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Article

Spatial Distribution of Energy Consumption and Carbon Emission of Regional Logistics

1
School of Information Engineering Institute, Shanghai Maritime University, Shanghai 200135, China
2
Logistics Research Center, Shanghai Maritime University, Shanghai 200135, China
3
School of Economics and Management, Shanghai Maritime University, Shanghai 200135, China
4
School of Computer Science and Information Engineering, Zhejiang Gongshang University, Hangzhou 310018, China
*
Author to whom correspondence should be addressed.
Sustainability 2015, 7(7), 9140-9159; https://doi.org/10.3390/su7079140
Submission received: 25 March 2015 / Revised: 29 June 2015 / Accepted: 30 June 2015 / Published: 15 July 2015

Abstract

:
Facing serious energy-related constraints and environmental stress, the development of the green logistics industry is restricted by degrees of logistics energy utilization and carbon emissions. Considering different logistics spatial distributions, this paper uses the degree of regional logistics energy utilization and the spatial distribution of carbon emissions as two indicators of green logistics to investigate the regional differences and changes in spatiotemporal logistics energy efficiency. We firstly measure the regional logistics in terms of energy consumption and carbon emission, then further measure the logistics by energy intensity and carbon intensity. Based on these four indicators, the relations between spatiotemporal logistics and regional logistics development are analyzed. Through studying the spatial and temporal evolution trends of the above indicators, we found that a certain convergence exists. Finally, based on the analysis, the suggestions for energy saving and emission reduction are proposed according to regional conditions. The results benefit to narrow the efficiency gap between regions and achieve the goal of improving logistics energy efficiency.

