There are four main methods for TFP measurement: growth accounting, the production function method, the productivity index method based on data envelopment analysis, and the stochastic frontier method. The applicability of these four methods depends on the research context, data quality, and the objectives of the researcher. The Malmquist productivity index method based on DEA can handle multiple inputs and multiple outputs simultaneously and can further decompose the productivity index (Färe, Grosskopf, Lindgren, & Roos, 1992), thus giving richer results. The basic idea of the method is to construct a non-parametric production frontier, comparing the actual production of the evaluated production unit with its projection (improvement target) on the production frontier based on the Distance Function (DF), and thus calculating the productivity index and its decomposition term. Färe et al. (1992) originally calculated the Malmquist productivity index, only considering expected outputs and inputs. Chung, Färe, and Grosskopf (1997) used the directional distance function (DDF) to introduce bad outputs into the calculation of the Malmquist productivity index, and obtained the Malmquist Luenberger (ML) productivity index. Many scholars have since used this angular and radial directional distance function to calculate GTFP. However, the angle assumes that the inputs (outputs) are given, and the inefficiency is measured in terms of the degree to which each output (input) can be improved. However, the unit of production may have both over- and under-inputs, which can lead to biased results. The radial approach requires equal scaling down (up) of inputs (outputs) and ignores the possibility of individual scaling down (up) of inputs (outputs), which means that considering only equal scaling of improvement without considering slack improvement is not in line with production reality and is likely to overestimate the efficiency of the evaluated production unit. Pastor, Ruiz, and Sirvent (1999) and Tone (2001) proposed efficiency calculation methods, which consider slack improvement, namely Enhanced Russell Measure (ERM) and Slack Based Measure (SBM) respectively. These models are essentially the same, but the SBM nomenclature is more widely used. On this foundation, Cooper, Seiford, and Tone (2007), Färe and Grosskopf (2010), and others have taken combinatorial approaches and the resulting SBM-DDF-ML productivity index has been widely used in studies of total factor productivity measurements that consider resource and environmental constraints3.

In the Variable Returns to Scale (VRS) settings4, the ML index based on the non-radial, non-angular SBM-DDF is chosen to measure the GTFP change of Chinese cities. Furthermore, borrowing the decomposition method from Zofio (2007), the ML index is further decomposed into Pure Efficiency Change (PEC), Pure Technical Change (PTC), Scale Efficiency of Efficiency Change (SEEC), and Scale Efficiency of Technical Change (SETC). The following relationships exist between the ML index and the decomposition terms.

• (1)

  Desirable Output

Gross regional product is a common indicator of desirable output. Most studies use actual values, but a few studies suggest that the effect of prices will be offset if nominal values are used for both inputs and outputs, so nominal GDP is used directly (Gao, 2007; Wang, Xu, Zeng, & Guo, 2015). To offset the possible impact of prices, this paper still chooses to use real values. Due to the lack of city-level GDP deflators, most of these studies use provincial GDP indices (previous year = 100) to discount nominal GDP for each city. However, this treatment ignores the differences in price levels between cities, such that the price level in provincial capitals is usually higher than that in prefecture-level cities. We use the 2005 nominal GDP of each city and the constant price growth rate of GDP over the years to obtain real GDP (billion yuan, 2005 as the base period)6.

• (2)

  Undesirable Outputs

Based on the availability of pollution product data at the city level in China, this paper selects industrial wastewater emissions (10,000 tons), industrial sulfur dioxide emissions (tons), and industrial smoke (dust) emissions (tons) as proxies for undesired outputs. China's Urban Statistical Yearbook only gives city-wide data on pollution products, and considering that most of the industrial activities are concentrated in municipal districts which are exactly our study objects7, rather than municipal counties or municipal cities, we believe that this error is relatively small.

• (3)

  Input: Labor

The labor force is measured in terms of all employed people in urban areas, which is obtained by summing two indicators: urban unit employees and urban private and self-employed persons8. Some scholars only consider the former, which is potentially problematic. Private and self-employed workers are important components of China's urban labor force. Calculations show that the number of private and self-employed workers in urban areas as a share of total urban employment gradually increased between 2003 and 2018, and by 2018 this proportion had exceeded 50%. Private and self-employed persons have played an important role in absorbing employment and have become an important source of urban economic growth, for example, the street vendor economy that was created to boost the economy during the 2020 COVID-19 crisis.

• (4)

  Input: Capital

In the neoclassical economic growth model, capital investment refers to the capital stock that is productive. In view of the difficulties in accounting for the capital stock of cities, a few scholars have directly used the amount of fixed asset investment in each city as a proxy for capital investment (Tao, Tan, & Chen, 2013; Yu, Zhou, & Wang, 2006). Most scholars use the perpetual inventory method to estimate the capital stock of city i in period t (Kit=Iit+Ki,t−1(1−δ)). The capital stock depends on the base period capital stock K0, depreciation rate δ, and investment series I. Different parameter settings result in different capital stock series.

① Determination of the base period capital stock

Drawing on Reinsdorf and Cover (2005), the base period capital stock (K0) is estimated by means of a mathematical relational derivation.

Taking g as the average growth rate of I, then g

The amount of investment for the previous year that still remained in the base period capital stock was I−1(1−δ)=I0(1−δ)/(1+g).

Likewise, I−2=I0/(1+g)2,

The investments for year (–2) that still remained in the base period capital stock were

Pooled Investments for all periods prior to the base period may result in

Here we take g as the average of the five-year investment growth rate from 2003 to 2007.

② The depreciation rate is based on existing studies on China, such as Zhang, Wu, and Zhang (2004) and Shan (2008), who set the depreciation rate at 9.6% and 10.96%, respectively, in their estimations of China's interprovincial capital stock. Ke (2009) and Ke and Zhao (2014) set the depreciation rate at 5% when calculating the capital stock of Chinese counties and cities. This figure has been applied in this study.

