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Article

Energy R&D towards Sustainability: A Panel Analysis of Government Budget for Energy R&D in OECD Countries (1974–2012)

Graduate School of Science and Technology Policy, Korea Advanced Institute of Science and Technology (KAIST), Daejeon 34141, Korea
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Author to whom correspondence should be addressed.
Sustainability 2017, 9(4), 617; https://doi.org/10.3390/su9040617
Submission received: 30 January 2017 / Revised: 8 April 2017 / Accepted: 10 April 2017 / Published: 15 April 2017

Abstract

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Energy transition is one of the greatest challenges for sustainability. However, the overall composition of the world energy supply has not changed much since the late 1970s, with fossil fuels providing 81% of the world’s total primary energy supply. While political leaders increasingly call for proactive policies to innovate the energy sector in the face of climate change, governments around the world commit vastly different levels of budgets to energy R&D. This research examines the potential determinants of cross-national variations in government budget allocations for energy R&D with three perspectives. With the panel data analysis of OECD countries (1974–2012), we check the supply-side, demand-side, and institutional factors inducing government investment in R&D for energy in general as well as for renewable energy. Among the multitude of factors tested in our analysis, gross domestic R&D expenditure, refinery output, and the rightist orientation of the governing party show significantly positive influences on government R&D budgets for energy in general. However, refinery output shows the negative effect on government R&D budget for renewables. This contrasting finding about the impact of refinery output on government investment in energy R&D in general vs. renewable energy R&D suggests that policymakers and scholars need to better appreciate the complex roles of the oil sector in driving public R&D investment in energy. It also calls for more proactive renewable energy policy to make progress towards sustainable energy transition.

1. Introduction

Since The Limits to Growth (1972) opening the floodgates to numerous publications on sustainability [1], energy issues have been a central part of the sustainability discourse. The famed definition of sustainability from the Brundtland Report (1987), “meeting the needs of the present without compromising the ability of future generations to meet their needs” is quite pertinent to the discussion of energy issues these days, for keen interest in renewable energy and concern with fossil fuels are all rooted in the need to ensure the provision of energy not just for the present but for the future of humanity [2]. More recently, climate change has intensified public concerns with the sustainable energy transition, which have been met by aggressive calls for investment in energy technologies by high-ranking government officials and energy policy scholars around the world [3,4,5].
However, the overall composition of world energy supply has not changed much. In addition, 81% of the world’s total primary energy supply (TPES) still comes from fossil fuels, which is not much different from the TPES level (87%) in 1973 [6]. Furthermore, fossil fuels expectedly continue to a major source of global energy consumption, projected to account for 78% of global energy use in 2040 [7].
It is then somewhat puzzling why progress towards the sustainable energy transition has been too slow to make a real impact in world energy supply and demand despite the decades-long concerns with energy security and climate change.
Motivated by the apparent gap between the persistent calls for sustainable energy and the reality reflected in the energy statistics, this study examines public investment in energy technologies as manifested in the government budget appropriations for energy research and development (R&D) on energy. Since much of the development for sustainable energy depends on technological innovations enabling the cost-effective extraction and reliable storage of sustainable energy, R&D investment for energy technologies is the crucial link in the sustainable energy transition. In this regard, it is quite notable that governments around the world spend astonishingly different amounts on energy R&D. Why is this so? What can explain the level of government investment in energy R&D across countries?
This study assesses various factors explaining cross-national variations in public R&D on energy including R&D on renewable energy in order to uncover the major determinants of public commitment to R&D on energy technologies in advanced countries as manifested in government budget appropriations for energy R&D. In what follows, we first introduce three theoretical perspectives on public expenditure in R&D for energy technologies, reviewing the existing accounts of different factors underlying government investment levels on energy R&D. We then present an empirical analysis of the governmental expenditure on energy R&D based on the panel data from 34 OECD countries (1974–2012). One of the key empirical findings from the study concerns the significant impact of the petroleum refining sector on energy R&D investment. The size of refinery output turns out to be positively linked to government budgets for energy R&D but negatively linked to government budgets for renewable energy R&D. We discuss the implications of our findings and conclude the study with the suggestions for further research.