1. Introduction

With the development of global economics, the negative environmental consequences brought by accelerated economic activities are becoming increasingly serious. As one of the world’s largest energy consumers and carbon dioxide emitters, China is pressured by environment issues. According to the BP Statistical Review of World Energy published in June 2014, China’s energy consumption accounts for 22.4% of global consumption, and 49% of global growth during the last year. Meanwhile, China’s carbon dioxide emissions are greater than that of the European Union and the United States, by up to 10 billion tons [1]. According to the survey data, China’s energy consumption of tertiary industry accounts for approximately 30% of the total energy consumption. Moreover, as the main forms of the logistics industry, transportation, warehousing, and postal service account for more than 80% of energy consumption of tertiary industry. Thus, the logistics industry is expected to improve its energy efficiency and reduce carbon dioxide emissions for environmental protection.
Because of the situation of energy shortage and environmental deterioration, China’s current extensive economic growth model makes the contradiction between economic development and environment increasingly conspicuous. With the rapid growth of the economy, the logistics industry has also rapidly developed in recent years. Furthermore, the logistics industry was incorporated into China’s top ten revitalizing industries in 2009. This shows the logistics industry has gradually become an important industry that serves other industries and is strategically significant. As one of the major industries with serious energy consumption, the rising trend of energy consumption in the logistics industry is significant, as shown in Figure 1. It presents the positively correlated relations between logistics energy consumption and economic development. This means the development of the logistics industry can promote economic growth, but it also causes an increase in energy consumption and carbon emissions. Thus, in the concept framework of green logistics recently, energy efficiency and environmental influence have gradually become factors that restrict the sustainable development of this industry. Faced with many factors (e.g., patchy infrastructure, chaotic market management) that affect logistics’ economic model with high input and low output in terms of energy, the logistics industry not only has a high benefit of economic output; but also portrays a great negative impact on energy consumption and environmental protection [2]. Thus, in support of environmental policy, the logistics industry has a bright future once a good operation system to reduce energy consumption and carbon emissions is formed.
In the background of the sustained growth of logistics energy consumption, green logistics attracts the attention of various countries. Green logistics emphasizes sustainable development in logistics operations, thereby limiting the negative impacts of logistics on environment and guiding the green development [3]. Thus, energy conservation and emissions reduction can be regarded as two indicators of green logistics, and in the macroscopic perspective, it involves the extents of energy efficiency in the logistics industry. To evaluate the energy utilization preliminarily, the energy intensity is widely used, which is represented by energy consumption (million tons of standard coal) of unit GDP (billion) [4]. Figure 2 presents the energy intensity in China. It can be seen that China’s overall energy intensity increased initially and then declined from 2002, until reached 1.2 or so in 2011, whereas logistics energy intensity presents an upward tendency from 2001. Even from 2008 to 2011, it also maintained at around 1.77 and had no obvious downward tendency, whereas the decline of the national energy intensity was obvious. The phenomenon shows that although China is trying to reform its economic growth model for the logistics industry, the potential for energy efficiency is still not ideal and energy consumption remains at a high level. Thus, the research of logistics energy efficiency is beneficial for revealing the whole situation of energy utilization in China and exploring possible directions to improve logistics efficiency.
Figure 1. Logistics energy consumption in China (1995–2011).
Figure 1. Logistics energy consumption in China (1995–2011).
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Figure 2. Energy intensity in China (2000–2011).
Figure 2. Energy intensity in China (2000–2011).
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Furthermore, low-carbon economy requires that the logistics industry should pay attention to energy efficiency as well as to lowering carbon emissions. Considering global warming, countries all over the world are trying to build a new emission control systems, and China is no exception. As the main industry of carbon emissions, the logistics industry will inevitably undertake tremendous pressure to make reductions in the future. According to statistical data, the energy consumption of transportation, warehousing, and postal service focuses on oil consumption, and there is still a certain proportion of coal energy used in parts of regional logistics industry. The structure of energy consumption is very unreasonable [5]. In 2011, it accounted for 38% of the total passenger and freight turnover [6]. Thus, the structure of transportation still needs to be optimized. Above all, the research of energy utilization efficiency of logistics based on the carbon emission constraint has benefits for revealing China’s current situation of carbon emission in the logistics and for adjusting and controlling its direction.
Additionally, China’s economic development has obvious regional characteristics, and regional logistics systems with regional differences leads to differences in logistics energy efficiencies. A regional logistics system involves in multi-domains, e.g., economy, technology and social development, which is closely related to the relations between regions, within regions, industrial structure, and logistics models. On the one hand, the development of regional logistics must rely on the promotion of the regional economy; on the other hand, the inherent mechanisms of regional economics also affects green logistics [7]. Thus, it is necessary to promote the development of green logistics. In the background of the complex economic environments, the operational regional logistics system must be emphasized. However, China is developing and the differences of the developing levels of the regional green logistics lead to the situation where planning policy of the logistics industry must be based on regional development. Decision-makers should deeply understand the relations between regional green logistics, economic development and spatial distribution characteristics, so that the logistics development policies can be adjusted according to local conditions. Thus, it is beneficial to reveal the development characteristics of the green degree of the regional logistics system through studying the relations between energy efficiency and economic development, spatial distribution models, and the main factors causing the regional difference.
Based on the above analysis, China is used as the research background. Three aspects are investigated to study the connotations of regional green logistics: logistics energy consumption, carbon emissions, and their spatial distribution. Consideration of different geographical regions, factors including the structure of regional economy, logistics energy consumption, transportation models and so on, are discussed. Thus, this study contributes to the literatures in the following aspects. First, considering the spatiotemporal characteristics of regional logistics, we analyze the trend of logistics energy efficiency changing with time and the regional difference of logistics energy efficiency, which offsets the deficiency that only pays attention on one-year static data or ignore spatial factors. Second, based on geography information systems (GIS) and empirical study, we analyze different mechanisms for many external factors affecting logistics energy efficiency and its fluctuation characteristics, according to the geographical division (e.g., eastern, central, and western).
The rest of the study is organized as follows. In Section 2, the studies related to green logistics, carbon emissions, and spatial distribution are reviewed. Then in Section 3, the methods of measuring energy consumption and carbon emissions are introduced for regional logistics. The data is described and analyzed in Section 4. Finally, we conclude the study in Section 5.

