I. Introduction

With the aim of achieving the Sustainable Development Goals by 2030, policymakers, governments, and researchers are continuously seeking a solution that can provide ecological balance along with economic development. According to the International Finance Corporation, green finance is a financial innovation that will provide economic growth and environmental benefits. Green finance is attracting the attention of many countries (Zhang et al., 2019). Y. Wang & Zhi (2016) define green finance as a fiscal model that combines economic development and environmental protection.

Various studies have explored the role of green finance in balancing economic growth and environmental protection. Broadly, these studies can be divided into two schools of thought. The first school argues that green financing has a negative impact on economic development (Wei & Jinhua, 2014), while the second school argues that green financing enhances growth and recommends improvements in green financing systems (Haiyang, 2017). The second school has gained more support in the literature. For example, K. Wang et al. (2019), Chen et al. (2021), and He et al. (2019) contend that green finance has attributes that are similar to those of traditional finance, exemplifies environmental issues, and can help achieve economic growth. Hence, studies have started supporting green finance as an option to attain the Sustainable Development Goals (Dabyltayeva & Rakhymzhan, 2019; Taghizadeh-Hesary & Yoshino, 2019). Most of these studies point out that the major contributions to green investment have been made by the public sector.

Although several studies focus on fiscal development and economic growth, very few examine the impact of green finance on economic growth. In addition, given the economic and financial uncertainty induced by the COVID-19 pandemic, raising green funds has now become more challenging than ever. The COVID-19 pandemic has changed the scenarios and priorities of countries toward environmental issues. In response, this study is an attempt to understand the role of green financing in economic growth during the pandemic. Using a sample of 30 countries from high-, upper middle-, lower middle-, and lower-income economies, we document that green financing has a positive impact on economic growth.

The study uniquely contributes to the literature by examining the contribution of green finance to economic growth. This helps in verifying whether green financing achieves its stated intention of balancing economic development and environmental issues. In addition, it unifies green finance, environmental benefits, and economic growth into one model and draws conclusions from it that are currently lacking in the literature. Furthermore, whereas prior studies focus on one country at a time, this study considers and compares 30 countries.

The remainder of the paper is arranged as follows. Section II outlines the data and the methodology. The analysis and interpretations are discussed in Section III. Finally, the study concludes in Section IV.

II. Data and methodology

The present study uses secondary data. The conceptual model’s construction involves analyzing the impact of green spending in 30 countries on their economic growth against the background of the COVID-19 pandemic outbreak in 2020. The sample economies consist of 18 high-income economies (with a gross national income, or GNI, per capita of USD 12,696 or more), seven upper middle–income economies (with a GNI per capita of USD 4,096–12,695), four lower middle–income economies (with a GNI per capita of USD 1,046–4,095), and one low-income economy (with a GNI per capita of USD 1,045 or less). This income classification follows the World Bank Atlas method. The study employs the causal relation between green spending and other vectors of variables on the economic growth of select countries.

The data for green spending was extracted from the Global Recovery Observatory, a repository for data on global government spending during the COVID-19 crisis aimed at a sustainable impact and development. The data cover the fiscal spending of governments in the recovery from the after effects of the COVID-19 pandemic announced by 50 leading world economies.[1] Of the 50 countries with data available for green financing, only 30 countries were selected, since the data for key explanatory variables were missing from the other countries. The explanatory variables comprise inflation to proxy for monetary policy, exports as a percentage of the gross domestic product (GDP) to proxy for external sector/trade, gross capital formation as a proxy for investment, and gross debt as a percentage of the GDP to proxy for fiscal health. The data period for the explanatory as well as explained variables correspond to the year 2020. The variable descriptions and their sources are provided in Table 1.

Table 1.Variable Description
Variables Short name Description Source
Log of Green Spending by Governments (in USD billion) greenspend Cumulative spending by governments on green and sustainable development projects in the year 2020 Global Recovery Observatory Database
Inflation, Consumer Prices (Annual %) Inflation It is percentage change in the cost to the average consumer of having a basket of goods and services World Bank
Exports of Goods and Services (% of GDP) Exports The value of all goods and services provided to the rest of the world World Bank
Log of GDP Per capita (Constant 2010 USD) GDPpercapita It is GDP divided by midyear population World Bank
Gross capital formation (Constant 2010 USD) GCF It consists of outlays on additions to the fixed assets of the economy plus net changes in the level of inventories. World Bank
Gross Debt as % of GDP Gdebt All liabilities of the country that requires future payment of interests and principal. International Monetary Fund

This table describes the variables and states the data sources.