2. Existing Explanations

Existing research on investment on energy technologies takes three perspectives in identifying and understanding the determinants of governmental investment in R&D for energy technologies, which can be named as the supply-side, demand-side, and institutional perspectives [8]. Before turning to each perspective, it should be noted that the research on public R&D for energy are relatively little compared to the firm or industry level research on energy R&D, as pointed out in a recent overview of public expenditures on energy R&D [9]. As for the latter, there exist a couple of stylized findings. One of them relates to the effect of firm size, as large fixed costs acts as a barrier for firms’ investment in energy R&D [10,11,12]. Another finding is that it is the access to knowledge and the market structure (such as the degree of existing monopoly), rather than the cost and financing of R&D, that explain firms’ energy R&D choices better [13,14,15,16,17]. This finding resonates with one of the discussions of the national innovative capacity explained below.
When it comes to public R&D on energy technologies, one may consider three general perspectives that are complementary to one another. The first perspective focuses on the supply side viewing R&D investment to be driven largely by resources and capabilities to initiate and implement technological innovation for sustainable energy, which largely corresponds to the technology-push model of innovation [18].
In the context of generic R&D investment, scholars have identified several factors related to resources and capabilities such as scientific talent pool, knowledge stock, or research infrastructure [19,20,21,22]. As R&D is a capital-intensive and knowledge-intensive process, R&D investment hinges critically on material and non-material input whether in the form of research funding, personnel, or experimental equipment. Like any other kind of R&D, energy R&D also requires extensive investment in various forms of input. In particular, technological innovation for alternative forms of energy tends to be more of a more radical nature, which often is made available by a large-scale outlay of capital, labor, and knowledge.
In one of the most comprehensive studies of the so-called “national innovative capacity”, Furman et al. outlined the analytical framework accounting for a number of factors underlying national innovation competitiveness based on three theories—endogenous growth theory, national industrial competitive advantage, and national innovation systems [23]. Furman et al.’s framework has been widely applied in cross-country innovation studies including technology spillovers in the Chinese high-tech industries, studies of firms’ location strategies and knowledge spillover patterns in the United States, the factors of radical innovation across nations, and the national innovative capacity of latecomer countries in East Asia [24,25,26,27]. Many of the variables included in Furman et al.’s analysis such as R&D personnel, gross domestic expenditure on R&D (GERD) and international patent stocks would probably matter as well for innovations in energy technologies as well as government investment in them.
The second perspective for understanding the drivers of government investment in R&D for energy technologies is the demand-side explanation, which hinges on the role of the needs or challenges facing sustainable energy transitions. Two such factors stand out in the discourse on sustainable energy transitions—energy security and climate change [28,29].
Defined simply as “the uninterrupted availability of energy sources at an affordable price” [30], energy security has long been a critical issue for national security. Especially in the aftermath of the oil shocks, many industrialized countries came to view dependence on imported oil as a serious threat to national security, out of concern for vulnerability to supply disruption of oil exporting countries located in one of the most volatile regions in the world. Dependence on imported oil is often equated to energy security, yet the same rate of imported oil dependence can mean different levels of energy security depending on the political, economic, and social context of each country [31,32]. In many countries of widely different political and economic circumstances, however, the insecurity of energy supply has been a common rationale for proactive government roles in technological innovations for sustainable energy.
In addition to the need to reduce imported oil dependence, the need to reduce greenhouse gas emissions for climate change mitigation has emerged as a key driver of governmental investment in energy technologies. Governments around the world undergoing a series of international climate negotiations in the last decade have become keen on technological solutions to reduce reliance on fossil fuels. Climate change mitigation and adaptation are now the cornerstones of energy policy in many countries including the European Union [9,28].
The third perspective is an institutional explanation focusing on the politics and policies underpinning government R&D decisions on energy innovation. The well-known Porter hypothesis, for example, states that government regulatory policies imposing strict environmental standards can trigger technological innovations, thereby raising competitiveness [33]. While the Porter hypothesis being relevant to the firm level has been tested extensively with industry or sectoral data on environmental innovation [34], there are relatively fewer studies that delve into the effect of political and institutional factors on energy innovation at the country level.
Some such studies include those examining the effect of legislative fractionalization and government partisanship on cross-national differences in public R&D expenditure on energy technologies [35,36,37]. In a more general context of policy initiation and change, veto player theory [38] is often utilized to model the constraints of existing power constellations in the government on proactive policy change such as increased expenditure on particular purposes like welfare reforms, environmental protection, or energy security [39].