2. Related Studies

Economic growth promotes the development of the logistics industry. The environmental benefits of logistics activities gradually get extensive publicity from the international communities. Thus, green logistics has become an important research subject. In the green logistics and supply chain management field, Zhang and Zhao [8] put forward a specific management strategy for government and enterprises aimed at the principles of green packaging. Government can enact specialized tax system to encourage enterprises to package on a large scale and use the materials that are green and recyclable. To help manufacturing companies achieve sustainability performance, Chin et al. [9] proposed a plausible conceptual model to elucidate the relations between green supply chain management, environmental collaboration, and sustainability performance. Kuei et al. [10] studied the critical factors that influence the adoption of green supply chain practices in Chinese firms. By analyzing the data, they found that external environmental factors including customer pressures, regulatory pressures, government supports, and environmental uncertainty were the most important in adopting green practices. Gunasekaran [11] discussed the current trends and future research directions in green supply chain collaboration and incentives. Sheu et al. [12] presents an optimization-based model to deal with integrated logistics operational problems of green-supply chain management (G-SCM). Used-product reverse logistics in his given green-supply chain was considered. Besides, to describe green logistics quantitatively, many scholars always adopt the way of calculating the energy consumption and greenhouse gas emission in the logistics process. Zhang and Wei [13] examined the dynamic changes in total carbon emission performance within the transportation sector in China, by considering regional heterogeneity. Through using the new total factor index, they found carbon emissions increased 6.2% for the 2000–2012 periods. Fahimina et al. [14] presented a tactical supply chain planning model that can be used to investigate tradeoffs between cost and environmental degradation including carbon emissions, energy consumption, and waste generation. Florian and Igl [15] set up a quantitative distribution network model to study the carbon footprints of 125 scenarios. They concluded that logistics service provider (LSP) structures practicing a geographically decentralized consolidation of shipments are most efficient in reducing of greenhouse gas (GHG) emissions. Thus, it can be seen that the concept of green logistics has enjoyed popular support and it deserves further research.
In this paper, we seek to find out the evaluation indicators to analyze the green degree of logistics industry. Due to the green logistics being a relatively new concept and there not being a clear indicator system used to measure the degree of green logistics, energy consumption and carbon emission become two good indicators for the main negative effects on the environment brought by logistics activity. With the exception of the above work that considered carbon emissions [13,14], there are many other scholars who focus on carbon emission and energy consumption in logistics. For example, based on analysis of the impact of transportation structure on carbon emission, WEI et al. [16] employed a quantitative approach and time series data (1989–2009) to analyze the effect in China. Song and Xu [17] researched carbon emission in container shipping, and they found that high port handing capacity and efficient empty container repositioning can reduce emissions in seaborne transportation. He et al. [18] estimated the carbon emission and energy consumption from China’s urban passenger transportation sector up to year 2030. They presented that promoting public transportation and limiting car usage can contribute 21% of the total energy reduction of China’s transportation sector in 2030. Yin et al. [19] explored the future development of China’s transportation sector in terms of energy consumption, carbon emission, and service demands. They pointed that transportation carbon emission and energy consumption will continue to increase rapidly without major policy intervention, though carbon price policies may have certain inhibiting effect. Besides, considering logistics activity associated with economic output, logistics energy intensity and carbon intensity, which usually performance on energy efficiency, are also involved in the study of green logistics. Hu and Wang [20] analyzed energy efficiencies of the 29 administrative regions in China for the period 1995–2002 with a newly introduced index system. The data envelopment analysis (DEA) was used to confirm the scenario that energy efficiency increases with economy growth. Zhang et al. [21] proposed a hybrid energy input-output model to analyze the total energy consumption of different regions. They thought that, for industries, developing and energy efficiency is significant; and for developing and energy exporting regions, transforming primary energy into high value-added products would be beneficial for economic development and energy conservation. Caraiani et al. [22] developed investigations on the causal relationship between energy consumption and GDP in the context of emerging European countries covering the period 1980–2013. The results were concluded through empirical study as follows. A balance exits in confirmative conservation, growth and neutrality hypotheses. In some specific cases, energy consumption and economic growth are jointly determined.
Aimed at the characteristic that China is a large country, it is necessary to study the regional features of logistics. Logistics development is affected by the economy for economic development causes more demand for logistics services, meanwhile, it also promotes economic development [23,24]. Thus, to research the regional logistics, it is necessary to connect regional economic development. Dai and Yang [2] analyzed the contribution of logistics park construction to regional economic development. From the perspective of growth pole theory under regional economic theory, they indicated that the logistics park would be a growth pole in certain cities of regions. For the phenomenon that the speed of logistics infrastructure investment in central China is lower than other regions, Hu et al. [25] pointed that there existed co-integration relations between the regional logistics investment, logistics value-added, and GDP. Connected to carbon emission and energy consumption, Duan [26] built a logistics-induced energy economic hybrid model considering regional characteristics to find the optimal carbon tax in China. By solving the model, the optimal carbon tax was monotonically increasing and S-shaped. Comparing to other country with large areas like the US, their government was investing significant resources in the development of logistics clusters [27]. Due to the influence of small population density and good environment, researchers aimed at other large countries are less attention on carbon emission and energy consumption, and they usually focus on economics and transportation [28]. Nevertheless, the literatures that directly describe regional logistics and economic characteristics in connection with carbon emission and energy consumption are still lacking [29,30]. Thus, the contribution of our work is to link the four parts (regional logistics, economy, energy consumption and carbon emission) and analyze their synergy and inhibition mechanism.
Besides, the research based on spatial distribution of energy consumption is not well studied in literature, especially the logistics energy efficiency. Howard et al. [31] built a model to estimate the building sector’s end-use energy intensity for space heating, domestic hot water, electricity for space cooling, and electricity for non-space cooling applications in New York City. Spreng [32] discussed the intra- and international distributions of energy consumption and their implications for intergenerational equity. They concluded that we might have already reached or perhaps even surpassed the sustainability limit of energy inequality. Some scholars used GIS in their studies. Therefore, many methods including geographically weighted regression [33] and spatial correlation analysis [34] were introduced. Dujardin et al. [35] analyzed the impact of territorial structures upon energy consumption in the Wakkoon Region and revealed that some rural settlements characterized by low density show good performance in terms of energy efficiency. Li et al. [36] described the spatial dynamic distribution of heavy metals by using GIS; and Mua et al. [37] also used GIS to analyze the distribution of species. From the above literatures, it can be seen that there is still no systematic research aimed at spatial logistics energy efficiency and spatial patterns.
Thus, based on the review of literatures, we introduce GIS to analyze the spatial distribution of energy consumption and carbon emission in logistics industry. Regional economics was used to analyze its relationship with spatial distribution.

