Next Article in Journal
Fintechs and Institutions: A Systematic Literature Review and Future Research Agenda
Next Article in Special Issue
Design of a Blockchain-Based Service Platform for Industrial Interconnection Supply and Demand Networks
Previous Article in Journal
Virtual Reality Experience of Mega Sports Events: A Technology Acceptance Study
Previous Article in Special Issue
Application of Benford’s Law on Cryptocurrencies
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
JTAER
Volume 17
Issue 2
10.3390/jtaer17020037
jtaer-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Synergistic Mechanism of the High-Quality Development of the Urban Digital Economy from Blockchain Adoption Perspective—A Configuration Approach

by
Ming Xia
1,2,
Zhimin Xie
3,
Hui Lin
2 and
Xiangwu He
1,*
1
Business School, Jiaxing University, Jiaxing 314001, China
2
School of Economics and Management, Tongji University, Shanghai 200092, China
3
School of Management, Nanjing University of Posts and Telecommunications, Nanjing 210003, China
*
Author to whom correspondence should be addressed.
J. Theor. Appl. Electron. Commer. Res. 2022, 17(2), 704-721; https://doi.org/10.3390/jtaer17020037
Submission received: 25 April 2022 / Revised: 14 May 2022 / Accepted: 23 May 2022 / Published: 26 May 2022
(This article belongs to the Special Issue Blockchain Commerce Ecosystem)
Browse Figure
Versions Notes

Abstract

:
Blockchain technology is suited to the high-quality development of the digital economy in addressing privacy and data security issues. This study explores the synergistic mechanism of the following six factors from three dimensions based on the Technology-Organization-Environment (TOE) framework theory with a fuzzy set qualitative comparative analysis (fs/QCA) method: technology, organization, and environment, namely, Blockchain service capability, Blockchain knowledge accumulation, government attention allocation, government funding support, industry carrying capacity and blockchain technology R&D environment, on the quality of the digital economy of 43 cities in China. The conclusions are as follows: (1) the absence of government funding regarding the blockchain domain is a condition contributing to the absence of high urban digital economy quality; (2) there are three driving configurations for the high-quality urban digital economy in the blockchain technology adoption perspective, which are as follows: knowledge-industry driven, government-service driven, and R&D-service driven; (3) there is one driving configuration for the absence of high urban digital economy quality, namely the knowledge-R&D-funding-inhibiting type. The relevant policy implications can provide theoretical references for local governments to develop the digital economy with the help of blockchain technology.

1. Introduction

In recent years, with the rapid development of digital technologies such as blockchain, cloud computing, big data, and artificial intelligence, as well as their deep integration with various industries, the digital economy has penetrated all aspects of economic and social development, becoming a new engine for future economic growth and a new path for industrial transformation [1]. In 2019, the Chinese government stated their aim to “focus on promoting high-quality development and vigorously develop the digital economy” as the basic task and to “take blockchain as a breakthrough in independent innovation of core technology and accelerate the development of blockchain technology and industrial innovation”, which sets the direction for the transformation of China’s economic growth model [2]. Considering the important role played by the digital economy in the transformation of dynamic energy, promoting economic growth, and demonstrating national competitiveness, improving the quality of the digital economy is becoming a focal point for achieving high-quality economic development [3,4]. However, as a new economic form with digital knowledge and information as the key production factors, data privacy, and data security have become key to the high-quality development of the digital economy [5]. Based on its decentralization, distributed storage, asymmetric encryption, smart contracts, peer-to-peer information transmission, traceability, and other characteristics, blockchain technology is suited to the digital economy in terms of solutions to privacy and data security issues and is becoming an important technical foundation for the development of the digital economy [6]. Therefore, it is of great practical significance to explore the synergy between blockchain technology and the high-quality development of the digital economy.
The digital economy, as of the next stage of techno-economic paradigm change, is an advanced economic form based on a new generation of information technology and oriented to the optimal allocation of resources, emphasizing the mutual relationship between technology and the economy [7]. From the technical perspective, most existing studies focus on the exploration of the mechanism of digital technology for promoting the high-quality development of the digital economy, including the study of the mechanism of the role of digital technology in promoting digital industrialization [8], industrial digitization [9], and digital governance [10]. For blockchain technology, existing research mostly focuses on the application of blockchain technology in digital financial services [11], digital financial regulation [12], food safety traceability [13], digital cryptocurrency [14], etc. It is widely believed that blockchain technology is essentially a distributed database system and a new generation of Internet protocols involving various nodes that can automatically track all digital actions thereby creating a decentralized database to verify identity and disrupt traditional governance models with lower cost and higher efficiency [15]. At the logical level of equipping blockchain technology to improve the quality of the digital economy, Zutshi (2021) argues that blockchain technology can strengthen the resource allocation potential of the digital economy [16]. Based on the theoretical analysis framework of “macro-meso-micro”, Kuang and Peng (2020) analyzed the theoretical logic of blockchain technology in promoting the development of the digital economy in terms of economic operation efficiency improvement, and industrial transformation and improvements, and enterprise business model innovation [17]. Relevant mechanistic research results lay the foundation for the application of blockchain technology in the digital economy.
However, from the perspective of the current analysis, the diffusion of innovation theory (DOI) shows that the diffusion of new technology undergoes three stages of “intention-adoption-programming” [18]. Previous studies related to blockchain technology mainly focus on the first stage (intention stage), and the few studies involving the perspective of blockchain technology adoption fail to address the issue of government attention and fund allocation in the process of blockchain technology adoption. Moreover, in terms of research methods, previous researchers mainly used traditional analysis methods, such as Wamba (2020), who empirically investigated the diffusion process of blockchain technology in supply chain management from the perspective of technology adoption using statistical regression [19].
Moreover, according to the theory of the Technology-Organization-Environment (TOE) framework, the adoption of blockchain technology is jointly influenced by multiple factors such as technology, organization, and environment, and different combinations of factors may produce the same results. It is necessary to systematically consider the synergistic effects of multiple factors in the process of blockchain technology adoption on the development of the digital economy. With regard to methods, traditional analysis methods focus on the net effect of a single factor and do not show good applicability in terms of exploring the synergistic effects of multiple factors, meaning that traditional analysis methods act in isolation or are only partially related and focus on a single causal relationship. The qualitative comparative analysis (QCA) method based on the configurational perspective can help to overcome the limitations of traditional methods by using set theory and Boolean operations to uncover the “configurational effects” of multiple factors and to explore the different ways to achieve the same effect and the relationship between each path.
In summary, based on the TOE framework theory, this study further extends its application in analyzing the combination of multiple factor relationships and reveals the complex mechanism of multiple factors linking to influence output. We propose an integrated analytical framework for analyzing the impact of blockchain technology adoption on the high-quality development of the urban digital economy from the perspective of blockchain technology adoption and introduce configuration thinking into the study of digital economy quality at the city level. This study takes 43 representative cities in China as samples and applies the fuzzy set qualitative comparative analysis (fs/QCA) method to extend the application area of the QCA method by analyzing the relationship between the set of elements involved in blockchain technology adoption at the technical, organizational and environmental levels in the studied cities and the set of digital economy quality, and uncovering the complex causal mechanism of multiple factors concurrently affecting the high-quality development of the urban digital economy. The key questions to be addressed in this study are as follows: which paths in the blockchain technology adoption process can lead to the generation of a high urban digital economy quality? Which paths in the blockchain adoption process inhibit the generation of a high digital urban economy quality? Do the necessary conditions exist for blockchain technology adoption to lead to a high urban digital economy quality?
The remainder of the paper is organized as follows. Section 2 provides a brief theoretical analysis. Section 3 briefly describes the research methods and data sources used in this study. Section 4 presents the empirical results and discussion. Section 5 reports some conclusions and provides further policy implications.