In the following empirical analysis, we present a comprehensive test of the potential determinants of energy R&D investment including government R&D on renewables by deriving the explanatory variables from those three perspectives.

3. Empirical Tests

This study intends to explore the determinants of energy R&D investment at the country rather than the firm level. The empirical tests of this study are mainly designed to check the potential determinants of governmental R&D investment in energy technologies across countries over a certain period time, thus necessitating the use of panel regressions.
More specifically the data for the current empirical tests come from 34 OECD countries observed between 1974 and 2012. While the choice of OECD countries is largely due to the data availability, it is also justifiable given that these countries have taken more than a half of the world’s primary energy supply over the last four decades [40].
We use three indicators for government R&D investment on energy technologies in general and two indicators for energy R&D on renewables as dependent variables. One of the government R&D investments on energy technologies is the government budget appropriation or outlays for R&D (GBAORD) for energy expressed in million dollars (2005 constant prices and PPP). GBAORD for energy is a better measure for fiscal commitment of the government for energy R&D than government-financed gross domestic expenditure on R&D. This is because GBAORD is based on reports by R&D funders unlike the government-financed expenditure on R&D that draws on reports by R&D performers that could over- or under-estimate the level of funding. It is also more comprehensive as it covers payments to foreign R&D performers including international organizations, unlike government-financed gross domestic expenditure on R&D (GERD) that is limited to R&D performed within the national territory. The second indicator for government R&D investment on energy technologies is the energy share of GBAORD expressed as % of total GBAORD. As such, it just represents GBAORD on energy R&D in relative terms.
The third indicator for government investment in general energy R&D is the total government budget of energy research, development, and demonstration (RDD) expressed in millions of dollars (2012 prices and exchange rates). While GBAORD for energy covers only basic and applied research and experimental development (i.e., R&D), total energy RDD includes “demonstration” (often in the forms of prototyping, field tests, or lab trials). The data for energy RDD are compiled by the International Energy Agency (IEA), while the GBAORD data are collected by the OECD Directorate for Science, Technology, and Industry following the well-known Frascati Manual [41].
Two indicators for energy R&D on renewables are energy RDD for renewables in absolute and relative terms. The absolute measure is the amount of energy RDD for solar energy, wind energy, ocean energy, biofuels, geothermal energy, hydroelectricity, other renewable energy sources, and unallocated renewable energy sources denominated in million dollars (2012 prices and exchange rates). The relative measure is the share (%) that renewable energy sources take in the whole energy RDD.
As for the explanatory variables, we use three groups of variables drawing on the theoretical perspectives for the drivers of government R&D on energy innovations as reviewed in the previous section. The first group of the explanatory variables derived from the supply-side perspective include the variables capturing resources and capabilities for energy innovation such as international patent stocks, total R&D personnel, gross domestic expenditure on R&D (GERD), public spending on education, GERD financed by industry, and GERD performed by higher education institutes. These are the very variables identified in Furman et al.’s study to be part of the national innovative capacity.
The second group of the independent variables is based on the demand-side explanations. Touching upon two challenges boosting energy policy demands—energy security and climate change—these variables are the share of energy import in total energy use, refinery gross output, CO2 emissions, and total electricity consumption.
As for climate change risks, greenhouse gas emissions such as CO2 emissions are generally considered as a reliable proxy for them. In contrast, there is no common indicator for energy security challenges agreed upon among policy makers and scholars, for each country faces different kinds and levels of energy security challenges as pointed out previously [31,32]. However, for most energy importing countries, the level of their dependence on imported energy sources is considered as a critical indicator of energy security [42]. In addition, the size of the oil sector as captured by refinery gross output can be taken as another demand-side indicator, for the larger the oil sector, the more challenging the shift towards sustainable energy [43]. Total electricity consumption generally captures the market demand for energy investment [44].
The last group of the independent variables captures political and institutional aspects that might as well relate to governmental decisions to make proactive policy changes such as the promotion of energy R&D. One of these variables is the partisanship of the governing party, for partisan orientations of top political leadership have general influence on the directions of many governmental policies [45]. Two other variables of this category, the degree of control of parliamentary houses and the vote share of opposition parties, are used to check the veto player theory in relation to energy transition. Figure 1 outlines the variables categorized into each group with detailed data descriptions for each variable available in Table 1.

