To achieve our study objectives, we followed the systematic review guidelines prescribed by Hanelt et al. (2021) comprising the following three steps: (1) data collection, (2) data analysis, and (3) data synthesis. We only considered peer-reviewed journals because they propagate well-validated knowledge and have the highest review standards. We used the Web of Science (WoS) database because of its broad coverage and inclusion of academic journal articles relevant to our study and it allows users to tailor their searches based on article titles, abstracts, and keywords (Tandon et al., 2021). WoS provides broad interdisciplinary coverage of various scientific fields, making it useful for reviews across the natural sciences, social sciences, and humanities. It includes prestigious citation indices such as the Science Citation Index (SCI), Social Science Citation Index (SSCI), and Arts & Humanities Citation Index (A&HCI). It also emphasizes high-quality peer-reviewed journals, ensuring that the articles included have undergone rigorous academic scrutiny, thereby supporting high standards for systematic reviews (Mongeon & Paul-Hus, 2016). According to our search criteria, only articles that included terms from both of the following search strings in titles, keywords, or abstracts were included in the sample. The first search string included the following keywords: “digit*” or “Internet of Things” or “IoT” or “artificial intelligence” or “AI” or “industry 4.0” or “mobile computing” or “cloud computing” or “social media” or “3D printing” or “4D printing” or “data analytics” or “big data” or “blockchain” or “social media” or “augmented reality” or “virtual reality” or “AR” or “VR” (Nambisan, 2017; Yang et al., 2021). The second search string included “innovat*” (e.g., innovate, innovative, and innovation), “R&D,” “research and development,” “research & development,” “patents*,” “new product development*,” and “creativity” (Acar et al., 2019; Agarwal & Kapoor, 2022). Furthermore, only articles published in the FT50 (the Financial Times’ top 50 journals), UTD24 (24 business journals selected by the University of Texas at Dallas), or 11 technology and innovation-related journals were included. This resulted in 1357 articles from 51 journals. We read various sections of each article, including the abstract, introduction, discussion, and conclusion, to screen and verify that those selected were oriented towards the mechanisms involved in revealing the impact of DTs on innovation. Finally, the number of articles was further reduced to 685 published in 41 journals between 1997 and 2023 (Fig. 1).

Fig. 1.

Data collection process.

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Although we began our effort to find articles written since 1900, the first article we found was by Liberatore and Breem (1997) on the possible influences of the adoption and implementation of digital imaging technology on banking and insurance industry innovation. Furthermore, 1900 is the earliest year available for the WoS database literature search. We included all articles written through the end of 2023, which was the endpoint of our study. Studies focusing on the principal relationship between DT and innovation have experienced an exponential surge since 2014, with 94 % of the articles in the final sample published between 2014 and 2023 (Fig. 2). As shown in Table 1, the most popular journals in our article pool are Technological Forecasting and Social Change (32 %) and IEEE Transactions on Engineering Management (15 %).

Fig. 2.

Growth of publications on DTs and innovation.

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Topic modeling is an unsupervised machine learning algorithm that can automatically identify latent themes in a large sample of articles (Blei et al., 2003). We adopted a neural topic model with pretrained contextualized document embeddings. This model builds on ProdLDA (Srivastava & Sutton, 2017), a state-of-the-art topic model that implements variational inference, and integrates a pre-trained bidirectional encoder representations from transformers (BERT) model. Therefore, this contextualized neural topic model consistently demonstrates significant improvements in topic coherence. Building on previous studies (Miric et al., 2023), the inputs for the LDA model were text corpora from the collected articles, including abstracts. Before feeding this text into the model, we preprocessed the data by removing stop words, stemming words to their root forms, and converting the text into a bag-of-words format, in which each document was represented as a vector of word counts. The algorithm treats each document as a mixture of several topics, and each topic is characterized by a distribution of words. By analyzing these patterns, the model groups words that frequently appear together, thereby uncovering the underlying themes within the data. Through a manual examination of each topic solution, we determined that the 11-topic solution yielded the most interpretable results. Our initial approach tested multiple models with varying numbers of topics, ranging from 3 to 20. The 11-topic model produced the highest coherence score while maintaining distinct interpretable topics relevant to our research questions. The other models either merged relevant themes or produced overly granular insufficiently distinct results. By selecting the 11-topic model, we ensured that each topic captured a specific dimension of the literature without excessive overlap, thereby providing a robust and meaningful representation of the research field. Based on the top ten keywords for each topic, the weights generated by the topic modeling algorithm, and the independent judgment and research experience of multiple innovation management researchers, we inferred 11 themes from these research topics. Table 2 presents the list of the 11 topics and keywords.

