Social media provides an open platform for online users, enabling them to develop networks. The latest Datareportal (2023) survey showed that there are currently 5.16 billion Internet users and 4.76 billion social media users worldwide, representing 59.4% of the world's total population. The growing accessibility of personal data and widespread information dissemination pose escalating threats to individual privacy (Stewart, 2023). On social media platforms, users inadvertently share a vast amount of personal information, including identity particulars, location data, and daily activities, which may increase their vulnerability to unauthorised exposure or mishandling (Such & Criado, 2018). Moreover, the advancement of novel digital technologies has made data management, storage, sharing and utilisation more complex.

On a theoretical level, privacy protection and data security are key determinants of digital technology adoption. According to privacy computing theory, users' concerns about privacy protection when digital technologies are used directly affect their technology adoption behaviours (Zhang et al., 2024). Especially in the case of technology applications involving sensitive personal data, privacy and security risk concerns tend to be the main barriers to users' reluctance to adopt (Xu et al., 2023a). For example, Islam et al. (2021) noted that IoT technology has expanded the collection of personal data through household and wearable devices, heightening the risks to privacy if robust safeguards are not in place. Cui et al. (2022) noted that technology enables both private companies and public agencies to utilise data from personal wearables to control their activities on an unprecedented scale. However, owing to the inherent openness of wearable devices, they are limited by the network, terminal resources and technology, which hinders the design of security and privacy protection programs for wearable devices and networks (Alsubaei et al., 2018). Moreover, users' concerns about data leaks and misuse reduce their acceptance of new technologies. Although the decentralised nature of blockchain technology is seen as an advantage in enhancing data security, practical applications still face privacy protection challenges, which limit its widespread adoption in areas such as finance and healthcare (Soltanisehat et al., 2023). Chen et al. (2023) reported that almost all blockchain-based data sharing models suffer from the difficulty of protecting the privacy and integrity of uses' data, as well as their data ownership. Gao et al. (2020) noted that the open network and publicly stored data of blockchain pose serious risks of data theft and user privacy leakage, which has become a core issue that restricts blockchain technology from becoming practical. AI systems usually require large amounts of data for training and learning, and there is a potential for data privacy to be abused or illegally accessed (Ellahham et al., 2020). Chen et al. (2023) noted that privacy-related anxieties can significantly impede the acceptance and utilisation of digital health innovations.

Digital technology adoption also faces multiple challenges, such as data integrity, authentication and intellectual property (Todorov & Lutfiu, 2023). Data integrity concerns how to ensure that data are not tampered with or corrupted during transmission. Authentication confirms the identity of the user to prevent impressions and fraud (Awuson-David et al., 2019). In particular, with the advent of generative AI, ethical considerations around generating content, potential bias, and intellectual property will be new anxieties (Khatun et al., 2023). Therefore, ensuring information security is essential for safeguarding uses' rights and interests, protecting data security, and increasing digital technology adoption. To this end, we propose the following hypothesis:

• H1: Privacy security risks have a negative impact on the adoption of digital technologies.

States and societies are becoming increasingly knowledge- and information technology-intensive. Information technology-based learning will become a key factor affecting the digital divide between people, thereby affecting the well-being of countries and societies at large (Wei et al., 2011). Fossen & Sorgner (2022) noted that learning ability and digital literacy are important abilities for individuals to adapt to a digital society. Digital literacy is a basic ability necessary for individuals to participate in social, economic and cultural activities in the context of the information explosion of the twenty-first century (Dorozhkin & Chemoskutova, 2020; Jang et al., 2021). It involves not only basic computer operating skills but also more complex competencies, such as the identification, evaluation, utilisation and creation of information (Reddy et al., 2022). According to Wang & Luan (2022), the lack of digital literacy has become a key factor limiting the widespread adoption of digital technologies, especially in terms of education, employment and social participation, with obvious negative consequences. Individuals who lack digital literacy often have difficulty judging the authenticity and reliability of information when confronted with vast amounts of information (Svyrydenko & Terepyshchyi, 2020). Jiang et al. (2023b) noted that the level of information searching skills of Internet users directly affects the quality of the information they obtain. Digital technology adoption is not just about purchasing or being exposed to new technologies but also about being able to use them effectively. According to the (TAM) and the extended TAM, a user's perceived ease of use and usefulness of a new technology directly affects their willingness to adopt it (Davis, 1989; Venkatesh & Davis, 2000). The presence of digital illiteracy reduces users' ability to understand and operate new technologies, leading to lower perceived ease of use and thus inhibiting adoption (Hamad et al., 2021). For example, in the application of complex technologies such as AI and blockchain, digitally illiterate users often struggle to understand the basic concepts and operational processes of the technology, which makes their acceptance of these technologies significantly lower.