3. Regional Logistic Energy Consumption and Carbon Emission

The models of measurement method of logistics energy intensity and carbon emissions are demonstrated in Section 3.1 and Section 3.2, respectively. The reasonable measurement methods are the basis of evaluating logistics energy efficiency. Moreover, it helps to understand the current stage of Chinese logistics under the condition of energy utilization and carbon emissions.

3.1. Measuring Logistics Energy Intensity

According to the General Principles for Calculation of the Comprehensive Energy Consumption published by Standardization Administration of the People’s Republic of China (SAC) in 2008, we can design the measurement method of regional logistics energy consumption. Then the energy consumption can be calculated.
(1) Logistics energy consumption
Logistics Energy Consumption (LEC) refers to the physical quantity of all kinds of fuels consumed by energy-consuming units in logistics during the studied period of statistics. All types of energy consumption are converted into standard coal. The indicator mainly reflects the total energy consumption level of regional logistics. LEC is determined as Equation (1).
L E C = i = 1 n e i × p i
L E C represents logistics energy consumption; n denotes the types of fuels consumed by logistics activity; the amount of fuel i consumed by logistics activity is denoted by e i ; and the conversion coefficient of fuel i is p i (Table 1).
Table 1. Conversion coefficients for different kinds of fuels.
Table 1. Conversion coefficients for different kinds of fuels.
Energy CategoryConversion CoefficientEnergy CategoryConversion Coefficient
Raw coal0.7143 kgce/kgFuel oil1.4286 kgce/kg
Clean coal0.9 kgce/kgNaphtha1.500 kgce/kg
Other coal washings0.2857 kgce/kgLubricating oil1.4143 kgce/kg
Briquette0.600 kgce/kgParaffin1.3648 kgce/kg
Coke0.9714 kgce/kgSolvent naphtha1.4672 kgce/kg
Coke Oven Gas0.5714 kgce/m3Petroleum asphalt1.3307 kgce/kg
Other Coal Gases0.5143 kgce/m3Liquefied petroleum gas1.7143 kgce/kg
Other coking products1.3 kgce/kgRefinery dry gas1.5714 kgce/kg
Oil1.4286 kgce/kgOther petroleum products1.400 kgce/kg
Gasoline1.4714 kgce/kgNatural gas1.330 kgce/m3
Kerosene1.4714 kgce/kgHeating power0.03412 kgce/MJ
Diesel oil1.4571 kgce/kgElectric power0.1229 kgce/kw·h
Liquefied Natural Gas1.7572 kgce/kgOther fuels1.00 kgce/kg
Resource: General Principles for Calculation of the Comprehensive Energy Consumption, 2008.
(2) Logistics energy intensity
Based on the measurement method of logistics energy consumption, we introduce the concept of logistics energy intensity to investigate the relations between logistics energy consumption and economic output. Logistics energy intensity is the ratio of energy utilization and economic output, which is commonly used to describe the degree of energy utilization. Some scholars have also conducted, but no scholar has analyzed the energy intensity on the logistics industry in the literatures. Thus, we further calculate China’s logistics energy intensity in this section to observe the difference of the change of China’s total energy intensity with other countries.
Logistics Energy Intensity [4] refers to the ratio of energy utilization and gross domestic product (GDP) during the studied period. It reflects the logistics energy consumption for per logistics GDP in a country or region, and can be used to measure the relations between logistics development level and logistics energy consumption. The lower value indicates that the efficiency of logistics energy utilization is higher and the economic output is better. LEI is determined by Equation (2), where LEI represents logistics energy intensity; and G represents the GDP of logistics industry during the period of statistical.
L E I = L E C G