The dependent variable for green funding (in US dollars) is cumulative spending on clean archetype projects aiming at green growth and comprises green market creation (with the V and V-3 subtypes of capacity investments), clean research and development investment (ψ), electric vehicle incentives, clean transport infrastructure investment (δ), clean energy infrastructure investment (η), building upgrades and energy efficiency infrastructure investment (λ) including other building upgrade support (λ3), natural infrastructure and green space investment (μ), including the subcomponents of tree planting and biodiversity protection (μ2), ecological conservation initiatives (μ3), and an agricultural uplift (μ5), and finally, local (project-based) infrastructure investment (θ) including the subcomponent of investment in clean new housing (θ3). With the above variables, we construct the following empirical model:

GDPpercapitai= α+β1greenspendi+β2GCFi+β3Gdebti+β4Inflationi+β5Exportsi+εi

where α represents the intercept, β represents the slope coefficients, and ε is the error term. The variables are outlined in Table 1.

III. Analysis and interpretation

A. Data description

The summary statistics and correlations between the variables are provided in Table 2. The results show that the green spending, inflation, and exports to the GDP of various countries are quite distinct. The reason could be that different countries have different economic conditions and priorities.

Table 2.Descriptive statistics and correlation matrix
Panel A: Descriptive Statistics
Variable N Mean SD Min Max
Log of GDPPC 30 9.748 1.36 6.744 11.417
Log of Green Spending 30 .445 2.247 -4.605 4.021
Gross Capital Formation 30 3.86e+11 9.69e+11 2.24e+09 5.37e+12
Gross Debt as % of GDP 30 77.352 30.672 32.542 155.562
Inflation 30 3.167 6.949 -1 36.1
Exports as % of GDP 30 39.008 24.735 9.578 127.64
Panel B: Matrix of Correlations
Variables (1) (2) (3) (4) (5) (6)
(1) Log of GDPPC 1.000
(2) Log of Green Spending 0.487 1.000
(3) Gross Capital Formation -0.062 0.423 1.000
(4) Gross Debt as % of GDP -0.020 0.086 0.008 1.000
(5) Inflation -0.324 -0.164 -0.118 0.029 1.000
(6) Exports as % of GDP 0.539 -0.057 -0.189 -0.184 -0.308 1.000

This table reports descriptive statistics and the correlation between variables of the variables. The statistics are number of observations (N), mean (Mean), standard deviation (SD), minimum (Min), and maximum (Max). The sample covers 30 countries.

Panel B of Table 2 presents the correlation matrix for the model. The logarithm of green spending and the logarithm of the GDP per capita are weakly positively related, with a correlation of 0.48, while gross capital formation and the logarithm of green spending are also positively related (0.42). Exports as a percentage of the GDP are, as expected, positively correlated with the GDP per capita, indicative of the positive contribution of exports to the economy. Inflation rates, as expected, are negatively correlated to the GDP per capita (-0.32) and exports as a percentage of the GDP (-0.308), respectively.

B. Regression results

The study employs ordinary least squares (OLS) and a robust regression method to estimate the proposed model. The robust regression method employed as a preliminary inspection of the model noted the presence of outliers. Further, for the OLS model, specific diagnostic tests are performed to check for multicollinearity (variance inflation factor) and heteroscedasticity (Breusch–Pagan/Cook–Weisberg test), as well as link tests, to check for specification errors and omitted variables (through Ramsey’s regression equation specification error test or RESET). The primary motive behind the use of robust regression was to remove influential observations from the model, since high leverage points in the latter can have a significant effect on the estimates obtained for the regression coefficients. Table 3 shows the OLS regression and robust regression results.

