Abstract
In the transition to a low carbon economy, minerals are crucial. The demand for the minerals required to create and install green energy technology, such as solar panels, wind turbines, electric vehicles, and energy storage, is rising along with it. In particular, the countries that hold these mineral reserves should be thought of as thriving economically from the rising demand for essential mineral resources (such as cobalt, lithium, and others). This study uses import demand function analysis to look at how the major mineral importing countries’ mineral import demand changed in response to the clean energy transitions between 2000 and 2021 for selected 14 countries. In the study, the cross-sectional autoregressive distributed lag (CS-ARDL) method was used. Findings show that long-term renewable energy production has a largely favorable impact on mineral import demand. Additionally, CO2 emissions have a long-term negative impact on mineral import demands, but energy intensity and exchange rate are favorable for mineral imports. The findings have significant ramifications for using the mineral trade to speed up the transition to sustainable energy around the world. Therefore, the study’s key proposed policy is to emphasize the value of mineral resources in clean energy while maximizing their use in the transition to carbon-free energy.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
The existing energy system is heavily built on fossil fuels, including both technology and storage infrastructure. Therefore, countries set net zero carbon targets to avoid catastrophic climate change as a result of the Paris Agreement, which was signed in 2015. To achieve the established net zero carbon target and meet their energy demand, countries must create significantly varied systems based on renewable energy (RE) sources (Figueres et al. 2017). The production and maintenance of RE technologies and electric vehicles (EV) require the flow and stock of mineral resources (lithium, nickel, cobalt, manganese, etc.). In other words, mineral reserves are of great importance in the transition to a low-carbon energy system (Calvo and Valero 2022; Toro et al. 2020; Vidal 2017; Ali et al. 2017). Minerals are used to generate and sustain energy conversion technologies in the clean energy transition from fossil fuel-based energy sources to RE sources (Moreau et al. 2019).
Today, the strategic importance of vital minerals is still emphasized, and their competitiveness is getting more intense due to the intensity of trade conflicts and uncertainty in the international arena (Zhu et al. 2022; Huang et al. 2021). Additionally, the COVID-19 pandemic, which affected the entire world in 2020, has caused and is currently causing the possible risk of disruption in the supply chains of essential minerals, which in this case hinders the clean energy transition process (Giese 2022; Zhu et al. 2021; Kim and Karpinski 2020; Chadha 2020). Hence, a country’s position in the key mineral trade network depends on its control and influence over these essential minerals, which are crucial to the growth of RE sources (Zhu et al. 2022; Xi et al. 2019). Critical minerals can have different effects on the development of RE industries.
The main motivation for this paper is to reveal the contribution of minerals, which have an important place in the use of RE, to the CO2 emission target. Major mineral-importing countries also support the global carbon target (which aims to keep the rise in average temperature under 1.5 °C) (Calvo and Valero 2022). Countries must adopt the usage of RE sources and electric vehicles to fulfill their objectives. Following motivation of the study is that a lot of raw material is required for RE technologies. Many authors have drawn attention to how to access critical minerals required for RE generation, distribution, or storage technology (Vakulchuk et al. 2020; Mills 2020; Habib et al. 2016). For instance, a solar power plant needs four tons of copper to produce one megawatt of installed capacity, and also photovoltaic cells include copper-indiumgallium-selenide alloy (CIGS) or cadmium-tellurium (CdTe) and silver (Bleiwas 2010). Furthermore, electric vehicles often use lithium, cobalt, or nickel for batteries (Chitre et al.2020). Hence, the main driver of growth in the EV market is maintaining stable and reliable access to mineral resources (Ballinger et al. 2019). As can be seen, mineral resources are crucial for countries that want to convert to clean energy sources and produce RE. The final motivation of the present study is that the mineral demands in the clean energy transition process have been drawn attention in the literature, and the need for some critical minerals especially in the deployment of RE use has been emphasized (Islam et al. 2022b; Zhu et al. 2022; Gielen 2021; Liang et al. 2022; Klimenko et al. 2021; Ren et al. 2021; Toro et al. 2020; Månberger and Stenqvist 2018; McLellan et al. 2016; Viebahn et al. 2015; Moss et al.2013). It is anticipated that demand would rise significantly for the metals lithium, cobalt, rare earth elements, and graphite, which are particularly necessary for the manufacture of batteries. There will be a seven-fold rise in demand for lithium-ion batteries by 2025 and an 11–13 times increase by 2030 (Dolganova et al. 2020; Küpper et al. 2018). The literature will be improved by exploring minerals, which play a significant role in the shift to sustainable energy.
Based on the aforementioned motivational disclosure, the present paper aims to investigate the response of total mineral import demands to clean energy transitions (capacity of RE) within the context of external determinants (energy intensity, fuel import, economic growth, exchange rate, CO2 emission, and foreign direct investment) in the context of important mineral importing countries between 2000 and 2021. To CO2 emission goals, specific country policies relating to mineral resources are also looked at. As a result, the paper promotes collaboration within three distinct fields, which are environment, energy, and mining economics.