③ The increase in capital stock will only result from an increase in investment that creates real productive capacity. The existing literature, when estimating the national and interprovincial capital stock, uses three series of investment I: total societal fixed asset investment (Jin & Wang, 2016; Li, Xu, & Chen, 2005; Wang & Xiao, 2011), total fixed capital formation (Jin & Zhang, 2013; Shan, 2008; Zhang et al., 2004), and new fixed assets (Ke & Xiang, 2012). By definition, the latter two investment series are better proxies of net investment. Indicators of gross fixed capital formation are lacking in China's city-level statistics. Moreover, only half of the provinces (cities) publish data on new fixed assets, but all provinces (cities) publish indicators for total social investment in fixed assets at the city level. Therefore, in estimating the capital stock at the city level in China, the existing literature has tended to adopt the total social fixed asset investment index. A few scholars, such as Wang et al. (2016) and Wu (2019), weight the fixed capital formation of the whole province (city) by the amount of fixed asset investment in each city to obtain the city-level fixed capital formation. However, this treatment assumes that the capital formation rate is the same for all cities in the same province. In this paper, we use the total societal fixed capital investment series and convert it into actual values (million yuan, 2005 base period).

Other scholars have tried to include the land factor, and this paper finds that the TFP index remains basically unchanged after including the built-up area. Considering that land finance is an important source of revenue for local governments in China, it is speculated that the direct or indirect revenue generated by the urban land factor is eventually used as capital inputs in urban production and construction, that is, land inputs may already be reflected in capital inputs. Therefore, this paper does not include land indicators in GTFP calculations.

Based on data availability, the study period is set as 2003–2018. The above data are mainly acquired from the China City Statistical Yearbook (2004–2019). Currently published data for Chinese cities are available for both city and municipality districts. All the above indicators, except for the non-expected output, are within the statistical range of the municipality.

Since 2017, the China City Statistical Yearbook no longer publishes fixed asset investment data for all cities. Therefore, the 2017 and 2018 fixed asset investment data for all cities are taken from the statistical yearbooks of all provinces (cities) separately. During data collection, it was found that five provinces did not publish municipal district data for cities under their jurisdiction in 2017, and ten provinces did not publish municipal district data for cities under their jurisdiction in 2018. However, citywide fixed asset investment data are available for all cities. For this, we assume that the growth rate of investment in the municipal districts of these cities is equal to the growth rate of investment in the city as a whole, thus filling in the missing data on fixed asset investment in these municipal jurisdictions. Since municipal districts are usually the main areas of economic activity in cities, this estimate does not introduce much bias.

The sample is selected from the 298 cities at the prefecture level and above in 2018 given in the China City Statistical Yearbook (2019), that is, 279 prefecture level cities, 15 sub-provincial cities, and 4 municipalities directly under the central government, excluding cities with a large number of missing data or unknown data trends and thus difficult to interpolate, resulting in a final sample of 264 cities at the prefecture level and above. Additionally, compared to 2003–2016, some cities in 2017 and 2018 have a large number of missing data on undesirable outputs which are difficult to interpolate, so this paper recorded these cities as having complete data missing in 2017 or 2018. Therefore, the final research samples from 298 cities at the prefecture level and above are 264 cities during 2003–2016, 238 cities in 2017, and 195 cities in 20189.

Table 1, Fig.1 and Fig.2 present the green TFP and its decomposition terms for Chinese cities between 2004 and 2018. It can be found that, first, the overall GTFP in Chinese cities shows a growth trend. The average annual growth rate from 2004 to 2016 was 0.9%. The GTFP growth rate in 2017 and 2018 is higher than this average value, so the average annual growth rate from 2004 to 2018 is higher, specifically 1.3%. The corresponding cumulative growth rate is 20.6% (2003 = 1)10. The poor performance of TFP growth compared to the average constant price growth rate (over 10%) of China's urban area gross domestic product (GDP) over the same period reflects the fact that China's urban economic growth is still a crude form of economic growth dependent on factor inputs.

Fig. 1.

Temporal trends in the GTFP two-part decompositions between 2004 and 2018.

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Fig. 2.

Temporal trends in the GTFP four-part decompositions between 2004 and 2018

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Second, the main source of GTFP growth is technological progress (TC), that is, GTFP growth is primarily due to urban best practitioners continuing to pull the production frontier outward, rather than urban laggards shifting to best practices. This growth pattern leads to a widening gap in productivity growth among cities, as confirmed by the following estimates of the nuclear density of GTFP and its components.

Third, considering the scale effect, the improvement in technical progress depends mainly on the growth of technical scale, with the average annual growth rate of pure technical progress less than 1; the improvement in technical efficiency relies mainly on the improvement of pure technical efficiency, with the average annual growth rate of scale efficiency less than 1. From Fig.2b, the relationship between technical scale and scale efficiency growth exhibits a trade-off, while the evolution of the total scale effect indicator is smoother and sharper, which allows us to capture more clearly the contribution of scale effects to urban productivity growth, with total scale effects growing at an average annual rate of 0.8% between 2004 and 2018, and contributing 65.7% to GTFP growth. The scale effect implies that in the process of factor accumulation and production scale expansion, the "learning-by-doing" effect, which is dependent on investment and human learning experience, endogenously triggers productivity growth. The total scale effect makes the largest contribution to GTFP growth, which implies a strong "learning by doing" effect in urban production in China. However, it is noteworthy that the growth of the aggregate scale effect is stable and shows a slight climb between 2004 and 2014, and the aggregate scale effect growth decreases significantly since 2015 (see Fig.1), because the "learning by doing" effect decreases rapidly with the narrowing of the technology gap and eventually shows the characteristic of diminishing returns (The Research Group of Economic Institute of CASS, 2006). This evolutionary feature of the aggregate scale effect reflects that China's urban production has entered the stage of decreasing "learning by doing" effect from the perspective of productivity growth, which is consistent with the finding of the Research Group on China's Economic Growth (2014) that China is already in the stage of decreasing "learning by doing" effect. This also implies that the GTFP growth pattern should shift from the scale effect of production expansion to one that relies on PEC and PTC, the latter two being more dependent on organizational or institutional innovation and technological revolution.

