regardless of segregation into net oil exporters and importers.Footnote 35

  2. 2.

    With regard to illiquidity there is a two-way relationship between global illiquidity (GAM) and GDP, similar to Galariotis and Giouvris (2015).

  3. 3.

    The Baltic Dry index (BD)Footnote 36 and oil (OB)Footnote 37 show a two-way relationship with GDP, but it appears to be stronger for the former.

  4. 4.

    Oil (OB) is apparently more important for net oil exporters as the two-way causality remains, while for net oil importers, we observe a one-way causality from GDP to oil (OB).

4.5 Net oil exporters: developed versus emerging countries

Lim and Giouvris (2016) find that causality between macroeconomic variables and liquidity is different for developed and developing markets. Since our data consist of two (2) countries that are categorized as emerging markets/countries by MSCI, we decide to investigate this briefly by further regrouping our net oil-exporting countries into developed and emerging countries. Therefore, developed countries are consisting of Norway, Canada, and Denmark, while Mexico and Brazil will form part of emerging countries.

4.5.1 Summary of the average adjusted R 2 for net oil exporters: developed versus emerging countries

As before, Table 8 presents a summary of the grand average of adjusted R2 of the relevant variables. According to Table 8, national foreign exchange (NFX) has extra explanatory power over financial variables for emerging countries, which could probably be due to Brazil, as Brazil is the only country that shows significant results in the earlier sections. Both illiquidity variables provide extra explanatory power for developed countries which is probably due to the more established financial markets of developed countries. Nevertheless, global illiquidity (GAM) remains superior compared to national illiquidity (NAM) for developed countries. As expected, oil (OB) is more important for emerging countries, as oil (OB) provides superior explanatory power over financial variables, potentially due to emerging countries over-reliance on oil. Surprisingly, the Baltic Dry index (BD) does not provide any extra explanatory power over financial variables for both developed and emerging markets. However, then again in Table 1, our net oil-exporting countries are in the bottom five “liner shipping connectivity index” of our sample.

Table 8 Summary of the average adjusted R2 of the five (5) net oil-exporting countries as a group of developed and emerging countries (net oil exporters-developed countries and net oil exporters-emerging countries)

The main point to be taken onboard from Table 8 is that oil (OB) appears to be more significant for emerging countries, while illiquidity variables provide superior explanatory power for developed countries.

4.5.2 Causality results for net oil exporters: developed versus emerging countries

We have also conducted causality tests on net oil exporters (developed countries) and net oil exporters (emerging countries) to investigate whether there is a two-way causality between GDP and the chosen predictive variables for the two groups of countries (or markets).

Panel A in Table 9 reports causality results between GDP and our predictive variables for net oil exporters (developed countries). The panel shows that national foreign exchange (NFX) Granger causes GDP, but there is no interaction between national illiquidity (NAM) and GDP. Global illiquidity (GAM) Granger causes GDP, and surprisingly, there is two-way relationship between the Baltic Dry index (BD) and GDP although in our last section BD apparently does not provide any extra explanatory power. More surprisingly, there is no interaction between oil (OB) and GDP, probably due to insufficient amount of data after segregation of net oil-exporting countries to developed and emerging countries.

Table 9 Granger causality tests (panel data of net oil exporters–developed countries and net oil exporters–emerging countries)

Panel B of Table 9 shows causalities for emerging countries among net oil exporters. Unlike developed countries, emerging countries do not show any interaction between GDP and NFX, which is unexpected as our earlier results appear to show that Brazil may be the reason that there is a relationship between GDP and NFX. GDP appears to cause both national illiquidity (NAM) and global illiquidity (GAM). Also, there is no two-way causality between GDP and the Baltic Dry index (BD), but BD does cause GDP. Similar to developed countries, there are no interactions found between GDP and oil (OB) also for emerging countries, again probably due to insufficient data.

The findings of this section are summarized as follows:

  1. 1.

    There is a two-way causality between Baltic Dry (BD) and GDP for developed countries.

  2. 2.

    There is no causality between national illiquidity (NAM) and GDP for developed countries, while for emerging countries there is a one-way causality from GDP to NAM.Footnote 38

  3. 3.

    Surprisingly, one-way causality for national foreign exchange (NFX) is found only in developed countries and not in emerging countries.

  4. 4.

    In addition, there is no causality between oil (BD) and GDP for both developed and emerging countries, probably due to insufficient amount of data after segregation of net oil-exporting countries to developed and emerging countries.

5 Conclusion

This study looks into the relationship between macroeconomic growth (captured by GDP) and predictive variables, namely national foreign exchange (NFX), national illiquidity (NAM), global illiquidity (GAM), oil (OB), and the Baltic Dry index (BD). By investigating net oil-exporting countries (Norway, Canada, Denmark, Mexico, and Brazil) and net oil-importing countries (Singapore, UK, Germany, Japan and France), this study offers original results on the two groups of countries which have not been commonly segregated in the past as highlighted by Wang et al. (2013).