Some empirical studies have also revealed that in developing countries, despite the increasing penetration of smartphones and the internet, many people still face significant barriers to using digital technologies due to their lack of basic digital skills (Zheng et al., 2020). ScheeL et al. (2022) noted that individuals with learning deficits have difficulty updating their knowledge base in a timely manner, leading to a lag in the technologies and methods they use. Nikou et al. (2022) also reported that individuals with an insufficient learning ability may not be able to fully grasp and utilise the full capabilities of these technologies, even if they adopt them. A typical example is that with the increasing popularity of remote work, for employees who are unable to quickly learn and adapt to telecommuting software, their productivity and ability to collaborate as a team may plummet, which in turn affects the efficiency of the organisation as a whole (Kohn et al., 2023). In some rural areas of Africa and South Asia, high rates of digital illiteracy have led to relatively low adoption of new technologies such as mobile payments and e-commerce. Similarly, among older populations, high rates of digital illiteracy limit the diffusion of health management applications and online services (Mbunge et al., 2024). In these contexts, digital illiteracy not only affects individual technology adoption decisions but can also lead to wider social exclusion and economic inequality, hindering the digital transformation of society as a whole. To this end, we propose the following hypothesis:

• H2: Digital illiteracy has a negative impact on the adoption of digital technologies.

Affordable access to broadband services enables individuals to enjoy the benefits of digital connectivity and allows businesses to thrive in the digital economy (Policy Brief, 2022). In 2022, the International Telecommunication Union (ITU) estimated that although the majority of the world's population (95%) is covered by mobile broadband networks, every third person on the planet is offline (ITU, 2022). In many developing countries, the cost of mobile data can exceed the normal reach of individuals (Statista, 2022). A World Bank study in 11 emerging countries revealed that 48 percent of respondents have difficulty servicing their mobile data usage and that 42 percent limit the amount of data they use (World Bank, 2021). Habib et al. (2023) noted that high data prices relative to income levels are a major barrier to accessing digital services and information. According to rational choice theory (RCT), individuals weigh the potential benefits and costs of technology when making technology adoption decisions (Becker, 1993). For users with a limited ability to pay, high initial costs and ongoing maintenance costs can significantly reduce their willingness to adopt new technologies. In addition, the TAM has shown that users' perceived usefulness and perceived ease of use directly influence their technology adoption decisions (Davis, 1989). When the ability to pay is limited, users' perceived ease of use and availability of a new technology decreases, thus reducing the likelihood of adoption.

Several existing empirical studies have also discussed the impact of a limited ability to pay on technology adoption. According to Ayanso & Lertwachara (2015), a lack of access to affordable mobile data has reduced the use of digital technologies such as mobile apps, online services and e-commerce platforms. This, in turn, limits the opportunities for education, healthcare and economic empowerment that they can enhance. Reddick et al. (2020) noted that without affordable access to mobile data, individuals, organisations and society as a whole will be unable to realise the full potential of digital tools for personal and professional development, and organisational improvement and social progress will be difficult to achieve. Sandhu (2022) noted that in big data analytics and cloud computing applications, which require the storage and processing of large amounts of data, the inability of individuals or enterprises to afford expensive cloud services limits their ability to participate in relevant fields. Owing to low economic levels and limited social resources, many people find it difficult to afford the high cost of communications, equipment and digital services, especially in some developing countries or regions (World Bank, 2021). This has limited the diffusion of digital technologies, leading to the exacerbation of the digital divide. In addition, tax policies also have a direct effect on affordability. Excessive taxation increases the prices of digital products and services, adding to the burden on customers (Guo et al., 2022). A heavy tax burden on the digital industry discourages research and innovative activities by enterprises, reducing the affordability of digital technologies.

