Social enablers of Industry 4.0 technology adoption: transformational leadership and emotional intelligence

2.1 Industry 4.0 adoption and the role of social factors

Industry 4.0 encompasses manufacturers' digital transformation of their production systems towards more smart and dynamic versions by adopting an ever-growing list of cyber-physical system technologies, thereby enabling new and more efficient customisable and connected processes, products and services (Tortorella et al., 2019). Examples of such front-end technologies are sensors, additive manufacturing, augmented reality and rapid prototyping using 3D printing (Frank et al., 2019; Tortorella et al., 2019), which are supported by base technologies (Frank et al., 2019), such as the Internet of Things (IoT), cloud services, big data and analytics, to enable vertical, horizontal and end-to-end integration of the organisation with its supply chain (Chiarini and Kumar, 2021). In its most radical form, digital networks of technologies enable high-end production with minimal manual intervention (Olsen and Tomlin, 2020; Wagire et al., 2021). The increasing attention to Industry 4.0 is primarily due to the need to overcome the inherent complexity of implementing such technologies (Hahn, 2020; Thoben et al., 2017).

Since the concept was launched in 2011, a plethora of advanced/Industry 4.0/smart technology adoption and digital transformation maturity models have emerged (Colli et al., 2019; Mittal et al., 2018; Saabye et al., 2022). These models mainly focused on the type, level, complexity and scope of technology integration into operations. The basic underlying assumption in those models is that the effectiveness of advanced technology adoption depends on the comprehensiveness of technology integration.

But the fourth industrial revolution has major implications for the work organisation (Cagliano et al., 2019) and the sociotechnical aspects of advanced technology adoption are still understudied (Marcon et al., 2022; Saabye et al., 2022). Indeed, recent reviews on manufacturer's adoption of Industry 4.0 did not highlight the role of employees in acceptance and the effective adoption of Industry 4.0 (Schneider, 2018; Schneider and Sting, 2020), even though Industry 4.0 adoption is likely to lead to employee reorganisation and requires certain skills (Calabrese et al., 2021; Srinivasan et al., 2020). Similarly, Kummer et al. (2017) examined the use of sensor-based technologies in healthcare and reported how technology-induced anxiety creates negative emotions, apprehension and fear of using the technology and, in turn, can affect employees' decision to accept or resist a technology. Reflecting on the important role of management practices in Industry 4.0, Shamim et al. (2016) proposed a framework that highlighted the critical role of organisational structure, leadership and HR practices in providing an environment for learning and innovation compatible with Industry 4.0 practices. Furthermore, managers can influence innovativeness and learning among employees (Tan et al., 2021), e.g. by adopting the right HR practices required for embracing Industry 4.0, but Shamim et al. (2016) failed to highlight how managers can influence digitalisation-induced change among employees.

A barrier to adopting Industry 4.0 may be “internal resistance to organisational changes” (Calabrese et al., 2022; Da Silva et al., 2020; Marcon et al., 2022) as it challenges employees to relinquish the status quo in preparedness for reskilling or upskilling, apart from the financial and technological challenges (Liboni et al., 2018; Srinivasan et al., 2020). However, Piderit (2000) and Oreg et al. (2018) critiqued the “resistance to change” metaphor as research fails to account for good intentions of resistors and also variability in the conceptualisation of resistance. The research suggested that resistance to change can be best understood by capturing the employees' attitude towards change which can be cognitive, emotional and intentional. Even though employee's attitude towards digitalisation-induced change is critical (Schneider and Sting, 2020), scholars have paid limited attention or provided evidence to the issue of employee acceptance, with most relying on conceptual studies to allude to acceptance problems among employees (Hirsch-Kreinsen, 2014; Piderit, 2000; Schneider, 2018; Strebel, 1996). Therefore, it is important to capture employees' attitudes towards change or managers' responses to change, a growing area of interest in Organisational Behaviour studies.

Schneider (2018) and Schneider and Sting (2020) highlighted some key areas for future Industry 4.0 research including conducting exploratory qualitative in-depth case studies focusing on socio-cultural aspects including changing roles of workers in a manufacturing setting, to identify contextual factors impacting managerial decisions on using Industry 4.0 technologies and creating acceptance in employees to embrace digitalisation-induced change. In the literature review conducted by Schneider (2018), it was reported that no single contribution provided empirical evidence of employee or managers' perspectives regarding the acceptance of Industry 4.0 solutions. Similar gaps were also reported in earlier publications (Dombrowski and Wagner, 2014; Hirsch-Kreinsen, 2014; Kummer et al., 2017; May, 2015). Both Schneider (2018) and Schneider and Sting (2020) called for more field research and observations to explain managers' role in convincing employees to embrace digitalisation-induced change. Furthermore, as underlined by Olsen and Tomlin (2020, p. 118), studying the acceptance of Industry 4.0-type technologies seems “like a natural line of inquiry for the OM field”. This leads us to the literature on technology adoption and employees' acceptance of those technologies for driving technology-induced change in organisations.