4. Findings

This section presents our empirical findings in two sub-sections—one from descriptive analyses and the other from panel regression analyses.
As shown in Table 2, countries in the sample of the current analysis show substantially large variation in both absolute and relative amounts of R&D budget for energy in general as well as of R&D for renewable energy in particular. For instance, the government budget appropriation for energy averaged for the period of study ranges from 1.7 million (Iceland) to 3.9 billion dollars (Japan). If grouped into quartiles, it still ranges from 4.9 million to 1.3 billion dollars.
The relative amount of the R&D budget for energy also shows a large variation across countries, ranging from 0.34% (Poland) to 18.12% (Japan) of the government R&D budget allocation. In terms of quartiles, the first-quartile countries turn out to allocate about 8.8% of the government R&D budget to energy, which is more than eight times that of the fourth-quartile countries. The total government budget for energy research, development and demonstration ranges from 4.7 million (Poland) to 4.7 billion (US) dollars. Finally, energy R&D for renewables also reveals substantial variation across countries. Most notably, the US, which spends the largest amount in absolute terms, turns out to be one of the countries devoting the least share of its energy RDD expenditures to renewable energy sources.
What can then explain such large cross-national variations in government investment in energy R&D as well as on R&D for renewables? Following the framework introduced in the previous section, we run the panel regressions with three groups of explanatory variables capturing supply-side, demand-side, and institutional factors.
Before we proceed to the regression analysis of the potential determinants of government budget allocations for energy R&D, we present the descriptive statistics including those for the dependent variables in Table 3. The ratio of the standard deviation (SD) to mean shown in the last column of this table allows us to compare the degree of variations in each variable as it adjusts the SD to the scale of the variable. It turns out that the three dependent variables have generally larger variation compared to the independent variables except a few ones such as R&D expenditure (GERD), energy imports rate, and refinery gross output.
Our main regression findings are reported in two sets of tables. Table 4 and Table 5 shows the regression results for government energy R&D expenditures, while Table 6 and Table 7 show those for government R&D expenditures on renewable energy. All regressions contain the absolute and relative measures of government energy R&D expenditures. Furthermore, in all tables, we report the results of the fixed-effects and random-effects panel regressions. While the Hausman specification test is available for the choice over fixed-effects vs. the random-effects model, it does not provide a definite result for the current data due to the finite sample problem. We thus report the results from both models.
As for the regressions of government energy R&D expenditures reported in Table 4 and Table 5, three variables in our explanatory framework of government investment turn out to have relatively consistent effects, each of which happens to correspond to each of three dimensions.
One of them is the size of overall investment in R&D (GERD) among the supply-side factors. Other than in the random-effects regression of energy share of GBAORD, GERD shows a statistically significant coefficient in all regressions. In particular, according to the random-effects estimation, an increase in GERD by a million dollars turns out to boost government budget allocation for energy by as much as $18,000. The same increase also leads to $17,000 more in the total budget for energy RDD. This finding may be quite a straightforward result of GERD encompassing R&D on energy, but given that much of the existing literature focuses on R&D at the industry level as well as looks into the effect of GERD on energy innovation output (such as patents), this finding is worth contemplating, as it is perhaps one of the first pieces of evidence on the direct effect of GERD on public R&D expenditure on energy technologies.
The second variable that shows a consistently significant effect is the refinery gross output measured in megaton among the demand-side factors. While this variable is insignificant in the fixed-effects estimation, it is strongly significant in all random-effects regressions. An additional megaton of refinery gross output is associated with a $8.8 million increase in the government R&D budget for energy, which suggests that countries with greater output in refinery products allocate more, not less, R&D for energy. In addition, in terms of relative investment in energy, refinery gross output has a positive effect on the share of energy in the government R&D budget.
Among the institutional factors, the political orientation of the governing party is significantly linked to the government R&D budget for energy as well as to the total budget for energy RDD. The negative coefficient on the chief executive party orientation indicates that rightist governments tend to devote more R&D budget to energy. More specifically, when the political orientation of the chief executive party changes from right to center or center to left, it is likely to reduce the energy R&D budget by 38 million dollars and to reduce the total energy RDD budget by 35 million dollars, according to the random-effects estimation. However, the governing party orientation has no significant effect on the relative share of energy in the government R&D budget.
Table 5 presents the first-order autoregressive panel regression results, as the budget data are typically time-series that often become stationary after first-differencing. Once first-order autoregression is accounted for, most variables lose statistical significance. However, the overall size of R&D investment (GERD) still shows a positive effect on the absolute amount of the energy R&D budget. Refinery gross output also shows a positive effect on both absolute and relative amounts of R&D budget in the random-effects regressions.
As for the regressions of government expenditure on energy RDD for renewables presented in Table 6 and Table 7, we find three notable differences in the results from the previous ones. First, gross domestic R&D (GERD) performed by higher education shows much more significant effects on government expenditure on energy RDD for renewables than on government expenditure on energy R&D in general. For instance, as seen in Table 6, the coefficient on GERD performed by higher education ranges from 0.347 (for the renewable share of energy RDD in Regression IV) to 3.233 (for energy RDD for renewables in absolute amount in Regression I). The latter figure implies that one percentage point increase in gross domestic R&D performed by the higher education sector turns out to generate 3.2 million dollars more based on fixed-effect estimation (or 1.8 million dollars more based on random-effects estimation), if other conditions are held constant. Even the first-order autoregressive regressions turn out highly significant results for the effect of GERD performed by the higher education sector on the absolute size of energy RDD for renewables.
This result makes a great deal of sense. Renewable energy technologies tend to be of a more radical nature compared to other types of more traditional and more mature energy technologies that tend to develop in the incremental fashion. Compared to the industry sector, the higher education sector performs more basic research, which brings more opportunities for breakthrough inventions or innovations. Thus, renewable energy R&D would critically hinge on research capabilities of higher education institutions.
Second, contrary to the finding for government expenditure on energy R&D in general, refinery gross output has a negative effect on renewable energy R&D. As seen in the last two tables, in both regressions with and without the first-order autoregressive term, refinery gross output shows a consistently negative coefficient on energy RDD for renewables in both absolute and relative terms.
This result, together with the previous one, indicates that, while the governments of countries with a larger oil sector invest more on energy R&D in general, they spend less on R&D for renewable energy. This finding may be not surprising at all, yet it is still worth noting in two regards. First, our analysis is on government expenditure rather than total R&D expenditure on R&D. The contribution of the oil sector to energy R&D expenditure in general may be quite obvious, given that the oil industries (and other fossil fuel sectors such as natural gas or coal) have great incentives and need to pour money into energy R&D. However, it is not so straightforward that oil industries would also have similar effects on “government” expenditures on energy R&D. The effect of oil industries on government R&D spending on energy could be either positive or negative. The well-known crowding-out hypothesis in the public finance literature posits that public expenditure diminishes the incentives for private investment, thus reducing private spending rather than complementing it [46,47]. The current finding suggests a possibility of the oil sector wielding influence on governmental budget decisions for energy R&D, which may, in turn, crowd out the R&D investment by the oil sector.
Finally, we find virtually no institutional variables to have significant effects on government expenditure on energy RDD for renewables. This result is quite surprising, for the size of renewable R&D is very much likely to be tied to public commitment to sustainable energy transition, which, in turn, is reflected in various political and institutional features of the regime such as partisan orientation of the governing party.
When it comes to the overall explanatory power of the current models, the set of independent variables derived from our framework of government investment in energy R&D explain a fairly large portion of the variations in the absolute amount of energy R&D budget. The random-effects regression explains more than three fourths of cross-national variations in the absolute amount of government energy R&D budget—78% of government R&D budget allocation and 82% of total government budget for energy RDD (81% and 87%, respectively, in the first-order autoregressive regression). The current set of explanatory variables also explains about 34% of the relative size of government energy R&D budget with the random-effects estimation. Furthermore, for the renewable energy R&D expenditure, our explanatory framework explains about 72% of the cross-national variations in the absolute amount of government expenditure on energy RDD for renewables when estimated with the random-effects model. In contrast, our model explains 39% of the variation in the relative share of renewables in energy RDD when estimated by the random-effects model with the first-order autoregressive term.
A high R 2 with relatively few significant individual coefficients is a symptom of the multicollinearity problem. According to the bivariate correlations among the variables, total R&D personnel shows very high correlations with three other variables—refinery output, CO2 emissions, and total electricity consumption. The regressions excluding total R&D personnel—unreported here but available upon the request to the authors—show better results in terms of the significance of individual coefficients.