2. Theory

2.1. TOE Framework Theory

The TOE framework theory, first proposed by Tornatizky and Fleischer (1990) [20], is an extension of the theory of diffusion of innovation (DOI). It is essentially a comprehensive analytical framework based on technology application contexts and has been applied to many fields such as e-government, e-commerce, green technology, supply chain resilience, knowledge management diffusion, and organizational management [21]. Specifically, the TOE framework theory classifies the conditions that affect the application of technology into the following three categories: technical, organizational, and environmental conditions [22]. Technology conditions refer to the characteristics of the technology itself and its relationship to the organization, and focuses on whether the technology matches the structural characteristics of the organization, whether it is compatible with the organization’s application capabilities, and whether it can bring potential benefits to the organization [23]. The impact of organizational conditions on technology adoption has also received extensive attention in empirical studies, which include many aspects such as the organizational size, the scope of operations, formal/informal institutional arrangements, communication mechanisms, and idle resources for standby savings [24]. Environmental conditions include aspects such as the market structure in which the organization is located and the regulatory policies of external governments [25].

2.2. Conceptional Model

The TOE framework has excellent applicability as it can be adapted to improve the effectiveness of the model according to the characteristics of the research area and the research object [26]. Moreover, the three dimensions of the TOE framework do not work independently, and the conditions of the three dimensions work together in some kind of linkage matching mode in specific scenarios. Based on this, this paper constructs a debugged and expanded TOE framework, combining the institutional context of the Chinese government and the specific practice scenarios of urban digital economy development, as shown in Figure 1.

2.2.1. Technology Conditions

Technology conditions concern whether the available technology matches the organization’s structure, whether it is coordinated with the organization’s application capabilities, and whether it increases the potential benefits to the organization [25]. According to the characteristics of blockchain technology itself and the specific problems faced in the development of the urban digital economy, the technical conditions specifically include two secondary indicators: blockchain service capability and blockchain knowledge accumulation.
In the interaction between technology and organizations, the adoption of technology affects the efficiency of management decisions and the operational management efficiency of the organization [27]. At the macro level, the adoption of blockchain technology can improve the operational efficiency of the urban digital economy by improving the information of market players, correcting market failures, regulating price discrimination and curbing market speculation with the help of a decentralized bookkeeping scheme [17]. At the mesoscopic level, it relies on the technical characteristics of distributed, tamper-proof, complete traceability, open programming and common maintenance to empower agriculture, manufacturing and traditional service industries to promote the transformation and upgrading of traditional industries, form a network system of shared credit governance with the characteristics of encrypted transactions and accelerate the process of rationalizing the structure of the financial industry [27,28]. At the micro-level, it promotes the flattening of enterprise organization, optimization of the enterprise management model, and innovation of the enterprise profit model to drive the digital transformation and upgrading of enterprises through value interconnection and other features [17,29]. It can be seen that the stronger the blockchain-service capability, in principle, the more significant the promotion of the urban digital economy will be.

2.2.2. Organization Conditions

Technology can recreate organizations, but it can also be influenced by the organization [25,30]. Organizational factors focus on whether the organization can choose an innovation strategy suitable for its development according to its characteristics. Researchers usually explore the factors affecting the application of technological innovation at the organizational and managerial levels, including the resource capacity of the organization, and the degree of centralization of the structure [31,32]. The finite rational decision theory suggests that the allocation of governmental attention to issues determines the choice of governmental behavior, and there is a logic of “governmental attention—governmental behavior choice” [33]. In this study, according to the degree of local government support for blockchain development and the strength of that support, the organizational conditions specifically include the following two secondary indicators: government attention allocation and government funding support. Combined with the Chinese context, the government’s attention allocation to blockchain technology plays a facilitating role in the development of the digital economy through the corresponding institutional arrangements and policy support [25]. Moreover, blockchain technology as an emerging digital technology has a large capital demand from technology research and development to technology marketization, and the government’s provision of funding support is crucial to the development of blockchain technology [34].

2.2.3. Environment Conditions

The influence of environmental factors on technology adoption is usually expressed as pressure or motivation [21], and specifically includes the following two secondary indicators: industry carrying capacity and technology R&D environment. For the blockchain industry, the city’s industrial carrying capacity essentially refers to the maximum industrial scale that the city can effectively support in its current state, which not only demonstrates where the city currently is in the industrial development process, but also represents the city’s current level of blockchain industrial development and its pressure due to industrial development [35,36]. As one of the basic technologies of the digital economy, blockchain technology plays a core supporting role in promoting the digital transformation of traditional industries and creating new industries and new business models through its characteristics of permeability, substitutability, and synergy [37]. Technology R&D is regarded as a major factor in the formation and accumulation of technological capabilities, and a major determinant of competitive advantage in high-tech industries [38]. As the forefront of the entire digital economy value chain, the technology R&D environment provides a solid foundation for blockchain technology innovation, which in turn promotes the formation and development of the digital economy.
In summary, the study of the impact of a single factor on the quality of the digital economy provides a basis for the selection of conditions for this study and a theoretical guide for discussing the quality development of the digital economy at the city level within the TOE framework. However, related studies have not revealed the complex interactions among the elements and their synergistic effects on the quality of the digital economy. The configuration approach focuses on the synergistic effects of multiple system elements on output and aims to uncover complex causal relationships such as asymmetry and equivalence between elements and output [39], which is suitable for analyzing the synergistic effects of technological, organizational, and environmental elements on the quality of the urban digital economy from the perspective of blockchain technology adoption. Based on this aim, this study introduces the QCA approach using the TOE framework to explore the complex causal mechanism of blockchain technology adoption affecting the high-quality urban development of the digital economy in China, for which the theoretical model is shown in Figure 1. That is, the way the six factors of blockchain service capability, blockchain knowledge accumulation, government attention allocation, government funding support, industry carrying capacity construction, and technology R&D environment synergistically link together to influence the quality of the urban digital economy in China.

3. Materials and Methods

3.1. QCA

Qualitative comparative analysis (QCA) is an ensemble analysis approach that aims to deconstruct the problem of causal complexity, using cases as causal conditions and focusing on the complex causal relationships between conditional configurations and outcomes, which considers that the factors influencing a given outcome are not independent but mostly interdependent [40,41,42]. On the one hand, the multidimensional and holistic characteristics of QCA expand the isolated perspective of the traditional quantitative regression analysis and provide a more ideal way to analyze the complex causality of interdependence among variables and their configurations affecting the results [43]. On the other hand, QCA can better answer the question of the asymmetry of causality, i.e., it answers the question that the causes that produce high and non-high quality are not the same [44].
The QCA method integrates the respective strengths of qualitative and quantitative analyses and is suitable for both small sample studies of up to 10 or 15 and large sample studies of 100 or more, as well as medium-sized sample studies of 10 or 15 to 50 [45]. Based on the case sample data of 43 cities in mainland China, this study explored the configuration influence and complex causality of blockchain service capability, blockchain technology knowledge reserve, government attention allocation, government funding support, industry carrying capacity, and the technology R&D environment in the high-quality development of the urban digital economy from the following three dimensions: technology, organization, and environment. The sample of 43 cases in this study is a medium-sized sample, which allows us to explore both the depth and uniqueness of the cases and the external validity. For medium-sized samples, the ideal number of conditional variables is generally between four and seven [41]; therefore, this study determined that six conditional variables met the requirements. Considering that the fuzzy set QCA (fs/QCA) is more suitable for dealing with contact variables, fs/QCA was used for the analysis in this study.

