The emergence of AI and Big data in HE is a recent phenomenon that lacks both conceptual and empirical research (Hinojo-Lucena et al., 2019). In a bibliometric analysis of the scientific literature, Hinijo-Lucena et al. (2019) show that the most cited articles between 2007 and 2017 focus on two main themes: 1) development of virtual tutoring to improve learning; 2) use of intelligent systems to predict student mood and learning style. The first theme questions the role and place of tomorrow’s teacher alongside intelligent machines. The second theme questions the personalization of learning and more generally the performance of the tools and methods proposed to students. More generally, both themes question the identity of the teacher, the way of learning and the control of learning by the learner, but still conceal many submerged educational issues and allow us to imagine the extent of the underground transformations at work in the field of HE.

To explore the underside of the iceberg, we do a thorough review of the extant education management research to assess the current state of the field in relation to the use of digital technologies. In so doing, we identify the key dimension of management education that would be more likely impacted by the emerging digital transformation and implementation of digital technologies. Using an inductive approach, we reviewed over 100 articles dealing with digital technologies and education. Our literature review reveals that five areas in the sphere of education management will most benefit from digital transformation including nature of knowledge, learning processes, methods and tools, learning spaces, and teachers. These five key dimensions were in turn incorporated to form our theoretical framework. Then, our empirical investigation turns to exploring how the adoption and implementation of AI, as a disruptive, cutting-edge digital technology, may benefit and transform the key dimension of management education as portrayed in our theoretical framework. In table 2, we propose an overview of the themes and the related issues in this emerging area.

Big Data and AI are based on the further development of knowledge. The current development of new digital technologies in HE raises questions similar to those asked when books dispossessed scholars of their role as producers and disseminators of knowledge: what should be done with this immense external storage capacity for the information produced? Which pieces of information are necessary to allow students to deepen their knowledge of a subject, to the point of eventually becoming an expert? How durable is the knowledge acquired? (Serres 2014; Watters, 2017). In this way, future knowledge development relies on the mobilization of three forms of memory: human memory (partial, contingent, malleable, contextual, erasable, fragile), material memory (permanent, stable, unchangeable) and digital memory (easy to erase, stored in files that may become obsolete, relying on electricity and batteries that are rare elements dependent on the environment and politics) (Watters, 2017). The combination of these three memories is a source of complexity and fragility.

Furthermore, if quantitative data production takes precedence over qualitative production, our collective memory may be at risk in this abundance of digital information (Boyd and Crawford 2012; Droll et al., 2017). With this growing body of data, researchers will thus have to be able to avoid misinterpretations: the models discovered may be false (Prinsloo et al., 2015). They will also play a very important role in rigorously cross-referencing public and private data to produce quality statistics on economic behaviour (Einav and Levin, 2014).

Like books, AI and Big Data can contribute to improving learning by providing a rich and easily accessible digital environment for learning different subjects, such as mathematics (Brown, 2015). Additionally, the use of these technologies in HE frees both time and brain resources allocated to certain technical and rational knowledge, making it possible to focus attention on the development of imagination, creativity, inventiveness, reflexivity and emotional awareness (Pink 2006; Serres, 2014). Other researchers stress that the emergence of Big Data and AI in all sectors of society will force educational institutions to radically transform themselves—something they have not been able to do for several centuries—by focusing more on experimentation and the development of an intelligence which is no longer based on memorization.

The qualitative use of Big Data leads to more personalised study pathways by improving, for example, students’ knowledge of their own personalities, which means not just a fixed description of their characteristics but also understanding their cognitive processes, that is, their ways of acting, thinking and expressing themselves (Boyd and Pennebaker, 2017). Digital technologies, including social platforms and networks, play a crucial role in strengthening collaborative and social learning by improving information selection, enabling learners to connect with the right people and motivating community members who contribute and collaborate (Al-Dhanhani et al., 2015). The mobilization of these new learning resources therefore questions the nature of the knowledge produced and the evaluation of learning (Calderón and Ruiz, 2015; Manero et al., 2015; Fox et al., 2018).

Technologies related to AI and Big Data are available in the form of a wide variety of tools that support blending learning-based pedagogical approaches (Jones and Lau 2010). Stevenson and Zweier (2011) mention the “flow of learning” concept, which is based on mixing faculty learning (small groups) with help from a teaching assistant and/or a tutor. Mentoring and/or intelligent tutoring via a chatbot allows the student to progress towards his or her learning goals (Redfield and Larose 2010; Cavanaugh 2017; Hinojo-Lucena et al. 2019).