Furthermore, a limited ability to pay not only directly affects the adoption decisions of individuals or households towards the new generation of digital technologies but also may negatively affect technology investments by businesses and government agencies. Among small and medium-sized enterprises (SMEs), limited funds and resources make it difficult for them to afford the high cost of technology required for digital transformation, thus limiting innovation and competitiveness (Babilla, 2023). Similarly, when governments promote digital infrastructure development, they may find it difficult to provide adequate financial support due to financial constraints, leading to a slowdown in the process of technology diffusion (The et al., 2024). To this end, we propose the following hypothesis:

• H3: Digital unaffordability has a negative impact on the adoption of digital technologies.

The rapid development of digital technologies is bringing unprecedented opportunities for various aspects, driving economic growth, social progress and technological innovation.

For businesses, these technologies enable data-driven decision-making, personalised marketing, and improved operational efficiency. Karagozlu et al. (2020) noted that cloud computing provides scalable and cost-effective solutions for organisations to store, process and access data and applications over the internet, enabling them to align resources with changing needs. Hadded & Hamrouni (2022) also noted that cloud-based services facilitate seamless collaboration and communication between remote teams, allowing for increased productivity and workflow efficiency. In customer service, AI-powered chatbots and virtual assistants can improve response times and resolution rates, leading to increased overall customer satisfaction (Hsu & Lin, 2023). By analysing large datasets, AI can also predict customer behaviour and preferences, making it possible for personalised recommendations and targeted marketing campaigns (Chiu & Chuang, 2021). Additionally, the tokenisation of blockchain allows for partial ownership of assets, facilitating crowdfunding and investment opportunities. Mahjoub et al. (2022) asserted that this democratisation of capital markets opens new avenues for funding and investment, especially for startups and SMEs seeking alternative finance solutions. Moreover, according to Firmansyah & Umar (2023), the metaverse can provide immersive and interactive virtual environments for business activities where users can socialise, collaborate and transact with each other.

In healthcare, using historical data and machine learning algorithms, healthcare providers can predict disease progression, identify at-risk populations, and implement preventive interventions (Abraham et al., 2022). Cloud-based electronic health record (EHR) systems enable healthcare providers to access patient information remotely, improving the coordination and continuity of care between different healthcare organisations (Joshi et al., 2018). Cloud-enabled telemedicine allows remote consultations, remote monitoring, and telehealth intervention, especially in underserved and rural areas, where patients can access healthcare services at home (Li et al., 2021a). The metaverse can facilitate virtual consultation, medical simulation and training environments for healthcare professionals. Virtual reality (VR) and augmented reality (AR) technologies achieve immersive and interactive experiences, allowing healthcare providers to conduct virtual consultations and examinations, remotely monitor patients' vital signs, and perform virtual surgeries in a simulated environment (Kanschik et al., 2023; Twamley et al., 2024).

In the agricultural sector, digital technologies facilitate precision agriculture, crop monitoring and supply chain optimisation (Kim & Heo, 2024). Technologies such as global positioning systems (GPSs), IoT sensors and drones are being used to optimise agricultural practices and resource management. Machine learning algorithms can process data from a variety of sources, including weather forecasts, soil surveys and historical crop yields (Ragunath et al., 2022). Supply chain optimisation technology improves transparency, traceability and efficiency across the agricultural supply chain (Kamble et al., 2020). Blockchain technology provides end-to-end traceability of produce from farm to fork by recording every transaction and movement on an immutable ledger (Torky & Hassanein, 2020). Consumers can verify the authenticity and origin of produce, which in turn ensures food safety and quality.

Next-generation digital technologies present significant opportunities and transformations for a number of representative industries, but the key to realising the full potential of these technologies is to facilitate their widespread adoption. A good regulatory environment can provide a clear legal framework and data protection standards to reduce risks and uncertainties in the application of technology (Zhang et al., 2023). This includes not only direct regulation of technology adoption, such as regulations to ensure data security and protect consumer privacy but also policies that provide support for technological innovation. Good regulation not only boosts the confidence of market participants in new technologies but also provides an equal playing field for all businesses by ensuring fair competition (Yakubi, 2022).

