1. Introduction
As human economic activities continue to expand and globalization accelerates, the severity of global climate change and environmental issues is increasing. It is crucial to address the challenges of reducing energy consumption, improving carbon emission efficiency, and promoting sustainable urban development while pursuing economic growth [
1,
2]. Achieving a green and low-carbon development model is a pressing global concern [
3,
4]. In order to combat the pressing issues of climate change and environmental pollution, the United Nations has implemented the 2030 Agenda for Sustainable Development. Furthermore, during COP27 in 2022, the UN established a set of practical agreements aimed at reducing carbon emissions. Meanwhile, China has taken strategic action to reduce carbon emissions, pledging to peak carbon emissions by 2030 and achieve carbon neutrality by 2060 [
5,
6].
Smart cities are considered an important policy practice to reduce urban carbon emissions and achieve sustainable urban development [
7]. It refers to the intelligent management and transformation of a city’s infrastructure, public services, government governance, business operations, and residents’ lives through the usage of advanced information and communications technology (ICT), big data, the Internet of Things (IoT), and cloud computing [
8,
9,
10,
11]. The European Commission considers energy, transport, and ICT to be the core elements of smart city construction. For example, Francesco Russo et al. found that smart cities are the main path to pursuing sustainability goals in mobile planning tools [
12]. Additionally, Paola Panuccio found that smart planning is an important tool in the pursuit of urban sustainability in complex territorial systems, based on the Italian case study [
13]. The ultimate purpose of a smart city is to create more sustainable and efficient urban environments [
14].
Since the 1990s, numerous countries and regions, such as the European Union, the United States, and Singapore, have implemented smart city projects. In 2012, China launched its own nationwide smart city program, with over 100 cities approved as national smart city pilot cities in 2012, 2013, and 2014. These initiatives have yielded valuable policy experience for the study of smart cities.
In recent years, scholars have conducted many studies on sustainable development. The research covers several aspects, including ecosystem services, the circular economy, climate change, and the interaction between social development and natural ecology. For instance, Yan et al. examined the main EU nations’ energy efficiency using panel data collected between 2010 and 2018 and found that countries with higher ecological security outperformed others in terms of energy efficiency [
15]. Moreover, Lagodiienko et al. found that the external economic activity of enterprises has an important role in sustainable development based on Ukrainian data [
16].
Academics have also conducted extensive research on smart cities and carbon emission issues. Research on smart cities is conducted in three main aspects: theoretical research, practical research, and methodological research. Theoretical research focuses on the conceptual connotation, explanatory framework, and functional role of smart cities [
17,
18,
19]. Practical research includes the digital economy, green innovation, and communication technology [
20,
21,
22]. Methodological research encompasses policy evaluation, practical case studies, and development trend research [
23,
24,
25]. Research on carbon emissions has focused on identifying the factors that influence carbon emissions, developing effective measurement methods, and evaluating the performance of carbon emissions [
26,
27,
28,
29].
The current body of literature serves as a strong foundation for this paper, however, there is a noticeable gap in research regarding the effect of smart city policy (SCP) on carbon emissions, particularly in terms of how these policies can improve carbon emission efficiency (CEE). So, can SCP, a sustainable urban development policy that is widely used around the world, have an impact on CEE? What is the mechanism of its impact? What are the factors associated with this impact on cities? Therefore, this paper builds on previous research to propose our research topic, which is to evaluate the impact of smart city policies on carbon emission efficiency. The research goal is to explore how smart city policies affect carbon emission efficiency and give constructive policy recommendations for improving urban energy use efficiency and promoting sustainable urban development. The research tasks of this paper are three: first, to construct a quasi-natural experiment on the impact of smart city policies on carbon emission efficiency based on China’s smart city construction experience using the time-varying DID method; second, to measure urban carbon emission efficiency based on the DEA model; and third, to identify the action channels of smart city policies on carbon emission efficiency.
This paper offers a unique contribution to the existing studies by highlighting three distinct aspects that have not been previously explored. Firstly, from a research perspective, this paper presents a quasi-natural experiment on SCP using practical experience from China. It investigates the impact of SCP on CEE, providing empirical evidence to enrich the literature on SCP evaluation and improve CEE. Secondly, this paper employs two different measurement methods to assess CEE. The baseline model uses SBM-DEA, while the robustness test utilizes EBM-DEA. This approach helps to prevent any bias in the estimation results that may have arisen from relying solely on a single measurement method, as was done in prior studies. Lastly, from an analytical perspective, the mechanism of action is examined through three aspects: promoting industrial upgrading, increasing public environmental attention, and enhancing marketization. To analyze the heterogeneity of policy impact, four perspectives are selected: regional differences among cities, environmental regulation intensity, green finance level, and official change cycles. This approach offers a fresh analytical perspective for evaluating the impact of SCP on CEE and provides theoretical guidance for the scientific construction of SCP.