3.2. Sample and Data Collection

During the case collection process, cities that were listed in both the top 50 Chinese cities in terms of blockchain development level and the top 100 Chinese cities in terms of digital economy development in 2018 were selected. Combined with the administrative regions of China, this study covers all provincial administrative regions in mainland China as extensively as possible. The selected cases are all prefecture-level cities and can reflect the quality of the digital economy, meeting the homogeneity requirement of case selection. Moreover, from the geographical scope, this study covers 30 provincial-level administrative regions in mainland China, meaning that the condition and outcome variables of the case cities are more heterogeneous, thereby meeting the diversity requirement of case selection, and the finalized research sample contains 43 case cities as shown in Table 1. The descriptions of condition and outcome variables, data sources, and descriptive statistical analysis are detailed in Table 2.

3.3. Variables

3.3.1. Digital Economy Quality

Within the existing literature [46], the index is a frequently used indicator to measure the level of development of regional digital economy. The European Commission (2020) measures the level of digital economy development in EU countries in four dimensions, namely Connectivity, Human Capital, Use of Internet Services, and the Integration of Digital Technology to form the IDESI (International Digital Economy and Society Index) index [46]. The CAICT (2020) measures the digital economy development of selected Chinese cities in the following four dimensions: data and information technology infrastructure, urban services, urban governance, and industrial integration [2]. From the perspective of simplifying the research design and improving data precision, this study adopts the digital economy index data of sample cities in the 2019 China City Digital Economy Index White Paper to reflect the quality of the urban digital economy.

3.3.2. Blockchain Service Capability

The continuous development of blockchain technology services forms effective support for the digital economy. Following the literature [47], the blockchain service capability of each city was measured in terms of the number of blockchain information services in each city.

3.3.3. Blockchain Knowledge Accumulation

As a kind of knowledge resource, technical knowledge accumulation is the concentration of technology attached to enterprise products [48]. The patent is an important manifestation of technical knowledge accumulation, and existing studies usually use the number of patent applications to reflect the level of technical knowledge accumulation in a region. In line with the literature [49], this study adopts a number of blockchain-related patent applications to measure the level of blockchain technical knowledge accumulation in cities.

3.3.4. Government Attention Allocation

Local governments in China implement the central government’s policy guidelines by issuing local implementations in line with the central government’s guiding documents [50]. Scholars often use the time interval between policy implementation as a measure of government attention allocation. By referencing the literature [25], and drawing on the idea of clear sets, the allocation of each local government’s attention to the development of blockchain technology was measured depending on whether each local government introduced institutional arrangements for blockchain technology within six months thereafter using 28 May 2018, the date of the speech disseminated by Chinese leaders proposing the development of blockchain technology, as the starting point in time.

3.3.5. Government Funding Support

As an important carrier combining the role of government and market mechanisms, the government industrial fund is an important policy tool used to increase the supply of venture capital and industrial investment capital and to guide social capital to invest in key areas and weak links of industry [51]. Government special industrial funds have a significant positive impact on the development of high-tech industries. Guided by the literature [52,53], the scale of government blockchain industrial funds in each region was adopted as an indicator to measure government funding support.

3.3.6. Industrial Carrying Capacity

The differences in geographic characteristics and industrial development logic have caused differences in regional industrial structures and affected the industrial carrying capacity of specific industries [36]. The degree of agglomeration of an industry can reflect the strength of the regional industrial carrying capacity [54]. The geographical agglomeration represented by industrial parks highly fits the development concept of industrial agglomeration. Following the literature [55], this study selected a number of blockchain industrial parks to measure the carrying of the blockchain industry in each region.

3.3.7. Technological R&D Environment

Technological innovation is an important source of the core competitiveness of enterprises [56]. The R&D institutions of enterprises, research institutes, and universities, as the main body of technology R&D and innovation, are an important part of the technology R&D environment; therefore, the number of research institutions influences the regional technology R&D environment to a certain extent. As an emerging digital technology, the specific form and embedding process of blockchain technology embedded into the digital economy is in continuous development, which requires theoretical and technical support from blockchain R&D institutions. Therefore, following the literature, this study adopted a number of blockchain R&D institutions to assess the strengths and weaknesses of the blockchain technology R&D environment [57].

3.4. Coding Cases’ Set Memberships

As an ensemble analysis method, The QCA method reveals the causal complexity of social phenomena by exploring the ensemble relationships between conditions and outcomes [58]. In the set methodology, converting raw data into set membership scores is a necessary step for set analysis and operations, and the process of assigning membership scores to cases and conditions is known as variable calibration; however, uncalibrated data are uninterpretable and unrealistic [39]. Ragin (2008) argues that the specific locations of the three qualitative anchors should be determined based on theoretical knowledge and empirical evidence, and because of the lack of actionable theoretical and empirical guidance in the social sciences [42], the data were based on the cases themselves, which were calibrated using a direct calibration method to convert the data into fuzzy set membership scores, considering that the case cities in this study are relatively representative.
Specifically, (1) we adopted clear set calibration for government attention allocation, government funding support, industry carrying capacity, and the technology R&D environment, i.e., assigning a value of 1 to cities that have released blockchain industry support policies within six months, otherwise, assigning a value of 0; assigning a value of 1 to case cities that have set up blockchain industry funds, otherwise, assigning a value of 0; assigning a value of 1 to case cities that are planning blockchain industry parks, otherwise assigning a value of 0. Case cities that have set up special blockchain technology research institutions are assigned a value of 1, otherwise, it they are assigned a value of 0. (2) We adopted fuzzy set calibration for Blockchain service capability, Blockchain knowledge accumulation, and digital economy quality, and the three anchor points were set to the 75% quantile (fully affiliated), 50% quantile (intersection), and 25% quantile (fully unaffiliated) of the sample data [42]. The calibration information of the results and condition variables in this study are shown in Table 3.

4. Results and Discussion

4.1. Necessity Analysis

When a factor outcome is always accompanied by a condition, such a condition is considered necessary for the outcome [39]. Consistency reflects the extent to which cases of the same condition configuration are subordinated to the same outcome and is an important measure of whether the condition is necessary. Following the literature [55], this study set the necessary condition consistency threshold at 0.9 and used the fsQCA3.0 software to conduct the necessary condition analysis for high digital economy quality and the absence of high digital economy quality, respectively. The results for this are shown in Table 4. For a high digital economy quality, none of the individual condition variables had a consistency level of higher than 0.9, so none of them constituted a necessary condition. For the absence of high digital economy quality, the consistency level for the absence of government funding support was 0.94, which constituted a necessary condition for the absence of high digital economy quality, indicating that lack of government funding support was a necessary condition leading to the creation of the absence of a high urban digital economy quality.