Fourth, the entire study period can be divided into two stages, with the growth rate of GTFP oscillating between 2004 and 2014, and increasing significantly from 2015 onwards. The GTFP growth from 2004 to 2014 is mainly driven by the total scale effect, and the total effect of pure technological progress and pure technological efficiency is less than 1; after 2015, the GTFP growth is due to the growth of pure technological progress and pure technological efficiency, and the total scale effect is less than 1. In the early period, China's economy was growing at a high speed and concomitant ecological and environmental problems in the cities became increasingly serious under the heavy growth target. As such, the superposition of multiple factors leads to the fluctuating decline in GTFP growth. After 2012, the overall economy gradually entered the stage of medium-high speed growth. In 2014, President Xi Jinping for the first time described the new stage of China's economic growth in terms of the new normal, that is, the growth rate has shifted from high to medium–high speed, the economic structure has been continuously optimized and upgraded, and the growth momentum has shifted from factor-driven and investment-driven to innovation-driven. As the main carrier of economic growth, cities have transformed in terms of improving quality and efficiency, no longer blindly pursuing expansion, but focusing on the improvement of resource allocation efficiency and technological innovation. The post-2015 growth rate in GTFP and growth model changes reflect the fact that the quality of China's urban economy is gradually improving under the new governing philosophy of the "new normal" and the "new economy."

To avoid misjudging the trend due to the reduction of the city sample in 2017–2018, Fig.3 presents the temporal trends of urban GTFP for samples constituted by 264, 238, and 195 cities in China. Some years (e.g., 2004–2008) exhibit different magnitudes of GTFP rise and fall, reflecting the fact that differences in the study sample are a main reason for the different urban productivity results measured by different scholars, but they also show a consistent trend. Moreover, the evolutionary trajectories of the three series between 2009–2016 are almost identical. Therefore, based on the different number of city samples in 2017 and 2018, our judgment on the evolution of GTFP since the new normal will not be significantly biased. To avoid bias due to different city samples as far as possible, we focus on a sample of 264 cities from 2004–2016 in the next analysis. We also calculate and analyze the relevant results for the period 2004–2018, but due to space limitations, the corresponding conclusions are not given. However, where there is a large discrepancy in the conclusions, it will be noted.

Fig. 3.

Comparison of urban GTFP for different city samples

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• (1)

  Green total factor productivity and its compositions in 264 cities

Calculating the average annual growth rate of GTFP and its components for 264 cities between 2004 and 2016, the main findings are as follows. First, 141 cities have GTFP greater than 1, accounting for 53.4% of the total sample, reflecting the poor performance of the overall growth of GTFP in Chinese cities. Among them, the top five cities in terms of average annual GTFP growth rate are Tianjin (19.4%), Changchun (16.4%), Beijing (15.8%), Ya'an (14.8%), and Chaozhou (12.2%), and the five cities with the most serious declines in GTFP are Xuancheng (–9.0%), Laibin (–9.3%), Yuxi (–10.0%), Hezhou (–10.2%), Huzhou (–10.2%), and Ningde City (–13.1%). Second, the technical efficiency of 114 cities is greater than 1; the technical efficiency of Changchun, Haikou, Shenzhen, Daqing, and Sanya is equal to 1; while that of other cities is less than 1. The top five cities in terms of technical efficiency are Ya'an (13.6%), Heihe (10.7%), Zhangjiajie (9.3%), Chaozhou (8.5%), and Jiayuguan (7.8%). Ningde City (–12.7%) has the largest decrease in technical efficiency. Third, there are 160 cities with technological progress greater than 1. The top five cities are Changchun (16.4%), Tianjin (14.7%), Hohhot (11.8%), Shanghai (10.1%), Zhongshan (10.1%). The largest decrease is in Maoming (–5.05%). Thus, the cross-sectional analysis further confirms the above-mentioned time-trend analysis results, namely, the GTFP growth performance of Chinese cities needs to be further improved; most of the cities experienced negative growth in technical efficiency; the number of cities where technical progress achieved growth and the improvement range of technical progress are both higher than for technical efficiency, making technical progress the main driver of GTFP growth.

Further from Table 2, 112 of the 141 cities that saw an increase in GTFP had a technical efficiency greater than or equal to 1, 104 had a technical progress greater than 1, and 75 had improvements in both technical progress and technical efficiency; 7 of the 123 cities that saw a decrease in GTFP had a technical efficiency improvement, 57 had a technical progress increase, and none of the 123 cities that saw a decrease in GTFP had a technical efficiency increase. No cities have achieved both technological progress and efficiency improvements at the same time. This shows that technical efficiency is a serious drag on the growth of urban GTFP in China. At the same time, implying ample scope for further improvement in technical efficiency. For example, in 2017 and 2018 the growth rate of technical efficiency is higher than that of technical progress, becoming the main driving force for the growth of GTFP. It is expected that the improvement in technical efficiency will be an important breakthrough as far as the promotion of GTFP in Chinese cities in the future goes.

Considering the East–West and North–South divisions of China's economy, Fig.4 presents the geographical distribution of the 141 cities that have achieved GTFP growth in these two dimensions, with decreasing numbers of cities in the Yangtze River Economic Zone, Yellow River Basin, and other regions, and decreasing numbers of cities in the East, West, and Central regions. The Yangtze River Economic Zone and the Yellow River Basin account for more than 70% of the total number of cities, and the number of cities in the Yangtze River Economic Zone (52) is higher than the number of cities in the Yellow River Basin (47) which is consistent with the large gap between the economic development of northern China and southern China. The regional distribution of cities in the east and west is also in line with economic intuition, but the fact that the number of cities in the west is higher than that in the center and closer to that in the east is not consistent with the stage of economic development of the three regions. This reflects that urban GTFP is closely, but not completely, related to the level of urban economic development. Next, this paper will further analyze the regional heterogeneity of GTFP changes based on the division of China into three regions: East, Central and West.

