Socioeconomic Productive Capacity and Renewable Energy Development: Empirical Insights from BRICS
Abstract
:1. Introduction
2. Literature Review
- Income: The effect of income or per capita income on the development of renewable energy has also been studied by researchers. According to [31], the key factor influencing the per capita use of renewable energy is the rise in real per capita income. In other words, those with higher incomes have a greater capability or resources to encourage the use of renewable energy. The effects of green and traditional energy usage on economic development in the fields of agriculture, manufacturing, services, and total income across a group of G20 countries were examined by [32] using annual data from 1980 to 2012. Their findings demonstrated that the use of green and traditional energy contributed favorably to economic development across all industries. In [33], the authors examined the impact of the use of renewable energy on national income in a worldwide sample of 85 industrialized and emerging nations, together with other important model components. To accomplish the research goals, the authors used annual data from 1991 to 2012 along with various econometric approaches. The system GMM and FMOLS findings showed that the use of renewable energy has a considerable favorable impact on national income.
- Human capital: While it is commonly recognized that human activities are mostly to blame for resource imbalances, research on renewable energy has seldom taken the influence of human development into account. Since business owners and workers are drawn from the public, a society’s degree of human capital is crucial for both its consumers and its producers. More precisely, customers who have received an education are more informed about the environmental impacts of consuming non-renewable energy sources. The research on the factors that influence energy demand varies according to geographies, nations, time series, and other variables using data from 1965 to 2014, and ref. [34] discovered a conflict between human capital and traditional energy consumption while discovering harmony between human capital with renewable energy consumption. In [35], the authors state that human capital is a significant factor in regulating energy demand. For ten nations with significant ecological footprints, ref. [36] confirm that resource availability harms the ecosystem but that air degradation is reduced by human capital. In contrast, ref. [37] highlighted the positive connection between human capital and ecological footprints in BRICS nations.
- Institutional quality: It has long been believed that for society to become more environmentally conscious and for environmental programs to be effective, there must be well-managed governmental involvement, solid institutions, and excellent democracy [28]. Inside the institutional framework, this process also holds for renewable energy development [38]. There has been a lot of work on how political factors such as democratization affect the ecosystem, but there have been few efforts to analyze institutional factors that impact the use of renewable energy. The initiatives in this category that may be assessed have usually concentrated on how fundamental institutional factors such as lobbying activities, ideology, democracy, and corruption affect renewable energy. The use of clean energy in European nations was shown to be negatively impacted by lobbying operations, according to [39]. The conventional and organizational drivers of renewable energy in the ECO nations from 1992 to 2012 were investigated by [40]. The results showed that the use of renewable energy was favorably impacted by political stability. Contrary to what has been said, corruption was discovered to have a detrimental impact on the use of renewable energy. The political, economic, and ecological factors of clean energy in 26 European nations from 2004 to 2011 were examined by [41]. The usage of clean energy was unfavorably impacted by lobbying and national income but favorably impacted less corruption in society. In more than 100 nations, ref. [42] looked at the connection between democracy and renewable energy. The study’s usage of all democratic metrics had a favorable impact on the utilization of renewable energy.
- Financial development: The relationship between financial growth and renewable energy has drawn considerable attention from the empirical community. Nevertheless, a significant number of empirical studies have looked at the link while considering the demand side of this sector, in other words, the use of renewable energy. For example, ref. [43] highlight how the usage of renewable energy benefits from institutional and financial robustness. For high-income countries, ref. [44] found that financial capital encourages the switch to modern renewable sources of energy, while debt securities and bank loans are thought to have a positive impact on sustainable energy requirements. In [45], the authors investigated the relationship between financial development, economic expansion, and the usage of renewable energy. According to their results, there is no direct causal relationship between the usage of renewable energy and monetary advancement. In four BRICS countries, ref. [46] looked at how FDI and stock market expansion affected the adoption of renewable energy. They showed how FDI and stock market expansion have a big impact on the uptake of renewable energy.