The remainder of the article is structured as follows:
Section 2 is the policy background and mechanism analysis.
Section 3 displays the research design.
Section 4 presents the benchmark analysis of SCP on CEE.
Section 5 is the robustness test.
Section 6 outlines the heterogeneous analysis of SCP. The following
Section 7 draws on the mechanism analysis. The final section gives the conclusions and policy implications.
2. Policy Background and Mechanism Analysis
2.1. Policy Background
Numerous countries have already embarked on practical explorations of smart city construction. One such example is the Intelligent Transportation System (ITS) project, launched by the city of Seattle in 1996, aimed at resolving the issue of urban traffic congestion. The ITS project uses intelligent transportation technology to dynamically monitor and analyze traffic flow, optimizing carbon emissions by reducing traffic congestion and improving traffic efficiency. Another instance is the Songdo International Business District (SIBD) project, implemented in Incheon, South Korea, in 2003, which investigated the potential of urban science and technology parks and sought to optimize their operational efficiency. One of the features of the SIBD project is the adoption of green building design principles. The project involves the extensive use of energy-efficient equipment and technologies in the main buildings. High-efficiency lighting systems, solar panels, and geothermal energy are used in buildings to reduce energy consumption and carbon emissions. Additionally, in 2009, the Amsterdam Smart City (ACS) project was launched by the city of Amsterdam in the Netherlands. This project developed an open data sharing platform that facilitates data sharing and applications to improve the efficiency of city management and the quality of life of residents. Similarly, the ‘Virtual Singapore’ (VS) project aims to build a large-scale 3D city model and a multidimensional data collaboration platform based on the concept of data-driven digitization. The goal of this project is to improve the efficiency of city operations. A common feature of the ACS and VS projects is the use of big data and smart technologies to collect and analyze a variety of urban data to support data-based decision-making. This helps identify areas with high energy consumption and carbon emissions and develop corresponding emission reduction measures.
The development of smart cities in China was officially initiated in 2012 with the announcement of the Notice on National Smart City Pilot Work (NNSCPW) and the National Smart City Pilot Index System (NSCPIS) by the Chinese Ministry of Housing and Urban-Rural Development. This policy practice marked the beginning of smart city construction in China. NNSCPW and NSCPIS mainly provide guidelines for the direction of urban carbon reduction in four aspects: urban infrastructure protection, green building, urban intelligent management, and sustainable industrial development. Furthermore, the construction direction and target for smart city construction have been indicated in two documents: Several Opinions on Promoting Information Consumption to Expand Domestic Demand (SOPICEDD) from 2013 and the National New Type Urbanization Plan (2014–2020) (NNTUP) from 2014. SOPICEDD and NNTUP point out that information infrastructure construction and information consumption are the focus of smart city construction. Information-driven smart city construction based on information can promote sustainable urban development and efficient allocation of energy use. Meanwhile, the following release of two documents, namely Guidance on Promoting the Healthy Development of Smart Cities and Guidance on the Construction and Application Implementation of the Smart City Standard System and Evaluation Index System, has established evaluation standards and operational guidelines for the development of smart cities. This provides a unified analytical framework for scientifically evaluating the efficiency of urban operations, measuring energy consumption, and identifying carbon emissions footprints. Notably, in 2017, the inclusion of smart city construction in the report of the 19th National Congress of the Communist Party of China marked the formal recognition of smart cities as a national strategy and top-level design. Following this, the Chinese government issued a series of guidance documents to promote the integration and development of smart cities with various industries. This indicates that the construction of smart cities is moving towards specialization and sophistication.
During the development process of SCP, it became evident that these policies have a direct impact on carbon emissions. As environmental issues continue to escalate, improving CEE has become a key focus of SCP. As a result, it is crucial to investigate the impact of SCP on CEE and explore the mechanisms behind this impact.
