1. Introduction
In recent years, new energy has gradually become a focal point of global industrial competition [
1,
2]. New energy can help mitigate the overexploitation of natural resources and environmental pollution problems caused by rapid economic development [
3,
4] and suits the needs of sustainable development and the world’s transition to low-carbon energy [
5,
6]. The Renewable Energy Law is a law enacted by the Chinese government to encourage economic entities of all forms of ownership to participate in the development and utilization of renewable energy and achieve sustainable economic and social development. The implementation of the law marks the development of renewable energy into a standardized stage. With the implementation and revision of the law, the Chinese government has paid more attention to the development of the new energy industry and has successively promulgated industrial subsidy policies and support policies, which has greatly improved the quantity and quality of China’s new energy enterprises. Since the Renewable Energy Law came into effect on the first of January 2006, China has seen continued advances in new energy technology and equipment, but the country still depends on imports when it comes to core technology as well as key parts and equipment. China is in urgent need of independent innovation to end its reliance on external technology. However, to innovate, new energy firms need to bear high costs and face huge risks over a long investment cycle [
7], with their innovation outcomes producing significant positive externalities in technological advances [
8,
9], environmental protection, and energy security, among other aspects. This challenge, coupled with the fact that both technology and the market are immature in the new energy industry, will discourage firms from innovating. In this context, support from the national government becomes essential.
Government subsidy is a form of direct subsidy, using grants, soft loans, and other ways to directly support enterprises’ R&D and innovation. In China, the regulators hope to improve firms’ research and development (R&D) and innovation by directly providing them with financial resources. A total of CNY 2.796 trillion was invested in research and experimental development (R&D) in 2021. Energy conservation and environmental protection accounted for CNY 2.4 trillion in the 13th Five-Year Plan. Government subsidies became a crucial support for enterprises to grow innovation-driven R&D. In the future, high-level R&D and innovation will turn China from the world’s factory into a global innovation powerhouse. As one of the important policy tools designed to boost the independent innovation capability of firms, government subsidies have long been adopted in China, with some remarkable results. Government subsidies can help address market failures brought about by unavoidable knowledge spillovers and non-complete exclusivity in the process of R&D and innovation [
10]. This is particularly true for today’s new energy industry requiring huge investments. While firms invest themselves, government subsidies provide an important additional source of financing which motivates them to continually work on R&D and innovation. However, it cannot be ignored that there is also much literature in existing studies that focuses on the negative effect of government intervention on enterprise innovation activities. For example, Blanes and Busom believe that government subsidies may distort the price of innovation inputs, and some companies may even conduct rent-seeking to obtain subsidy programs [
11]. Additionally, government subsidies may also phase out R&D inputs from firms themselves and hinder firms’ innovation to some extent [
12,
13].
Weaknesses of developing countries in independent innovation, including in the massive new energy industry, make the targeted implementation of government subsidy policies a high priority. Different from the development of traditional industries, R&D and innovation is the key for the new energy industry to keep vital. However, focusing on new energy companies, there is still a lack of systematic evidence of how much government subsidy can effectively spur their innovation and development. In a major study, Li et al. found that there exist complex nonlinear relationships between government innovation and non-innovation subsidy and new energy firms’ innovation inputs and outputs, and only at certain intervals can those subsidies play a role in boosting firms’ innovation [
14]. The study also argues that because of innovative inertia, firms can still maintain a certain innovation even if the role of government subsidy is not immediately visible. Wu et al. found an inverted U-shaped relationship exists between the scale of subsidy to new energy firms and their innovation investment, believing government intervention is the best choice [
14].