5. Discussion

Calls for energy transitions towards sustainability have been increasingly pervasive and intensive in energy policy discourses, echoed by various policies and programs to promote technological innovation for sustainable energy around the world [48]. When it comes to actual investment for energy R&D, however, governments have shown vastly different levels of commitment to energy transitions. Even if we take into account different rates of sustainable energy transitions across countries [49], government budget allocations for energy R&D in general as well as for R&D on renewable energy sources vary a great deal across countries in both absolute and relative terms.
In an effort to understand the sources of such variations in government investment in energy R&D, we have formulated an analytical framework to help sort out a multitude of factors directly or indirectly influencing public investment on energy R&D including governmental expenditures on renewable energy R&D. The framework consists of three—supply-side, demand-side, and institutional—dimensions, derived from the previous literature on the socioeconomic and infrastructural factors underpinning energy R&D. Based on this framework, our empirical analysis examines a score of potential determinants of cross-national variations in government investment in energy R&D in general as well as R&D on renewable energy using the panel data from 34 OECD countries for the period of 1974–2012.
One of the key empirical findings is the significant impact of the petroleum refining sector on energy R&D investment. The size of refinery output turns out to be positively linked to government budgets for energy R&D but negatively linked to government budgets for renewable energy R&D. This suggests that despite popular perceptions of the oil sector as an obstacle to energy innovations [50,51], countries with larger oil sectors invest more of their government budget on energy R&D. However, their governments spend less on research, development, and demonstrations for renewable energy, which largely conforms to the conventional wisdom of the reduction of dependence on fossil fuels for sustainable energy transition. However, the contrasting findings of the oil sector in government energy R&D in general vs. R&D for renewables call for a more in-depth analysis in the future of the roles of the oil sector in energy innovation towards sustainable energy transition.
In addition, the findings about the institutional factors—especially, the influence of governing party orientation—challenge the conventional wisdom, for leftist parties tend to be more critical of oligopolistic energy supply characteristic of the fossil-fuel driven energy sector and thus more supportive of sustainable energy R&D funded by governments.
One of the contributions of this study is that it provides a more comprehensive understanding of energy R&D and innovation activities by looking into cross-national differences in governmental budget for energy R&D, given that much of the existing literature on energy innovation has focused on the firm level [28]. In addition, our findings hold practical implications for making sustainable energy transitions.
The finding about the positive linkage of the oil sector and government budget for energy R&D suggests that energy policymakers need to recognize and analyze the role of the oil sector in driving government investment on energy R&D rather than simply scapegoating it as an obstacle to the transition to a sustainable economy. However, the negative effect of the oil sector on governmental investment in renewable energy implies that countries with large oil sectors need to come up with more proactive policies for public investment in renewable energy in order to compensate for such negative influence of oil industries on renewable R&D at least supported by the government budget.

6. Conclusions

Despite decades-long calls for sustainable energy transitions, the overall composition of the world energy supply has not changed much since the late 1970s, with fossil fuels comprising 81% of the world’s total primary energy supply. In this study, we address this persistent gap between the call for sustainable energy transition and the reality of energy supply around the world with an empirical analysis of cross-national differences in government commitment to energy innovation as manifest in government budgets for energy R&D. Our panel regressions of cross-national data from 34 OECD countries (1974–2012) reveal a couple of variables to have significant influence on the size of government budget allocation for energy R&D in general as well as for R&D on renewables.
One is the gross domestic expenditure on R&D (GERD), which captures the level of overall R&D investment. As expected, this supply-side variable is positively linked to both government investment on energy R&D and R&D on renewables measured in absolute terms. However, the overall level of domestic R&D expenditure does not show significant effects on government R&D budget allocations for either energy R&D in general or renewable energy R&D measured in relative terms.
The second variable is refinery gross output, which reflects the demand side for energy R&D investment. Interestingly, refinery gross output measured in megatons show the opposite effects on government budget allocations for energy R&D in general and those for renewable R&D. It is positively linked to the former but negatively linked to the latter. That is, the governments of countries with a larger oil sector tend to devote more of their R&D expenditure to energy R&D but less to R&D for renewables.
The third variable of statistical significance is the political orientation of the governing party, with the rightist governments turning out to be more inclined to spend on energy R&D. However, none of the institutional variables have significant effects on government budget allocations for renewable R&D. Some of these findings seem to correspond to conventional wisdom, while others do not.
This study leaves some to be desired, which leads to the suggestions for further improvement in future research. One of the improvements that can be made relates to the sample of countries. The current empirical analysis is limited largely to affluent countries. While this is a result of data inaccessibility of developing countries, further research can modify the analytical framework to suit the data availability of developing nations even if that means the set of variables is relatively reduced compared to that of the current analysis.
Another improvement that can be made is to explore government R&D expenditures on different categories of renewables more in detail. It could be very likely that the aggregate effects we find in the current analysis may differ by the type of renewables. This would generate more specific policy implications for sustainable energy transitions. In particular, given the vastly different political economic regimes around the world, countries would have to develop more refined approaches to promoting sustainable energy supply and consumption rooted in their historical and political realities as documented well in the recent review of sustainable energy transitions [52].
Finally, if we are concerned with the overall impacts of the fossil fuel sector in energy innovation and sustainable energy transition, we should also consider the roles of other types of fossil fuel than oil, such as natural gas and coal. While the distribution of countries (and particularly the government budgets) is much wider in the data on petroleum, it is clearly worth investigating the effects of natural gas and coal sectors on governmental commitment to energy R&D.

Acknowledgments

All sources of funding of the study should be disclosed. Please clearly indicate grants that you have received in support of your research work. Clearly state if you received funds for covering the costs to publish in open access.