2.2 Factors influencing employee acceptance and use of technology

One of the existing theories regarding employee's acceptance of technology is the extended Technology Acceptance Model (TAM2), coined by Venkatesh and Davis (2000). The original TAM demonstrates three important factors that influence one's usage of new technology, namely, perceived ease of use, perceived usefulness and intention to use (Davis et al., 1989). This model is strongly built upon the theory of reasoned action (Fishbein and Ajzen, 1975). The extended TAM (labelled as “TAM2”) adds social influence processes (e.g. subjective norm, the voluntariness of technology usage and image) and cognitive processes (job relevance, output quality, result demonstrability and perceived ease of use) (Venkatesh and Davis, 2000). The integrated TAM model (i.e. “TAM3”) then further reduced so called “crossover effects” between the various antecedents of behavioural intention (Venkatesh and Bala, 2008), while adding to the determinants of perceived ease of use (based on Venkatesh, 2000).

Synthesising the aforementioned and other existing models related to technology acceptance, the UTAUT model was introduced (Venkatesh et al., 2003; Williams et al., 2015). UTAUT distinguishes four antecedents of people's intention to adopt technology, and, in turn, usage behaviour: performance expectancy, effort expectancy, social influence and facilitating conditions (Williams et al., 2015). Following the UTAUT model, people will embrace technology when they have a reasonable expectation that using the technology: 1) will lead to favourable results; 2) will not cost too much effort; 3) will be supported by others; and 4) will have enough resources and guidance for implementation. Hence, a supportive environment for innovation is key. This corresponds with the main tenets of employee innovation literature. A psychologically-safe climate for innovation must exist for employees' innovative work behaviour to occur (Scott and Bruce, 1994). Leaders are crucial in enabling the creation of such a climate (Anderson et al., 2014).

Nonetheless, the different versions of UTAUT nebulously identify managers' role in positively influencing workers' acceptance of technological adoption (Vidyarthy et al., 2014). Only recently, a meta-analysis and conceptual paper identified the need to expand the UTAUT model and analyse multi-level variables, like leadership (Blut et al., 2022; Venkatesh et al., 2016). In addition, the UTAUT model failed to account for how to effectively deal with employee's emotions and how it affects employee's adoption and acceptance of new practices (Venkatesh, 2000), which may be especially harmed when those practices may affect job or status loss. Although the UTAUT model has its limitations, a variety of Operations Management studies on Industry 4.0 have used it as a fundamental, ranging from understanding employees' blockchain technology adoption (Pieters et al., 2022; Queiroz et al., 2021) to the adoption of electronic marketplaces (Collignon and Sternberg, 2020) and the use of big data (Aloysius et al., 2018). This study, therefore, explores how managers can effectively facilitate employees' acceptance of Industry 4.0 technology adoption using the UTAUT model as a springboard for a further model extension.

2.3 Manager's leadership style and employee's acceptance and use of Industry 4.0 technology

Leadership support for digital transformation activities has been ranked as one of the key criteria for a firm to mature its Industry 4.0 technology adoption (Wagire et al., 2021). As noted by Da Silva et al. (2020, p. 12), the role of “leadership will be instrumental in conducting changes in the company” as Industry 4.0 technology adoption affects both the organisational structure and culture. The plethora of publications on effective leadership in the past decades of increasing industrialisation introduced many leadership theories (Lord et al., 2017). As elaborated below, among the most prevalent are leader–member exchange, transformational leadership, transactional leadership and shared leadership (Lord et al., 2017).

Venkatesh and Bala (2008) suggested leader–member exchange theory (Liden et al., 1997) to better understand the impact of management support on information technology adoption. Leader–member exchange proposes that the quality of the dyadic relationship between managers and their subordinates differs per individual, and, as such, managers have a different impact on different employees (Lord et al., 2017). Based on cross-sectional survey data, such dyadic differences have indeed been found to impact TAM's perceived usefulness variable (Magni and Pennarola, 2008). Therefore, these studies assume a personalised leadership approach is most effective in the context of technology adoption.