• (2)

  Heterogeneity Analysis of Urban GTFP in the East, West, and Central Regions of China

Fig. 4.

Geographic distribution of the 141 cities with GTFP positive growth between 2004 and 2016. Notes: Among the 264 cities in the sample, 106 and 75 are located in the Yangtze River Economic Zone and the Yellow River Basin, respectively; while the number of cities located in the East, Central, and West are 93, 97, and 74, respectively.

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The study sample was divided into three major regions in the east, central, and west (Fig.5); the overall regional distribution of the sample is relatively balanced.

Fig. 5.

Subregional Sample Composition

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This paper presents a comparative analysis of GTFP and its composition in the three regions between 2004 and 2016 (Table 3). The GTFP growth performance of the three regions is "West>East>Central"; the growth performance of technical efficiency is "West>Central>East"; and the growth performance of technical progress is "East>West>Central." This paper makes the following analysis of this phenomenon. ① The eastern cities have the highest concentration of quality resources and the fastest increase in pure technological progress and thus technological progress. However, the abundant factor resources have not been effectively utilized in the eastern cities, and these cities have the lowest pure technical efficiency and technical efficiency. In the early stage of development, there are many labor-intensive technologies in the eastern region (i.e., the Pearl River Delta region), and most of them are highly polluting industries. After the 2008 financial crisis, the Pearl River Delta and Yangtze River Delta started to slowly promote industrial transformation and upgrading. However, this created pressure on the environment and because the process of transformation and upgrading is gradual, between 2004 and 2016, the performance of the efficiency component in the developed eastern region is weaker than that of the central and western regions. Considering differences in economic development, the eastern cities are the first to enter the stage where the learning-by-doing effect diminishes, thus showing the lowest total scale effects. Therefore, the GTFP of eastern cities, considering resource and environmental constraints, is not at the forefront of the three regions. ② Western cities have less high-quality factor resources, but their resource utilization efficiency is higher, and their pure technical efficiency and technical efficiency are the highest among the three regions. Although the lack of innovation resources such as human capital and R & D funds leads to the pure technological progress of western cities being less than 1, the technological progress brought by the learning-by-doing effect is larger, and the average annual growth of technology scale is 4.2%. Finally, the pure technological efficiency and technology scale are the two main reasons why the GTFP of western cities is higher than that of eastern cities. ③ The technological progress of central cities is the lowest, but the problem is that the central region is closer to the eastern region, and the technological spillover and industrial transformation of the eastern region are the first to penetrate the central region. Therefore, theoretically, it should be the case that the technological progress of the central region is better than that of the western region. However, following two facts must be emphasized. First, the industries of the eastern region undertaken by the central region are often labor-intensive, which cannot benefit pure technological progress; second, if environmental protection is considered, it is precisely because of the introduction of non-advanced production capacity that leads to a more unfavorable position in the index of technological progress. This, coupled with a lag in technical efficiency, leads to a collapse in the central GTFP.

Finally, it should be noted that there may be some sample selection bias in each region, and this bias may affect the judgment of the relative level of regional productivity to some extent. Generally, the availability and completeness of urban statistical data are positively related to the level of economic development of a city, and we see that the data availability of developed eastern provinces and cities is relatively high and the sample is more complete, while the data availability of western regions is the lowest. The western cities which are thus included in the sample are relatively developed, with some cities with low development performance in the western region being omitted. Thus, this paper may overestimate the overall productivity level of the western region by selecting a subset of cities with higher productivity levels. As of 2018, there were 297 cities at prefecture level and above in China, and this paper retains 88.9% of this population of cities. Although this is a high proportion and the resulting conclusions are generally in line with China's urban profile, there is still the possibility of misjudgment due to regional sample selection bias.

As shown in Fig.6, the cumulative growth rate of GTFP in each region is highest in the West, second highest in the East, and lowest in the Central part of the country. In terms of temporal trends, the cumulative growth rate of productivity in the west and east has gradually shifted from a widening to a narrowing gap, while the gap between the central part of the country and the eastern and western parts of the country has always been large. Although after 2015, there has been a tendency for the central region to catch up with the eastern and western parts of the country, but the reduction is small. In recent years, with the change in the prevailing conception of economic development, eastern cities are actively assuming the responsibility of being forerunner, and these cities also have sufficient resources and policy advantages to carry out the transformation of economic development mode, so that the development quality gap with the west is gradually narrowing, and further showing a trend of surpassing the west. At the same time, some eastern provinces and cities, such as Guangdong, started to transform and upgrade heavy-consuming industries during as early as 2009, and at the same time transferred some heavy-consuming and heavy-polluting industries to the central and western regions. Therefore, theoretically, the relative productivity levels of eastern, central, and western cities are also somewhat affected by such industrial transfer, and this can be reflected in the statistical indicators. Further, from the economic development stage of each region, the western region is the slowest among the three regions, but all regions must go through various stages of industrialization. If the industrialization of the western region does not learn the lessons from the early industrialization of the eastern region, it is possible that low-end industries will proliferate to take advantage of local resource endowments (such as labor and land which are relatively cheap). This may lead to a repeat of the old way of “pollution first and treatment later” in eastern China. However, in the context of high-quality development, the western region may also avoid such a situation and commit to green development, thus avoiding the old road and overtaking on curve.

Fig. 6.

Cumulative Growth Rate of GTFP by Subregion (2003=1)

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In summary, from the perspective of GTFP, western cities have the highest quality economic development, eastern cities rank second, and productivity collapse exists in central China. Under the concept of high-quality development, eastern cities still play the role of pioneers, and the development gap with western cities is obviously narrowing; the development of western cities depends on their future development model; central cities are facing the most severe task of improving quality and efficiency.