4.2. Configurations Sufficient for the High-Quality Digital Economy

A sufficiency analysis is used to identify the possible configurations consisting of multiple factors that lead to the focal outcomes. Following previous studies, this study set the consistency threshold for configuration analysis at 0.8 [59], the PRI consistency threshold at 0.7 [55], and the frequency threshold at 1 [60]. For the three solutions (complex, parsimonious, and intermediate) output by the fs/QCA3.0 software, following the method of previous studies [60], this study used the intermediate solution as the first solution and the parsimonious solution as the second solution in the reporting process. The results of the configuration analysis of the six factors are shown in Table 5, revealing the existence of three configurations that can lead to a high-quality urban digital economy (HQ1a, HQ1b, HQ1c, HQ1d, HQ2, HQ3).
Configuration HQ1 represents the knowledge-industry-driven path, which means that greater blockchain technology patents accumulation and a stronger blockchain industry carrying capacity can promote the generation of a high-quality urban digital economy. The configuration reflects the synergistic linkage of blockchain knowledge accumulation and the blockchain industry carrying capacity to drive the high-quality development of the urban digital economy. A technology patent is the basic guarantee to protect and stimulate innovation, and also an important bridge to transform innovation results into real productivity [56]. A higher accumulation degree of blockchain technology patents reflects a higher level of blockchain technology innovation in the city, and the high technology innovation ability further accelerates the transformation and upgrading of the regional blockchain industry, while the greater the construction of the blockchain industry carrying capacity, the stronger its ability to undertake the transformation and upgrading of blockchain industry, and the coupling effect of technology knowledge accumulation and industry carrying capacity construction promotes the generation of high-quality urban digital economies [61]. The typical city under this configuration is Shanghai. Shanghai, as the leader of blockchain development in China, has accomplished a high level of blockchain knowledge accumulation and strong blockchain technology innovation capabilities through layout in blockchain technology patents and has further consolidated blockchain technology innovation by planning blockchain industrial parks and innovation bases, while carrying blockchain industries, to realize the beneficial cycle of blockchain technology in helping digital economy development and promoting the generation of the high-quality urban digital economy.
Configuration HQ2 represents the government-service-driven path, which means that a higher government focus with a higher level of blockchain service capability can facilitate the generation of a high-quality urban digital economy. The configuration reflects the synergistic linkage of government attention allocation and blockchain technology service capabilities in driving the high-quality development of the urban digital economy. According to the behavior logic of “government attention—government behavior choice” [33], the high level of attention of local governments to blockchain technology and industry means blockchain technology is more closely connected with digital finance, digital government, digital healthcare, and other fields and leads to the deep integration of blockchain technology with various industries. This integration will facilitate the digital transformation of blockchain technology in traditional industries and promote the quality of the urban digital economy. The representative city under this configuration is Suzhou. The local government of Suzhou encourages information technology service enterprises represented by blockchain technology to become stronger and better, supports enterprises to develop markets, promotes industrial optimization and upgrading, and actively plays a guiding role in terms of financial funds to promote the high-quality development of the digital economy based on the software industry.
Configuration HQ3 represents the technology-R&D-driven path, which means that a better blockchain technology R&D environment and higher blockchain service capability can promote the development of the high-quality urban digital economy. The configuration reflects the synergistic linkage of the blockchain technology R&D environment and blockchain service capability to promote the high-quality development of the urban digital economy. Digital technology R&D is an important driving force of the digital economy, and as a fundamental digital technology, the strength of the blockchain technology R&D environment determines the level of development of blockchain technology in the region to a certain extent [62]. Meanwhile, all digital technologies are at a certain stage in the cycle of “R&D-application-marketing-R&D iteration”, and the technology service capability provides an assessment of the marketability of the technology [63]. The excellent technology R&D environment promotes the development of blockchain technology. The higher blockchain service capability facilitates the marketization of blockchain technology, and the synergy between the blockchain technology R&D environment and technology service capability leads to the high-quality development of the urban digital economy. The representative city under this configuration is Tianjin. The local government of Tianjin supports universities and research institutes to carry out blockchain technology research and innovation and supports universities to build blockchain research and innovation platforms and research talent teams, creating a favorable R&D environment for blockchain technology research. Moreover, Tianjin seizes the opportunity of “One Belt, One Road” development, encourages enterprises to apply blockchain technology to more scenarios, rapidly builds blockchain application ecology, forms relevant application standards, expands business fields, and promotes the continuous and rapid development of enterprises, all of which represent strong Blockchain service capability.

4.3. Configurations Sufficient for the Absence of High-Quality Urban Digital Economy

Considering the causal asymmetry of the QCA approach (the conditions leading to the emergence and absence of outcomes are asymmetric), and to gain a comprehensive understanding of the mechanisms driving urban digital economy quality, this study then analyzed the configurations that lead to the absence of a high-quality urban digital economy. Following the literature [60], the calibration rule for the absence of a high digital economy quality is the opposite of high digital economy quality, i.e., the non-set of high digital economy quality is used. The results of the adequacy analysis of the absence of a high digital economy quality are detailed in Table 6, and one driving path of the absence of high urban digital economy quality (configuration AHQ1a, AHQ1b) is found by combining the core conditions of the six configurations.
The configurations AHQ1a and AHQ1b represent the knowledge-R&D-funding inhibitory path, which means that weaker blockchain knowledge accumulation, poorer blockchain technology R&D environment, and less government funding support inhibit the generation of the high-quality urban digital economy. The insufficient accumulation of blockchain technology knowledge leads to a lack of motivation for blockchain technology innovation, which, coupled with a poor technology R&D environment, further weakens the city’s blockchain technology innovation capability [48]. In addition, the failure of the government to establish a special blockchain industry fund to guide technological innovation has led to a serious lack of incentive for blockchain technological innovation and investment, thus inhibiting the generation of a high urban digital economy quality. A typical case under this driving path is Changchun, as Changchun has very few blockchain technology patent applications and lacks blockchain R&D institutions and government-led blockchain industry funds, resulting in a poorer level of blockchain technology innovation and industry development, inhibiting the generation of a high digital economy quality.
In addition, in terms of the influence of geographical characteristics on regional industrial development, Shanghai and Suzhou are located in the Yangtze River Delta city cluster, with a strong manufacturing base and deep accumulation in the new-generation information technology industry represented by blockchain, and their digital industry competitiveness is leading in China, which also contributes to the formation of a high-quality urban digital economy. Tianjin is located within the BeijingTianjin-Hebei metropolitan area and is an important port city in North China. While catering for the technology spillover from Beijing, Tianjin promoted the high-quality development of the digital economy by developing the ICT industry with the platform of Northern Big Data Exchange. Changchun is a non-high-quality representative case city located in the heavy industrial zone of Northeast China, which lacks the foundation for digital economy development, contributing to the predicament of the digital economy. Thus, it can be seen that geographical characteristics influence the development of the regional digital economy by affecting the regional industrial structure.

4.4. Robustness Test

We conducted two additional analyses to assess the robustness of the results. First, we re-performed the analysis with a higher consistency threshold of 0.85 [64]. In terms of the number of specific solutions, we observed slight changes, but the interpretation of the results remained unchanged. The results, overall, remained unchanged (see the footnote in Table 7 for a more detailed explanation). Second, we recalibrated with the 55th percentile of all conditions (blockchain service capability, blockchain knowledge accumulation, government attention allocation, government funding support, technology R&D environment, and technology carrying capacity) and outcomes (digital economy quality) as alternative intersections [65]. Again, the generated solutions remain similar, as do the interpretations of the results. The interpretation of the results, therefore, still holds (Table 8).

5. Conclusions and Future Work

5.1. Conclusions

This study explored the synergistic influence mechanism of six factors from three dimensions based on the TOE framework theory with the fuzzy set QCA method: technology, organization, and environment, namely, blockchain service capability, blockchain knowledge accumulation, government attention allocation, government funding support, the industry carrying capacity and blockchain technology R&D environment, on the quality of the urban digital economy. The main findings are as follows: (1) the absence of government funding support is a necessary condition for the absence of high urban digital economy quality, indicating that weaker government funding support has stronger explanatory power for the absence of high urban digital economy quality; (2) there are three configurations for high urban digital economy quality, which are as follows: the knowledge-industry-driven path with sufficient blockchain knowledge accumulation and perfect industrial carrying capacity construction; the government-service-driven path with sufficient government attention and strong technical service capability; and the R&D-service-driven path with good blockchain technology R&D environment and strong technical service capability; (3) there is one configuration of the absence of high urban digital economy quality, namely the knowledge-R&D-funding inhibiting path that consists of a lower blockchain technology knowledge reserve, poorer blockchain technology R&D environment, and less government funding support.