The contribution of the paper is the many folds. First, import demand function analysis is used to examine how mineral import demands respond to clean energy transitions. This is the first attempt made by using data, a certain time interval, and selecting 14 countries. Second, unlike earlier research, this study considers major mineral importing countries to anticipate how imported minerals will react to clean energy transitions, such as installed RE capacity under various external dynamics, including RE capacity fuel import, foreign direct investment, economic growth, exchange rate, CO2 emission, and energy intensity by using CS-ARDL approach. Third, the results of this study, which show how minerals affect the growth of RE, will help us better comprehend the relationship between clean energy transition and minerals. By empirically studying the relationship between key minerals and the clean energy transition, this study creates a fresh contribution to the field. The sample countries, the data used, and the analysis method are all different in this study as compared to earlier studies. Fourth, the present paper also attempts to formulate a sustainable development policy objective in light of the energy and environmental regulations in place in 14 mineral-importing countries. This policy framework is intended to be created by considering how mineral resources have shaped the relationship between RE and climate change. Finally, a clean energy transition may lower the usage of fossil fuels, but it also tends to increase the use of non-fuel essential minerals in supply chains. This creates new dependencies and introduces new scarcity scenarios. Therefore, it is crucial that policy-makers address this condition when developing policies for the demand for critical minerals. Herein lies the study’s contribution at the level of policy.
The remainder of the present paper is structured as follows. A review of the available literature on strategic mineral resources is provided in “Literature review.” The study’s methodology is described in depth in “Materials and methods” and “Empirical findings” presents the empirical findings and is discussed in the literature. The study’s final section ends with conclusions and political implications.
Literature review
The overall global mineral demand is anticipated to exceed 40% for copper and rare earth elements, 60–70% for nickel and cobalt, and over 90% for lithium within the context of the Paris Agreement in the next 20 years (Mróz 2022). Lithium is now the most widely used material in electric vehicles and battery storage (Diouf and Pode 2015). As part of the energy transition, the rapid implementation of clean energy technology will result in a considerable increase in mineral demand (Lee et al. 2020). Figure 1 shows the minerals used in RE technology.
When studies on minerals are evaluated in the literature, some studies forecast the future mineral requirements from the perspectives of several countries and the rest of the world (Wang et al. 2022; Galos et al. 2021; Hu et al. 2021; Wen et al. 2019; Beylot et al. 2019; Meinert et al. 2016). Some research has focused on addressing risk scenarios for highly used minerals in the clean energy transition (Nate et al. 2021; Krane and Idel 2021; Church and Crawford 2020; Capellán-Pérez et al. 2019; Watari et al. 2019). According to some studies, the concentration of natural resource reserves in a few key locations could lead to bottlenecks in the process of using minerals to produce sustainable energy (Calvo and Valero 2022; Bazilian 2018; Grosjean et al. 2012). The literature has generally considered studies on the impact of mineral resources on energy or clean energy transitions as theoretical or reviewed. Empirical research on this topic is scarce, and Table 6 in the “Appendix” section also gives specific details on a recent empirical literature review on the linkage between minerals and clean energy.
According to the literature, the demand for this resource on the global market is rising as a result of the mineral consumption flow of countries that produce sustainable energy. In light of this, the hypothesis that “clean energy transitions boost the import demands of minerals on the global market” starts to take shape.
To sum up, earlier researchers examined scenarios for present mineral reserves, mineral use, and the significance of minerals in the switch to clean energy. Environmental concerns including ecological footprint, low-carbon earth, and mineral exploitation have been linked in several studies. To our knowledge, no studies have looked at the response of essential minerals, such as the capacities of RE installation to clean energy transitions.
Materials and methods
Data
This study investigates the responsiveness of mineral import demands to clean energy transitions in the context of China, the USA, Japan, India, South Korea, the Netherlands, Germany, Italy, the UK, Turkey, Russia, Australia, Canada, and South Africa, which import the most minerals. Depending on the data availability of selected countries, the data range is limited from 2000 to 2021. The variables used for analysis, as well as their definition, units of measurement, and sources are presented in Table 1.
To examine the impact of renewable energy capacity (REC), fuel imports (FI), energy intensity (EI), foreign direct investment (FDI), economic growth (GDP), the exchange rate (EX), and CO2 emissions (CO2) on mineral resource import (MSI) by the control variable in the theoretical framework, the following econometric model is used:
The model variables are log-transformed for the purpose of an empirical estimate, which reduces the sharpness of the data and improves the distributional features of the variables. Data difficulties related to autocorrelation and heteroscedasticity can be eliminated via natural logarithmic processing except for FI because FI has been taken as a percentage of merchandise imports. Results from log-transformed models are more reliable and effective than results from linear transformation (Benoit 2011).
Mineral resource import (MIS) is the log of total MIS measured in US$ thousands, and main explanatory variable renewable energy capacity (REC) is the log of total energy consumption measured in cumulative in megawatt (MW). REC variable include solar, wind, hydropower, and others. When the literature is reviewed, many studies certainly prefer the data of REC to strengthen the model.
FI is the fuel import and measures percentage of merchandise imports. Fuel imports comprise the mineral fuels, lubricants and related materials.
EI is energy intensity measures kilogram of oil equivalent (koe)/dollars at constant exchange rate, price and purchasing power parities of the year 2015 ($15p). As the CO2 and other environmental impacts of mineral production are progressively incorporated into the cost structure of mineral not only will the absolute price of mineral increase, but there will also be a relative shift in price between minerals due to the different energy intensities of mineral production processes (Norgate and Haque 2010). Therefore, EI is the major contributor to the emission mitigation. For example, Lin and Ouyang (2014) show that the EI effect makes the greatest contribution to the reduction of CO2 emissions.