3.2. Measuring Logistics Carbon Emission

Due to the method recommended by IPCC can be used to calculate the carbon emissions effectively [38,39], we use the IPCC carbon accounting method to measure the amount of logistics carbon emission, which is formulated as Equation (3).
L C s t = ( E s j t × δ s × η i )
Here, L C s t represents the total amount of logistics carbon emissions of the region s in the year t ; E s j t denotes the amount of energy consumption of the region s in the year t ; the conversion coefficient of energy i is denoted by δ i ; and the carbon emission coefficient of energy i is η i . Table 2 shows the carbon emission factors for different kinds of fuels.
Table 2. Carbon emission factors for different kinds of fuels.
Table 2. Carbon emission factors for different kinds of fuels.
Energy CategoryCarbon Emission FactorEnergy CategoryCarbon Emission Factor
Raw coal0.7559Kerosene0.5714
Clean coal0.7559Diesel oil0.5921
Coke0.8550Fuel oil0.6185
Other coking products0.6449Liquefied petroleum gas0.5042
Coke Oven Gas0.3548Refinery dry gas0.4602
Other Coal Gases0.3548Natural gas0.4483
Oil0.5857Other petroleum products0.5857
Gasoline0.5538Electric power2.2132
Resource: 2006 IPCC Guideline for National Greenhouse Gas Inventories, 2006.
According to the measuring of logistics carbon emissions, to investigate the relations between logistics carbon emissions and economic output, we can further measure the logistics carbon intensity by Equation (4). Here, C I denotes the carbon intensity; L C is the amount of carbon emissions; and G is the economic output during the period of statistical. The smaller value of C I indicates that the amount of carbon emissions caused by unit logistics GDP is less, and thereby the environmental benefits of unit logistics activity is higher.
C I = L C G
Through the above indicators related to regional logistics and economics, we define some variables (Table 3) to reveal the present situation, historical trends, and spatial pattern of China’s energy utilization and carbon emission.
Table 3. Four energy and carbon emission indicators for regional logistics.
Table 3. Four energy and carbon emission indicators for regional logistics.
SymbolVariableDefinition
LECLogistics Energy ConsumptionActual consumption of all kinds of fuels in logistics industry (ten thousand tons standard coal)
LCLogistics carbon emissionsCarbon emissions in logistics industry (ten thousand tons)
LEILogistics energy intensityRatio of energy utilization and logistics GDP (ten thousand tons standard coal/billion yuan)
CICarbon intensityRation of logistics carbon emissions and logistics GDP (ten thousand tons/billion yuan)

4. Data and Analysis (2000–2011)

Based on the equations in Section 3, we calculate the panel date of China’s 30 administrative regions in this section. First, with the time going on, the trends of logistics energy consumption, carbon emissions, logistics energy intensity and carbon intensity, and the relations between these indicators are analyzed. Then, based on ArcGIS platform (www.esrichina-bj.cn), the logistics spatial distribution pattern of energy consumption and carbon emissions are further analyzed.

4.1. Data Sources

Considering the lack of classification system in the logistics industry in China, we use the relevant transportation, warehousing, and postal data to estimate the overall situation of logistics industry, for their increased value accounted for over 80% of the total increased value of the logistics industry in the past statistical yearbook.
Based on the data availability and empirical study, the panel data of China’s 30 administrative regions (not including Hong Kong, Macao, and Taiwan) is used as study sample for the period 2000–2011. To ensure the quality of sample data, the logistics energy consumption and carbon emissions of Tibet have not been calculated because of the lack of statistical data (especially energy-related data). Energy-related data is from the China Energy Statistical Yearbook [40], and economic-related data is from China Statistical Yearbook [41].