However, some researchers believe that problems such as information mismatch [
15] and R&D failures [
16] create obstacles to new energy firms’ innovation and development [
17,
18]. To solve those problems, external financial and technological support is crucial for their innovation and development [
7]. However, problems exist in implementing subsidy policies in reality, a topic that has drawn wide attention from scholars. Existing studies discuss the question from the perspective of different countries. Peters et al. discusses the impact of demand-pull and technology-push policies on innovation in the photovoltaic industry of Germany [
8]. Sung uses data on South Korean new energy firms to investigate the impact of government policies on firm-level innovation [
19]. In fact, whether government subsidies can effectively promote new energy firms’ innovation remains a controversial question.
In addition, enterprise R&D funding and manpower investment provide financial and intellectual support for the innovation activities of enterprises and are the decisive factors to improve the independent innovation ability of enterprises. When carrying out innovation activities, enterprises invest R&D funds to improve the supporting hardware and software facilities required for R&D activities and also invest in high-quality R&D personnel to realize enterprise knowledge accumulation and achievement creation. Earlier studies mostly paid attention to the role of R&D investment as part of government subsidies in boosting innovation [
20,
21,
22] without distinguishing between funding investment and manpower investment. This highlights the need to investigate the effect of government subsidy in innovation and how it influences innovation in developing countries.
This paper will further build on existing research to fill that gap by gauging the effect of government subsidies on innovation with new evidence recorded from China, the largest developing country. Therefore, we take China’s new energy-listed companies as an example to explore the answers to the following questions: Taking direct financial subsidies as an example, do government subsidies have an impact on the innovation performance of new energy enterprises? Is the impact positive or negative? What paths do government subsidies affect enterprise innovation performance? What are the differences in the innovation effect of government subsidies between different corporate ownership structures? In addition, we also discuss the subsidy size differences and regional differences, which may be related to affecting the innovation performance of new energy enterprises.
Our study begins with an eye-catching event: the Chinese government’s direct financial subsidy policy for new energy firms. More precisely, this paper sheds light on the causal relationship between government subsidy policies and new energy firms’ innovation performance using empirical models. The empirical analysis starts with consolidating the data about government subsidy and listed new energy firms’ innovation performance between 2007 and 2021. The focus of this study is on estimating the influence of government subsidy on the number of granted patents for listed new energy firms during the 15-year period. Based on the characteristics of patent data, we use the fixed-effect Poisson regression model to analyze the effect of subsidy on innovation. The empirical model assesses the average impact of government subsidy on each firm’s patent grants in different years. In the meantime, we introduce R&D investment as a variable to investigate the mediating effect of R&D funding investment and R&D manpower investment on how government subsidy influences a firms’ innovation. The analysis also includes other control variables that manifest the level of a firm. Furthermore, this paper also takes into account the heterogeneous effect of subsidy scale and firm ownership on how government subsidy influences innovation. In the end, a series of robustness tests are conducted to validate the robustness of the baseline regression result.
The main contributions are as follows: First, this paper offers the latest findings about how government subsidies influence firms’ innovation. Previous studies have contradictory conclusions, so this paper mainly focuses on the impact of direct financial subsidy on the number of patents of enterprises, and further subdivides the innovative effect on the subsidy policy of the government. Second, we examine the role of R&D investment in government subsidies and enterprise innovation. Government subsidies promote most corporate innovation through R&D funding investment, rather than R&D manpower investment. Third, focusing on new energy enterprises, we explore the innovation benefits of government subsidies, which provides a reference for the sustainability of the new energy industry. The remaining sections of this paper are organized as follows:
Section 2 presents the theoretical analysis and hypotheses.
Section 3 describes the data, defines key variables, and introduces our empirical models.
Section 4 discusses the results of our empirical analysis, including baseline regression, mechanism analysis, heterogeneity analysis, and robustness analyses.
Section 5 discusses our findings.
Section 6 presents the managerial applications of this paper.
Section 7 presents the main conclusions of this paper.