5.2. Contributions

(1)
This study enriched the theories related to digital economy quality and proposed a comprehensive analytical framework for the urban digital economy quality from the perspective of blockchain technology adoption. Compared with existing studies that focus on single-level causality [19], this study incorporated multiple factors into the same analytical framework and proposed an integrative analytical framework under the perspective of blockchain technology adoption, which lays a theoretical foundation for multiple factors to synergistically affect the urban digital economy quality.
(2)
This study extended the applicability of the TOE framework theory through a configurational perspective and extended its application to explain the complexity of causal relationships. Previous studies on the TOE framework theory have been less concerned with the configurational effects between multiple factors [22]. This study empirically discussed the synergistic effects of six elements affecting the quality of the urban digital economy in three dimensions as emphasized by the TOE framework theory, with the help of the configuration perspective, extending the scope of application of the TOE framework theory to a certain extent.
(3)
This study extends the applicability of the QCA approach to the study of digital economy quality at the city level and deepens the understanding of the complex causal mechanisms by which multiple factors influence the quality of the urban digital economy. At present, the QCA approach in digital economy research is mostly limited to the enterprise level [60], but this study extended the QCA approach to the city level, which not only identified the equivalent driving paths of high digital economy quality, but also explored the driving mechanisms of the absence of high digital economy quality from the perspective of causal asymmetry, and also broadened the application area of the QCA approach.

5.3. Implications

The findings of this study provide two policy implications for local governments to promote the high-quality development of the digital economy with the help of blockchain technology.
On the one hand, the government should combine the regional resource endowment and focus on the development of key core elements. The impact of blockchain technology adoption on the quality of the urban digital economy is influenced by the synergistic effects of various factors such as blockchain technology technical service capability, blockchain knowledge accumulation, government attention allocation, government funding support, industry carrying capacity, and the technology R&D environment. Moreover, there exist multiple paths for blockchain technology adoption to improve the quality of the urban high digital economy. Therefore, in the process of promoting digital economy development, the government should reasonably consider differences in regional resource endowments, combine the region’s advantages, choose the driving paths that adapt to local development endowments, use configuration thinking to formulate targeted education, finance, industry, and public policies, take advantage of policy combinations, concentrate strong regional resources and develop key core elements.
On the other hand, the government should strengthen the available financial support for the blockchain industry. The absence of government funding support for the blockchain industry is a necessary condition that leads to the absence of high urban digital economy quality, indicating that the absence of government funding support for the blockchain industry inevitably leads to the absence of a high urban digital economy quality. Therefore, in terms of increasing the source of funds, the government should strengthen the financial support for the blockchain industry in various ways, such as by establishing a special fund for the blockchain industry, providing subsidies for blockchain technology innovation, and formulating tax incentives for the blockchain industry. In terms of reducing the cost of enterprises, the government should encourage the use of the technical license of national research institutions and the production support role of state-owned enterprises to reduce the cost of enterprises so as to mitigate the absence of a high digital economy quality.

5.4. Limitations and Future Work

There are some limitations in this study that need to be improved in future research. First, although this study analyzed the synergistic influence mechanism of blockchain technology service capacity, Blockchain knowledge accumulation, government attention allocation, government funding support, blockchain industry carrying capacity construction, and the blockchain technology R&D environment on the high-quality development of the urban digital economy from the perspective of blockchain technology adoption based on the TOE framework theory, the urban digital economy as a complex system is also influenced by factors such as blockchain technology management capacity, citizens’ external demand and technology imitation in the process of blockchain technology adoption. Second, the empirical analysis of this study mainly explored the cross-sectional data among the 43 cases and did not consider the longitudinal data on the evolution of the sample over time. Subsequent studies can be conducted on the time vertical dimension for typical cases to examine the dynamic trends of the high-quality development of the urban digital economy over time. Third, in this study, in terms of variable measurement, the specific data were not precisely characterized for each variable due to the limitation of data availability, and follow-up studies should further strengthen the data integrity to improve the comprehensive and in-depth analysis of the impact mechanism on the high-quality development of the urban digital economy.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/jtaer17020037/s1.

Author Contributions

Conceptualization, M.X. and X.H.; methodology, M.X.; software, Z.X.; validation, M.X., X.H. and H.L.; formal analysis, M.X.; investigation, M.X.; resources, H.L.; data curation, Z.X.; writing—original draft preparation, M.X.; writing—review and editing, X.H.; visualization, Z.X.; supervision, X.H.; project administration, M.X.; funding acquisition, Z.X. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the National Social Science Foundation of China, grant number 19BGL047.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

The data presented in this study are provided in the Supplementary Materials.