A leadership style that follows a personalised approach entails transformational leadership which was first introduced by Burns (1978) and then further developed by, most prominently, scholars like Bass and Avolio (Avolio et al., 1999; Bass, 1985, 1990, 1999). Transformational leadership theory states that managers, through their leadership behaviours, impact (or ‘transform”) their employee's collective identification, value internalisation and self-efficacy (Siangchokyoo et al., 2020). These leader behaviours have been summarised in the following four subdimensions, namely, manager's provision of idealised influence (i.e. charisma), inspirational motivation, intellectual stimulation and individualised consideration (Bednall et al., 2018; Peng et al., 2021). It is through these behaviours that transformational leaders are suggested to impact their followers' motivation for (organisational) change and innovation (Tan et al., 2021, in press). Shamim et al. (2016) also noted that transformational leadership had been associated with innovation and learning, which are relevant to Industry 4.0 technology adoption. Schepers et al. (2005) noticed that especially the intellectual stimulation subdimension might boost employee's perception of the usefulness of technology at work by encouraging their imagination and innovative thinking. Still, not only Shamim et al. (2016) but also Schepers et al. (2005, p. 505) called for the investigation of “other leadership theories and constructs (e.g. leader characteristics) to TAM”.

In particular, Shamim et al. (2016) suggested including, next to transformational leadership, also transactional leadership in studies on Industry 4.0 adoption. Transactional leadership is grounded in the idea of an exchange relationship with followers (Burns, 1978) and based on contingent reward, meaning that effective leaders are thought to provide rewards to their employees when they achieve specified goals (Bednall et al., 2018; Lord et al., 2017). In addition to contingent reward, transactional leadership also contains two management-by-exception subdimensions: an active, more proactive way of dealing with issues and a passive, more reactive one (Anderson and Sun, 2017; Avolio et al., 1999). Transactional leaders are thus primarily focused on employees' (correct) task execution. The augmentation hypothesis states that a combination of both transformational leadership and transactional leadership is most effective in many contexts (Lord et al., 2017). Indeed, Schneider (2018) proposed that leaders of Industry 4.0 initiatives must not only govern, control and coordinate the transformation process (behaviours that are associated with transactional leadership), but also create acceptance for the change and establish a culture of experimentation, risk-taking, and collaboration (behaviours that strongly resemble transformational leadership). Yet, another cross-sectional survey, by Schepers et al. (2005), on technology acceptance, found that transactional leadership did not relate to service agent's technology acceptance, while transformational leadership was positively associated with the technology's perceived usefulness. Hence, it is still unclear whether both styles are still relevant and equally effective when a firm wants to adopt major digitalisation-induced change like Industry 4.0 technology adoption.

Finally, Yammarino (2013) added that a more collectivistic, shared leadership style would best fit the typically flat organisational structures of technology-driven organisations. Shared, or distributed, leadership considers the sharing of formal leadership tasks among team members (Anderson and Sun, 2017). How such a shared leadership style could benefit Industry 4.0 technology adoption has not yet been studied though. Thus, our review of the available literature highlighted the lack of conclusive evidence on how different leadership styles impact employee's Industry 4.0 technology adoption. Together with the general recent call of leadership scholars for more qualitative studies (Fischer and Sitkin, 2023; Siangchokyoo et al., 2020), this study explores the role of leadership more broadly to provide more direction for future studies on this topic.

2.4 Role of manager's understanding of emotions in the adoption of Industry 4.0 technology

Next to manager's leadership style, this study explores an aspect of their leadership that has hardly been incorporated in studies on Industry 4.0 technology adoption, namely, manager's sensitivity to and ability to act upon employee's feelings vis-à-vis the desired change (Harlan, 2020). The acceptance, resistance, disengagement or proactivity to the change by the recipients is inherently an affective process (Oreg et al., 2018) that greatly impacts the smoothness and success of the Industry 4.0 technology implementation process. One of the explaining mechanisms for these effects stems from the Social Exchange theory “which describes the exchange of socio-emotional resources between leaders and followers” (Vidyarthy et al., 2014, p. 233). Following this theory, “employees who perceive supportive relationships with the organization [or: leader] have favourable attitudes and engage in positive extra-role behaviours that help it to succeed” (Gibney et al., 2009, p. 666). Yet, we still know very little about the role of leaders' behaviours in shaping employees' responses to change, including how they impact employees' emotions (Oreg and Berson, 2019). Oreg et al. (2018) argued that employee's change coping potential, which can be activated by social support and perceived control of the change, might help them control their emotional responses to change. Such a coping mechanism can help employees facilitate adaptation and embrace change instead of resisting it (Huy, 1999; Wiens and Rowell, 2018). Indeed, the following quote from Marcon et al. (2022, p. 279) justifies the focus of our study on employee's acceptance of technology: “manufacturing companies that focus on workers' operational processes and social needs (i.e. organizational and social subsystems) as preconditions for Industry 4.0 implementation are more prone to achieve higher levels of maturity in technology implementation”. The summarised literature leads us to empirically explore the role of leadership in employees' acceptance of Industry 4.0 technology, and consequently, their actual usage of the Industry 4.0 technology.