FDI is foreign direct investment and measures balance of payment (BoP) in the current US$. FDI refers to direct investment equity flows in the reporting economy. FDI is the total of equity capital, reinvested earnings, and other capital (Nejati and Bahmani 2020). Although FDI in mineral resources is often a significant long-term investment (Wang et al. 2020), countries with an abundance of natural resources—particularly mineral sources—attract greater FDI. The most significant aspect that defines a country’s desirability for international mining investment is its geological potential. Nevertheless, some countries with abundant mineral resources have drawn more FDI than others; for instance, Australia and Canada have drawn more international investment in mining than China and Russia (Vivoda 2011).
GDP is the log of the GDP measured in current US$ as an indicator of economic development. EXR is measure as real effective exchange rate index (2010 = 100) and EXR is calculated by dividing nominal effective exchange rate, which measures a currency’s value against a weighted average of many foreign currencies, by a price deflator or cost index (Lenarčič and Ganesh 2020). Islam et al. (2022a, b) reveal that the exchange rate devalued mineral import demands in the long run.
CO2 is the log of total CO2 emission from the consumption of fossil-based sources such as oil, natural gas, and coal gas measured in tons CO2 per capita. The growth of RE needed for the clean energy transition depends significantly on essential mineral resources, which may cause worries about potential mineral scarcity and associated CO2 (Wei et al. 2022; Tokimatsu et al. 2018). The worldwide mining and metals sector is responsible for about 8% of the CO2 emission (Ritchie and Roser 2020).
Although mining has a sizable impact on global CO2 emissions, this is outweighed by the economic contribution of the sector. Therefore, many studies have recommended for the mineral industry to implement a carbon price (Cox et al. 2022; Zhu and Lin 2022).
Methods
The CD-ARDL model is used in this study to estimate mineral import demand for the 14 countries that were chosen. Thus, the potential joint correlation effects of the strong economic link between the selected countries can be measured. Chudik and Pesaran (2015) claim that the CS-ARDL model enhances the ARDL model with a linear combination of the average cross-sectional of both the dependent and independent variables in order to account for cross-sectional correlation in the error term. Further, the CS-ARDL paradigm regards the 1-year lag of the regressed variable as a weakly exogenous regressor within the error correction process (Sohag et al. 2021). Additionally, the CS-ARDL process makes it possible to significantly control for the unobservable factors that are used to measure the long-term impacts in the regression model. In addition, it makes possible to address cross-sectional dependence (CD) in both the long and short terms (Samargandi et al. 2021; Chudik et al. 2016). Pesaran et al. (2008) recommend the CD test for potential co-correlation effects of strong economic linkages between selected countries. The CD test is suitable for estimating cross-section independence versus cross-section dependence between sample items (Islam et al. 2022a). The mathematical representation of the CD test is as follows.
\(\overline{P }\) Represents the levels of pair-wise correlation of the cross-sectional residuals using the augmented Dickey-Fuller (ADF) regression model. T is time and N is the cross-sectional units. The study may estimate the slope homogeneity across the panel entities after looking at the CD and panel unit root test. Ultimately, the paper assesses the short- and long-term relationships between the variables contained inside the co-integration mechanisms using the cross-sectional autoregressive distributed lag (CS-ARDL) approach. The paper for a number of reasons chose the ARDL model. First, the ARDL model enables simultaneous estimation of the long- and short-term elasticities (Fedoseeva and Zeidan 2018). Second, models with a single I(0), I(1), or mixed order of integration can be handled by the model (Shin et al. 2014). Finally, the ARDL approach also prevents issues with endogeneity (Adewuyi 2016). It is noteworthy that the CS-ARDL paradigm treats the regressed variable’s 1-year lag as the weakly exogenous regressors within the error correction framework. Additionally, the unobservable problems that are used to measure the long-term impacts in the regression model are precisely controlled by this technique. Additionally, it makes possible to control cross-sectional dependence (CD) in both long and short runs (Sohag et al. 2021). Equation 3 describes the empirical baseline panel model for dependent variable mineral imports (MSI) using the CS-ARDL method.
\(\Delta {MSI}_{it}\) Denotes the dependent variable (mineral sources import); \({X}_{it}\) means explanatory variables which are REC, FI, EI, FDI, GDP, EXR, and CO2. While \({\overline{MSI} }_{t-1}\) denotes the long-run scrutinized coefficient of the dependent variable, \({\overline{X} }_{t-1}\) shows the long-run scrutinized coefficient of explanatory/independent variables. Furthermore, the short-run coefficient of dependent and explanatory/independent by \({\Delta MSI}_{it-j}\) and \({\Delta X}_{it-j}\), respectively. The disturbance term is \({\varepsilon }_{it}\), and J = 1…J shows the cross-sectional units. Time is t = 1….T, and \({\pi }_{ij}\)/\({\omega }_{ij}\) show the short-run coefficient of the dependent and explanatory/independent variables, correspondingly. Lastly, \({p}_{1i}\) and \({p}_{2i}\) display the short-run coefficient of the mean of dependent and explanatory/independent variables, respectively.