Mentored training is personalised and can be done remotely and at the university (McAndrew et al. 2010). Students build the learning experience by themselves and move along a pathway previously established with the help of their personal data (interests, previous academic background, professional background, etc.). The programme is varied and includes digital textbooks, participating in MOOCs (Al-Atabi and DeBoer, 2014), social platforms and networks (Al-Dhanhani et al. 2015), E-Conferences (Shi and Morrow, 2006), and carrying out assignments based on structured and non- structured data (Bryant, 2017). Students also participate in certain activities, for example, courses based on experimentation in the form of small group practical projects guided by a teacher, participation in a video game (Martín-San José et al., 2015), or immersion with total interaction via virtual reality: “immersive learning will surpass active learning, which in its day surpassed passive learning in effectiveness” (Hinojo-Lucena et al., 2019). At the university level, the analysis of data produced through Big Data and AI can strengthen the quality of teaching programmes, student monitoring and strategic decisions in order to adapt more quickly to educational needs (Daniel, 2015).

Technology is a resource. It implies the creation of adapted learning environments, facilitating active, engaging and collaborative use of technology (Tritz, 2015). Aided by new digital technologies, learning allows learners to define what and how they wish to learn (Seely et al., 2008) by interacting with members of the learning community (other students, teachers, etc.) (Joksimović et al., 2015a; 2015b). AI and Big Data amplify the possibility of learning from different locations, whether private, public, personal or professional (McAndrew et al., 2010). This evolution therefore raises questions about the future definition of the university learning space (Toutain et al., 2019).

AI and Big Data also offer new solutions for creating and managing academic programmes and university functions, and for monitoring students as they move along their personalised study pathway. This personalised learning system is strongly linked to the development of an organic system, which encourages interaction and the use of a diversity of data sources and technological tools adapted to the learner’s specific needs (Shulman, 2016).

Big Data and AI are accelerating the transformation of an educational model traditionally tasked with “civilizing each generation of children as if they were a barbaric invasion” (Arendt, 1971). The traditional educational model is generally a closed model, limited in its space, specialized in transmitting knowledge in an authoritarian manner by one type of intelligence (that of the teacher), considered superior to other types of intelligence (that of the learner) (Rancière, 2014). Such model is disappearing in favour of an open, permeable system that moves beyond the physical limits of the learning space, crossing disciplines, and multiplying interactions with actors in the environment outside the school, as well as technological tools and ways of learning (McAndrew et al., 2010).

AI and big data also redefine the nature of the knowledge to be transmitted, the learning process, the tools and methods used to learn, the dedicated spaces and the role and place of the teacher. New stakeholders (i.e. computer scientist, social scientist, tech giants, or the new actors of the digital economy in education—tutors, trainers, publishers) play a growing role. In this context, the aim of our research is to observe, from the perspective of AI-Edtechs, the paradigm transformation processes at work in management education. Overall, given the immense potential of AI to disrupt the current paradigm in management education, through the five dimensions presented above, we collect data on 765 Edtechs to examine how their mission statement may disrupt and change the institutional arrangements in the field of education.

To explore our research question, we collected data on 785 new ventures which were listed on Crunchbase and Angelist in 2019 as startups in an early funding stage (seed and series-A) and were categorized in both “AI” and “education”. The final sample of 785 startups was reached after a manual cleaning of the larger sample of 1152 startups based on the two matching categories. For instance, we eliminated startups whose mission statement and activities were unrelated to education, such as training tools for specialized professions or Entreprise-Resource-Planning software companies. These Edtechs in the final sample employ AI systems and associated technologies to provide innovative tools to augment or transform education. We relied on a set of descriptions that explain the mission statements, visions, and goals of the Edtechs under study. In our analysis, we relied on the descriptions that are most relevant to how the investigated Edtechs transform the world of education through the adoption and implementation of AI. Since the descriptions are mostly provided by the startups to the two online platforms, we were aware that they represented the narratives of the mission rather than actual implementation. In the meantime, given our aim to examine the ways AI may disrupt management education, studying mission statements is relevant in that they reflect the values and aspirations of the startups (Grimes, Williams, & Zhao, 2019), and thus may well represent their strategic intentions (Crilly, Zollo, & Hansen, 2012). Consequently, mission statements are useful information in the study of how some of the main actors in the educational ecosystem intend to disrupt the field. In the management literature, mission statements have been widely used to elicit strategic intent (Bart Baetz, 1998; Klemm, Sanderson, & Luffman, 1991; Sidhu, 2003), and therefore represent an important source of information for understanding an organization’s values, intent and behaviours.