3.1 Research design

Comparative case studies with two firms leading Industry 4.0 technologies implementation were adopted. We used multiple qualitative methods, including site visits and interviews with managers and their employees. These different observations were collected and integrated to permit complete and synergistic data utilisation (Fetters et al., 2013). By associating multiple types of qualitative data, one can better explain the phenomena under consideration through triangulation (Edmondson and McManus, 2007). This process, whereby complementary perspectives are combined, increases the external validity and construct validity (Edmondson and McManus, 2007). Consequently, befitting the inductive nature of the present study, a mixed-methods approach can expand and strengthen the theoretical and practical implications, thus answering the research question more rigorously (Johnson et al., 2007).

3.2 Sampling and sample description

A purposive sampling strategy was followed (Yin, 2011). To answer our research question, we identified companies that implemented Industry 4.0 technologies on their work floor, thus involving frontline employees. The database of the 2,200 firms that were members of the largest employer association for the Dutch technology industry was utilised to select the cases. Their members account for a sixth of the Netherland's total export earnings. In the years prior to our study, the employer association had installed so-called “ambassador groups” consisting of firms deemed frontrunners for industry-specific developments such as Industry 4.0. These ambassador firms were selected by the employer organisation based on their self-nomination and the level of progress made. Activities were organised among these ambassador groups meant to share experiences and best practices. From the firms labelled in the database as “Industry 4.0 ambassadors’ we selected 12 companies that the employer association saw as best practices that were actively implementing one or more Industry 4.0 technologies in their daily operations. Similar to Schneider and Sting (2020), we rejected those firms in the database that were still in the (strategic) preparation phase of Industry 4.0 technology adoption, despite their strong interest in participating in the study. The premises of those 12 firms were then visited to further assess the level of Industry 4.0 technology adoption within their firm. During those visits, interviews were held with key informants and each factory was toured. Eight firms were excluded because their Industry 4.0 technology adoption initiative was too nascent. Four manufacturing firms fit our selection criteria and were selected to participate in the study. Two of those firms had to opt out at the last minute because they could not participate due to other priorities. The other two manufacturing firms agreed to participate in the study.

The two sampled firms were large-sized, with 250 and 700 employees, respectively, and had existed for more than 45 years (see Table 1 which summarises the commonalities and differences). The two multinational firms worked in different, non-competing industries: One produced metalworking machinery, whereas the other was engaged in design and engineering. Both firms actively worked with smart intuitive machine operations, multi-system integration, innovative technologies and integrated production lines with flexible productions. Both firms had a history of adopting new technologies, including recently implemented Enterprise Resource Planning packages, without laying off people. The case studies focused on introducing two particular Industry 4.0 technologies:

The first firm adopted a large autonomous robot called here “Creator”. The Creator introduction was prepared over multiple years and aimed at enabling a more efficient production system. The Creator constitutes a full-automatic robot, which autonomously calculates the slopes/angles and welds pre-assembled parts into a final product based on customer-tailored 3D models fed into the system by operators. The robot had been placed immediately after a fully automatic production line that prepared the separate parts by sawing and drilling them. The Creator replaced a set of machines previously operated by frontline workers, who became responsible for operating the Creator instead and keeping in contact with software programmers to optimise the Creator's settings.

Firm number two integrated augmented reality in its design process using the “Microsoft HoloLens”. This technology was piloted into the firm via a student's internship to gradually move away from the traditional production approach in their sector towards more high-end customer service and attract new customers and employees. The HoloLens constituted a pair of augmented reality glasses that, together with a tailored software application integrating spatial mapping and holograms, enables both design engineers and sales agents to portray the firm's products at the customer's location. In addition, maintenance engineers can remotely check a machine's settings or status and immediately fill out the maintenance form. As such, the HoloLens supports customers' decision-making and a more efficient design and maintenance process.