2.2. Mechanism Analysis
2.2.1. SCP Can Improve CEE by Promoting Industrial Upgrading
The effect of industrial upgrading can be observed in three main areas: the aggregation of industrial factors, the transformation of traditional industries, and the development of emerging industries. In terms of the aggregation of industrial factors, SCP aims to optimize industrial layout and enhance industrial agglomeration, resulting in efficient allocation and utilization of resources [
21]. By sharing infrastructure, technical resources, and talents, enterprises in industrial agglomeration areas can reduce production costs and improve economic efficiency [
30]. Industrial agglomeration not only facilitates the formation of the scale effect but also reduces energy consumption and carbon emissions during transportation by optimizing the supply chain and logistics [
31]. Furthermore, the synergic effect and technological innovation brought by industrial agglomeration can promote the development and application of green production technologies, enhancing the efficiency of energy utilization and carbon emissions in the production process. In terms of the transformation of traditional industries, the SCP aims to promote technological transformation in traditional industries by introducing advanced energy-saving and low-carbon technologies, thereby reducing energy consumption and carbon emissions [
32]. To achieve this, the policy offers R&D support, financial subsidies, and tax incentives to reduce the cost of renovation and stimulate the reform motivation of enterprises. The policy not only encourages enterprises to reduce carbon emissions but also aims to improve their efficiency by implementing clean production standards, carbon emission quotas, and market mechanisms. This can be achieved through the adoption of intelligent, networked, and environmentally friendly production methods, which can help traditional industries achieve their goals of high efficiency, low carbon emissions, and environmental protection [
33]. In terms of the development of emerging industries, the SCP aims to optimize and upgrade the economic structure by supporting the development of emerging industries such as new energy, clean technology, and green building [
34]. These low-carbon industries have high added value and environmental performance, which can effectively reduce carbon emission intensity [
35]. The smart city policies offer financial support, talent training, market development, and other measures to attract companies to invest in emerging industries. This leads to an increase in the proportion of emerging industries in the economy, resulting in a significant improvement in CEE. Additionally, the development of emerging industries drives the green transformation of related industrial chains, creating a low-carbon industrial ecology.
2.2.2. SCP Can Improve CEE by Raising Public Environmental Attention
The public environmental concern effect of smart city policies is mainly reflected in three aspects: raising environmental awareness, promoting green consumption, and influencing policy implementation. From the perspective of raising environmental awareness, SCP aims to increase public awareness of environmental protection through enhanced environmental education and public participation [
36]. A highly environmentally conscious public is more likely to adopt a low-carbon lifestyle, which includes green travel, energy savings, and waste reduction. Moreover, improving environmental awareness helps to create a positive social atmosphere and encourages enterprises to fulfill their social responsibility by paying attention to carbon emission issues, thus improving CEE [
37]. From the perspective of promoting green consumption, SCP aims to encourage environmentally conscious consumption by promoting green products and services as well as establishing green labeling and certification systems. This approach has proven effective in reducing carbon emissions as consumers opt for energy-efficient home appliances, clean energy, and public transportation [
38]. From the perspective of influencing policy implementation, SCP enables the government to obtain real-time information and policy recommendations on carbon emissions by creating a data analysis platform to analyze, evaluate, and monitor data related to public environmental concerns [
39]. This information helps the government adjust policy direction and measures in a timely manner, optimize resource allocation, and achieve CEE.
2.2.3. SCP Can Improve CEE by Increasing Marketization
The marketization effects of SCP are mainly reflected in three aspects: improving resource allocation efficiency, stimulating innovation-driven development, and promoting carbon emissions trading. Regarding improving resource allocation efficiency, the SCP aims to efficiently allocate and utilize resources through market-oriented operations, optimize industrial layouts, guide capital investment, and adjust energy structures [
40]. As part of this goal, the policy encourages the development of clean and renewable energy sources to reduce reliance on high-carbon energy. Additionally, the policy not only encourages the adoption of circular economy and green development strategies but also introduces market competition mechanisms to stimulate the growth of the renewable energy market. Thus, it helps reduce resource waste and improve CEE. Regarding stimulating innovation-driven development, the SCP aims to enhance talent competition and innovation development mechanisms through market-based approaches. It supports investments in research and development, talent training, and technological innovation to stimulate innovation. The policy promotes healthy competition, reduces costs and energy consumption, and fosters green technology innovation and research [
41]. Additionally, it encourages the research and application of clean, low-carbon, and energy-saving technologies to reduce carbon emissions. Regarding promoting carbon emissions trading, the SCP encourages businesses to engage in the trading of carbon emission rights by creating a carbon emission trading market and quota system [
42]. This approach facilitates a market-based allocation of carbon emissions, which incentivizes companies to reduce their carbon emissions and improve their CEE. Consequently, enterprises can use market-based trading to buy or sell carbon emission rights, which can help them achieve their carbon emission reduction targets. Additionally, the carbon emission trading market can aid in the rational allocation of resources and ultimately reduce the overall cost of carbon emission reduction.