1) Digital enabled decision-making. Under this theme, scholars have investigated the effects of DTs on individuals’ digital thinking or mind, cognition, and decision-making behaviors in innovation activities, as well as the innovative reshaping of work boundaries (Zirar et al., 2023). 2) Digital transformation of goods/service innovation. Drawing on processual and consequential perspectives, scholars have examined how DTs affect the innovation process and product or service outcomes (Bell et al., 2024; Wang, 2022). 3) Digital transformation of organizational capabilities. Leveraging DT to develop capabilities in big data management, real-time information capturing, and business intelligence reflects a central theme in innovation research (Füller et al., 2022). 4) Digital transformation of business models and digital platforms. Under this theme, scholars have primarily investigated how DTs facilitate business model innovation through the digital extension and enhancement of traditional business models and through the digital transformation of business models (Cennamo, 2021; Stonig et al., 2022). 5) Digital communities. The disruptive impact of DTs has altered the dynamics of collaboration and competition among enterprises, making governance and design within digital communities significant research topics (Marchegiani et al., 2022). 6) Emerging DT industry. Researchers have focused on the current state and planning of emerging industries arising from DTs (Gomber et al., 2018; Willems et al., 2017). 7) Digital transformation of traditional industries. Under this theme, the digital transformation of traditional industries, such as healthcare, transportation, and education, has emerged as a key topic in innovation research (Dozier & Montgomery, 2020; Zhou et al., 2022). 8) Digital transformation of nations. Under this theme, researchers have investigated national digital investment and policy formulation, as well as the transformation of the digital economy (Okpalaoka et al., 2023). 9) Digital sustainability. DTs can offer considerable opportunities to deliver environmental and social benefits along with sustainability (Chin et al., 2022; Halbusi et al., 2023). 10) Digital societal impact. Within this theme, scholars have focused on the impact of DTs on societal functions such as the economy, education, environmental management, and public health (Bresciani et al., 2018; Zorina & Dutton, 2021). 11) Dark side of DTs or digital transformation. Studies have focused on the tangible harm and potential risks caused by DT (Stahl et al., 2023). To show the relationships among the research topics, we plotted a network graph with exemplar keywords for each of the 11 research topics. Furthermore, we conducted citation analyses to examine how topics influence the research impact of articles, as measured by citations (Bergh et al., 2006; Vakili & McGahan, 2016). The findings show that topics 2, 3, 4, 7, 8, and 9 tend to receive more citations. Overall, we provide evidence that some topics across the firm, industry, and national levels lead to more citations than others. Therefore, we should not only review highly impactful topics but also pay attention to the less impactful topics that could shed light on future research opportunities.

The proliferation of DTs and the innovations to which they contribute can be a “force for good” and facilitate the achievement of grand challenges (Murray et al., 2012). However, DTs may also create innovations that cause harm at individual, firm, and national levels.