- Structural change: Energy consumption is greatly influenced by structural change, which is often assessed by comparing sectoral proportions in the domestic economy. For the transitioning nations, structural change includes a shift from centralized planning to economic liberalization. There is a substantial body of literature that supports the idea that structural modifications might increase energy efficiency, but there hasn’t been much empirical research on how structural changes may affect the development of renewable energy [47]. According to [18], structural change has a significant impact on renewable energy in China. Likewise, in [48], the analysis reveals that structural changes improve energy efficiency in various groups of transition countries. In 39 nations between 1995 and 2009, ref. [49] clearly showed that economic transitions from manufacturing to service-led industries increase global energy productivity while increases in industrial output decrease it.
3. Model, Methods, and Data
4. Empirical Results and Discussion
5. Conclusions
6. Implications
7. Limitations and New Directions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Variables | Definitions | Sources |
---|---|---|
REP | Total production of nuclear, renewables, and other (quad Btu) | EIA |
GNI | GNI per capita, Atlas method (current US$) | WDI |
FD | Domestic credit to private sector (% of GDP) | WDI |
PCI | Productive capacities index: overall index | UNCTADstat |
HC | Human capital capacity index | UNCTADstat |
ICT | ICT capacity index | UNCTADstat |
IQ | Institutional quality capacity index | UNCTADstat |
SC | Structural change capacity index | UNCTADstat |
Mean | Median | Max | Min | Std. Dev. | Skewness | Kurtosis | Jarque-Bera | Prob. | |
---|---|---|---|---|---|---|---|---|---|
REP | 0.697 | 1.189 | 3.215 | −2.025 | 1.405 | −0.768 | 2.671 | 12.32 | 0.002 |
GNI | 8.246 | 8.498 | 9.628 | 6.016 | 0.953 | −0.647 | 2.388 | 10.23 | 0.006 |
FD | 4.157 | 4.074 | 5.209 | 2.623 | 0.632 | −0.277 | 2.093 | 5.646 | 0.059 |
PCI | 3.443 | 3.446 | 3.762 | 3.200 | 0.112 | 0.430 | 3.376 | 4.409 | 0.110 |
HC | 3.930 | 3.961 | 4.163 | 3.604 | 0.141 | −0.434 | 2.111 | 7.713 | 0.021 |
ICT | 2.068 | 2.077 | 3.068 | 0.647 | 0.546 | −0.290 | 2.246 | 4.530 | 0.104 |
IQ | 3.894 | 3.900 | 4.189 | 3.580 | 0.168 | −0.004 | 1.843 | 6.689 | 0.035 |
SC | 3.215 | 3.176 | 3.772 | 2.998 | 0.151 | 1.474 | 5.396 | 72.19 | 0.000 |
LLC | IPS | ADF | ||||
---|---|---|---|---|---|---|
I(0) | I(1) | I(0) | I(1) | I(0) | I(1) | |
REP | −0.165 | −5.658 *** | 0.857 | −5.857 *** | 0.804 | −5.325 *** |
GNI | −2.935 *** | −0.812 | −1.897 ** | −0.865 | −2.023 ** | |
FD | −1.687 * | −0.165 | −3.254 *** | −0.154 | −3.214 *** | |
PCI | −1.546 * | 0.567 | −4.985 *** | 0.756 | −4.856 *** | |
