3.2. Analysis of Regression Results of STIRPAT Model
The regression results of the STIRPAT model showed that the model had a decidable coefficient R² of 0.999 and the Durbin–Watson value of 2.263. The Durbin–Watson value refers to a test statistic proposed by Durbin and Watson for the autocorrelation of diagnostic model residuals. The value of this statistic is between 0 and 4, and the closer it is to 2, the more the model tends not to have autocorrelation. All variables passed the 5% significance test. This shows that the model is statistically significant and has a good fit. The VIF values of each variable were below 10, indicating that no multicollinearity existed among them (
Table 7).
(1) Population urbanization was found to exert a significant positive effect on urban carbon emissions. For every 1% increase in population urbanization, urban carbon emissions were shown to increase by 1.185%; population urbanization is thus an important factor in increases in carbon emissions. As one of the regions with the highest level of development in the country, the PRD urban agglomeration has absorbed a large number of foreign populations. According to data published by the National Health and Wellness Commission, the PRD urban agglomeration had a resident population of 59.985 million in 2016, with 33.5053 million local household residents and 26.4797 million migrants, which is one of the largest influxes of migrants in the country. At the same time, the large number of migrants keeps the population density high and drives urban development, the latter of which in turns stimulates the consumption of logistics goods like fuel and cement, which in turn has led to increases in carbon emissions. Compared with other cities, megacities within urban agglomerations have higher urbanization levels, higher population densities, and more diverse consumption patterns. Urban residents can afford higher consumption levels, and many families have purchased private cars due to their improved living standards, all of which increase CO2 emissions from transportation trips. In addition, the limited size of the built-up areas of megacities and the rapid population growth rates are not matched by corresponding levels of urban facilities and environmental population affordability (such as urban park green space, sewage treatment plant, sanitation facilities, etc.). These reasons further contribute to the deterioration of the carbon emission situation in cities. As a result, cities should consider measures to relieve urban population pressure (such as optimize the layout of urban population, guide the population to the peripheral areas of the PRD urban agglomeration orderly transfer, fully liberalize the restrictions on settlement in established towns and small cities, liberalize the restrictions on settlement in medium-sized cities in an organized manner, reasonably determine the conditions for settlement in large cities, and strictly control the size of the population of megacities), develop and improve urban facilities, and build new urban areas.
(2) Economic urbanization is the most important factor that affects urban carbon emissions, and a negative correlation exists between the two. Our results show that for every 1% increase in the economic urbanization index, there is a corresponding 1.207% reduction in urban carbon emissions. This is the largest regression variable among the five independent variables. Moreover, the economic urbanization index passed the 1% significance test, indicating that this variable is the important factor affecting urban carbon emissions. With the national goals of “carbon peaking in 2030” and “carbon neutral in 2060,” the PRD urban agglomeration is facing double pressures in the form of economic development and energy consumption control. Therefore, cities in the PRD urban agglomeration have increased their investment in research and development and strengthened their policy support for new energy technology enterprises, such as photovoltaic and hydrogen-based energy. Moreover, the PRD urban agglomeration has economic advantages, market potential, and talent structure, and these advantages have attracted many large enterprises and foreign businesspeople to collaborate and start businesses. These collaborations have helped introduce advanced pollution prevention technologies and management methods, and they have also promoted the transformation and upgrading of enterprises. At the same time, these energy technology advances have also driven carbon emission reduction in cities within the agglomeration and improved the energy utilization efficiency and clean energy capabilities of the cities.
For example, most cities have switched from previously fuel-driven to electric buses. In December 2020, the electrification rate of urban buses in Guangdong Province reached 93.5%. Among the cities, the bus electrification rates of Guangzhou, Shenzhen, and Zhuhai have reached 100%, effectively optimizing these cities’ energy consumption structures. While cities are investing in research and development in energy technology, they are also targeting higher pollution emission standards in some heavy industries. The impact of traditional high-polluting industries on carbon emissions is being limited, which indirectly promotes the reduction of carbon dioxide emissions in cities and the implementation and effectiveness of national emission reduction initiatives. Finally, the operation of the carbon trading market should be promoted, the carbon emission statistics and accounting system should be improved, and more binding regulations should be introduced for key emitters in different industries to better play the role of energy conservation and emission reduction. Although total carbon emissions have slowed in the past two years, there is still a long way to go to achieve the goal of “carbon neutrality” by 2060. The PRD urban agglomeration should continue to encourage and support the research and development of clean energy and energy storage technologies, optimize the overall industrial structure of the urban agglomeration (such as promote the transformation and development of the PRD region with a single industrial structure, use national policies to promote counterpart cooperation with the central cities in urban agglomeration, and accelerate the joint construction of industrial parks, factor flow, and resource sharing), guide the gradual replacement of traditional energy with clean energy, and promote low-carbon urban development.
(3) Social urbanization has a negative effect on urban carbon emissions. Specifically, for every 1% increase in the social urbanization index, urban carbon emissions are reduced by 0.275%. Since the number of college students in cities has increased in recent years, the overall quality of the urban population has also improved. In addition, with the publicity and encouragement of environmental behaviors by urban media, residents are gradually establishing basic environmental concepts such as green travel and water conservation. People are gradually aware of the importance of establishing a more harmonious coexistence between human beings and nature.