The literature has explored numerous internal and external moderators that influence the relationship between DTs and innovation. For example, studies have identified key internal moderators such as innovative leadership (Bag et al., 2021; Reuter & Floyd, 2024), strategic flexibility (Li & Wang, 2023; Shi et al., 2023), coordination capabilities (Candi & Beltagui, 2019), and research and development activities (Radicic & Petković, 2023). Prior research suggests that organizational enablers constitute a crucial moderating factor in the DT–innovation relationship, while organizational context and technology demonstrate strong interdependence (Troilo et al., 2017). Innovative leadership (Bag et al., 2021) has shown a crucial role in enhancing the impact of big data analytics on healthcare supply chain innovation, responsiveness, and resilience, particularly during the COVID-19 pandemic (Browder et al., 2024; Savona, 2021). Li and Wang (2023) showed how DT investments affect different types of innovation, focusing on two dimensions of strategic flexibility: resource and coordination flexibility. Their findings revealed that resource flexibility can dilute the positive link between DT investment and exploitative innovation because of its substitution effect. Conversely, both resource and coordination flexibility amplify the association between DT investment and exploratory innovation, indicating a reinforcing effect of DT on innovation. Shi et al. (2023) highlighted that organizational agility can significantly enhance the abovementioned relationships between DT adoption and vertical and horizontal collaborative innovations in China's high-speed rail industry.

Moreover, external factors that affect the relationship between DT and innovation explored in the literature include technological turbulence (Candi & Beltagui, 2019) and (non)institutional regulation (Lee et al., 2022; Zhao et al., 2023). For example, Candi and Beltagui (2019) offered insights into how technological turbulence affects the use of 3D printing for product innovation, observing that technological turbulence positively moderates the relationship between the use of 3D printing in innovation and innovation performance. Regulatory frameworks, including formal and informal regulations, also significantly influence this relationship. Lee et al. (2022) showed that strong environmental regulations positively moderate the relationship between industrial robot applications and green technology innovation in manufacturing. Similarly, Zhao et al. (2023) investigated the effects of informal environmental regulation and found that it positively moderates the impact of digital administration on regional eco-innovation and enhances the relationship between digital citizenship and regional eco-innovation. Liu et al. (2023) suggested that an intellectual property rights protection system negatively moderates the relationship between DT adoption and innovation speed, as well as operational efficiency.

DTs such as cloud and edge computing, machine learning, advanced AI, and the IoT are known to disrupt human perception, with previous studies mainly focusing on human perception barriers (Mani & Chouk, 2018) and intelligent decision-making (Pietronudo et al., 2022). Considering this, future research should focus on how the broadening of human perception can contribute to algorithmic thinking and drive creative breakthroughs. Another area for future research is investigating how DTs in general and AI technologies in particular affect decision processes in organizations, which may lead to improvements or augmentation in perceptions to assist in the creation of innovations. For example, studies could explore the appropriate balance of automated, augmented, and human decision-making in driving innovative thinking in marketing and branding, strategy formulation, capability development, operations, and supply chain strategy at the highest level of the organization, such as the CEO or top-management-team level. Our topic network also confirms that there are few existing connections or a lack of research between digitally enabled decision-making at the individual level and the digital transformation of organizational capabilities at the firm level. Furthermore, since DTs frequently mediate leadership behaviors and managerial practices (Leonardi et al., 2012; Reuter & Floyd, 2024), we recommend that future research elucidate the use of DT by leaders (e.g., CEOs) as a special type of end user and examine how DTs and different DT combinations may lead to novel work designs or managerial practices. In a digital platform context, Parker et al. (2017) noted that DTs can change or modify knowledge, skills, motivations, and perceived opportunities and may lead to innovations in work design and managerial practices for better adaptation to a digital environment. Other issues to be addressed in this research stream include how DTs affect the tasks in the innovation process, what new individual competences are needed in cross-functional NPD teams, how digital cognition affects the human–machine relationship.