Acknowledgments

We express our most sincere gratitude to the editors and reviewers for their careful review of this study.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Li, Z.; Li, N.; Wen, H. Digital Economy and Environmental Quality: Evidence from 217 Cities in China. Sustainability 2021, 13, 8058. [Google Scholar] [CrossRef]
  2. CAICT. White Book on New Prospect of Global Digital Economy. Available online: http://www.caict.ac.cn/kxyj/qwfb/bps/202007/P020200703318256637020.pdf (accessed on 15 March 2022).
  3. Li, Z.; Liu, Y. Research on the Spatial Distribution Pattern and Influencing Factors of Digital Economy Development in China. IEEE Access 2021, 9, 63094–63106. [Google Scholar] [CrossRef]
  4. Chen, Y. Improving market performance in the digital economy. China Econ. Rev. 2020, 62, 101482. [Google Scholar] [CrossRef]
  5. Amuso, V.; Poletti, G.; Montibello, D. The Digital Economy: Opportunities and Challenges. Glob. Policy 2019, 11, 124–127. [Google Scholar] [CrossRef]
  6. Calvão, F.; Archer, M. Digital extraction: Blockchain traceability in mineral supply chains. Political Geogr. 2021, 87, 102381. [Google Scholar] [CrossRef]
  7. Miao, Z. Digital economy value chain: Concept, model structure, and mechanism. Appl. Econ. 2021, 53, 4342–4357. [Google Scholar] [CrossRef]
  8. Ellström, D.; Holtström, J.; Berg, E.; Josefsson, C. Dynamic capabilities for digital transformation. J. Strategy Manag. 2021, 15, 272–286. [Google Scholar] [CrossRef]
  9. Kunkel, S.; Tyfield, D. Digitalisation, sustainable industrialisation and digital rebound—Asking the right questions for a strategic research agenda. Energy Res. Soc. Sci. 2021, 82, 102295. [Google Scholar] [CrossRef]
  10. Niu, F. The Role of the Digital Economy in Rebuilding and Maintaining Social Governance Mechanisms. Front. Public Health 2021, 9, 819727. [Google Scholar] [CrossRef]
  11. Larios-Hernández, G.J. Blockchain entrepreneurship opportunity in the practices of the unbanked. Bus. Horiz. 2017, 60, 865–874. [Google Scholar] [CrossRef]
  12. Gurinovich, A.G.; Lapina, M.A.; Tolstopyatenko, G.P.; Patrikeev, P.A. About Approaches to the Definition of Concept and Problems of Legal Regulation of Digital Financial Assets. Public Organ. Rev. 2021, 296, 1–20. [Google Scholar] [CrossRef]
  13. Feng, H.; Wang, X.; Duan, Y.; Zhang, J.; Zhang, X. Applying blockchain technology to improve agri-food traceability: A review of development methods, benefits and challenges. J. Clean. Prod. 2020, 260, 121031. [Google Scholar] [CrossRef]
  14. Longo, R.; Podda, A.S.; Saia, R. Analysis of a Consensus Protocol for Extending Consistent Subchains on the Bitcoin Blockchain. Computation 2020, 8, 67. [Google Scholar] [CrossRef]
  15. Yli-Huumo, J.; Ko, D.; Choi, S.; Park, S.; Smolander, K. Where Is Current Research on Blockchain Technology? A Systematic Review. PLoS ONE 2016, 11, e0163477. [Google Scholar] [CrossRef] [PubMed]
  16. Zutshi, A.; Grilo, A.; Nodehi, T. The value proposition of blockchain technologies and its impact on Digital Platforms. Comput. Ind. Eng. 2021, 155, 107187. [Google Scholar] [CrossRef]
  17. Kuang, J.; Peng, W. Blockchain Technology Drives the Development of Digital Economy:Theoretical Logic and Strategic Orientation. Soc. Sci. 2020, 9, 64–72. [Google Scholar] [CrossRef]
  18. Wonglimpiyarat, J.; Yuberk, N. In support of innovation management and Roger’s Innovation Diffusion theory. Gov. Inf. Q. 2005, 22, 411–422. [Google Scholar] [CrossRef]
  19. Wamba, S.F.; Queiroz, M.M. Industry 4.0 and the supply chain digitalisation: A blockchain diffusion perspective. Prod. Plan. Control 2020, 33, 193–210. [Google Scholar] [CrossRef]
  20. Tornatzky, L.G.; Fleischer, M. The Processes of Technological Innovation; Lexington Books: Lexington, KY, USA, 1990; pp. 15–20. [Google Scholar]
  21. Zhao, Y.; Wang, L.; Feng, T.; Zhang, X. A research on the differentiated paths adopted by governments for resumption of work and production in the context of COVID-19. Sci. Res. Manag. 2021, 42, 191–200. [Google Scholar] [CrossRef]
  22. Toufaily, E.; Zalan, T.; Dhaou, S.B. A framework of blockchain technology adoption: An investigation of challenges and expected value. Inf. Manag. 2021, 58, 103444. [Google Scholar] [CrossRef]
  23. Chau, P.; Tam, K. Factors affecting the adoption of open systems: An exploratory study. MIS Q. 1997, 21, 1–24. [Google Scholar] [CrossRef]
  24. Walker, R.M. Internal and External Antecedents of Process Innovation: A review and extension. Public Manag. Rev. 2013, 16, 21–44. [Google Scholar] [CrossRef]
  25. Tan, H.; Fan, Z.; Du, Y. Technology Management Capability, Attention Allocation, and Local Government Website Development—A TOE Framework-based Histogram Analysis. Manag. World 2019, 35, 81–94. [Google Scholar] [CrossRef]
  26. Wang, Y.-S.; Li, H.-T.; Li, C.-R.; Zhang, D.-Z. Factors affecting hotels’ adoption of mobile reservation systems: A technology-organization-environment framework. Tour. Manag. 2016, 53, 163–172. [Google Scholar] [CrossRef]
  27. Asare, A.K.; Brashear-Alejandro, T.G.; Kang, J. B2B technology adoption in customer driven supply chains. J. Bus. Ind. Mark. 2016, 31, 1–12. [Google Scholar] [CrossRef]
  28. Kwok, A.O.J.; Koh, S.G.M. Is blockchain technology a watershed for tourism development? Curr. Issues Tour. 2018, 22, 2447–2452. [Google Scholar] [CrossRef]
  29. Pan, X.; Pan, X.; Song, M.; Ai, B.; Ming, Y. Blockchain technology and enterprise operational capabilities: An empirical test. Int. J. Inf. Manag. 2020, 52, 101946. [Google Scholar] [CrossRef]
  30. Ghaleb, E.A.A.; Dominic, P.D.D.; Fati, S.M.; Muneer, A.; Ali, R.F. The Assessment of Big Data Adoption Readiness with a Technology–Organization–Environment Framework: A Perspective towards Healthcare Employees. Sustainability 2021, 13, 8379. [Google Scholar] [CrossRef]
  31. Abed, S.S. Social commerce adoption using TOE framework: An empirical investigation of Saudi Arabian SMEs. Int. J. Inf. Manag. 2020, 53, 102118. [Google Scholar] [CrossRef]
  32. Li, J.P.; Chen, R.; Lee, J.; Rao, H.R. A case study of private–public collaboration for humanitarian free and open source disaster management software deployment. Decis. Support Syst. 2013, 55, 1–11. [Google Scholar] [CrossRef]
  33. Blackmond Laskey, K.; D’Ambrosio, B.; Levitt, T.; Mahoney, S. Limited rationality in action: Decision support for military situation assessment. Minds Mach. 2000, 10, 53–77. [Google Scholar] [CrossRef]
  34. Zhang, Y.; Wang, Z.; Deng, J.; Gong, Z.; Flood, I.; Wang, Y. Framework for a Blockchain-Based Infrastructure Project Financing System. IEEE Access 2021, 9, 141555–141570. [Google Scholar] [CrossRef]
  35. Jiang, D.; Chen, Z.; Dai, G. Evaluation of the carrying capacity of marine industrial parks: A case study in China. Mar. Policy 2017, 77, 111–119. [Google Scholar] [CrossRef]
  36. Zhou, J.; Huang, X. Research on Evalution Method and Measurement of Urban Industrial Carrying Capacity in China. Hebei Acad. J. 2018, 38, 136–142. [Google Scholar]
  37. Khan, U.; An, Z.Y.; Imran, A. A Blockchain Ethereum Technology-Enabled Digital Content: Development of Trading and Sharing Economy Data. IEEE Access 2020, 8, 217045–217056. [Google Scholar] [CrossRef]
  38. Beladi, H.; Mukherjee, A. R&D competition and the persistence of technology leadership. Int. J. Econ. Theory 2020, 7, 1–13. [Google Scholar] [CrossRef]
  39. Du, Y.; Jia, L. Configuration Perspective and Qualitative Comparative Analysis (QCA): A New Path for Management Research. Manag. World 2017, 6, 155–167. [Google Scholar] [CrossRef]
  40. Zheng, L.; Ulrich, K.; Sendra-García, J. Qualitative comparative analysis: Configurational paths to innovation performance. J. Bus. Res. 2021, 128, 83–93. [Google Scholar] [CrossRef]