3. Data and Methodology
3.1. Database
To validate our hypotheses, we developed a unique panel dataset consisting of government subsidy and innovation performance of China’s listed new energy firms between 2007 and 2021. According to the industry classification of the China Securities Regulatory Commission, this paper defines the companies in the field of photovoltaic power generation or photovoltaic product manufacturing, wind power generation or wind power product manufacturing, biomass power generation, new energy product manufacturing and new energy vehicles as new energy enterprises. Our sample originally included all listed companies in the sample period. The sample data was taken from the China Stock Market and Accounting Research (CSMAR) Database, with patent data from estimates of business innovation in the domestic and foreign patent application form in the CSMAR Database. The patents included design, utility models, and invention patents. Next, we obtained the sample of all listed new energy firms by matching those data with the list of new energy firms published on the websites of East Money and Huaxi Securities.
Then, with a unique company code, we cross-linked and sorted information taken from different sources and screened the data according to the following standards: (1) removing firms the shares of which carry ST (special treatment, shares are placed under ‘risk alert’) and * ST tags; (2) removing firms for which important financial data, including operating income, gross assets, and gross liabilities, are missing; and (3) removing firms for which reporting periods are missing. In the end, we collected a study sample of 146 firms. We chose 2007 as the starting year because it was the year when new accounting standards were introduced for China’s listed companies, making some data before 2007 not comparable to data after 2007. Data about other company-level variables came from the CSMAR and Wind databases.
3.2. Measures
3.2.1. Dependent Variable
This study takes innovation performance as the dependent variable. Existing studies measure business innovation performance mainly through two approaches. One is patent numbers, including patent applications, patent grants and patent citations [
44]. The other is the sales revenue of new products. Given the difficulty in accessing new product data, this paper only uses patent numbers to measure firms’ innovation performance. According to the Chinese patent law, patents include invention patents, utility model patents, and design patents. Of the three types, invention patents are the most difficult to develop and approve, and also patents with the greatest innovation value, so they are most representative of innovation outputs. Some cities do not support utility model and design patents [
45], and patent subsidy across China is mainly targeted at invention patents. Meanwhile, the process from making an invention patent application to getting a grant takes three to four years in China [
45], not to mention that not all applications will be granted. Therefore, this paper takes the number of granted patents for firms as the proxy variable for innovation performance, including the total number of annual patent grants, as well as the number of inventions, utility models, and design patents for firms [
46,
47].
3.2.2. Independent Variable
We use direct financial subsidies as a measure of government subsidies. Direct financial subsidy refers to the use of national and local governments to provide financial donations, income, prices, and other support to certain specific targets, groups, or organizations. This paper uses the actual subsidy amount disclosed in annual reports. To display the relationship between data more clearly, this paper will analyze data after logarithmic processing of the subsidy amount.
3.2.3. Control Variable
Control variables include size, age, CI, SR, and Tobin’s Q, as shown in
Table 1. These company-specific characteristics may influence a firm’s innovative activities. Firstly, smaller and younger companies are more innovative [
48,
49], and the government R&D subsidy program has a significant impact on the number of patent applications, more markedly in the case of smaller firms [
50]; however, older companies have more time to accumulate knowledge and experience to support innovation, so we controlled the size and age of companies. We used the natural logarithm of companies’ gross assets to measure their size. Secondly, we define age as the number of years for which a company has been listed [
32]; define CI as the ratio of a company’s fixed assets to gross assets [
51]; measure SR, which will increase a firm’s explorative activities and therefore boost its innovation performance [
52], by the liquidity ratio, i.e., (current assets-inventories)/current liabilities [
51]; and define Tobin’s Q as the ratio of a company’s market capitalization to its gross assets. Lastly, we include time as a dummy variable to control characteristics associated with time-fixed effects.
3.2.4. Mediating Variable
Business R&D investment, which measures the ability of a firm in R&D investment, is regarded as the mediating variable. This paper uses R&D Investment (absolute amount of R&D investment + 1) to calculate the R&D funding investment of firms and the number of technical staff to calculate the R&D manpower investment of firms.