DTs and AI-driven applications can be used for information searches, idea generation, and value creation. At the frontend of the innovation process (Brem et al., 2023), during the ideation phase, AI tools could potentially augment human decision-making in four areas (Haefner et al., 2021): (1) scanning information spaces and identifying ideas by overcoming information processing constraints, (2) generating ideas by overcoming information processing constraints, (3) developing ideas by overcoming local search routines, and (4) generating and combining ideas by overcoming local search routines. How innovation managers can use tools such as reinforcement learning, deep learning, and machine learning for each of these tasks, and what the extent of human intervention should be, remain unclear. Furthermore, how organizations can best acquire and organize the skills necessary to perform these tasks requires further exploration Another important area for future research is examining several competing machine/deep learning approaches to identify the best fit at different stages in the innovation process across various product and service categories. This research will require interdisciplinary approaches. Finally, different DT configurations and their impact on individual innovation, innovative thinking, and innovative processes have great potential for future studies. For example, researchers can envision how AI tools, in conjunction with IoT and social media, can lead to new approaches for accomplishing tasks or solving problems.

Further down the innovation funnel, at the backend of the innovation process, AI tools and big data analytics can assist in feature selection for a chosen idea and user feedback. Future research should examine these poorly understood processes and compare them with traditional human-driven processes of feature selection and obtaining, analyzing, and acting on user feedback. As AI tools combined with rapid prototyping tools such as 3D printing may lead to new designs, research should investigate whether these are more successful than those created by humans.

Several questions regarding how digital innovations come into being based on the building blocks of DTs remain unanswered (Lyytinen et al., 2016; Nambisan, 2013). Nambisan et al. (2017) posited that the traditional segregation between innovation processes and outcomes is no longer valid in the digital age, calling for future research to examine the specific nature and dynamics of both. Researchers have taken the first step in this direction by showing how digital tools and technologies such as minimum viable products and wireframes are part of both innovation processes and outcomes (Pershina et al., 2019).

This topic cluster provides several opportunities for future research. For example, digitally transforming emerging organizational capabilities and turning them into dynamic capabilities in new ventures is an important area for exploration (Autio et al., 2018; Huang et al., 2017). Of critical importance in this research stream is the elucidation of the sources of competitive advantage in all types of companies because the extensive use of DT creates a high level of opaqueness (Brem et al., 2023) which, consequently, shrouds the real sources in uncertainty (McGrath, 2013). Therefore, future research must explore the temporal role of DTs, the transformation that they enable for organizational capabilities, and the link to the sustainability of competitive advantage. Future research may also need to focus on single organizational capabilities for digital transformation, what DTs are most appropriate, and how organizations can systematically and appropriately develop and transform a particular capability. Specifically, future research could synthesize the organizational capability and digital maturity model literature. Researchers should focus on the company itself as the target entity and call for studies on digital maturity models of organizations with an emphasis on the digital transformation of its processes, products/services, and business models.

Most studies on the digital transformation of organizational capabilities focus on organizational-level capabilities. Thus, research provides little insight into how employee-level individual competencies can aggregate and give rise to organization-level capabilities. Previous studies have identified individual competencies that explain heterogeneity in organizational capabilities (Rothaermel & Hess, 2007), suggesting that future research on the digital transformation of individual competencies should be linked to that of organizational capabilities.

We structure the discussion on future research on business model digitalization based on three key functions:1) value creation, 2) value delivery and 3) value capture. With respect to value creation, how combinations of DTs, such as digital fabrication and Web 3.0, lead to new means of value (co-)creation remains an open question. In addition, further insights are critically needed into the role of single and configurations of DTs and how they can enhance or create new value propositions. For example, value creation should be examined from the perspective of how customer data generated by AI tools and social media can enhance or create entirely new value-creation processes. Because value is frequently created in a digital ecosystem context, future research may examine how different ecosystem configurations may create different degrees of competitive advantage.

With regards to value delivery, future research could examine how a full set of DTs can achieve service innovations. The IoT, big data analytics, and cloud computing are among the most disruptive technologies for service innovation, and the role of other technologies, such as AI, augmented reality, and additive manufacturing, requires more exploration (Porter & Heppelmann, 2014). Future research should investigate the optimal configurations of DTs to create and deliver new services.