HC | −1.089 | −6.578 *** | 0.915 | −5.654 *** | 1.058 | −4.325 *** |
ICT | −5.654 *** | −1.987 ** | −1.667 ** | |||
IQ | −1.589 * | −2.456 *** | −2.567 *** | |||
SC | −1.021 | −4.566 *** | −1.356 | −5.654 *** | −1.213 | −4.521 *** |
(1) | (2) | (3) | (4) | (5) | ||||||
---|---|---|---|---|---|---|---|---|---|---|
Variable | Coef. | t-Stat | Coef. | t-Stat | Coef. | t-Stat | Coef. | t-Stat | Coef. | t-Stat |
Long-run | ||||||||||
GNI | 0.218 ** | 2.222 | 0.497 ** | 2.006 | 0.268 * | 1.928 | 0.517 * | 1.940 | 0.322 ** | 2.508 |
FD | 0.735 *** | 4.676 | 0.411 ** | 2.006 | 0.368 ** | 2.518 | 0.359 * | 1.831 | 0.496 * | 1.781 |
PCI | 1.375 *** | 5.562 | ||||||||
HC | 1.086 ** | 2.007 | ||||||||
ICT | 0.963 *** | 4.860 | ||||||||
IQ | 1.059 * | 1.931 | ||||||||
SC | 1.051 * | 2.026 | ||||||||
Short-run | ||||||||||
D(GNI) | 0.048 | 0.249 | 0.050 | 0.289 | 0.001 | 0.005 | 0.098 | 0.876 | 0.013 | 0.085 |
D(GNI(−1)) | 0.106 | 0.372 | 0.013 | 0.039 | 0.145 | 0.991 | 0.005 | 0.024 | 0.112 | 0.770 |
D(FD) | 0.045 ** | 2.277 | 0.029 ** | 2.179 | 0.158 * | 1.836 | 0.048 ** | 2.463 | 0.146 * | 1.814 |
D(FD(−1)) | 0.081 | 0.816 | 0.012 | 1.148 | 0.055 | 1.188 | 0.009 | 0.136 | 0.109 | 1.380 |
D(PCI) | 1.003 ** | 2.561 | ||||||||
D(PCI(−1)) | 0.830 | 1.014 | ||||||||
D(PCI(−2)) | 0.252 | 0.389 | ||||||||
D(HC) | 1.003 | 1.004 | ||||||||
D(HC(−1)) | 0.901 | 1.142 | ||||||||
D(ICT) | 0.482 * | 1.688 | ||||||||
D(ICT(−1)) | 0.020 | 0.092 | ||||||||
D(IQ) | 0.335 * | 1.668 | ||||||||
D(IQ(−1)) | 0.846 | 1.335 | ||||||||
D(SC) | 0.146 | 0.414 | ||||||||
C | 2.097 * | 1.933 | 2.174 ** | 2.085 | 1.855 ** | 2.256 | 2.362 ** | 2.005 | 1.861 ** | 2.031 |
Diagnostics | ||||||||||
ECM(−1) | −0.369 * | −1.696 | −0.401 * | −1.876 | −0.290 * | −1.921 | −0.286 ** | −2.030 | −0.326 ** | −2.125 |
Kao-coint test | −2.362 *** | 0.009 | −2.662 *** | 0.004 | −1.228 | 0.110 | −1.448 * | 0.074 | −2.013 ** | 0.009 |
Long-Run | Short-Run | ||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|
ECM | C | GNI | FD | PCI | REPP(−1) | GNI | GNI(−1) | FD | FD(−1) | PCI | |
0.05 | −0.114 | 20.23 | −0.144 | 0.951 | 1.595 | 1.025 *** | 0.208 | 0.220 | −0.178 | −0.189 | 0.006 |
(−1.469) | (0.875) | (−0.191) | (0.780) | (0.969) | (3.718) | (1.113) | (1.205) | (−0.555) | (−0.613) | (0.164) | |
0.10 | −0.117 * | 23.88 | −0.558 | 1.001 | 1.948 | 1.034 *** | 0.043 | 0.065 | −0.049 | −0.030 | 0.015 |
(−1.728) | (0.932) | (−0.664) | (0.861) | (1.083) | (3.653) | (0.660) | (0.981) | (−0.417) | (−0.260) | (0.610) | |
0.20 | −0.203 * | 27.47 | −1.184 | 1.292 | 2.063 ** | 1.030 *** | 0.081 | 0.104 | −0.107 | −0.121 | 0.031 |
(−1.947) | (1.305) | (−1.094) | (1.005) | (2.053) | (3.572) | (0.987) | (1.287) | (−0.899) | (−1.011) | (1.122) | |