Author Contributions

Inkyoung Sun conceived, designed, and performed the data analysis; So Young Kim refined the data analysis and wrote the main parts of the paper.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Analytical framework for government investment in energy R&D.
Figure 1. Analytical framework for government investment in energy R&D.
Sustainability 09 00617 g001
Table 1. Variables and Definitions.
Table 1. Variables and Definitions.
Full Variable NameDefinitionSource
Government Energy R&D
GBAORD for energyGovernment budget appropriations or outlays for R&D (GBAORD) for energy in millions of 2005 dollars, constant prices and PPPMSTI
Energy share of GBAORDEnergy share of GBAORD as % of GBAORDMSTI
Energy RDD budgetTotal budget of energy research, development and demonstration (RDD) in millions of dollars, 2012 prices and exchanges ratesERDD
Energy RDD for renewablesEnergy RDD for renewable energy sources (incl. solar energy, wind energy, ocean energy, biofuels, geothermal energy, hydroelectricity, other renewable energy sources, and unallocated renewable energy sources) in millions of dollars, 2012 prices and exchange ratesERDD
Renewables share of Energy RDDRenewable energy sources share of total Energy RDD as % of Energy RDDERDD
Supply-Side Factors
Log of international patent stocksLog of cumulative triadic patent familiesMSTI
Log of total R&D personnelLog of total R&D personnel (FTE)MSTI
Gross domestic expenditure on R&D (GERD)Gross domestic expenditure on RD (GERD) in million 2005 dollars, constant prices and PPPMSTI
Public spending on educationPublic spending on education as % of GDPWDI
GERD financed by industryGERD financed by industry as % of GERDMSTI
GERD performed by higher educationGERD performed by the higher education sector as % of GERDMSTI
Demand-Side Factors
Energy imports rate Energy imports rate as % of total energy useWDI
Refinery gross outputRefinery gross output in megatonne (Mt)IEA Oil
Log of CO2 emissionsLog of carbon dioxide emissions excluding land-use, land-use change, and forestry (total emissions) in thousand tonnes of CO2 equivalent OECD Env.
Log of total electricity consumptionLog of total electricity consumption in terawatt hour (TWh)IEA WESB
Institutional Factors
Chief executive party orientationChief executive party orientation with respect to economic policy. Right (1); Left (3); Center (2); No information (0); No executive (NA)DPI
Control all houseDoes party of executive control all relevant houses? Yes (1); No (0)DPI
Vote share of opposition partiesVote share of opposition parties in the legislature as % of total vote DPI
MSTI (OECD Main Science and Technology Indicators); ERDD (OECD IEA Energy Technology RD&D Statistics); WDI (World Bank, World Development Indicators); IEA Oil (IEA Oil Information Statistics); OECD Env (OECD Environment Statistics); IEA WESB (IEA World Energy Statistics and Balances); DPI (World Bank, Database of Political Institutions).
Table 2. Cross-national variation in government budget for energy.
Table 2. Cross-national variation in government budget for energy.
Dependent VariableMeanRangeCountries
GBAORD for Energy (in million $)
1st Quartile1327.46307.81~3902.58Japan, UK, Germany, France, Italy, Korea, Mexico, Canada
2nd Quartile114.5037.78~265.12Turkey, Spain, Netherlands, Sweden, Australia, Finland, Belgium, Norway
3rd Quartile25.4915.08~37.61Denmark, Czech Republic, Hungary, Switzerland, Poland, Portugal, Greece, Austria
4th Quartile4.871.70~8.43Israel, New Zealand, Slovak Republic, Ireland, Estonia, Luxembourg, Slovenia, Iceland
Energy Share of GBAORD (as % of GBAORD)
1st Quartile8.824.99~18.12Japan, Mexico, Italy, Germany, Canada, Finland, Korea, France
2nd Quartile4.063.28~4.71Belgium, Sweden, Hungary, Spain, Iceland, Denmark, Greece, Netherlands
3rd Quartile2.62.00~3.28UK, Norway, Luxembourg, Australia, Estonia, Slovak Republic, Turkey, Portugal
4th Quartile1.180.34~1.92Switzerland, Czech Republic, New Zealand, Ireland, Slovenia, Austria, Israel, Poland
Energy RDD (in million $)
1st Quartile1826.13573.14~4669.17US, Japan, France, Germany, Italy, Canada, UK
2nd Quartile245.64151.56~443.44Korea, Australia, Netherlands, Switzerland, Belgium, Sweden, Spain
3rd Quartile73.5821.78~147.31Finland, Norway, Denmark, Hungary, Austria, Slovak Republic, Czech Republic
4th Quartile10.914.67~17.81New Zealand, Ireland, Portugal, Greece, Turkey, Poland
Energy RDD for Renewables (in million $)
1st Quartile16153.26~542.53US, Japan, Germany, Korea, Italy, Canada, Australia
2nd Quartile43.7429.54~52.24Netherlands, UK, France, Sweden, Switzerland, Spain, Denmark
3rd Quartile12.886.38~25.29Finland, Norway, Austria, Ireland, Belgium, Slovak Republic, New Zealand
4th Quartile2.570.31~4.67Greece, Portugal, Czech Republic, Hungary, Turkey, Poland, Luxembourg
Renewables Share of Energy RDD (as % of Energy RDD)