Cities in the PRD urban agglomeration have also proposed policies to promote energy conservation and emission reduction in recent years. In December 2013, the PRD urban agglomeration officially launched a carbon emissions trading scheme. Heavy chemical industries with high energy consumption—such as steel, petrochemicals, electricity, and cement—were included in the scope of the carbon trading market. At the same time, enterprises with serious pollution emissions were required to carry out rectification measures. Market mechanisms are thus being employed to effectively control greenhouse gas emissions. In addition, Guangdong Province decided to implement the “Emission Limits and Measurement Methods for Light Duty Vehicles (China Stage 6)” in 2018, which strictly limits the pol-luting exhaust emissions from vehicle production. Some cities even have introduced policies to restrict the travel of motorcycles and other means of transport with serious exhaust emissions, as well as to strengthen the control of energy consumption standards for the production that enterprises produce. All these measures have effectively slowed down the contribution of total social energy consumption and per capita electricity consumption to carbon emissions. In this way, urban carbon emissions are effectively curbed.
(4) Spatial urbanization is positively correlated with carbon emissions. For every 1% increase in the spatial urbanization index, the corresponding increase in urban carbon emissions is 0.265%. During the pre-city construction period, the population was heavily concentrated as well as the industries were rapidly upgraded and expanded. To meet the needs of accelerated urbanization, commercial development was built substantially within the city and the scale of urban roads was expanded. High levels of energy consumption are known to cause environmental stress, destroy urban greenery, and worsen the carbon emission situation of cities. Compared to other indicators, however, spatial urbanization was found to exert the least impact on carbon emissions, which can be attributed to the following reasons: First, the improvement of the environment by park green space. While the extent of urban development is expanding in cities within the PRD, the scale of green spaces is also being expanded and the construction of green spaces accelerated, in line with the greening of urban parks; these initiatives have a positive effect on the mitigation of carbon emissions in cities. Second, the expansion of urban built-up areas and traffic roads in urban agglomerations has slowed, which has allowed the environmental impacts of spatial urbanization to also slow in recent years as the urbanization rate has increased. Third, the regional implementation of building energy efficiency standards and energy limit standards for building material products have been raised. With the improvement of technology and techniques, green building materials are gradually put into use. The state has improved building energy efficiency standards and encouraged the construction of low-energy buildings. The energy consumption generated in urban construction has been reduced and the energy-saving capacity of buildings has been improved—for these reasons, the rate of increase of carbon emissions generated by the expansion of urban development has slowed.
(5) Our results indicate that a positive correlation exists between the intensity of urban integrated linkage flows and carbon emissions. In fact, every 1% increase in this index is shown to increase the city’s carbon emissions by 1.140%. Although the economic growth rate of cities in the PRD has slowed in recent years, the economic cooperation and development links between cities continue to gain in strength. The formation of Guangzhou-Foshan-Zhuhai, Shenzhen-Dongguan-Huizhou, and Zhuhai-Zhongshan-Jiangmen metropolitan areas is gradually establishing a new urban cluster development pattern with a clear division of labor and complementary functions. The construction of several intercity transportation arteries, such as the Guangzhou-Zhuhai Intercity Railway and the Guangzhou-Foshan Ring Road, has shortened transportation travel time and reduced the cost of factor movement. This has had a long-term impact on optimizing urban functions and smoothing economic links between these cities, but the tailpipe emissions generated by transportation have exacerbated urban carbon emissions. It is worth noting that urban integrated linkage flows within the PRD urban agglomeration are mostly in the direction of Guangzhou, Shenzhen, Dongguan, and other developed cities in the region, rather than the relatively backward economic industries cities in the outer layer of the urban agglomeration. In the long run, this will be detrimental to the future development of the urban agglomeration as a whole. As the core of the PRD urban agglomeration, Guangzhou and Shenzhen should actively use their industrial and location advantages to play a guiding role. These cities should accelerate the economic and logistics links with the cities at the edge of the urban agglomeration, drive the backward economic industries cities to accelerate their development, alleviate the situation of excessive concentration of resource elements in the core cities, and promote the coordinated development of carbon emission reduction and economy.
(6) Urban energy consumption intensity was found to positively correlated with carbon emissions and emerges as one of the main factors affecting carbon emissions in urban agglomerations. For every 1% increase in urban energy consumption intensity, urban carbon emissions are shown to increase by 0.415%. For a long time, China’s energy consumption structure was coal-fired, making the energy structure inefficient. According to data published by the National Bureau of Statistics in 2020, the power generation structure of Guangdong Province is still dominated and thermal power generation, and thermal power generation accounts for 71.38% of the energy grid. To break the traditional coal-fired energy structure, ease the “double control pressure on energy consumption,” and achieve the “double carbon goal,” Guangdong Province should improve the energy efficiency of traditional heavy industries and accelerate the optimization and upgrading of industrial structures, such as metal smelting, construction logistics, cement, and other heavy chemical industries. However, these industries cannot be replaced in the short term, because of the huge demand that still exists in the current market. Therefore, on the one hand, we should target high energy-consuming and high-emission projects, strengthen the supervision work of relevant departments, while controlling high-energy-consuming and high-emission enterprises, replacing and shutting down excess capacity, and improve the pollution emission standards of high-energy-consuming and high-emission enterprises. On the other hand, we suggest that more attention be paid to research and development investment in the direction of strategic future industries such as green materials, advanced high-end equipment manufacturing, and new energy by driving technological innovation, improving energy utilization efficiency, and reducing the energy consumption of products to promote the transformation of high-energy-consumption industries to low-carbon development. At the same time, the PRD urban agglomeration should optimize the energy consumption structure within the urban agglomeration. A gap still exists between the environmental quality of the PRD region and other international urban agglomeration. To achieve a green development model and build ecological power systems as soon as possible, it is necessary to adhere to the green and low-carbon development of energy in the future, even in the face of rapid economic growth, by establishing an energy consumption system centered on new energy to promote research and development into clean energy technologies such as hydropower, nuclear power, and wind power. Furthermore, status quo energy consumption—dominated by coal-fired thermal power generation—will need to be controlled if cities are to reduce their carbon emissions.