• (3)

  Dynamics of the Spatial Distribution of GTFP and its Compositions

To analyze the dynamics of the spatial distribution of urban productivity, kernel density curves of urban productivity and its composition from 2004 and 2016 are presented based on the nonparametric analysis of kernel density estimation (Fig.7).

Fig. 7.

Estimation of Kernel density of GTFP and its compositions

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It can be seen from Fig. 7a, compared with 2004, the peak of the distribution curve in 2016 is basically flat but the left and right tails expand further to both sides, indicating that the dispersion of the GTFP growth rate in China's cities increased during the study period, which is consistent with the findings of Li and Tu (2017) and Li and Pan (2018), that is, there is no σ-convergence in urban productivity in China. At the same time, the right tail extends significantly more than the left tail, implying that the number of cities with declining GTFP growth and the number of cities with sharply increasing GTFP growth are both increasing, but the latter are more numerous. The shape of the distribution curve in 2016 is reasonably similar to that in 2004, but the overall distribution curve is shifted to the right, that is, the mode value of the 2016 distribution curve is larger, the height of the left tail is lower, and the height of the right tail is higher, revealing that the overall growth performance of GTFP in China's cities has improved. This is consistent with the results of the time trend analysis above.

As can be seen from Fig. 7b and 7c, compared with 2004, the kernel density distribution curves for both scale effect and technical efficiency in 2016 are overall left-biased, that is, the value of the mode index is smaller, the left tail is higher, and the right tail is lower, reflecting the declining scale effect and the increasing probability of low technical efficiency in China's cities between 2004 and 2016. From Fig. 7d, compared with 2004, the kernel density distribution curve of technological progress in 2016 shows an overall right deviation, that is, the mode value is larger, the left-tailed extension becomes smaller, and the right-tailed extension becomes larger, indicating a greater improvement in technological progress. Further, the tail extensions of the distribution curves in Fig. 7b, 7c, and 7d are all dilated to different degrees, reflecting the widening gap between cities’ GTFP components, which ultimately leads to a greater dispersion of the urban GTFP.

Given the important role of scale effects in the growth of urban GTFP in China, this paper further demonstrates the heterogeneity of urban GTFP and its compositions under different city sizes. This paper first classifies the sample of 264 cities into five categories: super-metropolises, megacities, large cities, medium cities, and small cities based on the urban population indicators given in the China Urban Construction Statistical Yearbook (2016)11. In terms of the five types of city size, prefecture-level cities and above are mainly small and medium-sized cities, accounting for more than 70%, followed by large cities, accounting for more than 20%, with the number of megacities and super-metropolises being relatively small. According to the seven population classifications, nearly 90% of urban areas have a population between 0.2 and three million, which means that Type I small cities, medium cities, and Type II large cities constitute the majority of cities at the prefecture level and above in China.

Table 4 shows the average GTFP and its composition for all types of cities, based on the results of the 2016 urban GTFP. The following conclusions can be drawn.12

• (1)

  The productivity of super-metropolises, megacities, and large cities is significantly higher than that of small and medium-sized cities, reflecting the fact that large-scale cities have many advantages such as location, physical capital, and favorable policies which eventually attracts migration and drives China's urban productivity growth. This feature is also consistent with the conclusion that the scale effect plays an important role in China's urban GTFP growth. The larger the city, the more abundant the specialized division of labor, and the lower the transaction costs of industrial development. At the same time, the division of labor creates deeper and broader knowledge and technology spillovers, which are more complementary, resulting in lower costs and higher expected benefits. In addition, the quality of infrastructure and human capital also makes it easier for large cities to achieve technological progress and improve resource allocation efficiency.

• (2)

  Technological progress indicators show the characteristics of "super-metropolises > megacities > large cities > medium cities > small cities." Similar to the GTFP, large-scale cities with an urban population of more than 1 million have the highest growth rate of technological progress, while small and medium-sized cities lag behind. From Table 4, we can see that due to the abundant innovation resources and large scale of production in large-scale cities, the technology scale brought about by the learning-by-doing effect, and the pure technological progress brought about by innovative R&D, are both considerable. It is noteworthy that the pure technological progress in small cities is outstanding, second only to mega-cities, which is inseparable from local governments' endeavors to attract talent and their efforts to create an atmosphere of "Mass entrepreneurship and innovation."13 However, small cities still seldom have large-scale production enterprises, and this, coupled with the problem of losing skilled labor and talent to large cities, affects the influence of the learning-by-doing effect on technological progress.

• (3)

  The technical efficiency indicators under the GTFP decomposition show the characteristics of "small cities > large cities > super-metropolis > medium cities > megacities." Under the combined effect of pure technical efficiency and the scale effect, the higher technical efficiency of small cities makes up for their lagging behind in technical progress, which is the key for their GTFP to surpass the average level of GTFP of Chinese cities. By contrast, medium-sized cities are similar to small cities in terms of technological progress, but also underperform in terms of technological efficiency, resulting in the lowest ranking in terms of productivity, 4.42 percentage points below the average GTFP of Chinese cities.

Based on the theory of neo-structural economics, this paper infers that industrial comparative advantage is one of the key factors of urban GTFP growth. This section empirically tests this theoretical inference based on urban panel data from the period 2004 to 2018, focusing on the static and dynamic effects played by industrial comparative advantage in urban productivity growth and the spatiotemporal heterogeneity of these effects. At the same time, control variables such as city size, human capital, and R&D will also be included in the econometric models, so as to further explore the arguments obtained from the productivity measurement analysis in the previous section, thus making the productivity analysis in this paper deeper and more complete.

The following basic panel econometric model is constructed.

The independent variables in model (1) are explained as follows.

First, Balassa (1965) proposed the Revealed Comparative Advantage Index (RCA), which is calculated as the ratio of the share of a country's exports of a certain commodity in its total export value to the share of global exports of that commodity in total global exports. If the RCA is greater than 1, it means that the country has a comparative advantage of the commodity in the international market, and the larger the RCA value, the stronger the country's international competitiveness in that commodity. Since then, this index has been widely used to measure the comparative advantage of a certain industry in the world or in a certain region. Here we take the whole country as the reference region and construct the following revealed comparative advantage index of the kth industry of city i.