This paper shows (based on the first stage of our analysis) that excess market returns (XS) is the most relevant financial variable, while among predictive variables, oil (OB) appears to be the most significant as the GDP of nine (9) countries is predicted by it. Both global (GAM) and national illiquidity (NAM) variables mainly show a negative relationship with GDP. National foreign exchange (NFX) is the least important predictive variable, as it is significant only in the case of Brazil. The Baltic Dry index (BD) is found to be negatively related to economic growth, which is contradictory to past research.

Both illiquidity variables provide greater explanatory power in comparison with financial variables, but global illiquidity (GAM) is apparently superior (based on R2). BD also provides some explanatory power, while NFX does not have any extra explanatory power when all countries are included. Overall, oil (OB) is the most important predictive variable, as it provides the greatest explanatory power. Our results show that oil (OB) has higher explanatory power for net oil exporters, while the BD seems to be more important for net oil-importing countries. Moreover, NFX is also found to provide some explanatory power for the group of net oil exporters only.

With regard to causality, we obtain almost similar findings to Galariotis and Giouvris (2015), as there is two-way causality between global illiquidity (GAM) and GDP. GDP is found to cause NFX when our sample countries are segregated into net oil exporters and importers. The Baltic Dry index (BD) and oil (OB) show a two-way causality, but it appears to be stronger for the former. Evidence for the BD is similar to Bloch et al.’s (2012) study. As expected, oil (OB) impacts GDP as noted by Mork et al. (1994). There is also an inverse causality, signifying that a group of countries can affect the price of oil (OB) as suggested by Kaufmann et al. (2004) although none of our countries are part of OPEC. In relation to net oil exporters and importers, oil (OB) is apparently more important for net oil exporters as the two-way causality remains. For net oil importers, there is only a single direction causality from GDP to oil (OB). GDP is found to cause NFX when the countries are segregated into net oil exporters and importers, signifying that macroeconomic inactivity (captured by GDP) may be the reason that countries try to manipulate their currencies as reported by Inman (2015) for China.

By further segregating net oil-exporting countries into developed (Norway, Canada, and Denmark) and emerging markets/countries (Mexico and Brazil), our results show that NFX has extra explanatory power over financial variables for emerging countries, while both illiquidity variables provide extra explanatory power for developed countries only. Nevertheless, global illiquidity (GAM) remains superior compared to national illiquidity (NAM) for developed countries. Oil (OB) appears to be more important for emerging countries, potentially due to emerging countries over-reliance on oil, while the Baltic Dry index (BD) does not provide any extra explanatory power for both developed and emerging countries. We find a two-way causality between BD and GDP for developed countries. Our findings on emerging countries are similar to Lim and Giouvris (2016), but they find no causality for developed markets. Surprisingly, a one-way causality for NFX is found only for developed countries and not for emerging countries.

Our findings are very important for policy makers and corporate managers. Oil is an important predictor of the future state of the economy, especially for oil-producing countries; therefore, policy makers in those countries need to consider carefully the movement of oil prices. This is particularly important for emerging oil-producing countries which over rely on the price of oil for their development. There have been many (un)successful attempts to manipulate the price of oil over the years. This had a temporary positive effect for the economies of oil producers and negative effects for oil importers. Prices in one way or another reverted to pre-manipulation levels. The price of oil can give a boost to oil producers, but this cannot last forever. The exchange rate is also quite important for emerging oil producers. Our results indicate that the FX rate has extra explanatory power over financial variables. Liquidity is also important; therefore, it is essential that policy makers try to keep financial markets as liquid as possible since liquid markets make new and existing investors more willing to invest in stocks which in turn makes cost of capital cheaper for companies that seek capital in the financial markets. Cheaper cost of capital facilitates new investment which in turn helps increase GDP. This is also true for developed oil exporters (Norway, Canada and Denmark). Some policy makers in developed oil-exporting countries may wrongfully believe that close monitoring of oil prices is all they need to do to keep their GDP on an increasing path. Finally, the Baltic Dry index appears to be mostly relevant to oil importers; therefore, close monitoring of the index could provide info for the future state of the economy of those countries.

Overall, in relation to illiquidity variables, our results are close to Galariotis and Giouvris (2015) and Lim and Giouvris (2016). However, in a limited number of cases our results diverge and this is probably due to different data and periods used. Nevertheless, we believe that further research is necessary in order to include OPEC countries especially when studying oil. One other issue that has arisen is the classification of the chosen countries based on the latest available data of 2012. For instance, Mork et al. (1994) classify UK as an oil-exporting country, while we consider it as a net oil-importing country. Moreover, Mork et al. (1994) highlight that the UK and Norway switch from a position of net importer to net exporter of oil in the 1970s, while Canada also has moved back and forth between net exporter and net importer over time. Therefore, for future studies the classification of countries should probably be based on the average or total oil exports or imports over the sample periods.