8. Conclusions and Policy Implications
8.1. Conclusions
This paper evaluates the impact of China’s SCP on CEE and its role in promoting green development and sustainable cities. The study uses Chinese city-level data from 2007 to 2020 and a quasi-natural experiment approach, employing a multiple-time-varying DID method. The findings of the study are presented below:
First, SCP significantly improves CEE. From the model estimation results, the implementation of SCP resulted in a 1.61% improvement in CEE after excluding relevant confounding factors. This finding holds after parallel trend tests, placebo tests, and other robustness tests.
Second, there is heterogeneity in the impact of SCP on CEE. In terms of city regions, SCP significantly contributes to CEE in eastern cities while having no impact on western and central cities. In terms of the environmental regulatory intensity of cities, SCP promotes CEE in cities with low environmental regulatory intensity. Additionally, among cities with different levels of green finance, the pilot policy exerts a significant carbon reduction effect in cities with high levels of green finance. Moreover, the implementation of SCP led to a greater improvement in CEE in cities without official changes compared to those with official changes.
Third, SCP acts on CEE through three mechanisms: industrial upgrading, public environmental attention, and marketization. Specifically, the impact of SCP on CEE is positively correlated with industrial upgrading, public environmental attention, and the level of marketization.
To our best knowledge, this study is the first to examine how SCP affects the CEE. Furthermore, we identify the paths (industry upgrading, public environmental attention, and marketization) of action for the policy. The results of this study may provide policymakers with clear operational directions and policy suggestions on how to increase the efficiency of urban carbon emissions.
8.2. Policy Implications
Firstly, Policymakers should prioritize summarizing and promoting the positive effects of carbon reduction in SCP. SCP plays a crucial role in improving energy efficiency, promoting eco-friendly practices, and achieving sustainable and innovative development. Therefore, it is important to leverage the potential of smart city policies to address environmental challenges and promote green growth.
Moreover, to enhance CEE, policymakers must prioritize industrial upgrading, public environmental attention, and marketization in smart city policies. It is crucial to acknowledge the significant role played by these factors and actively create channels for smart city policies to contribute to this goal. Specifically, to drive economic green growth, we recommend promoting the consolidation of industrial elements, fostering new industries while revamping traditional ones, and prioritizing industrial upgrading. Additionally, we suggest increasing public awareness of environmental protection, encouraging green consumption, facilitating access to information, and promoting environmental concerns. To achieve efficient resource allocation, we propose stimulating innovation-driven development, implementing a carbon emission trading system, and enhancing marketization.
Lastly, to ensure effective implementation of SCP, policymakers must consider the varying effects of such policies on different cities. It is crucial to optimize the implementation details and operational guidelines of SCP based on the unique characteristics of each city. City managers should focus on classification management and policy relevance when promoting smart city construction. The first point is to allocate more resources to central and western cities, focusing on improving the CEE of these cities with poor economies and green technologies. The second point is to promote greater autonomy among enterprises and other market players by reducing government administrative intervention in environmental regulation. The third objective is to strengthen the development of urban green finance, increase the funding available for environmental innovation markets, and encourage green innovation. The fourth point is to minimize the turnover of officials in order to maintain policy stability and continuity, ultimately improving the efficiency of policy operations.
8.3. Future Research Perspectives
This paper is the first to investigate the impact of smart city policies on urban carbon emission efficiency. However, there are still some shortcomings. Future researchers can start their research in the following two directions: ① Expand the measurement of carbon emission efficiency indicators. In this paper, when measuring the input indicators of carbon emission efficiency, coal consumption was mainly selected among the fuel types. Other fuel sources, such as natural gas, are not included in the analysis. Scholars can consider more fuel sources in the measurement of input indicators in order to obtain more accurate measurement results. ② Extending the scope of the city sample. The sample of smart city policies in this paper is from Chinese cities, and whether the findings are equally applicable to cities in other developing and developed countries is subject to further validation.