Where,Industryik denotes the value added of the kth industry in city i, and under the division of the three industries (i.e., primary industry, secondary industry, tertiary industry), k can take the values of 1, 2 and 3;GRPi is the regional GDP of city i; IndustryChinakand GDPChina is the value added of the kth industry and GDP in China, respectively.

The industrial structure of Chinese cities is principally composed of secondary and tertiary industries. In the period of our study, the sample mean value of the ratio of these two industries to the city's GDP is always over 90%, and there is a trade-off between the comparative advantages of cities in secondary and tertiary industries. Therefore, we mainly calculate the comparative advantage index of urban secondary industry which may be abbreviated as RCA. If the RCA index of the secondary industry in city i is greater than 1, it means that city i can rely more on industrialization to achieve productivity growth than the whole country, and it has a comparative advantage in the secondary industry; if the RCA index is less than 1, it means that city i is below the national average in industrialization process, and it is more likely that city i has a comparative advantage in the tertiary industry.

Second, the control variables are selected based on the theoretical and empirical studies obtained from the above urban productivity measurement analysis, namely, city size, human capital, R&D, and income level. Additionally, all control variables were logarithmically treated.

The specific descriptions of the variables are given in Table 5. Descriptive statistics for the main variables are given in Table 6.

The paper first examines the effect of industry comparative advantage on GTFP, and the obtained estimation results are presented in Table 7. It is evident that the F-test and Wald test show that all models except model (1) obtained from the panel mixed regression are statistically significant overall, and the difference in the chosen estimation method affects the judgment of the conclusions. In this paper, Lagrange multiplier test, test of overidentifying restrictions and likelihood-ratio test are used for model selection14, and the test results support the establishment of two-way fixed effects panel data models, that is, models (3) and (6). In the following, if the estimation method is not explicitly stated, we all use the two-way fixed effects panel data modeling. In addition to the statistical test method, there are also practical considerations for the choice of this estimation method in this paper. Among the factors affecting urban GTFP and its compositions are variables that vary with individual cities but not over time or vary over time but not with individual cities, such as the location and the natural environment of the city in the former case, and the overall national economic development strategy and changes in foreign environment in the latter case. Compared with mixed estimation or random effects panel modeling, the use of two-way fixed effects modeling can remove the effects of these unobservable variables and thus more accurately capture the true relationships between the core variables.

From models (3) and (6) in Table 7, we can see that the effect of industrial comparative advantage on GTFP is significantly positive regardless of the inclusion of control variables, indicating that comparative advantage in secondary industry is indeed one of the key drivers of urban productivity improvement. Note that the coefficient of industrial comparative advantage decreases from 0.0892 to 0.0627 with the inclusion of the control variables, while the model goodness of fit (R2) improves from 0.0424 to 0.0524. This implies that without the inclusion of the control variables, it is possible that the effects of other factors on urban productivity are attributed to industrial comparative advantage, and the resulting effect may be the cumulative value of the direct effect of industrial comparative advantage on productivity and the indirect effect of other factors on productivity mediated by industrial comparative advantage.

When the decomposition terms of GTFP are used as the dependent variables, the obtained estimation results are shown in Table 8. It is clear that the estimated coefficients of RCA on the decomposition terms are all positive, and the impact of RCA on EC is greater than TC under the two decompositions, while the influence of industrial comparative advantage on PEC, PTC and SEGTFP decreases under the three decompositions. The starting point of comparative advantage based on resource endowment is the efficiency of endowment allocation and the core logic is to optimize the efficiency of regional resource allocation, so the effect of industrial comparative advantage on urban productivity is mainly reflected in efficiency change and pure efficiency change.

Since the principal driving force of urban productivity in China is the scale effect (SEGTFP), and the estimation results show that the RCA index has the least influence on SEGTFP. In this regard, this paper makes the explanation that the comparative advantage of the secondary industry mainly works on the secondary industry itself, but not much in other industries. The larger scale effect of the secondary industry is likely to be accompanied by a decrease in the scale effect of other industries, resulting in a smaller and insignificant impact of the secondary industry comparative advantage on the total scale effect at the whole city level. Comparatively speaking, the promotion of pure technical progress and pure technical change by the comparative advantage of secondary industry can be directly incorporated into pure technical progress and pure technical efficiency at the city level, and it will not necessarily affect the expansion of production frontiers or the approach to production frontiers of other industries.

In terms of the control variables, (1) urban population (Scale) has a positive effect on PEC and PTC, but a negative effect on the total scale effect (SEGTFP), finally showing a significant positive effect on efficiency change (EC) and an insignificant negative effect on technical progress (TC). The learning-by-doing effect caused by scale expansion is more suitable for the low-skilled labor force. With the industrial transformation and upgrading of cities, low-skilled labor has entered a decaying phase over the years, and the cheap demographic dividend has been reversed, so the allocation efficiency of urban resources depends more on higher quality human capital, that is, urban population consisting of high quality human capital drives GTFP growth through pure technical efficiency and pure technological progress to a greater extent.

• (1)

  Human capital (HC) has a significant positive effect on PTC. The number of higher education faculty not only reflects the amount of high-quality human capital in the city, but most critically, the faculty itself is one of the main forces driving R&D and one of the main forces in expanding the frontier of production possibilities in the city. In fact, this finding coincides with (1), the difference is that the number of full-time faculty members in colleges and universities is a more precise proxy for the high-quality human capital component of the urban population, which is the main force in expanding the production frontier; whereas the urban population includes a larger proportion of the general workforce and thus has a statistically insignificant positive effect on PTC. Thus, the coefficient estimates for urban population and human capital actually provide mutually complementary economic explanations.