4.2. Trends of Logistics Energy Consumption, GDP and Carbon Emission

According to the measure method described in Section 3, we can get results (Table 4), which are the values of four variables (LEC, LEI, LC and CI) for the period 2000–2011. Figure 3 shows the trends of logistics energy consumption and carbon emissions. In the results, China’s logistics energy consumption, logistics economic output and carbon emissions all sustained growth whose average growth rates are 10.09%, 9.12% and 12.9%, respectively. The convergence trends of the three indicators are significant. In 2011, the logistics total energy consumption is 285.35 million tons of standard coal, which is 2.9 times of that of 2000; meanwhile, logistics carbon emissions reaches to 162.99 million tons, which is 3.8 times of that of 2000. Observing the changes in three types of indicators (Figure 4), the growth rates roughly showed an increasing tendency before 2005, and the growth rates of logistics energy consumption and carbon emissions are significantly higher than the growth rate of logistics GDP. Thus, China’s energy input has not obtained a satisfactory economic output in the logistics industry. To the contrary, the energy input aggravated the negative environmental consequences. Then from 2005 to 2011, the growth rates of all types’ indicators continued to decrease, and had obvious convergence trends. Especially in 2009, the downtrend was significant, which related to the financial crisis in 2008–2009. After that, the growth began to rise. The growth rates of logistics energy consumption and logistics GDP kept at about 10%, and logistics carbon emissions kept at about 8%. The situation tends to be stable.
Table 4. Measures for LEC/LEI/LC/CI (2000–2011).
Table 4. Measures for LEC/LEI/LC/CI (2000–2011).
YearLECLEILCCIYearLECLEILCCI
20009916.121.614290.750.7200618582.721.7410877.871.02
200110257.081.534950.120.74200720643.371.7312098.241.01
200211086.491.545447.440.76200822917.251.7913236.521.03
200312740.11.676466.420.85200923691.841.7814039.081.05
2004151041.737392.390.85201026068.471.7815124.171.03
200516671.811.729844.311.01201128535.51.7716299.491.01
Figure 3. Trends of logistics energy consumption and carbon emissions.
Figure 3. Trends of logistics energy consumption and carbon emissions.
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Figure 4. Trends of indicators’ growth rates.
Figure 4. Trends of indicators’ growth rates.
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The trend of China’s logistics energy intensity is affected by energy consumption and the change of logistics demands. Figure 5 shows the trends of China’s energy intensity, logistics energy intensity and carbon intensity, whose growth rates are −1.93%, 0.89% and 3.47%, respectively. Since 2004, China’s energy intensity was decreasing, with the proposal of Chinese Eleventh Five-Year Plan (2006–2010) which included a 20% reduction in energy intensity per unit of GDP compared with Tenth Five-Year Plan (2001–2005). In terms of energy utilization, the technology progress and the update of management concept all can promote social energy efficiency. Especially many heavy manufacturing industries (e.g., metallurgy, steel, power), which have experienced more than 30 years of reform and openness, have initially formed recycle and reuse methods by studying western technology and management experience, which led to a downward trend of China’s energy intensity overall. However, as a newly developed industry in China, the development of logistics industry is limited by many factors, which reflects on the change of logistics energy intensity for that did not obviously decline. In addition, carbon intensity also did not obviously decline. In the past five years, logistics energy intensity floated around 1.77, but carbon intensity kept at around 1.0. The phenomenon indicates that China’s energy consumption and carbon emissions consumed by unit, logistics’ economic output is still at a high level, and technical limitations, backward management and unreasonable regulations could lead to the value of indicators staying at a high level. Figure 6 presents a trend of growth in energy intensity. From the figure, we can see that the growth rate of carbon intensity was positive before 2010, and then it turned into a negative. Before 2006, the growth rate of carbon intensity has fluctuated, violently, related to the requirement for economic growth during Tenth Five-Year Plan (2001–2005). When there is a contradiction between economic growth and environmental protection, some departments and local governments always give priority to economic growth firstly, and then the deterioration of environment. After the deterioration of environment, the control of carbon emissions would be considered briefly. Overall, it is because of incomplete environmental protection policy. After which it becomes stable. It related to the influence of the new series of policies and regulations, for following the circumstances of energy conservation and emission reduction all over the world. In addition, the growth rate of logistics energy intensity is invariably at around 0% in recent years. Thus, although the effect of energy conservation and emission reduction in transportation industry has been vigorously promoted in China, logistics energy intensity has not substantially improved. The downward trend is not clear, and energy investment cost per unit of economic output is still high.
Figure 5. Trends of each energy intensity.
Figure 5. Trends of each energy intensity.
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Figure 6. Trends of each indicator’s growth rate.
Figure 6. Trends of each indicator’s growth rate.
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According to Equations (2) and (4), logistics energy intensity and carbon intensity are determined by logistics GDP, energy consumption, and carbon emissions. Nevertheless, in essence, the energy intensity is determined by technical and management capability, and the external policy environment. With the development of those factors, such as the innovation of energy technologies and the improvement of carbon technology, logistics energy-consuming units could gradually reduce the energy consumption but that is still not enough to cope with the growing logistics business. Thus, the energy intensity and carbon intensity still need to decrease gradually. We can think that energy intensity and logistics demands determine the level of logistics energy consumption. Based on the above analysis, China’s high logistics intensity and carbon emissions are caused by technology, management, and related policy and regulations.