  41. Ragin, C.C. The Comparative Method: Moving Beyond Qualitative and Quantitative Strategies; University of California Press: Berkeley, CA, USA, 1987; pp. 35–47. [Google Scholar]
  42. Ragin, C.C.; Strand, S.I. Using Qualitative Comparative Analysis to Study Causal Order. Sociol. Methods Res. 2008, 36, 431–441. [Google Scholar] [CrossRef]
  43. Thiem, A. Conducting Configurational Comparative Research with Qualitative Comparative Analysis. Am. J. Eval. 2016, 38, 420–433. [Google Scholar] [CrossRef]
  44. Schneider, C.Q.; Rohlfing, I. Case Studies Nested in Fuzzy-set QCA on Sufficiency. Sociol. Methods Res. 2014, 45, 526–568. [Google Scholar] [CrossRef]
  45. Vis, B. The Comparative Advantages of fsQCA and Regression Analysis for Moderately Large-N Analyses. Sociol. Methods Res. 2012, 41, 168–198. [Google Scholar] [CrossRef] [Green Version]
  46. Bánhidi, Z.; Dobos, I.; Nemeslaki, A. What the overall Digital Economy and Society Index reveals: A statistical analysis of the DESI EU28 dimensions. Reg. Stat. 2020, 10, 46–62. [Google Scholar] [CrossRef]
  47. Zhao, L.; Shi, J. Managing Blockchain According to Law: Technology Application and Legal Supervision of Blockchain. J. Law Appl. 2020, 3, 33–49. [Google Scholar]
  48. Chandra, P.; Dong, A. The relation between knowledge accumulation and technical value in interdisciplinary technologies. Technol. Forecast. Soc. Chang. 2018, 128, 235–244. [Google Scholar] [CrossRef]
  49. Nie, P.-Y.; Chen, Z.-R.; Wang, C. Intellectual property pricing under asymmetric duopoly. J. Retail. Consum. Serv. 2021, 58, 102261. [Google Scholar] [CrossRef]
  50. Cai, W.; Xu, F.; Zeng, C. Why do Chinese local governments transfer their rights of control over SOEs to the central government? Appl. Econ. Lett. 2015, 22, 1252–1256. [Google Scholar] [CrossRef] [Green Version]
  51. Anderson, C. United-States Government asked to fund more Industrial-Research. Nature 1992, 358, 615. [Google Scholar] [CrossRef]
  52. Fayyaz, A.; Lund-Thomsen, P.; Lindgreen, A. Industrial Clusters and CSR in Developing Countries: The Role of International Donor Funding. J. Bus. Ethics 2015, 146, 619–637. [Google Scholar] [CrossRef] [Green Version]
  53. Medve-Bálint, G.; Šćepanović, V. EU funds, state capacity and the development of transnational industrial policies in Europe’s Eastern periphery. Rev. Int. Political Econ. 2019, 27, 1063–1082. [Google Scholar] [CrossRef] [Green Version]
  54. Li, S.; Han, S.; Shen, T. How Can a Firm Innovate When Embedded in a Cluster?—Evidence from the Automobile Industrial Cluster in China. Sustainability 2019, 11, 1837. [Google Scholar] [CrossRef] [Green Version]
  55. Deutz, P.; Gibbs, D. Industrial Ecology and Regional Development: Eco-Industrial Development as Cluster Policy. Reg. Stud. 2008, 42, 1313–1328. [Google Scholar] [CrossRef] [Green Version]
  56. Liu, H.; Wang, P.; Li, Z. Is There Any Difference in the Impact of Digital Transformation on the Quantity and Efficiency of Enterprise Technological Innovation? Taking China’s Agricultural Listed Companies as an Example. Sustainability 2021, 13, 12972. [Google Scholar] [CrossRef]
  57. Miao, Y.; Yang, D.O. Analysis on the Efficiency of Allocation of scientific and Technological Resources in Central China Based on the Comprehensive Evaluation Method. China Soft Sci. 2020, 3, 134–149. [Google Scholar]
  58. Thiem, A. Beyond the Facts: Limited Empirical Diversity and Causal Inference in Qualitative Comparative Analysis. Sociol. Methods Res. 2019, 51, 527–540. [Google Scholar] [CrossRef] [Green Version]
  59. Cooper, B.; Glaesser, J. Analysing necessity and sufficiency with Qualitative Comparative Analysis: How do results vary as case weights change? Qual. Quant. 2015, 50, 327–346. [Google Scholar] [CrossRef] [Green Version]
  60. Palacios-Marqués, D.; Roig-Dobón, S.; Comeig, I. Background factors to innovation performance: Results of an empirical study using fsQCA methodology. Qual. Quant. 2016, 51, 1939–1953. [Google Scholar] [CrossRef]
  61. Zhang, L.; Shan, X. Research on Coordination Relationship of patent and Industry in Pharmaceutical Manufacturing Industry. Sci. Technol. Prog. Policy 2021, 38, 66–73. [Google Scholar]
  62. Kiella, M.L.; Golhar, D.Y. Total quality management in an R&D environment. Int. J. Oper. Prod. Manag. 1997, 17, 184–198. [Google Scholar] [CrossRef]
  63. Kim, L.; Dahlman, C. Technology Policy for Industrialization: An Integrative Framework and Korea Experience. Res. Policy 1992, 21, 437–452. [Google Scholar] [CrossRef]
  64. Greckhamer, T. CEO compensation in relation to worker compensation across countries: The configurational impact of country-level institutions. Strateg. Manag. J. 2016, 37, 793–815. [Google Scholar] [CrossRef]
  65. Fiss, P.C. Building Better Causal Theories- A Fuzzy Set Approach to Typologies in Organization Research. Acad. Manag. Rev. 2011, 54, 393–420. [Google Scholar] [CrossRef] [Green Version]
Jtaer 17 00037 g001 550
Figure 1. Configurational model of the quality-driven mechanism of the urban digital economy based on TOE framework.
Figure 1. Configurational model of the quality-driven mechanism of the urban digital economy based on TOE framework.
Jtaer 17 00037 g001
Table
Table 1. List of sample cities.
Table 1. List of sample cities.
CityAdministrative Level/Location CityAdministrative Level/Location CityAdministrative Level/Location
1BeijingA/North 16FoshanE/South31ZhuhaiE/South
2ShenzhenB+C/South 17WuxiE/East32TaiyuanD/East
3HangzhouB+D/East 18SuzhouE/East33ShenyangB+D/Southeast
4ShanghaiA/East19FuzhouD/South34LanzhouD/Northwest
5GuangzhouB+D/South20XiamenB+C/South35XuzhouE/East
6ChongqingA/Southwest21JinanB+D/East36QuanzhouE/South
7QingdaoB+C/East22ZhengzhouD/Central37NanchangD/East
8NanjingB+D/East23NingboB+C/East38XiningD/Northwest
9ChengduB+D/Southwest24GanzhouE/East39YinchuanD/Northwest
10GuiyangD/Southwest25HarbinB+D/Southeast40NanningD/South
11ChangshaD/Central26ChangchunB+D/Southeast41LasaD/Northwest
12HaikouD/South27DalianB+C/Southeast42HuhehaoteD/East
13XianB+D/Northwest28HefeiD/East43WulumuqiD/Northwest
14WuhanB+D/Central29KunmingD/Southwest
15TianjinA/East30ShijiazhuangD/East
Note: A: Municipalities directly under the central government, B: Sub-provincial cities, C: Planned cities, D: Provincial capitals, E: Prefectural cities.
Table
Table 2. Variable description and data sources.
Table 2. Variable description and data sources.
VariablesDescriptionUnitsData Source
Blockchain service capabilityNumber of blockchain information service filingsPcsThe official website of the Office of the Central Committee of the Communist Party of China for Network Security and Informatization
Blockchain knowledge accumulationBlockchain Technology Patents10,000 PcsInnojoy Patent Database
Government attention allocationNumber of blockchain industry policiesPcsChina Blockchain Industry Business Model Innovation and Investment Opportunities In-depth Analysis Report
Government funding supportNumber of Blockchain Industry FundsPcsChina Urban Blockchain Development Level Assessment Report
Industry carrying capacityNumber of Blockchain Industrial ParksPcsChina Urban Blockchain Development Level Assessment Report
Technology R&D EnvironmentNumber of blockchain R&D institutionsPcsChina Urban Blockchain Development Level Assessment Report
Digital Economy QualityDigital Economy Index%White Paper on China’s Urban Digital Economy Index
Table
Table 3. Fuzzy-set membership calibrations and sample description.
Table 3. Fuzzy-set membership calibrations and sample description.
VariablesFuzzy Set CalibrationsMeasurement Description
Fully InCrossoverFully OutMeanSDMaxMin
Blockchain service capability145122.7254.543090
Blockchain knowledge accumulation81184114.84278.3613480
Government attention allocation≥1<10.841.9390