• (2)

  The coefficient of R&D on urban productivity is positive and the most significant among the control variables, reflecting the fact that government-directed R&D spending has a very significant effect on urban GTFP growth. However, this effect lies mainly in improving PEC and technical efficiency change (EC). Government R&D expenditures are allocated to innovation-minded but weak high-tech firms, while large firms that really drive the productive frontier through innovation tend to be stronger and, coupled with the problems of adverse selection and rent-seeking activities, do not receive or even need government R&D funding. Looking back historically, large productive innovations have often come from the market rather than from government-supported programs, so R&D subsidies have actually helped the relative laggards catch up with the frontier firms and have not played a role in leading technological innovation. It is worth mentioning that this result shows consistency with the findings of the interprovincial study by Xia and Xu (2020). The findings of Xia and Xu (2020) may also provide some corroboration for this paper, given the differences in the study object, GTFP accounting method, study period, and the focus of causal analysis.

• (3)

  The effect of income level (Income) on urban GTFP and PTC is positive and statistically significant at the 5% significance level. Economically strong cities have the power to provide R&D capital, attract innovative talent, and implement better industrial policies, thus continuously stimulating the expansion of the frontier of production possibilities and increasing urban productivity, and thus are more likely to be at the forefront of national cities at every stage of urban economic growth, green development, and high-quality development. In addition, the effect of income level on SEGTFP is negative and statistically significant at the 10% significance level, which is consistent with the characteristic that the "learning-by-doing" effect decreases with the narrowing of the technology gap. Economically developed cities are closer to the frontier technology and face a smaller technology gap, so they are the first to enter the stage of diminishing “learning-by-doing” effect, which will bring about a decline in the scale effect, which is manifested in the empirical study as the income level has a negative effect on the scale effect.

This paper incorporates several lagged terms of industrial comparative advantage (RCA) in model (1) and examines the impact of RCA on GTFP from a dynamic perspective by comparing the differential impact of the lagged and current terms of RCA on GTFP. From Table 9, it can be found that the coefficients of the 1–5 period lags of RCA on GTFP are basically negative and mostly insignificant. The explanation being that the early endowment comparative advantage can only endogenize the early industrial structure. Due to the dynamic change of resource endowment caused by continuous capital accumulation and technological progress, which leads to the continuous transformation and upgrading of industrial structure, the previous industrial structure no longer matches the current resource endowment structure. If the previous industrial structure had continued to the present, it would inevitably achieve a lower productivity than that achieved under the current endowment structure and industrial structure. Thus, in the empirical study, it shows that the previous industrial structure that does not match the current endowment has a negative effect on the current GTFP growth.

This confirms the prediction of new structural economics concerning the relationship between urban productivity and industrial comparative advantage, that is, from a static point of view, comparative advantage lies mainly in allocative efficiency, while from a dynamic point of view, comparative advantage lies not only in allocative efficiency, but also in higher levels of allocative efficiency induced by technological progress, that is, under the guidance of technological progress, allocation efficiency will increase dynamically. However, if the resource endowment changes, and the industrial structure remains unchanged, the allocative efficiency will decline due to the dynamic change of the endowment structure or the mismatch between the endowment structure and the industrial structure.

Further, we examine how the dynamics of RCA affects the components of GTFP with a three-period lagged term15, see models (1)-(4) in Table 10. It is clear that the negative effect of the lagged term of industrial comparative advantage on GTFP is mainly reflected in the PEC and scale effect (SEGTFP), while there is a positive effect on the PTC16. In other words, since industrial comparative advantage promotes productivity improvement mainly by optimizing resource allocation efficiency,17 the early industrial structure that does not match the current endowment structure will inevitably reduce resource allocation efficiency and will also fail to realize the scale effect, thus having a negative effect on PEC and SEGTFP. The dynamic change in the early endowment and industrial comparative advantage must be accompanied by technical progress, so as to gradually cause industrial transformation and upgrading, and its ultimate effect will bring about the expansion of the current production frontier. Given that the dynamics of endowments spontaneously endogenize the need for technological progress, what happens if external forces introduce more advanced technologies? We interact the three-stage lagged term of comparative advantage with R&D, and the estimated results are shown in models (5)–(8) in Table 10. The coefficients of the interaction term on GTFP and PEC are significantly positive18. This implies that strengthening R&D can help reduce or even reverse the negative effect of the lagged term of industrial comparative advantage on current efficiency change and GTFP. This estimation result further supports the conclusion of new structural economics that the negative effect of lagged industrial comparative advantage on current productivity is an indication that resource endowments have changed and that the adoption of more advanced technologies is more consistent with the upgraded resource endowment structure and the new industry structure that is now in place.

In summary, based on the empirical study under the perspective of new structural economics theory, this paper finds that the mechanism of industrial comparative advantage on urban GTFP under the static perspective is mainly reflected in the PEC. Additionally, in the long run, the dynamic changes of industrial comparative advantage determined by resource endowment will also significantly affect PTC, as well as continuous R&D will help to improve resource allocation efficiency and GTFP. This study confirms that in China's high-quality development stage, giving full play to the comparative advantages of local industries and strengthening R&D innovation are key initiatives to improve pure efficiency change and pure technological progress and thus sustainably increase GTFP in cities.