For example, clear privacy protection regulations and data security standards can enhance business and consumer trust in technologies such as digital payments, e-commerce and big data analytics. In the United States and Europe, strict data protection laws (e.g., GDPR) not only safeguard consumers' privacy but also motivate businesses to pay more attention to data security and compliance, which promotes the innovative application of technology and healthy development of the market (Woerle & Gstrein, 2024). Therefore, a good regulatory environment provides a solid foundation for the commercial application of digital technologies and encourages more enterprises to invest in the development and application of new technologies, thereby promoting economic growth and innovation.

Clear regulations and standards can help healthcare organisations and technology providers standardise their operations and facilitate the diffusion of digital health technologies such as electronic medical records, telemedicine, and AI diagnostic systems. In the UK, the government has established standardised requirements for EHRs through the Health and Social Care Act, which has promoted the nationwide diffusion of EHRs and improved the efficiency and quality of healthcare services (Bach-Mortensen et al., 2024). This favourable regulatory environment has reduced compliance costs for healthcare organisations and increased technology acceptance and adoption.

Reasonable environmental regulations and data protection policies provide legal safeguards for farmers and agribusinesses to use drones, sensor networks, and blockchain technologies for precision management and supply chain optimisation. For example, in the European Union, regulations related to agricultural data sharing and management have facilitated transnational agricultural cooperation and data sharing and provided support for agri-tech enterprises to develop markets (Ibrahim & Truby, 2023). Therefore, a good regulatory environment not only promotes the application of new-generation digital technologies in agriculture but also promotes the development of sustainable agriculture. Thus, we propose the following hypothesis:

• H4: A good regulatory environment has a positive impact on digital technology adoption.

In addition to the impact of the regulatory environment on the adoption of next-generation digital technologies, governmental leadership plays an important role. Sound governmental leadership can promote the popularisation and deepening of new technologies through strategic planning, policy support and financial incentives.

For example, by providing financial support, tax incentives and technical training, the government can help SMEs overcome cost barriers to technological transformation and enhance the digitalisation of their enterprises. In Singapore, the government has provided a series of financial incentives and policy support through the Smart Nation Program to encourage enterprises to adopt AI and big data technologies for business model innovation and efficiency improvement (Woods et al., 2024). This strong government guidance not only promotes the popularisation of technology but also enhances the overall competitiveness of the country.

By establishing demonstration programs, providing financial support, and setting industry standards, governments can effectively lower the barriers to the adoption of new technologies by healthcare organisations. In the United States, the government has promoted the adoption of electronic health records through the Health Information Technology for Economic and Clinical Health (HITECH) Act, which has improved the efficiency of healthcare services and patient health outcomes (Bohn & Schiereck, 2023). This policy guidance and support has accelerated the process of digital transformation in healthcare and created favourable conditions for the spread of new technologies.

Through subsidies and project funding, governments can encourage farmers and agribusinesses to adopt advanced technologies such as drone monitoring, smart irrigation, and agricultural product traceability systems. In Israel, the government has promoted the widespread adoption of precision agriculture technologies by supporting agri-tech startups and research institutes, significantly improving agricultural productivity and water management efficiency (Shani, 2024). This strong policy guidance not only promotes the modernisation of agriculture but also the development of the rural economy.

On the basis of the above discussion, we believe that sound governmental leadership has effectively lowered the threshold for the adoption of next-generation digital technologies through policy support, financial assistance and demonstration projects and has promoted the widespread application of these technologies in various fields. Thus, we propose the following hypothesis:

• H5: Sound governmental leadership has a positive impact on the adoption of digital technologies.

Diffusion of innovations (DOI) theory is an important theory in sociology that involves four key elements, i.e., innovation, communication channels, time, and social systems (Rogers, 1995). Innovation has five characteristics that have a direct effect on the willingness and speed with which an individual or organisation adopts a new technology. A comparative advantage is the improvement that an innovation may bring to an individual or business. Compatibility is the level of affinity of the innovation with existing values and needs. Complexity is the level of difficulty in understanding or using the innovation. Trialability describes how easily an innovation can be tested. Observability is the degree to which the innovation is visible to others (Martins et al., 2016). Communication channels serve as a medium for innovation diffusion, either directly between individuals or through the media. The time factor relates to the adoption process of the innovation, the length of time it takes the innovator to make a decision, and the rate at which it spreads through the social system (Rogers, 1995). The content of social systems, such as social norms, cultural values, social networks, and the influence of leadership, can also have an impact on the diffusion and adoption of technology.