1st Quartile32.7528.47~37.39Slovak Republic, New Zealand, Denmark, Portugal, Ireland, Greece, Spain
2nd Quartile21.4918.41~25.44Sweden, Austria, Hungary, Switzerland, Netherlands, Czech Republic, Germany
3rd Quartile15.4710.78~18.38Turkey, Korea, Australia, UK, Finland, Poland, Norway
4th Quartile7.364.07~10.45Italy, US, Canada, Belgium, Japan, France
Reported means and ranges are obtained from national averages for the period of study (1974~2012).
Table 3. Descriptive statistics.
Table 3. Descriptive statistics.
VariableObsMeanSDMinMaxSD/Mean
Government Energy R&D
GBAORD for energy (in million $)775424.39942.830.0067042.22
Energy share of GBAORD (as % of GBAORD)8014.294.670.0034.461.09
Energy RDD (in million $)776687.5513650.0010,3291.99
Energy RDD for renewables (in million $)79667.12165.150.002322.632.46
Renewables share of Energy RDD (as % of Energy RDD)74318.9814.090.0081.650.74
Supply-Side Factors
Log of international patents stocks8707.032.93−0.6913.830.42
Log of total R&D personnel72410.861.436.6113.760.13
Gross domestic expenditure on R&D (GERD) (in million $)79123,05454,23433.4937,4192.35
Public spending on education (% of GDP)9155.091.320.008.980.26
GERD financed by industry (% of GERD)73049.5513.765.7490.680.28
GERD performed by higher education (% of GERD)77224.3010.640.2571.050.44
Demand-Side Factors
Energy imports rate (% of total energy use)129426.95108.49−842.4399.904.03
Refinery gross output (megaton)68060.51137.600.00840.62.27
Log of CO2 emissions72611.661.537.6415.630.13
Log of total electricity consumption12944.271.450.748.330.34
Institutional Factors
Chief executive party orientation (1 = right, 2 = center, 3 = left)11931.871.010.003.000.54
Control all house (1 = yes, 0 = no)12140.270.440.001.001.65
Vote share of opposition parties (% of legislature vote)122724.4612.910.0057.100.53
Table 4. Panel regressions of public energy R&D investment of OECD countries (1974–2012).
Table 4. Panel regressions of public energy R&D investment of OECD countries (1974–2012).
Dependent VariablesGBAORD for EnergyEnergy Share of GBAORDEnergy RDD
Independent VariablesI II III IV V VI
Supply-Side FactorsLog of international patents stocks65.102 10.444 0.241 −0.078 76.857**4.177
Log of total R&D personnel−30.113 −14.944 0.712 0.518 2.013 −5.585
Gross domestic expenditure on R&D (GERD)0.009 *0.018 ***−0.000**−0.000 0.010***0.017***
Public spending on education (% of GDP)41.891 42.229 −0.633 ***−0.469 **3.844 20.175
GERD financed by industry (% of GERD)1.137 −0.938 −0.138 ***−0.117 ***3.294 4.166
GERD performed by higher education (% of GERD)−3.930 −2.657 −0.110 **−0.086 **9.801***11.337***
Demand-Side FactorsEnergy imports rate (% of total energy use)1.067 −0.048 −0.002 −0.001 0.884 0.537
Refinery gross output (megaton)5.545 8.817 ***0.012 0.063 ***−0.259 4.631**
Log of CO2 emissions55.998 59.833 −2.796 −1.711 *−121.991 −136.077
Log of total electricity consumption−259.438 −187.723 1.691 1.148 −74.115 72.862
Institutional FactorsChief executive party orientation (right 1; center 2; left 3)−44.536 **−38.300 **−0.096 −0.101 −33.211***−35.091***
Control all house (yes 1; no 0)−14.378 −0.967 0.236 0.102 −72.689**−81.926***
Vote share of opposition parties (% of legislature vote)−0.641 0.216 −0.041 **−0.039 **−2.284 −2.285
Constant 277.367 −78.189 33.979 22.710 **1161.48 718.354
R2within 0.0743 0.0619 0.1127 0.0953 0.3370 0.3023
between0.4861 0.8018 0.2183 0.3870 0.1853 0.7821
overall0.5116 0.7838 0.1940 0.3401 0.2264 0.8268
corr( u i , Xb)0.3627 −0.7871 0.2111
N310 310 327 327 240 240
Note: * p < 0.1; ** p < 0.05; *** p < 0.01. Regressions I/III/V draw on the fixed-effects model, and regressions II/IV/VI on the random-effects model.
Table 5. First-order autoregressive panel regressions of public energy R&D investment of OECD countries (1974–2012).
Table 5. First-order autoregressive panel regressions of public energy R&D investment of OECD countries (1974–2012).
Dependent Variables GBAORD for EnergyEnergy Share of GBAORDEnergy RDD
Independent VariablesI II III IV V VI
Supply-Side FactorsLog of international patents stocks−197.956*20.089 −0.463 −0.122 −115.322***−33.823
Log of total R&D personnel179.040 48.617 −0.144 −1.246 155.312 −3.555
Gross domestic expenditure on R&D 0.015*0.023***−0.000 0.000 0.014***0.025***
Public spending on education (% of GDP)−8.494 −0.799 0.038 0.021 17.589 20.866
GERD financed by industry (% of GERD)−0.256 −1.617 −0.021 −0.020 1.812 1.835
GERD performed by higher education (% of GERD)3.878 −0.250 −0.048 −0.036 9.136 7.201*
Demand-Side FactorsEnergy imports rate (% of total energy use)0.253 −0.334 −0.004 −0.000 1.066 0.240
Refinery gross output (megatonne)1.152 4.712*0.007 0.049 ***3.758 4.690**
Log of CO2 emissions−26.759 7.111 0.523 −0.181 −159.959*−128.704
Log of total electricity consumption13.847 −155.178 1.861 1.153 141.826 49.656