As our aim was to unravel the mechanisms that explain how Edtechs impact the world of education through AI adoption and implementation, we pursued a grounded theory approach to data analysis (Strauss & Corbin, 1990). The analysis process involved three main stages: 1) Identifying relevant segments of text through “micro-analysis”; 2) creating a large set of codes through “open coding”; and 3) Identifying the key themes or AI mechanisms through “axial coding”, while relating these latter to the identified key dimensions from our review of the literature. Table 3 describes the three stages.

In this study, we consider AI as an umbrella technology that comprises machine learning and deep learning techniques (Agrawal, Gans, & Goldfarb, 2018), whose functioning is deeply dependent upon the availability of data or “big data”, that is, large-scale data made available through cloud storage (Microsoft Azure Architectural Guide, 2021). Therefore, big data and cloud computing technologies are assumed to be supporting technologies for AI and thus are mentioned in that sense. For instance, when mentioning big data as a technology in a particular service, it is assumed that the use of big data has a broader purpose such as the exploitation of these large-scale data through AI-based algorithms in the case of personalization of learning experiences.

First mechanism: AI-driven knowledge creation and sharing. This mechanism captures how the frontiers of scientific knowledge are being expanded through novel research collaborations and creative knowledge sharing. The Edtechs deploy AI-associated technologies to bring together multidisciplinary researchers with the aim of creating synergies that result from closer links between AI and ML scholars and experts on one side, and other disciplines’ researchers and specialists on the other. Despite their heterogeneity, these different actors rest on the consensus that AI and its pioneering technologies can advance significantly various fields of research including education.

AI can be deployed as a vehicle in the knowledge creation process, that minimizes the need for human intervention. The process of knowledge creation involves investigating complex phenomena and framing novel solutions to unresolved problems. Toward achieving this aim, colossal amounts of data need to be treated, processed, and interpreted; a task that turns out highly challenging and unlikely achievable by the sole human intervention. A number of contemporary educational organizations have recognized the need for tuning their knowledge creation processes with AI-based systems and tools. This does not only attenuate the need for “armies of people” to pursue research quests, but also help scholars and researchers figure out the right, “root-solving” problems to focus on. Here, we emphasize the element of human-machine collaboration as a key building block of AI-driven education organizations. Our conception of AI-generated education management models incorporates AI as a human augmenter, and thus sees future collaborations between machines and humans as fundamental to the sustainable functioning of contemporary educational institutions. Further, the role of AI in shaping the knowledge sharing process will depend on educational institutions’ capabilities for performing precise prediction of incremental shifts in market aspirations in terms of human capital skills and competencies. As such, knowledge sharing and transfer would be directed toward equipping the right skills and capabilities, thus fulfilling organizations’ needs for talented, pertinent profiles.

The Edtechs relied in their mission statements on phrases such as “collaborative knowledge sharing”, “gathering of experts and researchers”, and “multidisciplinary research laboratory” to outline this emerging trend for collaborative research and knowledge sharing among AI and other fields’ scholars to push the limits of the existing scientific knowledge. These accounts mirror the emerging collaboration between a multitude of disciplines including management scholars and researchers from scientific disciplines.

Further, our first mechanism delineates how Edtechs deploy the potential of AI to advance the way knowledge is constructed by scholars and researchers. For instance, within the field of healthcare it has been suggested by recent research that ML algorithms can provide more reliable medical diagnosis as compared to traditional diagnosis performed by human doctors. In the era of cutting-edge digital technologies, the creation of knowledge is no longer a mission restricted to scholars and researchers.

Second mechanism: AI-enabled hyper-personalization of learning. Our review of the literature reveals that the learning process can be improved through a number of different elements relevant to digitalization. Our qualitative analysis led to identifying a second mechanisms that delineate how Edtechs deploy the potential of AI to tackle the pedagogical challenges that hinder the improvement of educational learning processes.