Empirical findings
The descriptive statistics of the logarithmic variables used in the study models and the correlation matrix of the variables are shown in Tables 7 and 8 in the “Appendix” section, respectively. The aggregate mineral imports’ overall mean and standard deviation values are 15.304 and 1.444, respectively, showing improved efficiency and less variability for these metrics among the selected nations for the relevant time periods. According to the correlation matrix, it shows that there is a statistically significant correlation between all of the independent variables and the dependent variable (MSI).
Then, the paper employs the slope homogeneity test. Table 2 presents the slope heterogeneity issue checked by the slope homogeneity test results \((\widetilde{\Delta }\&{\widetilde{\Delta }}_{adj})\) developed by Pesaran and Yamagata (2008). To further check for homoscedasticity and serial correlation issues, Blomquist and Westerlund (2013) rehabilitated this test \(({\Delta }_{\mathrm{HAC}}\&{\Delta }_{\mathrm{HAC adj}})\). The findings of the two homogeneity of slope test inquiries are given in Table 2 below.
The results indicate that the p-values are less than 0.01 according to the findings. The null hypothesis of slope homogeneity throughout the panel entities is refuted by this result. The cross-section dependence (CD) test can still be used because different cross-section units have different slopes.
The cross-section independence of the panel units is assessed using the CD test (Hsiao et al. 2012). Additionally, it assists in choosing the right model to use based on the CD’s condition (Pesaran 2007). Table 3 displays the results of the CD test statistics and the average correlation (p) values.
As seen in Table 3, CD values are highly significant in the case of MSI, REC, FI, EI, and GDP variables. More importantly, the CD statistics of REC are the highest while FI (fuel import) is the lowest among all other variables.
To check the stationarity of the variables, a panel unit root test called CADF developed by Pesaran (2007) was applied. The CADF test, which dynamically chooses the integration order of each variable separately, is notable for its section unbiasedness (Zhuang et al. 2021). The integration decision order, in particular, is crucial for selecting the best technique for panel data analysis. The order of integration among the variables is mixed according to the CADF estimation (Islam et al. 2022a). However, the use of the CS-ARDL technique for cointegration is supported by the presence of CD and the variable’s mixed-order integration state (Li et al. 2020). The panel unit root test results among the variables are given in Table 4.
According to Table 4, while foreign direct investment and CO2 emission are stationary at the I(0) level, all other six variables are stationary at the I(1) level. Therefore, the CS-ARDL test was employed to discover long-term correlations between variables since the series is stationary at various levels.
The CS-ARDL method links competitively with the co-related effects mean group (CCEMG), the augmented mean group (AMG), and the pooled mean group (Abbasi et al. 2021). The interiority paradox and the heterogeneous slope coefficients can be solved with CS-ARDL (Su et al. 2021). Additionally, it provides reliable outcomes despite issues with cross-section dependence. Even when there are mixed sequential integration/non-stationary difficulties, it can still function well (Zaidi et al. 2021; Tao et al. 2021).
The present paper employs the CS-ARDL method to look at how responsive the overall mineral import demand is to clean energy transitions RE capacity within the fuel import (FI), energy intensity (EI), income (GDP), foreign direct investment (FDI), the exchange rate (EXR), and CO2 emission in the case of top 14 mineral importing countries. Cross-sectional ARDL is used in this paper to assess both the long- and short-term impacts, as indicated in Table 5.
Table 5 shows the results from CS-ARDL regression. The analysis revealed several explanatory variables that are significant determinants of the clean energy transition. In other words, Table 5 illustrates how sensitive total mineral imports (MIS), one of the key indicators of the transition to clean energy, are to the capacity of RE sources. In the short-term estimation, the error correction coefficient appears to be negative at the level of 1%. This result demonstrates how the variables have a long-term relationship and may be used to modify any short-term shock wave.
The study’s most significant finding is that the total mineral imports (MIS) respond favorably to the RE capacity built in the countries with the highest mineral import volumes. Over time, the REC coefficient is significant and positive. This finding demonstrates how the generation of RE raises the import demand for essential minerals in the countries that import the most minerals.
It is widely accepted that large-scale use of RE is one of the most critical steps necessary to reduce global warming (Wang et al. 2021). Thus, it suggests that important minerals are needed for key RE technologies (PV, CSP, Offshore and Onshore wind turbines etc.) to provide RE. This study’s finding about RE capacity positively influencing mineral import is consistent with earlier research by Islam et al. (2022a), Calvo and Valero (2022), Ma (2022), and Toro et al. (2020). These authors focused on the mechanical properties of many essential minerals and their ability to generate RE. Furthermore, Chevrel and Ranchin (2018) also support the findings obtained from the analysis that there is a greater need for mineral resources for RE development. A few minerals with expanding markets are aluminum, cobalt, copper, iron ore, lead, lithium, nickel, manganese, silver, steel, titanium, and zinc. In other words, the demand for minerals that are relevant to low-carbon technology is increasing quickly. Hammond and Brady’s (2022) emphasis is on the critical minerals used in batteries for RE and electric vehicles.
Table 5 also shows that the coefficient of energy intensity (EI) and exchange rate (EXR) is positive and statistically significant while CO2 emission is negative and statistically significant in the long run. The long-term positivity and significance of the exchange rate elasticity coefficient (EXR) indicate that the increase in EXR supports the import expansion of vital minerals in the majority of mineral-importing countries. The impact of energy intensity on mineral imports is anticipated because of the large rise in energy demand/intensity brought on by increasing industrialization, urbanization, and globalization (Yasmeen et al. 2022). The literature has also demonstrated the positive impact of expanding energy intensity and the growth of RE (Yu et al. 2022; Nawaz et al. 2021).
