1. Introduction
Currently, humankind’s effect on the environment has come to an irreversible stage [
1]. In particular, as one of the world’s largest energy consumers and carbon dioxide emitters, China is facing more severe environmental issues (such as extreme climate). According to the BP Statistical Review of World Energy 2018, China’s energy consumption accounts for 23.2% of global consumption and 33.6% of global growth during the last year. In this atmosphere, being environmental sustainability-oriented has become a key strategy for governments.
Transport plays a key role in the functioning and development of the city. Many empirical studies have proven that transportation is the most crucial of the determinants (e.g., the economy, land use, population, and employment) of urban development because it provides mobility for people and goods and influences the growth patterns of economic activity through changing accessibility [
2,
3,
4]. Meanwhile, it is also the main contributor of emission. According to survey data, China’s transport accounts for more than 9% of the total energy consumption and maintains an average annual growth rate of 28%. Moreover, with the significant increase in freight transportation, there is no doubt that the freight transport sector has become an important emission source [
5,
6,
7]. Therefore, environmental sustainability-oriented policies in the freight transport sector are essential.
In fact, many countries have been making and implementing policies for environmental sustainability in the field of freight transportation and logistics. For example, intermodal transport, as an efficient and environmentally friendly mode, has been vigorously advancing in Europe [
8,
9]. Similarly, China has been implementing the environmental logistics policy in road freight. This policy strongly advocates reducing emissions by the application of green energy in freight vehicles and the improvement of operational efficiency [
5]. Recently, sustainable supply chain management has been adopted in many logistics companies, because it allows to close and cycle resources and improve environmental sustainability [
10,
11].
However, the realization of the environmental sustainability goal still requires much work. One of the biggest challenges that stands in the way of achieving this goal is the lack of accuracy and realistic characteristics of freight transportation network to support freight transport planning [
12]. The identification of freight transportation network features thoroughly is the foundational work, which is directly related to the formulation of freight transport planning schemes (such as freight transportation network optimal scheme, infrastructure and related freight facilities layout scheme). Although this challenge has been acknowledged by planners and policy practitioners, the most recent studies related to freight transportation still focus on the technology and approach for capturing freight features at microlevels, such as the identification of OD information [
13], the individual truck’s trip chain information [
14], and travel time reliability [
15]. Little attention has been paid on freight transportation network. In addition, to better promote urban economic growth, the construction and development of transportation infrastructure, as a typical urbanization strategy, have been conducted in many developing countries [
16,
17]. However, with the implementation of this strategy, gradually, freight transportation activities are likely to become more complex in terms of patterns of travel [
18,
19,
20,
21], which increases the challenge of delineating and revealing the spatial interaction features of freight transportation. In this context, to understand the growing complexity of freight travel, there is an urgent need to thoroughly research the characteristics of freight transportation, which greatly benefits the optimization of goods and service delivery within existing transportation networks and thereby accelerates sustainable urban development and transportation.
A large number of studies have identified the characteristics of transportation networks based on massive amounts of travel data, including air passenger flow, rail passenger flow, traffic flow, and big geospatial data. Wang et al. [
22], Lao et al. [
23], and Dai et al. [
24] explored the spatial structure of an air transportation network using aviation passenger data. Zhong et al. [
25] examined the hierarchical structure of the China passenger railway transportation network and conducted a comparison analysis of the air transportation network and the railway transportation network. In addition, Wang et al. [
26] identified the spatial interactions between cities and explored the community structure of the railway and air transportation networks, and they stated that the barrier effects of the administrative boundary on these two networks’ forms were different. To study traffic flow, most studies have focused on road network layout evaluation and traffic demand analysis, as well as vulnerability analysis [
27,
28]. There is a need to use big geospatial data because there is an increasing need to identify travel activity characteristics more effectively. For example, Liu et al. [
29] used taxi trip data to explore the clustering characteristics of a person’s travel activities within a city and found that some clusters showed that the boundary scope of some clusters was not consistent with the administrative boundaries. Similar studies have been conducted by Joubert et al. [
30], Zhong et al. [
31], etc.