Government funding support≥1<10.210.4110
Industry Carrying Capacity≥1<10.601.0350
Technology R&D Environment≥1<123.64200
Digital economy quality7364.157.667.4211.5089.8045.1
Table
Table 4. The necessity of conditions for high and non-high digital economy quality.
Table 4. The necessity of conditions for high and non-high digital economy quality.
Condition TestedHigh QualityAbsence of High Quality
ConsistencyCoverageConsistencyCoverage
Blockchain service capability0.780.870.230.21
~Blockchain service capability0.280.310.850.76
Blockchain knowledge accumulation0.780.860.250.23
~Blockchain knowledge accumulation0.300.330.850.75
Government attention allocation0.470.800.140.19
~Government attention allocation0.520.420.850.57
Government funding support0.330.880.050.12
~Government funding support0.660.460.940.54
Industry Carrying Capacity0.560.830.140.16
~Industry Carrying Capacity0.430.380.860.61
Technology R&D Environment0.690.780.230.22
~Technology R&D Environment0.300.330.760.67
Note: the notation “~” means the absence of the variable.
Table
Table 5. Configurations sufficient analysis for the high quality of the urban digital economy.
Table 5. Configurations sufficient analysis for the high quality of the urban digital economy.
High-Quality Solution
HQ1aHQ1bHQ1cHQ1dHQ2HQ3
Blockchain service capability Jtaer 17 00037 i001 Jtaer 17 00037 i001 Jtaer 17 00037 i001 Jtaer 17 00037 i002 Jtaer 17 00037 i002
Blockchain knowledge accumulation Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i001
Government attention allocation Jtaer 17 00037 i003 Jtaer 17 00037 i003 Jtaer 17 00037 i003 Jtaer 17 00037 i002
Government funding support Jtaer 17 00037 i003 Jtaer 17 00037 i003 Jtaer 17 00037 i001 Jtaer 17 00037 i004 Jtaer 17 00037 i004
Industry Carrying Capacity Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i003 Jtaer 17 00037 i003
Technology R&D Environment Jtaer 17 00037 i001 Jtaer 17 00037 i001 Jtaer 17 00037 i003 Jtaer 17 00037 i003 Jtaer 17 00037 i002
Consistency0.990.980.9910.990.88
Raw coverage0.400.080.160.020.030.16
Unique coverage0.230.030.010.020.030.11
Overall consistency0.96
Overall coverage0.64
Note: Large, full black circle “ Jtaer 17 00037 i002” (present) and large, cross open circle “ Jtaer 17 00037 i004” (absence) represent core conditions. Small, full black “ Jtaer 17 00037 i001” (present) and small, crossed open circles “ Jtaer 17 00037 i003” (absence) represent peripheral conditions.
Table
Table 6. Configurations sufficient analysis for the absence of high-quality urban digital economy.
Table 6. Configurations sufficient analysis for the absence of high-quality urban digital economy.
Absence of a High-Quality Solution
AHQ1aAHQ1b
Blockchain service capability Jtaer 17 00037 i003 Jtaer 17 00037 i003
Blockchain knowledge accumulation Jtaer 17 00037 i004 Jtaer 17 00037 i004
Government attention allocation Jtaer 17 00037 i003
Government funding support Jtaer 17 00037 i004 Jtaer 17 00037 i004
Industry Carrying Capacity Jtaer 17 00037 i003
Technology R&D Environment Jtaer 17 00037 i004 Jtaer 17 00037 i004
Consistency0.850.85
Raw coverage0.620.58
Unique coverage0.080.05
Overall consistency0.86
Overall coverage0.67
Note: Large, cross open circle “ Jtaer 17 00037 i004” (absence) represents core conditions. Small, crossed open circles “ Jtaer 17 00037 i003” (absence) represents peripheral conditions.
Table
Table 7. Results of the robustness test with a higher consistency threshold.
Table 7. Results of the robustness test with a higher consistency threshold.
.RTHQ1aRTHQ1bRTHQ1cRTHQ1dRTHQ2aRTHQ2b
Blockchain service capability Jtaer 17 00037 i001 Jtaer 17 00037 i001 Jtaer 17 00037 i001 Jtaer 17 00037 i002 Jtaer 17 00037 i002
Blockchain knowledge accumulation Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i001
Government attention allocation Jtaer 17 00037 i003 Jtaer 17 00037 i003 Jtaer 17 00037 i003 Jtaer 17 00037 i002 Jtaer 17 00037 i002
Government funding support Jtaer 17 00037 i003 Jtaer 17 00037 i003 Jtaer 17 00037 i001 Jtaer 17 00037 i004 Jtaer 17 00037 i004
Industry Carrying Capacity Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i001 Jtaer 17 00037 i003
Technology R&D Environment Jtaer 17 00037 i001 Jtaer 17 00037 i001 Jtaer 17 00037 i003 Jtaer 17 00037 i001 Jtaer 17 00037 i003
Consistency0.990.980.99110.98
Raw coverage0.400.080.060.020.160.03
Unique coverage0.230.030.010.020.040.03
Overall consistency0.99
Overall coverage0.54
Note: Large, full black circle “ Jtaer 17 00037 i002” (present) and large, cross open circle “ Jtaer 17 00037 i004” (absence) represent core conditions. Small, full black “ Jtaer 17 00037 i001” (present) and small, crossed open circles ” Jtaer 17 00037 i003” (absence) represent peripheral conditions. For high-quality solutions, RTHQ1a, RTHQ1b, RTHQ1c, and RTHQ1d, which can be represented by the knowledge-industry-driven path; RTHQ2a and RTHQ2b can be represented by the government-service-driven path.
Table
Table 8. Results of the robustness test with alternative crossover points.
Table 8. Results of the robustness test with alternative crossover points.
RTHQ1aRTHQ1bRTHQ1cRTHQ2aRTHQ2b
Blockchain service capability Jtaer 17 00037 i001 Jtaer 17 00037 i001 Jtaer 17 00037 i002 Jtaer 17 00037 i002
Blockchain knowledge accumulation Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i001
Government attention allocation Jtaer 17 00037 i003 Jtaer 17 00037 i003 Jtaer 17 00037 i002 Jtaer 17 00037 i002
Government funding support Jtaer 17 00037 i003 Jtaer 17 00037 i003 Jtaer 17 00037 i004 Jtaer 17 00037 i004
Industry Carrying Capacity Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i002 Jtaer 17 00037 i003 Jtaer 17 00037 i003
Technology R&D Environment Jtaer 17 00037 i001 Jtaer 17 00037 i001 Jtaer 17 00037 i003 Jtaer 17 00037 i003
Consistency0.970.980.9910.99
Raw coverage0.430.090.070.180.03
Unique coverage0.230.030.010.040.03
Overall consistency0.99
Overall coverage0.54
Note: Large, full black circle “ Jtaer 17 00037 i002” (present) and large, cross open circle “ Jtaer 17 00037 i004” (absence) represent core conditions. Small, full black “ Jtaer 17 00037 i001” (present) and small, crossed open circles “ Jtaer 17 00037 i003” (absence) represent peripheral conditions. For high-quality solutions, RTHQ1a, RTHQ1b, RTHQ1c, and RTHQ1d, which can be represented by the knowledge-industry-driven path; RTHQ2a and RTHQ2b can be represented by the government-service-driven path.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Xia, M.; Xie, Z.; Lin, H.; He, X. Synergistic Mechanism of the High-Quality Development of the Urban Digital Economy from Blockchain Adoption Perspective—A Configuration Approach. J. Theor. Appl. Electron. Commer. Res. 2022, 17, 704-721. https://doi.org/10.3390/jtaer17020037

AMA Style

Xia M, Xie Z, Lin H, He X. Synergistic Mechanism of the High-Quality Development of the Urban Digital Economy from Blockchain Adoption Perspective—A Configuration Approach. Journal of Theoretical and Applied Electronic Commerce Research. 2022; 17(2):704-721. https://doi.org/10.3390/jtaer17020037

Chicago/Turabian Style

Xia, Ming, Zhimin Xie, Hui Lin, and Xiangwu He. 2022. "Synergistic Mechanism of the High-Quality Development of the Urban Digital Economy from Blockchain Adoption Perspective—A Configuration Approach" Journal of Theoretical and Applied Electronic Commerce Research 17, no. 2: 704-721. https://doi.org/10.3390/jtaer17020037

APA Style

Xia, M., Xie, Z., Lin, H., & He, X. (2022). Synergistic Mechanism of the High-Quality Development of the Urban Digital Economy from Blockchain Adoption Perspective—A Configuration Approach. Journal of Theoretical and Applied Electronic Commerce Research, 17(2), 704-721. https://doi.org/10.3390/jtaer17020037

Article Metrics

Back to TopTop