Table 1 presents an overview of measures about the listed new energy firms included in the sample, i.e., total number of granted patents (Gain_Total), number of granted invention patents (Gain_Invention), number of granted utility model patents (Gain_UM), number of granted design patents (Gain_Design), subsidy, R&D investment, size, CI, age, SR, and Tobin’s Q. In total, we include 1699 observation results in our analysis.
3.3. Estimation Methods
In this study, the dependent variable is measured by the number of patents granted to listed new energy firms each year. For this reason, the linear regression method (LRM) may result in biased estimates. As patent grants often vary greatly from company to company, a simple logarithmic transformation cannot solve this problem. First, since the variance (19.98) in our data is less different from the mean (4.570), we assume they are approximately equal. Therefore, we used a Poisson regression model for the estimation. Furthermore, the difference between variance and mean can be much larger in a Negative Binomial regression model. Hence, the Negative Binomial (NB) regression model is more appropriate. To provide a better fit to our data, we next used a Negative Binomial regression model to further test our hypothesis. Third, we tested the benchmark regression results with ordinary least square (OLS), generalized linear model (GLM), and zero-inflation Negative Binomial (ZINB) model to ensure its robustness.
We first use the Poisson regression model to determine the impact of government subsidy on innovation performance of new energy firms. Assuming innovation performance variable
(subscript
i represents the particular firm under observation,
t represents the year) also obeys the Poisson distribution with parameter
, the probability that the number of patent applications is
is:
where,
> 0 represents the mean times the event happens, determined by a series of dependent variables
. To ensure that
is not negative, we can transform the conditional expectation function
into the exponential function
. With a given sample
, we obtain the maximum likelihood estimation of
β through the maximum log likelihood function. The log likelihood function is expressed as:
We think that as a firm’s size, age, CI, SR, and Tobin’s Q change, its innovation capability will change accordingly. Therefore, this paper controls these variables in the model, establishing the following baseline regression model:
where,
represents innovation performance of firm
i in year
t, including Gain_Total, Gain_Invention, Gain_UM, and Gain_Design;
represents the government subsidy firm
i gets in year t;
includes all control variables in the model; and
represents the random disturbance term. The Poisson regression model uses the maximum likelihood estimation method to calculate the maximum likelihood estimate of
and
. In this study, our focus is on parameter
. If
is significantly larger than 0, it shows that government subsidy can significantly boost firms’ innovation.
5. Discussion
Firstly, according to the results in
Table 3, government subsidy has a direct role in boosting new energy firms’ innovation performance, and this result is consistent with H1 (a). However, that role is mediated by R&D funding investment, not by R&D manpower investment. Today China has elevated the development of the new energy industry to the status of national strategy. Due to the high costs of development and use, as well as external impacts associated with R&D, the industry’s development relies on government policy support. Our study reveals the general positive influence of government subsidy; that is, government fiscal support can give a boost to the development of new energy firms. To that end, the government should set up funds dedicated to providing financial support for new energy firms that boast greater innovation potential and benefit from a more favorable environment. Furthermore, local governments should offer more assistance to local new energy industries in achieving technological innovation through local special funds, special bonds, and the like.
Another finding of this study is that the role of government subsidies in boosting innovation performance varies considerably among different regions and is especially prominent in the eastern region. To address the gap, China should take necessary measures designed to make government guidance fairer and make sure subsidies and support are offered to firms in different regions and on different scales. The government should provide more subsidies for firms in regions taking a lead in innovation and increase the rate of return on government funding support. In addition, for the central and western regions, the government should not only employ policies to facilitate cross-region exchanges and communication over innovation activities but also increase subsidies to local governments there, through science-based macroregulation, in a bid to solve the problem of funding shortages and promote innovation in the new energy industry across China.