Conclusions and policy implications
Metals and minerals are essential for the shift to a low-carbon economy. The demand for the minerals required to create and use green energy technology, such as solar panels, wind turbines, electric vehicles, and energy storage, is increasing as well. In the shift to RE, this rising demand benefits the economies of nations that hold significant quantities of key minerals. In this context, the paper is shown how, for a selected group of 14 countries, the major mineral importing countries’ mineral import demand changed in response to the clean energy transitions between 2000 and 2021.
The current paper obtains some noteworthy findings. First, the research supports the study’s main hypothesis, which states that REC has a favorable long-term impact on mineral importation (MIS) in the countries that import the most minerals. That is to say, imports of minerals rise as RE sources develop. Secondly, the effects of energy intensity (EI) and exchange rate (EXR) on mineral import are favorable and statistically significant. Finally, CO2 does not help these countries’ demand for mineral imports to grow.
The findings of the paper have some significant policy implications. For instance, it encourages mineral-importing countries to move toward a decarbonized or net-zero emission pathway by utilizing minerals in the generation of RE. However, the recycling of these minerals should be a concern for the decision-makers in these economies. These countries might not succeed in implementing the circular economy goal if these mineral resources are not adequately recycled. Additionally, policymakers should use it to reshape the energy industry to rely more on renewable sources than on non-renewable ones in order to maximize the use of minerals.
In addition to the aforementioned policy recommendations, the rise of RE use is anticipated to boost demand for minerals; hence, policymakers of economies that import minerals should consider this as clean energy output grows. It is inevitable that policymakers in countries, particularly those that import minerals, will establish mineral import regulations to prevent issues with the global transition to clean energy when mineral imports expand. Mainly, the use and development of RE technology are included in the global sustainability paradigm. The most mineral-importing economies are drawn to utilize mineral resources in keeping with the carbon zero target since they are crucial for helping countries transition to clean energy in line with RE ambitions. Hence, the worldwide goal of achieving a decarbonized or net-zero emissions trajectory by the twenty-first century might be implemented by these countries’ mineral-driven clean energy generation procedure. Furthermore, the development and maintenance of national power systems depends on vital-critical minerals. In addition, supply chains for these minerals are unstable as the majority of critical mineral resources are concentrated in a small number of countries and geopolitical conditions magnify such risks (Bogdanov et al. 2019). Therefore, given the potential supply–demand imbalance of critical minerals, it is important that governments consider the strategic reserve of such scarce minerals. Finally, given that many current energy projects will eventually be forced to close, it suggests that more secondary sources will be identified in such End-of-Life (EoL) products. So that more essential minerals may be recovered from such EoL products, the policymakers should actively promote recycling activities by boosting the circular economy. A national information system on key minerals, regional EoL product collection sites, and financial subsidies are a few examples of the necessary policies that should be prepared to support recycling initiatives.
The study has a few limitations. First, due to access difficulties, mineral price data, which are important for mineral imports, were excluded from the analysis. However, the research included the exchange rate, which the paper expected to be significant in mineral imports, and it turned out that it had an impact on those imports. Second, the study’s analysis of how crucial minerals react to the transition to clean energy is also limited to 14 carefully chosen countries. In light of this, future research will compare crucial minerals and examine their sensitivity to the clean energy transition on a more regional level (OECD, EU, USA, or Middle East).
Data availability
Data is available and can be provided upon request.
References
Abbasi KR, Lv K, Radulescu M, Shaikh PA (2021) Economic complexity, tourism, energy prices, and environmental degradation in the top economic complexity countries: fresh panel evidence. Environ Sci Pollut Res 28(48):68717–68731
Adewuyi AO (2016) Determinants of import demand for non-renewable energy (petroleum) products: empirical evidence from Nigeria. Energy Policy 95:73–93
Aldakhil AM, Nassani AA, Zaman K (2020) The role of technical cooperation grants in mineral resource extraction: evidence from a panel of 12 abundant resource economies. Resour Policy 69:101822
Ali SH, Giurco D, Arndt N, Nickless E, Brown G, Demetriades A ... Yakovleva N (2017) Mineral supply for sustainable development requires resource governance. Nature 543(7645):367–372
Ballinger B, Stringer M, Schmeda-Lopez DR, Kefford B, Parkinson B, Greig C, Smart S (2019) The vulnerability of electric vehicle deployment to critical mineral supply. Appl Energy 255:113844
Bazilian MD (2018) The mineral foundation of the energy transition. Extract Ind Soc 5(1):93–97
Benoit K (2011) Linear regression models with logarithmic transformations. Lond Schl Econ Lond 22(1):23–36
Beylot A, Guyonnet D, Muller S, Vaxelaire S, Villeneuve J (2019) Mineral raw material requirements and associated climate-change impacts of the French energy transition by 2050. J Clean Prod 208:1198–1205
Bleiwas DI (2010) Byproduct mineral commodities used for the production of photovoltaic cells, vol 1365. US Department of the Interior, US Geological Survey, Washington, DC
Blomquist J, Westerlund J (2013) Testing slope homogeneity in large panels with serial correlation. Econ Lett 121(3):374–378
Bogdanov D, Farfan J, Sadovskaia K, Aghahosseini A, Child M, Gulagi A ... Breyer C (2019) Radical transformation pathway towards sustainable electricity via evolutionary steps. Nat Commun 10(1):1077
Calvo G, Valero A (2022) Strategic mineral resources: availability and future estimations for the renewable energy sector. Environ Dev 41:100640
Capellán-Pérez I, De Castro C, González LJM (2019) Dynamic energy return on energy investment (EROI) and material requirements in scenarios of global transition to renewable energies. Energ Strat Rev 26:100399
Chadha R (2020) Skewed critical minerals global supply chains post COVID-19: reforms for making India self-reliant. Brookings India.