0.30 | −0.254 ** | 29.04 *** | −0.886 | 1.491 | 1.840 ** | 1.035 *** | 0.087 | 0.108 | −0.040 | 0.056 | 0.023 |
(−2.378) | (6.733) | (−1.033) | (1.121) | (2.361) | (4.144) | (1.052) | (1.348) | (−0.321) | (0.452) | (0.728) | |
0.40 | −0.308 *** | 24.53 *** | −0.760 | 1.503 | 1.704 *** | 1.028 *** | 0.142 | 0.161 | −0.203 | 0.214 | 0.032 |
(−2.611) | (9.088) | (−1.229) | (1.276) | (3.212) | (3.914) | (1.653) | (1.136) | (−1.618) | (0.730) | (1.106) | |
0.50 | −0.411 *** | 23.38 *** | −0.381 | 1.078 | 1.549 *** | 1.017 *** | 0.037 | 0.064 | −0.094 | 0.116 | 0.047 |
(−2.684) | (3.094) | (−1.306) | (1.563) | (2.678) | (3.492) | (0.418) | (0.759) | (−0.691) | (0.873) | (1.490) | |
0.60 | −0.501 *** | 21.76 *** | −0.137 | 0.624 * | 1.419 *** | 1.018 *** | 0.016 | 0.048 | 0.076 | 0.099 | 0.060 ** |
(−3.405) | (3.898) | (−0.825) | (1.936) | (3.243) | (3.250) | (0.213) | (0.665) | (0.653) | (0.895) | (2.088) | |
0.70 | −0.566 *** | 19.05 *** | 0.025 | 0.256 ** | 1.331 *** | 1.003 *** | 0.011 | 0.025 | 0.006 | 0.031 | 0.063 ** |
(−3.313) | (7.181) | (1.230) | (2.047) | (5.619) | (2.999) | (0.160) | (0.379) | (0.052) | (0.290) | (1.984) | |
0.80 | −0.601 *** | 17.28 *** | 0.065 * | 0.159 ** | 1.265 *** | 1.007 ** | 0.066 | 0.006 | 0.145 * | 0.075 | 0.085 ** |
(−4.018) | (9.025) | (1.805) | (2.297) | (6.626) | (2.459) | (0.935) | (0.095) | (1.936) | (0.644) | (2.235) | |
0.90 | −0.651 *** | 15.63 *** | 0.095 * | 0.117 ** | 0.944 *** | 0.997 ** | 0.088 | 0.040 | 0.093 ** | 0.018 | 0.061 ** |
(−3.411) | (9.392) | (1.911) | (2.354) | (6.268) | (2.239) | (1.247) | (0.592) | (2.234) | (0.132) | (2.304) | |
0.95 | −0.701 ** | 15.86 *** | 0.056 * | 0.130 ** | 0.733 *** | 1.006 ** | 0.032 | 0.095 | 0.062 *** | 0.004 | 0.106 ** |
(−2.370) | (11.38) | (1.690) | (2.521) | (7.788) | (2.209) | (0.465) | (1.516) | (2.902) | (0.029) | (2.155) |
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Li, B.; Liu, Q.; Li, Y.; Zheng, S. Socioeconomic Productive Capacity and Renewable Energy Development: Empirical Insights from BRICS. Sustainability 2023, 15, 5986. https://doi.org/10.3390/su15075986
Li B, Liu Q, Li Y, Zheng S. Socioeconomic Productive Capacity and Renewable Energy Development: Empirical Insights from BRICS. Sustainability. 2023; 15(7):5986. https://doi.org/10.3390/su15075986
Chicago/Turabian StyleLi, Biqing, Qiuting Liu, Yuming Li, and Shiyong Zheng. 2023. "Socioeconomic Productive Capacity and Renewable Energy Development: Empirical Insights from BRICS" Sustainability 15, no. 7: 5986. https://doi.org/10.3390/su15075986
APA StyleLi, B., Liu, Q., Li, Y., & Zheng, S. (2023). Socioeconomic Productive Capacity and Renewable Energy Development: Empirical Insights from BRICS. Sustainability, 15(7), 5986. https://doi.org/10.3390/su15075986