4.3. Spatial Distribution of Logistics Energy Consumption and Carbon Emission

In Section 4.3, we analyze the evolution of China’s logistics energy consumption and carbon emissions over time, but the spatial distributions of related indicators are not involved. Thus, we explore the regional difference of logistics’ energy consumption and the spatial pattern based on ArcMap (www.esrichina-bj.cn) in this section.
Table 5 shows the measured value of energy consumption, energy intensity, carbon emission and carbon intensity of the logistics industry in 30 administrative regions in 2011. The provinces with the highest logistics energy consumption are Guangdong, Shandong, and Liaoning. Among them, the consumption of Guangdong is up to 26.2 million tons of standard coal. These regions are mainly distributed in eastern coastal China, which needs a lot of energy consumption to support the huge logistics demands. The high consumption also caused high logistics carbon emissions. The amount of carbon emissions in Shandong and Guangdong with the highest carbon emissions are 15.298 tons and 15.248 tons, respectively. In addition, Yunnan, Hainan, and Shanghai are the top three regions with the highest logistics energy intensity that are up to 4.07, 2.49 and 2.18, respectively. It shows that these regions consumed massive energy per unit of logistics GDP output. Similarly, the carbon intensities of the three regions are also of the highest, which indicate that the logistics activity caused great environmental pollution.
Table 5. Regional measures for LEC/LEI/LC/CI (2000–2011).
Table 5. Regional measures for LEC/LEI/LC/CI (2000–2011).
RegionLECLEILCCIRegionLECLEILCCI
Beijing926.231.14533.090.66Henan1119.561.16569.210.59
Tianjin448.470.71266.230.42Hubei1445.031.66862.330.99
Hebei826.630.40499.490.24Hunan920.800.97542.970.57
Shanxi766.721.01428.910.57Guangdong2619.671.251524.760.73
Inner Mongolia1315.401.26776.440.75Guangxi774.741.32455.750.77
Liaoning1700.901.49931.700.82Hainan297.892.49174.741.46
Jilin478.021.14287.060.68Chongqing551.141.21329.180.72
Heilongjiang836.051.54523.150.96Sichuan1104.881.73461.550.72
Shanghai1896.172.181107.281.28Guizhou514.970.87302.900.51
Jiangsu1398.560.66809.670.38Yunnan883.154.07520.922.40
Zhejiang1185.580.98691.540.57Shaanxi838.761.52502.430.91
Anhui520.450.88311.630.53Gansu299.181.07187.920.67
Fujian794.480.82465.590.48Qinghai106.721.5864.610.96
Jiangxi461.570.91272.240.54Ningxia132.180.7678.760.45
Shandong2587.571.111529.810.66Sinkiang496.201.93287.641.12
Based on the above analysis, we can conclude that the distribution patterns of logistics energy consumption and carbon emissions are similar. To confirm the conclusion, a scatter diagram (Figure 5) was drawn to observe the correlation between the two indicators easily. It shows the two indicators have obvious positive correlation. That is, regions with high logistics energy intensity also have higher carbon intensity.
Figure 7. Scatter plots of LEI and CI.
Figure 7. Scatter plots of LEI and CI.
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To reveal the spatial pattern of the logistics energy intensity and carbon emissions further, we draw a series of maps that reflect the logistics energy intensity and carbon emissions in 2001, 2006 and 2011 based on ArcMap (Figure 8). The intensities are divided into five levels. If the region’s color is deeper, the intensity is higher compared to other regions during the period of research. The dark regions represent the low energy utilization efficiency and poor environmental benefits.
Figure 8. Spatial distribution of CI and LEI.
Figure 8. Spatial distribution of CI and LEI.
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The logistics energy intensity and carbon intensity share a consistent spatial distribution pattern (Figure 8). That is, when the regional energy intensity is high, the carbon intensity of the region is also in a high level. From the perspective of regional distribution, the eastern regions especially in the economic circle of inshore-developed cities always have low logistics energy intensity and carbon emissions, but Shanghai and Hainan are exceptional. The regions’ of the Midwest are significantly higher than the east, especially Yunnan, Xinjiang, Ningxia and Gansu, which were at high levels in previous years. Their logistics energy efficiency and environmental impact are not optimistic, and it is urgent to conduct energy conservation and emissions reduction.
For the consistent spatial distribution pattern in two indices, it can be considered that high logistics energy intensity means low logistics economic output as well as low energy efficiency, so energy would be wasted and even cause serious carbon emissions. For the regional difference, it is closely related to policy, regional energy consumption structure, production technology, economic development, etc. The energy efficiency for different energy is not the same, for instance, the utilization efficiency of oil and gas is much higher than coal. As the regions with high logistics carbon intensity and energy intensity like Xinjiang, their coal consumption is more than 70% of total energy consumption according to China Statistical Yearbook [41] in 2011. On the contrary, the “West-to-East Gas Pipeline” produces clean energy of natural gas that is used by the eastern coastal cities widely, which optimized regional logistics energy structure and reduced logistics energy intensity and carbon intensity. Besides, the capacity eliminated by the eastern coastal cities will transfer to the Midwest also leading to the regional difference. On the other hand, the geographical positions for eastern cities are beneficial to absorb foreign technology and management experience to improve economic output. Expertly, Shanghai’s logistics energy consumption is staying at a high level, which can be roughly attributed to its special economic geography. Although its logistics GDP is higher than other regions, excessive energy consumption leads to the results that its logistics energy intensity and carbon intensity are higher than the other eastern coastal regions. In addition, many external factors may lead to this abnormal result. The deep-seated reasons for high logistics energy consumption in Shanghai can be studied further. Overall, rational policies, optimized logistics energy structure, and an advanced economy are beneficial to reduce logistics energy intensity and logistics carbon intensity.