Chevrel S, Ranchin T (2018) Impact of energy transition on mineral resources. In: GEO WEEK 2018
Chitre A, Freake D, Lander L, Edge J, Titirici MM (2020) Towards a more sustainable lithium-ion battery future: recycling LIBs from electric vehicles. Batt Supercaps 3(11):1126–1136
Chudik A, Mohaddes K, Pesaran MH, Raissi M (2016) Long-run effects in large heterogeneous panel data models with cross-sectionally correlated errors. In: Essays in honor of Aman Ullah, vol 36. Emerald Group Publishing Limited, pp 85–135
Church C, Crawford A (2020) Minerals and the metals for the energy transition: exploring the conflict implications for mineral-rich, fragile states. In: The geopolitics of the global energy transition. Springer, Cham, pp 279–304
Cox B, Innis S, Kunz NC, Steen J (2022) The mining industry as a net beneficiary of a global tax on carbon emissions. Commun Earth Environ 3(1):17
Diouf B, Pode R (2015) Potential of lithium-ion batteries in renewable energy. Renew Energy 76:375–380
Dolganova I, Rödl A, Bach V, Kaltschmitt M, Finkbeiner M (2020) A review of life cycle assessment studies of electric vehicles with a focus on resource use. Resources 9(3):32–52
Fedoseeva S, Zeidan R (2018) How (a) symmetric is the response of import demand to changes in its determinants? Evidence from European energy imports. Energy Econ 69:379–394
Figueres C, Schellnhuber HJ, Whiteman G, Rockström J, Hobley A, Rahmstorf S (2017) Three years to safeguard our climate. Nature 546(7660):593–595
Galos K, Lewicka ED, Kamyk J, Szlugaj J, Czerw H, Burkowicz A ... Guzik K (2021) Forecast trends in demand for deficit key minerals for the Polish economy. gospodarka surowcami mineralnymi 37(3)
Gielen D (2021) Critical minerals for the energy transition. International Renewable Energy Agency, Abu Dhabi
Giese EC (2022) Strategic minerals: global challenges post-COVID-19. Extract Ind Soc 101113
Grosjean C, Miranda PH, Perrin M, Poggi P (2012) Assessment of world lithium resources and consequences of their geographic distribution on the expected development of the electric vehicle industry. Renew Sustain Energy Rev 16(3):1735–1744
Habib K, Hamelin L, Wenzel H (2016) A dynamic perspective of the geopolitical supply risk of metals. J Clean Prod 133:850–858
Hammond DR, Brady TF (2022) Critical minerals for green energy transition: a United States perspective. Int J Min Reclam Environ 36(9):624–641
Hsiao C, Pesaran MH, Pick A (2012) Diagnostic tests of cross-section independence for limited dependent variable panel data models. Oxford Bull Econ Stat 74(2):253–277
Hu S, He S, Jiang X, Wu M, Wang P, Li L (2021) Forecast and suggestions on the demand of lithium, cobalt, nickel and manganese resources in China’s new energy automobile industry. In: IOP Conference Series: Earth and Environmental Science, Vol. 769, No. 4. IOP Publishing, p 042018
Huang J, Ding Q, Wang Y, Hong H, Zhang H (2021) The evolution and influencing factors of international tungsten competition from the industrial chain perspective. Resour Policy 73:102185
IEA (2021) The role of critical world energy outlook special report minerals in clean energy transitions. World Energy Outlook Special Report. https://iea.blob.core.windows.net/assets/ffd2a83b-8c30-4e9d-980a-52b6d9a86fdc/TheRoleofCriticalMineralsinCleanEnergyTransitions.pdf, (26/10/2022)
Krane J, Idel R (2021) More transitions, less risk: how renewable energy reduces risks from mining, trade and political dependence. Energy Res Soc Sci 82:102311
Lenarčič Č, Ganesh SG (2020) Calculation methodology of the effective exchange rate in Slovenia. Mednarodno inovativno poslovanje. J Innov Bus Manag 12(2):20–37
Islam MM, Sohag K, Alam MM (2022a) Mineral import demand and clean energy transitions in the top mineral-importing countries. Resour Policy 78:102893
Islam MM, Sohag K, Hammoudeh S, Mariev O, Samargandi N (2022b) Minerals import demands and clean energy transitions: a disaggregated analysis. Energy Econ 113:106205
Islam MM, Sohag K, Mariev O (2023) Geopolitical risks and mineral-driven renewable energy generation in China: a decomposed analysis. Resour Policy 80:103229
Kim TY, Karpinski M (2020) Clean energy progress after the Covid-19 crisis will need reliable supplies of critical minerals. IEA: International Energy Agency. https://policycommons.net/artifacts/1343400/clean-energy-progress-after-the-covid-19-crisis-will-need-reliable-supplies-of-critical-minerals/1955545/ on 26 Sep 2022. CID: 20.500.12592/djz7pt. (30.01.2023)
Klimenko VV, Ratner SV, Tereshin AG (2021) Constraints imposed by key-material resources on renewable energy development. Renew Sustain Energy Rev 144:111011
Küpper D, Wolf S, Xu G, Kuhlmann K, Pieper C, Ahmad J (2018) The future of battery production for electric vehicles. Boston Consulting Group. Inc., Boston