DOI theory is widely used in digital technology research to explain the adoption of technologies such as IoT, AI, blockchain, and the metaverse. For example, Saylam & Ozdemir (2022) integrated the TAM and DOI theory to analyse the military's acceptance of the IoT, revealing that risk factors do not seem to have a significant effect on IoT acceptance and that there seems to be a positive correlation between risk and trust, contrary to the expected negative correlation. Al-Dhaen et al. (2023) utilised DOI theory to consider the risks and complexities involved in using AI and reported that despite the contradictions of AI, sustained willingness-to-use behaviour can be predicted during the diffusion of IoT technologies. Xu et al. (2023) extended DOI theory to consider technological threats and examined the adoption of AI in the workplace from a dynamic, differential effects perspective, finding an association between the threat of AI (i.e., concerns about job security) and employees' increasingly negative attitudes towards adopting AI over time. Kumar et al. (2024) used DOI theory to study the adoption intention behaviour of enterprise metadata, and the results revealed that the dimensions of DOI theory are closely related to the use intention of enterprise metadata.

On the basis of the above discussion, we find that DOI theory provides an important perspective for understanding technology adoption in individuals and organisations, but its role in explaining technology adoption at the national level has not been sufficiently discussed in the existing literature.

Institutional theory is an important theoretical framework in organisation studies that is used to explain how organisations operate and develop in an institutional environment. The theory focuses on how formal laws and regulations, informal social norms, and cultural perceptions influence organisational behaviour and decision-making (DiMaggio & Powell, 1983). Scott (1987) further extended institutional theory by proposing three pillars of the institutional environment: the normative pillar, the cognitive pillar, and the regulatory pillar. The role of the normative pillar in technology adoption is reflected in social norms and industry standards. For example, Zhang et al. (2024a) explored the role of individual cultural values in the adoption of socially sustainable supply chain management (SSCM) by Chinese suppliers facing normative institutional pressures on guanxi, emphasising the dominant role of guanxi in improving SSCM practices due to its normative institutional power. The cognitive pillar reflects how cultural perceptions and collective beliefs influence the technology adoption process. The regulatory pillar is concerned primarily with the mandatory requirements of laws, regulations, and policies for technology adoption. Zhao et al. (2023) utilised institutional theory, social network theory and survey data from 689 female micro e-commerce entrepreneurs in China to explore the impact of the institutional environment on entrepreneurial performance, and the results revealed that the institutional environment (including both regulatory and cognitive dimensions) has a significant positive impact on entrepreneurial performance.

Institutional theory has also been used in a wide range of different fields and contexts. Zhang et al. (2023) studied a sample of 236 traditional manufacturing firms on the basis of institutional theory and showed that the institutional environment affects the association between digital technology adoption and business model innovation and that policy support strengthens the impact of digital technology adoption on strategic flexibility. Bennich (2024) conducted a study on digitisation in the water industry3 and reported that water companies face institutional pressures to digitise, which in turn affects how they respond to digitisation. In addition, institutional theory is applied when discussing the development of specific emerging digital technologies. Nahar (2024) simulated system dynamics modelling with institutional theory to make predictions about innovation in AI from 2022 to 2030. Allen et al. (2020) noted that a policy environment conducive to the adoption and use of blockchain technology can trigger entrepreneurial experimentation in institutional forms. Drawing on institutional theory, Lin et al. (2023) explored how various institutional forces influence stakeholder adoption of blockchain and metaverse technologies.

Institutional theory explains the impact of the external institutional environment on technology adoption, which provides important insights into the factors that influence technology adoption. However, it does not contain elements that go beyond institutional pressures (Martins et al., 2016).

On the basis of the above discussion, we find that there are several limitations to the existing single theories. DOI theory focuses on how technology diffuses at the individual or organisational level, emphasising the influence of the characteristics of technology adopters and social networks on technology diffusion. However, it has several limitations in analysing technology adoption at the macro level. It usually ignores the institutional environment, policy factors, and country-level influences that play crucial roles in the global technology adoption process. Institutional theory, which emphasises that organisational behaviour is influenced by the external environment, regulations, and social norms, is useful in understanding technology adoption at the organisational and industry levels. However, the theory often lacks a focus on the process of technological innovation, especially given the dynamic nature of technology diffusion and the early stages of innovation. It usually focuses on stable institutional environments and fails to adequately consider the rapid changes and uncertainties that can occur in the process of technology adoption.