5. Conclusions

As the revitalizing industry in China, logistics industry plays a key role in economic development. The methods of optimizing energy utilization and reducing environmental impact in the logistics industry are important to promote the development of green logistics systems. This paper measures the value of logistics energy consumption and carbon emissions. Further, to describe the relations between logistics industry and economic development, the logistics energy intensity and carbon intensity are examined. Then, from the perspective of time and space dimensions, we analyze the trends of four types of indicators (LEC, LEI, LC, CI), and reveal the specific situation of energy utilization impact on the environment. The main conclusions of this study involve the following features. First, logistics energy consumption and carbon emissions have positive correlations with economic development, and the scale expands continuously. Second, the negative environmental impact of logistics activities is expanding, when corresponding logistics economic output is created in China, for the growth rates of logistics energy consumption and carbon emissions are significantly higher than the growth rate of logistics GDP. Third, logistics energy intensity and carbon intensity remained at high levels in recent years, and the trends of decline are not obvious for factors involving technology, management, and environment institutions. Finally, the spatial distribution patterns of logistics energy intensity and carbon emissions are similar, where a certain space aggregation effect exists. The increasing tendency from east to west can be roughly concluded.
Based on the empirical results, the following suggestions are to be considered for relevant departments. First, energy management systems for energy conservation and emissions reduction in logistics industry can be established, such as carbon taxes and compensation policy for energy consumption and emissions reduction. Second, different goals of logistics energy efficiency should be established according to the regional economic differences. Thirdly, the structure of logistics energy consumption should be optimized and the development of new energy should be promoted, such as natural sun, wind, and bioenergy. Finally, the industrial structure should be optimized. Relevant policies should consider the central and western regions, so that high value-added industries and regional logistics value-added services are developed with high priority. As for the future research direction, the regional logistics energy efficiency can be evaluated by various methods, and the relations between regional logistics energy efficiency, economy, and development will be investigated.

Acknowledgments

This study is partially supported by the National Nature Science Foundation of China (71101088, 71471109), the Science Foundation of Ministry of Education of China or Shanghai (20113121120002, 14YZ100, 13SG48), the ministry of transport of the People’s Republic of China (2015329810260), and Zhejiang Provincial Natural Science Foundation of China (LZ14G020001).

Author Contributions

Zhi-Hua Hu promoted the research and designed the whole framework with Pei-Hua Fu, who is familiar with the background of regional logistics and carbon emissions. Fan Xiao devoted herself to the research on modeling and analysis, and wrote the whole paper. Ke-Xin Wang anticipated in collecting and processing the data, and assisted Xiao to write and optimize the work. All authors have read and approved the final manuscript.

Conflicts of Interest

The authors declare no conflict of interest.

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MDPI and ACS Style

Xiao, F.; Hu, Z.-H.; Wang, K.-X.; Fu, P.-H. Spatial Distribution of Energy Consumption and Carbon Emission of Regional Logistics. Sustainability 2015, 7, 9140-9159. https://doi.org/10.3390/su7079140

AMA Style

Xiao F, Hu Z-H, Wang K-X, Fu P-H. Spatial Distribution of Energy Consumption and Carbon Emission of Regional Logistics. Sustainability. 2015; 7(7):9140-9159. https://doi.org/10.3390/su7079140

Chicago/Turabian Style

Xiao, Fan, Zhi-Hua Hu, Ke-Xin Wang, and Pei-Hua Fu. 2015. "Spatial Distribution of Energy Consumption and Carbon Emission of Regional Logistics" Sustainability 7, no. 7: 9140-9159. https://doi.org/10.3390/su7079140

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