However, the existing literature on this topic has mainly focused on passenger transportation, providing few insights into freight transportation. In particular, the features of freight transportation remain largely unexplored. As noted by Allen et al. [
19,
32], there has been no comparable research on the spatial interaction of freight transport, although a large number of theoretical and empirical works on passenger transport have been conducted. More importantly, when depicting and revealing the characteristics of freight transportation, little attention has been paid to the impact of administrative boundaries on transportation. This is surprising, given that the urbanization trend of scope or spatial scale of freight movements is expanding and the number of cross-border freight flows is increasing [
19,
33,
34,
35]. Nevertheless, most applications treat the scope of freight movements as a “closed area” or a” static area”; i.e., the spatial interactions and transportation linkages in the outer areas of the selected study area are not usually considered [
36,
37,
38], which leads to unrealistic results.
Therefore, our research objective is to characterize freight transportation from multiscale perspectives, focusing on the freight flows generated in both inner and outer urban areas as well as the influence of the cross-border effect on freight transportation networks. This research uses origin–destination freight vehicle trip data from approximately 7000 trucks in Yunnan Province, China, as an example to characterize spatial topological properties and the community structure of freight transportation.
The contributions of this work are twofold. First, we propose an improved freight network building process that depicts more realistic freight activities and spatial interactions, and it provides evidence and findings regarding the impact of the cross-border effect on the topological structure of networks in China. This study enriches the approach used for freight network building in the increasingly complex travel environment and further enhances our understanding of urban spatial structures. Second, this study uses origin–destination freight vehicle trip data that shows intercity trips and intracity trips showing that the urban structure obtained has strong relations with freight transportation applications; this finding provides novel insights regarding the development and optimization of freight transportation and urban sustainable development. The following sections describe the study area, the process used to prepare the data, introduce the study methods, and reveal the features of freight transportation from two aspects of statistical properties and clustering characteristics. The last section provides the conclusion and recommendations for future research.
4. Conclusions and Discussion
4.1. Conclusions
This study used truck trip data extracted from the Freight Vehicles Trip Survey of Yunnan Province to explore freight transportation. From the perspective of spatial interactions, two subnetworks, namely, a prefecture-level city-scale network and a county-level city-scale network, were built from the data using graph theory; these networks were conducted to delineate the freight activities more realistically and comprehensively. Considering the influence of the cross-border effect on freight transportation, the boundary issue that generally occurs during network formation was taken into account in the process of building the freight networks. On this basis, network analysis indices based on complex network theory were applied to examine the topological structure and complexity of the freight transportation networks. Furthermore, the community detection method was introduced to reveal the freight network’s clustering characteristics. By doing so, information on the topological and community structure of Yunnan’s freight network and the spatial interactions both between cities and within cities was obtained.
We find that the prefecture-level city-scale network has scale-free properties only at the local level because it follows an exponential degree distribution and a power law strength distribution. This finding suggests that the freight network at the prefecture-level city-scale is in a transition phase from simple and random to a complex structure, and the overall large-scale network structure has yet to be formed. However, the degree distribution and strength distribution of the county-level city-scale network both fit the power law function, indicating that it has scale-free properties. Meanwhile, the prefecture-level city-scale network and the county-level city-scale network both have obvious small-world network characteristics, but the prefecture-level city-scale network has higher operating efficiency for goods movement. Additionally, the influence of the cross-border effect on the freight transportation network was verified by comparing the changes in small-world properties of the freight network of this study to those of the traditional network. Although some empirical studies have provided evidence that the influence of the cross-border effect has been observed, little attention has been paid to the methods used to build the networks. Therefore, our study will draw scholars’ attention to this issue, especially for studies on transportation and urban structure.
As terms of the community structure, we found that the freight network has distinctly clustering features only at the county-level city-scale. Most communities’ spatial interactions obeyed the distance decay law, and in this study, the border of each community differed from the prefecture-level city administrative boundary. Meanwhile, regardless of whether or not the freight demand was distributed within a community or between different communities, it was unbalanced. Large numbers of freight flows were generated by units that were district centers or had a relatively high level of economic development. These findings could provide some guidance for promoting the balanced and sustainable development of urban spatial structures from the perspective of transportation planning. For example, features of the community boundaries and spatial interactions not only provide insight into improving the mobility of goods, which thereby improves freight operational efficiency, but also help validate existing urban and freight transportation management policies.