Furthermore, more exploration is needed around a better understanding of the value capture of ecosystems of business models (Teece, 2018). For manufacturing firms in the digital era, how and under what conditions investment in DTs leads to value capture between manufacturers and distributors requires further investigation. Future research should adopt longitudinal designs to explore how revenue models evolve along the lifecycle of product-centric service companies.

As more companies realize the benefits (and challenges) of being involved in digital communities to enhance their innovation processes or outcomes (Fisher, 2019), several areas fertile for future research are emerging. A fruitful area revolves around the development of measures of involvement in digital communities and how they can fuel innovation. Similarly, future research can gauge how a company's involvement in multiple different digital communities drives innovation efforts and how their unique effects can be measured. Researchers should explore whether it is better for firms to create their own digital communities or to leverage existing communities, and under what conditions this can lead to innovations with the most impact. Digital crowdsourcing platforms are a type of digital community that sources ideas or funding to facilitate innovation processes or fuel innovations. Future research should examine the development of measures or metrics to gauge the value of crowdsourcing in innovation processes and outcomes. Other studies can explore the extent to which innovation quality depends on the type of incentives provided to address a problem (Afuah & Tucci, 2012).

More research is needed on the relationship between DTs and their relationship to the emergence of entirely new industries, representing innovation at the industry level. Several issues can be addressed in future studies, such as how firms in emerging DT industries influence co-development and co-creation with other companies and companies up and down the value chain and those in traditional industries. Future studies can also examine how dominant designs develop in emerging digital industries, as well as how emerging DT industries interact and coevolve with traditional industries.

From a theoretical perspective, existing theoretical lenses can be deployed (Hanelt et al., 2021) and new theories should be developed in the DT age with the advent of new actors and constellations that may facilitate, threaten, replace, or complement existing rules in digitally transformed traditional industries. Future research should conduct industry-wide surveys to examine the factors that influence the decision to invest in DTs to develop new products, processes, or organizational innovations, as the payoff in these investments is uncertain. Other pertinent research topics for future studies include how can small and medium-sized enterprises operating in traditional industries can leverage DTs in the innovation processes available within or outside their industries. Research is also needed on the roles of IoT, AI technologies, and cloud computing in reducing the barriers to accessing indispensable assets in the NPD process. Studies should also determine the extent to which innovation ecosystems in traditional industries accelerate the digital transformation of small and medium-sized enterprises and larger companies, as well as can start-ups can foster, accelerate, and contribute to large companies’ DT use to fuel innovation.

Future studies should also examine sectoral differences in the uptake and development of DT-enabled technological capabilities and how they can enhance both innovation processes and outcomes. In addition, more insights are needed to into how the accumulation of DT-based technological capabilities or lack thereof in low- and medium-technology sectors can either widen or close the innovation gap in high-tech sectors. Future studies should focus on skills, knowledge, learning mechanisms, and systemic actors that play a role in the digital transformation process driving innovations (Peerally et al., 2022).

A body of literature has emerged on the sharing economy, which represents a significant and growing portion of a nation's economy across industries as diverse as transportation, lodging, clothing, financial services, food services, and office space (Eckhardt et al., 2019). These products and services are delivered through platform-mediated ecosystems. Future research should examine topics such as whether the sharing economy creates well-being to induce innovation and if the sharing economy cam develop innovations that reduce inequality. Firms and distribution channels in a blockchain-based sharing economy alter how firm assets can be managed and innovation processes can be optimized for effectiveness and efficiency. Therefore, future research should examine how asset transparency and enhanced trust affect how assets are managed and deployed for innovation. From a methodological perspective, techniques should be identified that allow scholars to access empirical blockchain data from manufacturing and distribution operations to study the efficiency of innovative processes.