Table 3.Regression results
Panel A: OLS regression results
Variables Coefficient S.E. t-value p-value
Log of Green Spending 0.360 0.087 4.15 0.000***
Gross Capital Formation 0.000 0.000 -1.59 0.126
Gross Debt as % of GDP 0.001 0.006 0.20 0.846
Inflation -0.020 0.027 -0.73 0.475
Exports as % of GDP 0.028 0.008 3.56 0.002***
Constant 8.609 0.648 13.29 0.000***
R-squared 0.606 N 30
F-test 7.397 Prob > F 0.000
Panel B: Robust regression results
Variables Coefficient S.E. t-value p-value
Log of Green Spending 0.329 0.122 2.69 0.013**
Gross Capital Formation 0.000 0.000 -0.62 0.542
Gross Debt as % of GDP -0.003 0.007 -0.35 0.728
Inflation -0.142 0.079 -1.81 0.084*
Exports as % of GDP 0.020 0.009 2.18 0.040**
Constant 9.557 0.851 11.23 0.000***
R-squared 0.587 N 28
F-test 6.254 Prob > F 0.001

This table shows the robust regression estimates. The dependent variable is Log of GDPPC. *** p<0.01, ** p<0.05, * p<0.1 symbolize level of significance. S.E. denotes standard errors.

The preliminary identification of significant outliers is carried out through leverage versus squared residual plots.

Figure 1
Figure 1.Leverage vs. squared residual plot

The results show that, of the 30 countries in the sample, Argentina and China are influential outliers. Further, Cook’s distance (Di) is calculated to check for statistically significant outliers, and Argentina and China, with Cook distances of 2.93 and 3.45, respectively, are significant outliers. Countries with a Cook’s distance Di greater than one are considered influential outliers (Verardi & Vermandele, 2018), which works well in practice. Cases with Di greater than one (Argentina and China in this case) are assigned weights of zero with respect to the difference between predicted and actual values. The large absolute residuals are weighted less, and small absolute residuals are weighted more; thereafter, robust regression is run using generated weights.

Panels A and B of Table 4 show, respectively, the results for the OLS and robust regressions. These results suggest that green spending by governments has a statistically significant and positive impact on the GDP per capita of the sample countries (see Table 4), indicating that the financing of green projects can lead to economic growth (Jiang et al., 2020; X. Wang & Wang, 2020). Further, as an external sector variable, exports as a percentage of the GDP positively impact economic growth in both the models employed, primarily in the form of significant inflows of foreign exchange and appreciation of foreign exchange reserves contributing to the national Exchequer. Many studies have vouched for the role of exports in strengthening the GDP of a country (Emery, 1967). Our study also concludes that inflation has a negative impact on the GDP per capita, with a t-value of -1.81. Andres & Hernando (1997) have empirically investigated the negative impact of inflation on economic growth.

The diagnostic test for the OLS model is primarily aimed at detecting the presence of non-orthogonality in the explanatory variables and model specification issues. The mean value for the variance inflation factor for the OLS model is 1.19, indicating the absence of multicollinearity, while the link test results (for specification errors) have a (ˆY)2 value of -1.44, meaning the model is correctly specified. The Ramsey RESET for omitted variables indicates the presence of an omitted variable as Prob>F 0.0063 (with an H0 indicating no omitted variable bias); however, the Breusch–Pagan/Cook–Weisberg test for heteroscedasticity (with an that assumes constant variance) has Prob > χ2 0.0488 and, hence, indicates the presence of heteroscedasticity.

IV. Conclusion

This paper attempts to examine empirically the impact of green financing on the economic growth of different countries during the COVID-19 pandemic. The results show a positive impact of green financing on the GDP per capita for the sample countries, in line with the previous literature (Greco, 2018; Haiyang, 2017). The study also finds that exports as a percentage of the GDP has a positive impact on economic growth, whereas inflation has a negative impact on the GDP per capita. The model indicates that green financing can improve the economic development of countries, creating a win–win situation, and governments should therefore focus on green project financing by integrating it into economic recovery plans.

Amid two schools of thought, this study supports investment in green financing, adding to the literature review. The paper also has implications for policymakers and government bodies. The relevant national and international bodies should combine the features of different countries and frame an appropriate green financial policy to promote universal green development. They should also determine how green finance can accelerate green development at the national level, which will provide much needed impetus for global green recovery after the COVID-19 pandemic.

  1. More details can be obtained from https://recovery.smithschool.ox.ac.uk/tracking/.