A key distinguishing element that characterizes AI technologies is self-learning capability (Ferràs-Hernández, 2018; Mazzei and Noble, 2017). As opposed to existing digital technologies, ML algorithms are capable of learning. They first learn from the tremendous amounts of data provided to construct and train the algorithms through establishing meaningful patterns among the multiple data variables. Interestingly, this process of autonomous learning continues through the interaction of the machines with the users once the algorithm is operational, thus progressively increasing the reliability and accuracy of the algorithmic predictions.

While traditional algorithms are built to perform a predetermined set of tasks, AI algorithms are built to learn from past, current, and future interactions with the user. In this respect, we surface the mechanism of hyper-personalization as a key tenet of the future AI-driven education management. We advocate the emergence of a new pedagogical paradigm, which is enabled by AI learning and predictive capabilities. ML algorithms are designed to learn from curriculum historical data to identify patterns in relevance to the specific needs of each student. While the traditional pedagogical system is designed to meet the needs of large groups of students following pre-determined disciplines and fields of study, the AI-driven pedagogical system tends to hyper-personalize the taught material to match the particular needs and aspirations of students on an individual basis. Thanks to continuous interactions with students, ML algorithms can identify students’ areas of improvement and areas of strength, and thus provide highly personalized career recommendations and tips for improvement.

The extreme heterogeneity that characterizes today’s classrooms renders the process of learning highly complex and ineffective. Relying on state-of-the-art AI systems, Edtechs try to tackle this pedagogical issue through achieving a better understanding of students’ specific cognitive capabilities, career aspirations, and learning needs. Accordingly, classes can be built and structured based on personalized content and learning outcomes, thereby maximizing the learning and responding to the very specific needs of learners in various academic institutions. These Edtechs rely, in their mission statements, on phrases such as “find the best teacher”,’according to their needs, knowledge, and interest’, and ’adapted to each student’s learning abilities’, to signal the importance of personalization in responding to highly specific needs and aspirations of students who may have significant variations in their intellectual and cognitive abilities, skills, knowledge, and competencies.

Third mechanism: AI-maximized efficiency and productivity of learning. The extant educational management research summarizes the emergence of a host of new tools, technologies, and methods that can potentially revolutionize the world of education (Maritz, Brown, and Shieh, 2010). Our analysis reveals that the ultimate goal for developing and creating new innovative, novel learning tools and methods is to maximize the efficiency and productivity of learning. We label, thus, our third mechanism “AI-maximized efficiency and productivity of learning”. This mechanism portrays the process through which Edtechs use AI-based technologies to improve the educational efficiency and productivity not only in academic institutions, but within professional settings as well.

AI-based tools have revolutionized the traditional learning mechanisms in unprecedented ways. For example, a key distinguisher of AI is its ability to emulate complex human behavior (Shneiderman, 2020). Synthesizing educational material is a task that has been traditionally exclusively performed by human teachers. Our analysis reveals that ML algorithms can provide more accurate and more reliable material syntheses and summaries. Our argument lies in the idea that instructors and lecturers construct summaries based on specific cognitive capabilities. Yet, the viability of such competences is restricted by the teachers’ limited capacity for data processing and understanding, making AI a promising avenue for revolutionizing the learning experience. Relying on natural language processing (Kang et al., 2020), AI can learn then emulates the complex human behavior of synthesizing, performing it with a much higher efficiency, accuracy, and reliability. As such, Edtechs attempt to tackle the efficiency and productivity issues to maximize and accelerate the learning among various audiences of learners.

Fourth mechanism: AI-augmented learning environments. Our review of the literature suggests that learning environments in the future will be diverse (McAndrew et al., 2010), involve active and engaged use of digital technologies (Seely and Adler, 2008; Tritz, 2015), and help the learner engage with the members of his/her community to identify his/her learning aspirations (Joksimović et al., 2015a, 2015b). In relevance to the learning spaces aggregate dimension, our qualitative analysis revealed a fourth mechanism that depicts how educational learning environments can be augmented through AI pioneering technologies.

We identified an emerging trend among the Edtechs for creating universal world-classes. AI can help democratize universal classrooms and make them available to all including learners who speak various languages, suffer certain handicaps, or need special arrangements. AI-systems can help people with special needs or skill deficiencies maintain active participation in class, namely in heterogeneous learning environments that are characterized by a diversity of learners. Further, some Edtechs are creating smart virtual environments and applications that draw on AI and augmented reality to develop authentic virtual characters and realistic social interactions. The idea is to complement traditional educators with virtual human-like characters that can interact with learners in a natural way. Such examples illustrate useful applications that are enabled by the emulation, automation, and augmentation capabilities of AI. These use cases disrupt the traditional education paradigm and result in novel configurations of the existing educational business models. As a result, important structural reforms are required to adjust to the emerging AI-driven education paradigm.