Institutional FactorsChief executive party orientation (1 = right; 2 = center; 3 = left)−22.128 −21.307 −0.077 −0.104 −28.269*−18.679
Control all house (1 = yes; 0 = no)−19.703 25.601 −0.148 −0.226 −100.695**−67.379*
Vote share of opposition parties (% of legislature vote)−1.645 −0.077 −0.026 −0.028 −2.837 −1.133
Constant 97.098**−86.729 −2.788***15.332*186.210***1047.549
R2within0.0554 0.0405 0.0428 0.0077 0.3031 0.2476
between0.3714 0.8387 0.1208 0.5111 0.7863 0.8328
overall0.3519 0.8112 0.0989 0.4672 0.7753 0.8709
corr( u i , Xb)−0.0832 −0.2855 0.5264
N281 310 298 327 215 240
Note: * p < 0.1; ** p < 0.05; *** p < 0.01; These are the panel regressions with first-order autoregressive terms. Regressions I/III/V draw on the fixed-effects model, and regressions II/IV/VI on the random-effects model.
Table 6. Panel regressions of renewable energy research, development & deployment (RDD) investment of OECD countries (1974–2012).
Table 6. Panel regressions of renewable energy research, development & deployment (RDD) investment of OECD countries (1974–2012).
Dependent VariablesEnergy RDD for RenewablesRenewables Share of Energy RDD
Independent VariablesI II III IV
Supply-Side FactorsLog of international patents stocks13.239 *1.516 1.781 0.524
Log of total R&D personnel28.676 *27.907 **9.926 *16.033 ***
Gross domestic expenditure on R&D (GERD)0.004 ***0.003 ***0.000 0.000*
Public spending on education (% of GDP)1.587 6.097 *1.137 1.124
GERD financed by industry (% of GERD)0.327 0.312 −1.041 ***−0.569 ***
GERD performed by higher education (% of GERD)3.233 ***1.819 ***0.450 0.347 *
Demand-Side FactorsEnergy imports rate (% of total energy use)0.279 **0.008 0.021 0.025
Refinery gross output (megatonne)−1.455 ***−0.473 **−0.157 −0.234 ***
Log of CO2 emissions−13.536 −11.675 17.531 −7.028
Log of total electricity consumption−52.846 −9.109 16.367 −4.655
Institutional FactorsChief executive party orientation (right 1; center 2; left 3)−4.037 *−2.920 0.924 0.874
Control all house (yes 1; no 0)2.723 2.082 0.118 0.174
Vote share of opposition parties (% of legislature vote)−0.005 0.051 −0.068 0.029
Constant −67.418 −214.737 *−356.062 ***−36.180
R2within 0.5247 0.4724 0.3150 0.2157
between0.0018 0.8508 0.1505 0.4321
overall0.0227 0.7158 0.0627 0.3029
corr(ui, Xb)−0.7840 −0.9667
N248 248 240 240
Note: * p < 0.1; ** p < 0.05; *** p < 0.01. Regressions I/III draw on the fixed-effects model, and regressions II/IV on the random-effects model.
Table 7. First-order autoregressive panel regressions of renewable energy RDD investment of OECD countries (1974–2012).
Table 7. First-order autoregressive panel regressions of renewable energy RDD investment of OECD countries (1974–2012).
Dependent VariablesEnergy RDD for RenewablesRenewables Share of Energy RDD
Independent VariablesI II III IV
Supply-Side FactorsLog of international patents stocks12.960 1.267 −0.407 0.382
Log of total R&D personnel11.518 25.310 **10.424 16.547 ***
Gross domestic expenditure on R&D (GERD)0.003 ***0.002 ***0.000 0
Public spending on education (% of GDP)7.340 6.332 **0.730 1.401
GERD financed by industry (% of GERD)−0.352 0.408 −0.987 ***−0.319 **
GERD performed by higher education (% of GERD)2.176 **1.200 ***0.450 0.486 ***
Demand-Side FactorsEnergy imports rate (% of total energy use)0.189 −0.009 0.027 0.015
Refinery gross output (megatonne)−1.194 **−0.246 −0.357 *−0.150 *
Log of CO2 emissions−34.698 *−2.583 −10.461 **−5.267
Log of total electricity consumption24.249 −12.708 17.569 −11.784 **
Institutional FactorsChief executive party orientation (right 1; center 2; left 3)1.124 0.080 1.400 1.340
Control all house (yes 1; no 0)12.150 7.194 0.112 0.235
Vote share of opposition parties (% of legislature vote)0.472 0.244 0.075 0.122
Constant 23.532 **−274.437 **−9.355 −51.952
R2within 0.1936 0.4171 0.1800 0.1647
between0.0848 0.8987 0.0470 0.5964
overall0.1385 0.7238 0.0734 0.3833
corr(ui, Xb)−0.5217 −0.6257
N223 248 215 240
Note: * p < 0.1; ** p < 0.05; *** p < 0.01; These are the panel regressions with first-order autoregressive terms. Regressions I/III draw on the fixed-effects model, and regressions II/IV on the random-effects model.

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Sun, I.; Kim, S.Y. Energy R&D towards Sustainability: A Panel Analysis of Government Budget for Energy R&D in OECD Countries (1974–2012). Sustainability 2017, 9, 617. https://doi.org/10.3390/su9040617

AMA Style

Sun I, Kim SY. Energy R&D towards Sustainability: A Panel Analysis of Government Budget for Energy R&D in OECD Countries (1974–2012). Sustainability. 2017; 9(4):617. https://doi.org/10.3390/su9040617

Chicago/Turabian Style

Sun, Inkyoung, and So Young Kim. 2017. "Energy R&D towards Sustainability: A Panel Analysis of Government Budget for Energy R&D in OECD Countries (1974–2012)" Sustainability 9, no. 4: 617. https://doi.org/10.3390/su9040617

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