In addition, results of the sensitivity analysis illustrate that the key nodes (i.e., node with large freight volume) play a more important role in the intercity freight activities than the intracity freight activities. Regarding the transportation factor, the freight volume of is sensitive to transportation capacity and the freight volume of is sensitive to accessibility. These results can help provide a basis for regional freight transport planning. For example, in terms of Yunnan Province, the priority should be given to the optimization of intercity transportation network and the improvement of service capacity of related logistics facilities. With regard to intracity freight transport, there is an urgent need to improve the accessibility.
4.2. Implications
Based on our analytical results, this paper emphasizes the following implications.
First of all, regional freight transportation management must consider the impact of cross-border freight flows on freight network design. Our research observes that the influence of the cross-border freight flows on the freight network structure is unignored. From the space perspective, the freight network consists of nodes (i.e., administrative units) and spatial linkages (i.e., the spatial interactions), and its structure determines the strategic development direction of urban and regional freight transportation and logistics. Under the background of economic globalization and regional economic integration, the freight activities will more and more complex. Focusing on the cross-border freight flows in the guidance of freight transportation and urban space development is necessary, which will help to making a more effective and efficient planning or management policy, enabling the sustainability for freight transportation and urban development.
Secondly, for freight transport planning aligning with environmental objectives, the multidimensional perspective analytical approach of freight network is necessary. Many studies have proved that the improvement of transport efficiency is the benefit of the energy conservation and carbon emission mitigation [
5,
35]; however, what should be the priority and how to improve transport efficiency lack of effective approach and hamper by large regional disparities [
60]. In our research, we characterize freight transportation from multidimensional perspectives and identify the most influencing factors by sensitivity analysis, which is the basis for freight transport planning. For example, the results of sensitivity analysis show that Yunnan’s freight transportation depends highly on the minority key nodes. The priority is to improve the transport efficiency of these nodes in the premise of economic sustainability. By doing so, the freight transport emission will achieve reduction substantially more easily.
Finally, it is essential for China to consider the proper spatial layout of infrastructure and the related facilities. In recent years, growing flows of freight have been an important component of contemporary changes in economic systems at national, regional, and local scales, which contribute to national economic growth. In order to adapt to the increasingly freight flows, the government blindly planed a large number of logistics facilities. On the one hand, this has intensified the increasingly prominent contradiction of urban land use, and, on the other hand, it caused the waste of logistics resources. Recent surveys and studies have documented that the increasingly emissions are nature caused by the increased mileage and the poor transportation infrastructure and freight facility [
35]. In our study, we find that the different influencing factor in terms of transportation dimension determines the change of freight volume in different spatial scales. Moreover, several studies have examined that the transport infrastructure both has positive and negative effects on local freight transportation development. Therefore, there is an urgent need for the proper spatial layout of infrastructure and the related facilities so that they can offer quality service for freight transportation while ensuring a sustainable environment.
4.3. Research Limitations and Futuer Concerns
In the future, due to the acceleration of Chinese urbanization, the improvement in comprehensive transportation systems and growing transportation demand, the complexity of the freight network will also increase. Our research can provide some ideas for the precise description and exploration of transportation networks in such a context. However, it should be noted that although it is meaningful to analyze the characteristics and model by taking the transportation network of Yunnan Province as an example, the significance and value of the application still need more empirical support because of the dynamic relationship between transportation and urban development, as well as the evolution characteristics of the boundary and morphology of the freight network. Future research will focus on the dynamic evolution of freight transportation and will consider additional dimensions of the influence mechanism of urban structure.
In addition, some limitations of the freight vehicle trip data representativeness should be noted. First, freight vehicle trip data are only able to represent a part of freight activities occurred by Yunnan province. Some data, such as trip occurred by extraprovincial freight vehicle but traveled in Yunnan, is hardly obtained. Second, the freight vehicle trip data is only a sample data of 10 days, the freight activity information provided by them are only able to show freight transportation characteristics in a specific period of time. Recently, with the advancement of the information technology, truck GPS data are becoming more accessible. Truck GPS data is a more precis, objective, plentiful, and cost-effective data, which can provide an opportunity for depicting freight travels more effective; however, how to make full and reasonable use of this data and to reveal the freight transportation characteristics is still in the exploration stage. Future studies will consider combining freight vehicle trips with truck GPS data to characterize freight transportation characteristics and explore the spatial differentiation characteristics of freight characteristics by subdividing the data based on different time stages.