Fifth mechanism: AI-empowered educators. Early education management research suggests that the evolution of the teaching occupation is dependent on a number of factors including the nature of the piloting of the academic programs and student support (Tritz, 2015; Shulman, 2016), the formation of multidisciplinary teams (Tritz, 2015; Brown, 2015 Shulman, 2016), and the definition of new forms of leadership to assist students given the specific needs of each learner (McAndrew et al., 2010; Shulman, 2016). An important part of an educator’s occupation is concerned with non-teaching tasks such as grading, assessment, and routine admin tasks that are highly time consuming and effort demanding (Fournier, 2019). In this vein, a number of Edtechs explore how AI systems can relieve some of the efforts that are associated with these challenging tasks, thereby empower educators to focus on more important silos of their occupation such as closer and more personalized follow-up and monitoring of students. Accordingly, we label our fifth mechanism “AI-empowered educators”. Human-AI collaboration surfaces as a pilar of the evolving AI-driven education paradigm and an “ethical”, “socially acceptable” implementation strategy for educational institutions that aim at enhancing the capabilities of their collaborators, as supposed to the radical alternative of an integral replacement of their human capital.

The rise of AI questions many tenets of the current knowledge creation and sharing practices including: 1) the traditional educational ecosystems by decompartmentalizing between disciplines and professions to bring together the interests of very heterogeneous actors, thus facilitating their networking, collaboration and cooperation (both professionally and geographically); 2) the verticality of the discipline, defined by the recognition of experts specialized in management and recognized by their peers, in favour of a horizontal model, which crosses fields of expertise and scientific disciplines; 3) a planned and stable approach to the content of the knowledge to be taught to the benefit of unlikely associations of information favouring the emergence of new and unfixed knowledge (data relatability); 4) the nature of the management knowledge to be taught (didactic level of teaching) as well as the way to teach it (pedagogical level); 5) the deployment of new means to implement pedagogies based on learning experience and the shared construction of knowledge.

The results observed in our study show that Edtechs can contribute to the acceleration of a movement to break down barriers between disciplines and professions. The need to mobilize AI and to have massive digital data brings together the interests of these very heterogeneous players. Consequently, our study shows that the technologies of the Edtechs calls into question the nature of the management knowledge to be taught (didactic level of teaching) as well as the way of teaching it (pedagogical level). The analysis of the positioning of the Edtechs thus shows that they are no longer the only management specialists, but rather extended multidisciplinary networks, both public and private, which are already involved in defining the new knowledge to be taught. Thus, the study of the positioning of Edtechs in the creation and sharing of knowledge extends the general approach of the literature on the impact of AI and massive data in education.

Our results show that Edtechs which mobilize AI and massive data in the field of education offer tools and methods that contribute to a reinforcement of the personalization or even hyper-specialization of learning, to offer teachers more information (especially socio-cognitive information) about their students, to act on the student’s motivation in order to encourage his or her involvement in the learning process, and to optimize the adequacy of the teaching offer with the individual demand for learning. First, the mobilization of AI and Big data via Edtechs offers the possibility of providing a better knowledge of the student’s learning capacities based on her or his learning path, results and preferred ways of learning. Second, some Edtechs target the motivation and commitment of the student in his or her own learning. AI may be an effective tool for improving the development of the feeling of self-efficacy in management education. Third, AI can enable students to mobilize teaching according to their desires, needs and desired teacher. This approach underpins a vision of education considered as an offer proposed to potential applicants (students) in a principle of market economy education. The student is thus led to make personal choices that can reinforce his or her autonomy and the responsibility it entails.

However, the growing literature on algorithmic bias raises the risk that automated choices may produce discriminatory outcomes (Lambrecht & Tucker, 2019). Given that ML algorithms are trained on historical data and reinforced with new personal data, the risk is particularly pronounced in the case of hyper-personalization of learning as learning style (the way a student learns) tends to differ between males and females (Severiens & Dam, 1994), between cultures (Carroll & Garavalia, 2002), and between social classes (Cooke et al., 2004). Therefore, using automated algorithmic decision making for personalized learning raises the risk that the algorithm may reinforce an existing bias through offering contents and experiences that fit with the personal preferences of female or male students. For example, past studies show that learning process influences study choices and performance of male and female students in college such that the way we teach science may discourage female students to enroll in science programs (Severiens & Dam, 1994). In management disciplines, the difference in attitude between female and male students in teamwork may widen if the algorithm segments the learning process based on gender (Kaenzig et al, 2007). Automated personalized learning based on past learning preferences of female students may reinforce such bias rather than correcting it. An important task is to account for potential biases in this area and examine potential solutions to avoid them or, even better, to correct them.