Lee J, Bazilian M, Sovacool B, Hund K, Jowitt SM, Nguyen TP ... Kukoda S (2020) Reviewing the material and metal security of low-carbon energy transitions. Renew Sustain Energy Rev 124:109789
Li J, Zhang X, Ali S, Khan Z (2020) Eco-innovation and energy productivity: new determinants of renewable energy consumption. J Environ Manag 271:111028
Liang Y, Kleijn R, Tukker A, van der Voet E (2022) Material requirements for low-carbon energy technologies: a quantitative review. Renew Sustain Energy Rev 161:112334
Lin B, Ouyang X (2014) Analysis of energy-related CO2 (carbon dioxide) emissions and reduction potential in the Chinese non-metallic mineral products industry. Energy 68:688–697
Luo X, Pan L, Yang J (2022) Mineral resource constraints for China’s clean energy development under carbon peaking and carbon neutrality targets: quantitative evaluation and scenario analysis. Energies 15(19):7029
Ma W (2022) Diversity and political stability of rare earth supply for renewable energy in the context of energy security. Master Thesis, Nijmegen School of Management. https://theses.ubn.ru.nl/bitstream/handle/123456789/13765/Ma%2c_Wenjun_1.pdf?sequence=1, (14/11/2022)
Månberger A, Stenqvist B (2018) Global metal flows in the renewable energy transition: exploring the effects of substitutes, technological mix, and development. Energy Policy 119:226–241
McLellan BC, Yamasue E, Tezuka T, Corder G, Golev A, Giurco D (2016) Critical minerals and energy–impacts and limitations of moving to unconventional resources. Resources 5(2):19
Meinert LD, Robinson GR Jr, Nassar NT (2016) Mineral resources: reserves, peak production and the future. Resources 5(1):14
Mills MP (2020) Mines, minerals, and “green” energy: a reality check. Report July
Moreau V, Dos Reis PC, Vuille F (2019) Enough metals? Resource constraints to supply a fully renewable energy system. Resources 8(1):29
Moss RL, Tzimas E, Willis P, Arendorf J, Thompson P, Chapman A ... Ostertag K (2013) Critical metals in the path towards the decarbonization of the EU energy sector. Assessing rare metals as supply-chain bottlenecks in low-carbon energy technologies. JRC Report EUR, 25994
Mróz M (2022) Energy security in danger? A comparative analysis of oil and copper supply. Energies 15(2):560
Nassani AA, Aldakhil AM, Zaman K (2021) Ecological footprints jeopardy for mineral resource extraction: efficient use of energy, financial development and insurance services to conserve natural resources. Resour Policy 74:102271
Nate S, Bilan Y, Kurylo M, Lyashenko O, Napieralski P, Kharlamova G (2021) Mineral policy within the framework of limited critical resources and a green energy transition. Energies 14(9):2688
Nawaz MA, Hussain MS, Kamran HW, Ehsanullah S, Maheen R, Shair F (2021) Trilemma association of energy consumption, carbon emission, and economic growth of BRICS and OECD regions: quantile regression estimation. Environ Sci Pollut Res 28:16014–16028
Nejati M, Bahmani M (2020) The economic impacts of foreign direct investment in oil and gas sector: a CGE analysis for Iranian economy. Energ Strat Rev 32:100579
Norgate T, Haque N (2010) Energy and greenhouse gas impacts of mining and mineral processing operations. J Clean Prod 18(3):266–274
Ouedraogo A (2016) Local economic impact of boom and bust in mineral resource extraction in the United States: a spatial econometrics analysis. Resour Policy 50:292–305
Pesaran MH (2007) A simple panel unit root test in the presence of cross-section dependence. J Appl Econ 22(2):265–312
Pesaran MH, Yamagata T (2008) Testing slope homogeneity in large panels. J Econ 142(1):50–93
Pesaran MH, Ullah A, Yamagata T (2008) A bias-adjusted LM test of error cross-section independence. Econ J 11(1):105–127
Ren K, Tang X, Wang P, Willerström J, Höök M (2021) Bridging energy and metal sustainability: insights from China’s wind power development up to 2050. Energy 227:120524
Ritchie H, Roser M (2020) CO2 and greenhouse gas emissions, emissions by sector. Our World in Data. https://ourworldindata.org/emissions-by-sector, (30.01.2023)
Samargandi N, Sohag K, Kutan A, Alandejani M (2021) The force of globalization reshaping the local institutions: evidence from the Organization of Islamic Cooperation member countries. Int J Emerg Mark 16(8):1943–1963
Shin Y, Yu B, Greenwood-Nimmo M (2014) Modelling asymmetric cointegration and dynamic multipliers in a nonlinear ARDL framework. In: Festschrift in honor of Peter Schmidt. Springer, New York, pp 281–314
Sohag K, Chukavina K, Samargandi N (2021) Renewable energy and total factor productivity in OECD member countries. J Clean Prod 296:126499
Su CW, Umar M, Khan Z (2021) Does fiscal decentralization and eco-innovation promote renewable energy consumption? Analyzing the role of political risk. Sci Total Environ 751:142220