The above analysis of GTFP measures shows that there is temporal and regional heterogeneity in urban GTFP changes, and this section focuses on whether such heterogeneity also exists in the effect of RCA on urban GTFP. This paper first constructs the stage dummy variable (dummystage) with 2014 as the node19, and examines the temporal heterogeneity of the effect of RCA on GTFP by including the interaction term of RCA and dummystage in the baseline regression model. Second, this paper also conducts subsample regressions for the three major regions of East, West, and Central in China to discuss the regional heterogeneity of the effect of RCA on GTFP and whether this regional heterogeneity further varies over time. The estimation results are shown in Table 11. Model (1) shows that the coefficient estimate of the effect of RCA on urban GTFP growth is 0.0821 for 2004–2014, and this estimate is 0.02 for 2015–2018, which is the sum of the coefficient estimate of RCA and the coefficient estimate of RCA × dummystage. This implies that the positive effect of the comparative advantage of the secondary industry on urban GTFP is weakening over time. Since the New Normal, China's economy has gradually entered the stage when the tertiary industry has become the leading industry. In the future, cities with comparative advantages in the tertiary industry will be at the forefront of development, and from the industrial development trend, the enhancement effect of the secondary industry's comparative advantages on urban GTFP may be gradually replaced by the tertiary industry's comparative advantages that are more in line with the endowment structure. Models (2)–(4) show that the coefficient of the impact of the comparative advantage of the secondary industry on GTFP decreases with the East, Central, and West in order during 2004–2014. The coefficients of the impact of the comparative advantage of the secondary industry on the East, Central, and West during 2005–2018 are –0.0892, 0.0665, and 0.1107, respectively. This means that the impact of RCA on GTFP not only has obvious regional heterogeneity, but also that this regional heterogeneity changes over time. In the perspective of the new structural economics theory, such temporal and regional heterogeneity are essentially rooted in differences in resource endowments and industrial comparative advantages and their dynamics.

• (1)

  Granger causality analysis

The productivity difference of different industrial sectors is also an important factor in the factor flow and structural change between industries, so there may be a reverse causality from urban GTFP to industrial comparative advantage. Here, we conduct a panel Granger causality test on the relationship between the RCA index and urban GTFP.

Before conducting the causal analysis, the stationarity of GTFP and the RCA index is first tested. Since the sample in this paper belongs to a short panel, the Harris-Tzavalis unit root test (requiring a balanced panel and not allowing different autoregressive coefficients) and the Im-Pesaran-Shin unit root test (allowing an unbalanced panel and allowing different autoregressive coefficients) are applied. The results of both unit root tests reject the null hypothesis of all panels containing unit roots 20, thus allowing a direct panel Granger causality analysis of the two variables. The results for Granger causality test (see Table 12) show that at a significance level of 5%, the RCA index is the Granger cause of urban GTFP, but the reverse is not true. This implies that industrial comparative advantage (RCA) is indeed a key causal factor in urban GTFP changes, and the possible existence of reverse causality does not constitute a key confounding issue in the empirical study of this paper.

• (2)

  Handling of endogenous problem

In order to alleviate the potential endogeneity problem, this paper attempts to introduce the instrumental variables of RCA index. Firstly, drawing on Bartik (2009), the "Bartik instrument" is constructed as follows.

Where i denotes city (1,2...,264), and RCAt¯ is the arithmetic mean of the RCA index for all cities in year t. This instrumental variable simulates the expected value of the industries comparative advantage in each city under the same industrial development trend.

Also referring to the treatment of Nunn and Qian (2014), using the secondary industry comparative advantage index of each city in 2003 as an instrumental variable, and a time-varying factor is introduced to form a panel instrumental variable, which may be taken as the growth of RCAt¯, that is, RCAt¯/RCAt−1¯, thus obtaining another instrumental variable.

In this paper, the baseline model (1) is regressed on the panel fixed effects instrumental variables method, that is, the fixed effects model is first-order differenced, and then Continuously-updated GMM estimation (CUE), which is efficient in the presence of arbitrary heteroskedasticity, is conducted using the two instrumental variables. The results are shown in Table 13. Regardless of the inclusion of control variables (i.e., models (1), (2) respectively), the corresponding Kleibergen-Paap rk LM statistic and Kleibergen-Paap rk Wald F statistic show that there is no unidentifiable problem in model (1) and (2), and it can be considered that there is no weak instrumental variable problem at 15% significance level21 in both models. The corresponding Hansen J statistic cannot reject the null hypothesis of "all instrumental variables are exogenous" at the 5% significance level, indicating that the selection of instrumental variables in this paper is valid. After dealing with potential endogeneity, the effect of RCA on urban GTFP remains significantly positive, thus confirming the robustness of the conclusion that industrial comparative advantage determined by endowments is a key causal factor for urban GTFP growth under the new structural economics theory perspective.

• (3)

  Replacement of the core explanatory variable

In this paper, we replace the key explanatory variable (RCA) in the benchmark model (1) with the industrial comparative advantage index of the tertiary industry (which may be denoted as RCA3) and several structural change indicators constructed based on the output value of the three industries, including the value added of the secondary industry as a percentage of regional GDP (Secondary) which measures the industrialization process, the value added of the tertiary industry as a percentage of regional GDP (Tertiary) which measures the service process, and the index of industrial sophistication (TS) which measures the degree of industrial structure upgrading22. Moreover, different interaction terms for the core explanatory variables and dummystage are included in the corresponding fixed-effects panel data models, so that we can examine how the development of industries with and without comparative advantage, measured by multiple variables, affects urban GTFP over time. The estimation results are presented in Table 14. It is obvious that the effects of RCA3, Tertiary, and TS, which reflect the comparative advantage of the service sector, the development level of service sector, and the relative process of the service sector, respectively, on GTFP show consistency, that is, there is a significant negative effect on GTFP in 2004–2014 when the service sector does not have industrial comparative advantage; the effect on GTFP becomes positive in 2015–2018 when the service sector crosses over the secondary sector to become the dominant industry in society; the secondary sector remains the dominant industry in the whole study period, so the total effect of these three indicators on GTFP still shows a negative direction. Correspondingly, the effect of Secondary which reflects the industrialization process on GTFP remains consistent with the effect of RCA on GTFP as demonstrated in Table 11. This comparative analysis, on the one hand, verifies the above assertion that there is a trade-off relationship between cities' comparative advantage in the secondary industry and the tertiary industry, and thus it is feasible to conduct an empirical study with only the comparative advantage in secondary industry as the core explanatory variable; on the other hand, it not only verifies that the industrial comparative advantage consistent with endowment is the key causal factor of GTFP growth in cities, but also implies that since endowment is dynamic and thus industries with comparative advantage are not static, it is reasonable for the government to identify the changes in the endowment and develop the industries with comparative advantage in a timely manner.