Owing to the limitations of the above theories, fully explaining the global adoption process of next-generation digital technologies by using DOI theory or institutional theory alone is difficult. At the macro level, the adoption of digital technologies is not only influenced by the characteristics of the technology itself and social networks but also closely related to the policies, legal environment, economic conditions and cultural background of each country. Therefore, relying on a single theory alone is not sufficient to provide a complete explanatory framework.

Therefore, this paper combines DOI theory and institutional theory, which synthesise the effects of basic conditions, risks, and supportive environments on the adoption of digital technologies.

Digital technology adoption (DTA): Hooks et al. (2022) explored factors that influence the technology adoption rate using information about network readiness as the quantified index. Referring to this, we use the network readiness index (NRI) as the measure of DTA. The NRI is based on four fundamental dimensions—technology, people, governance, and impact—and covers issues ranging from futuristic technologies such as AI and the IoT to the role of digital transformation in achieving the sustainable development goals (SDGs), providing a holistic picture of a country or region's ability to use digital technologies (World Economic Organization, 2022). The data are derived from the annual Network Readiness Index Report published by the World Economic Organization.4 It is scored on a scale of 0 to 100, which denotes the digital technology adoption rate from lowest to highest.

On the basis of the five hypotheses presented in the previous section, we identify the five core explanatory variables for this paper.

Privacy and security risks (PSR): We choose the global cybersecurity index (GCI) as the measure of the PSR. The GCI is a measure of countries' level of commitment to cybersecurity, initiated and maintained by the ITU,5 which assesses the cybersecurity status of countries on the basis of five key areas: legal measures, technological measures, organisational measures, capacity building and cooperation. The data come from the GCI report published by the ITU and range from 0 to 100, with higher scores indicating better cybersecurity in that country. In this work, we take the opposite value to indicate the level of security risks; the smaller the value is, the lower the level of risks.

Illiteracy (ILT): This paper uses the literacy rate to express the situation of illiteracy from the opposite side. The literacy rate indicator is an important tool for measuring a country's level of education and national capacity. This indicator is usually defined as the proportion of the population aged 15 and over who can read and write. We collect the data from the Global System for Mobile Communications Association (GSMA) .6 This platform normalises literacy data published by UNESCO7 to obtain each country's score under the literacy indicator. The data are subsequently measured on a scale from 0 to 100, with 0 indicating the lowest level of literacy and 100 indicating the highest level of literacy. We take the opposite of this value to indicate the level of illiteracy; the smaller the value is, the lower the level of illiteracy.

Unaffordability (UAF): We use the opposite of mobile data affordability (MDA) to reflect the degree of unaffordability. The MDA focuses on the affordability of individuals or households to pay for mobile data services. It relates to four different types of affordability. The data are derived from the MDA subindex within the affordability pillar of the mobile connectivity index (MCI) published by the GSMA. The GSMA collates the data originating from Tarifica8 and averages these four affordability scores to obtain a final MDA score (0–100). Larger values indicate greater affordability. Since we take the opposite value to indicate the level of unaffordability, the smaller the value is, the lower the level of unaffordability.

Regulatory environment (RE): We use the information and communications technology (ICT) regulatory environment indicator as a measure of the regulatory environment in digital society. This indicator is based on the ICT regulatory tracker composite index, which provides a measure of the existence and features of ICT legal and regulatory frameworks.9 A healthy ICT regulatory environment encourages technological innovation and market competition and helps drive the development and adoption of emerging technologies, as it ensures an open and fair market (Zhang et al., 2023). A mature and adaptable ICT regulatory environment provides a stable foundation for the long-term development of the digital economy, supporting the growth of emerging business models ranging from e-commerce to teleworking. According to the annual report of the NRI,10 scores are standardised on a scale of 0 (worst environment)-100 (greatest environment).

Governmental leadership (GL): We use the e-government development index (EGDI) to reflect governmental leadership. The EGDI is based on a comprehensive survey of the online presence of all 193 member states of the United Nations.11 It is a composite indicator that measures a country's level of e-government development and assesses the development of e-government in countries on the basis of three main dimensions: the online services index (OSI), the telecommunications infrastructure index (TII) and the human capital index (HCI). These indicators reflect a country's degree of digitisation in the delivery of public services and its ability to use ICT to promote accessibility and efficiency in public services. This assessment provides a relative rating of countries' e-government performance rather than an absolute measure. According to the annual report of the NRI,12 scores are standardised on a scale of 0 (worst developed) to 100 (best developed).