Tokimatsu K, Höök M, McLellan B, Wachtmeister H, Murakami S, Yasuoka R, Nishio M (2018) Energy modeling approach to the global energy-mineral nexus: exploring metal requirements and the well-below 2 C target with 100 percent renewable energy. Appl Energy 225:1158–1175
Tao R, Umar M, Naseer A, Razi U (2021) The dynamic effect of eco-innovation and environmental taxes on carbon neutrality target in emerging seven (E7) economies. J Environ Manag 299:113525
Toro N, Robles P, Jeldres RI (2020) Seabed mineral resources, an alternative for the future of renewable energy: a critical review. Ore Geol Rev 126:103699
Vakulchuk R, Overland I, Scholten D (2020) Renewable energy and geopolitics: a review. Renew Sustain Energy Rev 122:109547
Vidal O (2017) Mineral resources and energy: future stakes in the energy transition. Elsevier
Viebahn P, Soukup O, Samadi S, Teubler J, Wiesen K, Ritthoff M (2015) Assessing the need for critical minerals to shift the German energy system towards a high proportion of renewables. Renew Sustain Energy Rev 49:655–671
Vivoda V (2011) Determinants of foreign direct investment in the mining sector in Asia: a comparison between China and India. Resour Policy 36(1):49–59
Yu S, Liu J, Hu X, Tian P (2022) Does development of renewable energy reduce energy intensity? Evidence from 82 countries. Technol Forecast Soc Chang 174:121254
Wang D, Tong X, Wang Y (2020) An early risk warning system for outward foreign direct investment in mineral resource-based enterprises using multi-classifiers fusion. Resour Policy 66:101593
Wang F, Harindintwali JD, Yuan Z, Wang M, Wang F, Li S ... Chen JM (2021) Technologies and perspectives for achieving carbon neutrality. Innovation 2(4):100180
Wang Y, Xiong X, Dongye M, Li D, Qu Y, Liu Q, Huo YA (2022) Prediction model and exploration prospect analysis of phosphate mineral resources in China. Geol China 49(2):435–454
Watari T, McLellan BC, Giurco D, Dominish E, Yamasue E, Nansai K (2019) Total material requirement for the global energy transition to 2050: a focus on transport and electricity. Resour Conserv Recycl 148:91–103
Wei W, Ge Z, Geng Y, Jiang M, Chen Z, Wu W (2022) Toward carbon neutrality: uncovering constraints on critical minerals in the Chinese power system. Fundam Res 2(3):367–374
Wen B, Chen Y, Wang G, Dai T (2019) China’s demand for energy and mineral resources by 2035. Strat Stud Chin Acad Eng 21(1):68–73
Xi X, Zhou J, Gao X, Liu D, Zheng H, Sun Q (2019) Impact of changes in crude oil trade network patterns on the national economy. Energy Econ 84:104490
Yasmeen R, Yao X, Padda IUH, Shah WUH, Jie W (2022) Exploring the role of solar energy and foreign direct investment for clean environment: evidence from top 10 solar energy consuming countries. Renew Energy 185:147–158
Zaidi SAH, Hussain M, Zaman QU (2021) Dynamic linkages between financial inclusion and carbon emissions: evidence from selected OECD countries. Resour Environ Sustain 4:100022
Zhu R, Lin B (2022) How does the carbon tax influence the energy and carbon performance of China’s mining industry? Sustainability 14(7):3866
Zhu X, Ding Q, Chen J (2022) How does critical mineral trade pattern affect renewable energy development? The mediating role of renewable energy technological progress. Energy Econ 112:106164
Zhu Y, Ali SH, Xu D, Cheng J (2021) Mineral supply challenges during the COVID-19 pandemic suggest the need for an international supply security mechanism. Resour Conserv Recycl 165:105231
Zhuang Y, Yang S, Razzaq A, Khan Z (2021) Environmental impact of infrastructure-led Chinese outward FDI, tourism development and technology innovation: a regional country analysis. J Environ Plan Manag 1–33
Funding
No funding was received for conducting this study.
Author information
Authors and Affiliations
Contributions
Nurcan Kilinc-Ata performed material preparation, data collection, and writing the paper. Kashif Munir performed only the analysis. Mohamed Alshami reviewed the paper. All the authors have read and agreed to the published version of the manuscript.
Corresponding author
Ethics declarations
Ethics approval and consent to participate
We can confirm we have no financial or other conflicts of interest associated with the paper.
Consent for publication
Yes.
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.
About this article
Cite this article
Kilinc-Ata, N., Alshami, M. & Munir, K. How do strategic mineral resources affect clean energy transition? Cross-sectional autoregressive distributed lag (CS-ARDL) approach. Miner Econ 36, 643–654 (2023). https://doi.org/10.1007/s13563-023-00373-3
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s13563-023-00373-3