The relationship between DTs and sustainable innovation can be examined at multiple levels. For example, a deeper understanding is needed regarding the positive and negative effects of DTs on sustainable innovation and whether the use and adoption of DTs facilitate convergence of the dual objectives of sustainability and financial performance. Future studies can also attempt to identify the disadvantages and limitations of DTs in the innovation process for sustainable products and services and in what industries is the relationship between DT and sustainable innovation is strongest or weakest. Furthermore, studies should explore configurations of DTs, such as big data, social media, AI tools, or the IoT, to maximize the success of sustainable innovations. Future studies could also adopt a meta-analytic approach to offer more conclusive evidence on the role of contextual specificities between DTs and sustainable innovations across industries and geographies. In addition, more scholarly work is needed on the relationship between DT and circular economy, a novel organizational innovation that does away with the “end-of-life” approach of products and services and replaces it with the “cradle-to-cradle” approach by effectively using DTs (Chauhan et al., 2022).

Different nations have various interpretations of the data generated by DTs. In the US, data are considered an asset that can be commercially exploited and platforms, allowing companies such as Amazon, Uber, and Tesla to profit from the data collected to develop innovations (Cusumano et al., 2019). In China, data are a public good, and digital platforms are asked to collect data that serve the state, often at the expense of profitable innovations. In European countries, data privacy is considered an individual right that requires protection, and as such, resulting innovations are defensive and reactive to regulations. Future studies should assess how these different views may affect innovation.

Furthermore, the labor force needs to be digitally transformed to fuel all types of innovation. Therefore, researchers should explore the potential impact of DTs on workers’ creativity potential and experimentation skills in the innovation process, as well as the impact of DT on the working conditions of those involved in this process. Future studies are also needed to identify the tasks in the innovation process that are best performed by DTs and those that are better conducted by humans. The new worker tasks that will emerge to complement DTs in the development of new product and service innovations must also be identified. Some workers will be displaced because AI will automate their tasks away. Therefore, research must address how these workers can be redeployed in other industries where their skills will be valuable in innovation.

Several research gaps exist for this topic cluster, as most of the icebergs that represent the dark side of DTs remain submerged. From a methodological perspective, beyond focusing on pure survey data, future studies should adopt longitudinal research designs, large-scale randomized controlled trials, and experiments to assess how the feelings and perceptions of DT users are aware of and deal with DT-enabled innovations with profound adverse side effects. More research is required on what motivates individuals and firms to use DTs to develop harmful innovations such as hacker software, digital ransom apps, cyberbullying, and gambling apps. Future research can also explore the product features responsible for adverse effects and how these can be redesigned to minimize the harm inflicted on users. Further research could also explore the unauthorized use of data obtained through the IoT or social media for the development of new innovations. Overall, more research is needed on the mitigation mechanisms that could be deployed to cope with the negative impact of harmful DT-enabled innovations.

Future research should explore the moderating impact of national culture on the DT–innovation relationship, as culture may affect DT adoption rates and thus innovations enabled or produced by DTs (Steers et al., 2008). Similarly, more insights are needed into how DTs shape organizational culture and all types of innovation. Future studies could also assess the moderating effects of industry, competitive intensity, environmental dynamism, market turbulence, and firm size on the principal relationships studied. At the firm level, different leadership styles may affect how DTs will lead to innovations at various levels.

As with any other study, this review has several limitations. First, although we focused on how DT affects various domain innovations across multiple levels, we did not consider the process level of analysis, which is important because innovation is a process. For example, the digital innovation process may involve various steps including initiation, development, implementation, exploitation, outcomes, and feedback, with each step requiring different resources, structures, routines, and performance evaluations. Future reviews could investigate the different (sub)-processes of digital innovation processes. Furthermore, a more comprehensive treatment of various institution-related moderators can be considered, such as cultures and the rule of law (Chen et al., 2024). Another limitation relates to the number of mediators considered. For example, several attributes of the top management team and employee skills can serve as important mediators in converting DT into various innovations.