After discussing the selection of explanatory variables for this paper, we next present the control variables used in the study. These control variables can help us further eliminate other factors that may affect technology adoption and thus more accurately assess the role of explanatory variables.

The GDP per capita (current USD$) is an important indicator of a country's level of economic development and the state of average wealth of its inhabitants. A higher GDP usually implies a stronger economy and a higher standard of living, factors that respond to influence the adoption of digital technologies. The data are obtained from the World Bank.

Secure internet servers (SIS) quantify the number of secure internet servers per million people in a country or region. By normalising the number of secure servers to the size of the population, the metric provides a way to compare the level of investment and sophistication in cybersecurity infrastructure in different countries or regions, regardless of their population size. The data are obtained from the World Bank.

The extent to which companies invest in emerging technologies (CIET) can be used as a measure of technology innovation. Data are obtained from NRI annual reports. The report normalises the data in the World Economic Forum's Executive Opinion Survey (EOS) ,13 with values ranging from 0 (lowest extent) to 100 (highest extent).

The school life expectancy (SLE) indicator reflects the number of years a child is expected to spend in the education system, ranging from the most basic level of education to the highest. The data are derived from the SLE subindicator in the MCI database published by the GSMA, which originated from UNESCO.14 The GSMA normalises the original data with values ranging from 0 (shortest average years of schooling) to 100 (longest average years of schooling).

The infrastructure development index (IDI) published by GSMA15 refers to the level of development of mobile network infrastructure, which includes the coverage of networks from the most basic 2G networks to the more advanced 4G and 5G networks, as well as network performance and the use of the radio spectrum. GSMA aggregates these three dimensions to produce the IDI score. The IDI is scored between 0 and 100, and a higher score is associated with greater infrastructure development.

To better understand the role and characteristics of these variables in the study, we move on to more specific descriptions and statistical analyses of the variables in the next subsection.

To reduce the interference of the extreme values of the sample data on the regression results, this paper is based on the value of the NRI, removing the top 12 countries and the bottom 12 countries in the NRI rankings in 2022 to conduct a robustness test on the sample data. Table 8 shows that some of the coefficients in the regression results after removing the 24 observed countries have changed slightly, but generally, the results remain consistent, indicating that the model is robust. For example, the coefficient on ILT increases from -0.603 to -0.539 but is still significant; the coefficients on PSR and UAF remain significant and negatively correlated. This robustness test suggests that the main factors affecting the NRI retain their direction of influence and most of their strength of influence, even after removing countries with potentially extreme effects. The impact of the year variable has changed but still shows a similar pattern to that of the benchmark regression.

This robustness test confirms the reliability of our model by demonstrating that the key findings are not unduly influenced by countries with extreme NRI values. The consistency in direction and significance of the main variables, even after excluding outliers, reinforces the validity of our conclusions regarding the factors affecting next-generation digital technology adoption. This analysis provides a strong foundation for our policy recommendations and theoretical contributions, ensuring that they are based on robust and stable empirical evidence.

In addition to the primary robustness test, we conducted another set of analyses to further verify the stability of our results. By reducing the core explanatory variables in the model, we separately examine the impact of barriers and opportunities on the new generation of digital technologies. Model 4 in Table 9 represents the impact of the three explanatory variables representing barriers on the regression results after removing the two core explanatory variables representing opportunities. Model 5 represents the effect of the two explanatory variables for opportunity on the regression results.

The results show that the coefficients and significance of each explanatory variable are almost consistent with those of benchmark Model 2, further validating the conclusions of this paper. That is, illiteracy, privacy and security risks, and unaffordability can hinder the use of digital technologies, whereas the regulatory environment and government demonstrations can promote the use of next-generation digital technology to some extent.

The separate examinations in Models 4 and 5 confirm that the core conclusions of our study hold true across different model specifications. This suggests that the identified factors—both barriers and opportunities—are fundamentally influential in shaping the adoption of next-generation digital technologies and that their impacts are not merely artefacts of model specification.