7. Conclusions
7.1. Findings
R&D and innovation are important drivers of economic transformation and upgrading. As an essential fiscal policy, government subsidies are meant to encourage firms to work on R&D and innovation amid efforts to transition from “Made in China” to “Created in China”. Based on both theoretical research and empirical analysis, this study offers a feasible economic explanation for the innovation of China’s new energy firms. This study investigates the causal relationship between government subsidies and innovation performance using a sample that includes data from listed Chinese new energy firms between 2007 and 2021. Furthermore, this study examines the mediating role of R&D funding investment in the relationship and analyzes the heterogeneity of innovation benefits from government subsidies. At the same time, a series of robustness tests are conducted to prove the robustness of the baseline regression results. The empirical results lead to the following conclusions:
First, the mixed Poisson regression model is established to make an in-depth analysis of the causal relationship between government subsidy and the innovation performance of new energy firms. Empirical testing points to the significant role of government subsidy increases in boosting innovation performance. The marginal effect of the Poisson regression is then compared with the OLS regression results to validate the model selection correctness. The benchmark regression is further tested using a Negative Binomial regression.
Secondly, this study analyzes how government subsidy increases new energy firms’ innovation performance from the perspective of R&D investment, or to be more specific, its mediating role in the relationship between government subsidy and innovation performance. It is found that R&D funding investment mediates the relationship between government subsidy and innovation performance, i.e., government subsidy spurs new energy firms’ innovation by increasing their R&D funding investment, while the mediating effect of R&D manpower investment is not significant.
Finally, a heterogeneity analysis of firms points to significant differences in the effect of government subsidies on innovation performance depending on the nature of property rights, subsidy scale, and region. State-owned firms are more reliant on government subsidies. The effect on innovation is generally higher in the high-subsidy group than in the low-subsidy group, although the effect on innovation is higher in the low-subsidy group when it comes to low-tech design patents. It is also found that only innovation in new energy firms in the eastern region is sensitive to government subsidies.
7.2. Sustainable Development
Based on the above findings, we draw some policy implications for sustainable development. First of all, from the perspective of sustainable new energy enterprises development, government subsidies should continue to be maintained or increased. From the research perspective, government subsidy is positively related to enterprise innovation performance. High government subsidies are conducive to the output of innovation performance of new energy enterprises. In the market economy, government subsidies are a direct incentive way to ensure the survival of new energy enterprises and promote their development, which is conducive to enterprises reducing resource pressure, better-optimizing resource allocation, and improving their innovation ability.
Furthermore, we standardize the innovation and promotion path of new energy enterprises after receiving government subsidies. Through R&D funding investment, government subsidies improve innovation performance. In order to relieve financial pressure, some new energy enterprises transfer them to non-R&D investment after receiving the government subsidy which leads to the inability to improve innovation performance, thus making the government subsidies fail. Therefore, after the introduction of national follow-up policies and regulations, it is necessary to refine the use path of new energy enterprises after receiving government subsidies.
Moreover, the allocation of resources to different new energy enterprises should be based on the characteristics of their property rights. The conclusion of the research shows that new energy enterprises with different proprietary rights have significant differences in the impact of government subsidies on innovation performance. Therefore, the government can focus on non-state-owned enterprises to promote their higher innovation performance when subsidizing incentives.
Finally, given that government subsidies vary by geographical location, governments should gradually provide targeted financial support and adjust subsidy measures.
7.3. Limitations and Further Research Suggestions
First, due to the availability of data, this paper only considers direct fiscal subsidies as government subsidies. Other types of government subsidies, such as tax incentives and fiscal interest discounts, are not discussed. Future research could more fully discuss government subsidies’ innovative effects. Secondly, when exploring influence paths, the intermediary roles of R&D capital investment and manpower investment are discussed. Future research may explore other impact pathways in more detailed ways, such as the study of mediating and regulatory effects, or within the framework of a more general structural equation model. Finally, the classification of subsidy size is not necessarily optimal. Future research may utilize a threshold effects model to more precisely determine the extent of government subsidies.