AI-based tools and methods can improve the effectiveness and efficiency of learning in several ways. AI and massive data facilitate the exploitation and analysis of information in a way that is adapted to the needs and comprehension capacities of the student. Also, AI can help the student experience what he or she knows through immersion in a distant and/or virtual universe. Finally, AI-Edtechs are now able to offer tools aimed at bringing the student’s demand closer to the company’s needs, which potentially favours his or her professional integration. More generally, the growing heterogeneous offer of Edtechs allows students to learn in a more personalized, engaging and faster way. However, the quest for efficiency and productivity may also come with new challenges. The greater accessibility to information and knowledge offered by AI does not guarantee the quality of successful learning. For instance, less time spent on a subject can generate “butterfly” behaviour, i.e. scattered, superficial learning that is not anchored in the memory and, in the end, loses its sense of usefulness.

AI-solutions can potentially accelerate the transformation of learning spaces. Our findings reveal that the services Edtechs offer raise the possibility of universal international classes. AI increases the possibility of involving a wider variety of participants from all over the world by reducing constraints related to the place of learning (e.g. physical presence in the classroom, the problem of geographical distance or disability). The technological solutions offered by AI thus provide greater teaching flexibility adapted to the constraints of the school, the participants and the teaching community (teachers and external stakeholders such as experts and collaborating teachers). Thus, the use of AI and massive data offer the possibility of preserving and combining particularities that were formerly inevitable barriers to learning. The reorganization of learning spaces and their enlargement without spatial limitations encourage management schools and their teachers to reconsider the use of traditional places of learning.

Our study shows that AI-Edtechs are now able to offer tools capable of alleviating time-consuming and repetitive tasks for teachers in higher education: administrative management of programmes, teaching and management of the resources involved, and management of student activities, particularly those related to the administration of exercises, automated answers to common questions (automated chatbots), real-time feedback, classification, progress and evaluation of their work. Thus, the automation of certain tasks and activities opens new opportunities for teachers and especially management educators (deeply connected with professional world) to develop new pedagogical approaches and new partnerships with the educational learning ecosystem, mobilize new tools, have more precise information about the student, his abilities, difficulties, involvement and progress in the training.

Our study involved the analysis of written and communicated information on a sample of Edtechs operating internationally. Given that mission statements are meant to be concise, future studies should examine larger written information with more detailed accounts of the mission and role of Edtechs. For example, we have not accounted for the cultural disparities, and more generally the political and educational contexts of the countries in which an Edtech belongs. The educational landscape is changing very quickly and amplified by events such as the coronavirus crisis. Future studies should examine and account for these limitations. Finally, a reasonable assumption is that our findings mostly apply to developed countries as they rely heavily on advanced technologies to enhance management education, and thus will be impacted by technological disruption (such as AI) earlier than countries with less technological endowment. We therefore encourage scholars to conduct cross-country studies to investigate whether the impact of AI on management education ecosystem is moderated country-specific characteristics such as technological infrastructure, educational system or simply geographical location. Further, it is important to delineate that effective AI adoptions require a set of pre-requisite structural adjustments. AI implementations require a ground of solid technological and data infrastructures. Given the technical and organizational complexity of AI implementations, we predict that areas of the world, sectors, and organizations which lack basic technological infrastructures, a proper corporate culture for technology acceptance, and the necessary capabilities for efficient data management are likely to benefit less for the current era from the evolvement of the AI-driven education paradigm. Future studies may examine such assumption. Finally, our sampling method was based on the categorization of Crunchbase and Angelist to identify AI-based education startups (using “AI” and “Education” as keywords for categories). We acknowledge that this may lead to including startups that do not operate directly in high education. In the meantime, the lens of the theory of diffusion of innovation (Rogers, 2010) suggests that a compelling innovation tends to diffuse to other fields (e.g. from secondary to higher education institutions) once it is broadly adopted by a segment of the population.