In both firms, these technologies were implemented to make the business more “future proof” and aimed to optimise work-floor operations and make them more attractive in the tight labour market (see Table 1). Both technologies, therefore, belong to the “smart working” group of “front-end” Industry 4.0 technologies (Frank et al., 2019). At the time, and to this date, both firms actively communicated about their application of these technologies on their company websites, confirming their long-term strategic goal of integrating Industry 4.0 technologies into their daily business. The two cases can be considered as polar from the perspective that in the Creator's case, the technology implementation was driven following a more bottom-up approach, whereas in the case of Hololens, it was a top-down approach to technology implementation (a proxy for potentially finding different leadership styles).

The participants involved managers responsible for implementing Industry 4.0 technologies in their production lines and their employees working directly with Industry 4.0 technologies. All managers had leadership responsibilities. The participants' job positions ranged from operations manager or production manager to technical advisor and technical maintenance engineer. In terms of demographics: all respondents were male, on average 31–40 years old, and holding a Bachelor's degree. Most of them held their current job position between 4 and 8 years (employees) and 9–12 years (managers). These demographics were equally distributed among both cases, enabling the cross-case comparison. Furthermore, following the university's ethical committee's approval for this study, each participant signed an informed consent form and individually agreed to participate in the study.

3.3 Qualitative data collection

Both cases were visited multiple times by the research team. During those site visits, the work floor was toured to observe the focal Industry 4.0 technologies' application in real-time and understand each case's production processes in which the technologies were embedded. This enabled the researchers to gain first-hand insight into the workings and verify the level of Industry 4.0 technology integration in the operator's daily work (Voss et al., 2002). Field notes were taken to capture the observations (Eisenhardt, 1989). During these shop-floor visits, participant observation and informal conversations helped create trust and a safe climate between the researcher and the respondents required to discuss also more sensitive, affective elements of the Industry 4.0 technology implementation process (Yin, 2011). After each field visit, the research team members individually shared and discussed their observations, thereby enriching each other's insights and enhancing validity and reliability of the reported data.

Furthermore, during those field visits, 14 one-hour interviews were held with eight employees and six managers in both companies (see, Table 1). The employees worked directly with the new Industry 4.0 technologies, while the managers were involved in the implementation of those advanced technologies. Pilot interviews with Industry 4.0 technology experts from similar companies were performed, after which the semi-structured interview guide (Appendix) was finalised. This interview guide included open-ended questions and the critical incidents technique (CIT) (Flanagan, 1954). The CIT enables detailed and structured exploration of people's behaviour and feelings in key situations by first asking for those key moments and then probing through follow-up questions (Bott and Tourish, 2016; Flanagan, 1954). As noted by Bott and Tourish (2016, p. 276): “CIT potentially offers the kind of ‘thick description’ that is particularly useful in theory building”. This interview method thus fits the exploratory nature of our study. Example questions are: “What change has the company experienced regarding Industry 4.0 adoption?”, “How did the managers communicate about these changes?” and “How did this change affect your job or you personally?”. All interviews were audio recorded and then transcribed verbatim.

3.4 Data analysis

The interview transcriptions were content analysed in ATLAS.ti, following Strauss and Corbin's open, axial and selective coding phases (Ketokivi and Choi, 2014). Two Master students supported the authors in the coding process, whereby the first author monitored the code-development process and then double-checked and fine-tuned the coding that was initially performed by the Master students. Developing the code labels was done based on a group discussion among the coders and the first author to arrive at a common understanding, and corroborating with the field observation notes during the coding process.

We followed a “ground-up” approach to coding the data whereby the language used by the interviewees formed the basis for finding themes and developing a theory closely linked to the data (Caldwell et al., 2017). Thus, after the initial screening of the transcriptions, the data was coded in an open manner, thereby using first-order code labels that closely aligned with the actual quotes, following a “ground-up” approach whereby the actual language used by our interviewees was used to find patterns and closely linking it to developing theory. In two consecutive axial and selective coding rounds, second-order codes and aggregate dimensions were developed that corresponded with partially theory-based (sub) dimensions, as we were going back and forth between the literature and our emerging data structure (Strauss and Corbin, 1990). As mentioned by Grodal et al. (2021, p. 13), in qualitative data analysis, “past research serves as a springboard for asking questions to spur new lines of research”. Thus, in line with the rationale of inductive research, the first-round coding was not limited to the previous theory. For example, in terms of leadership style, the first-order codes were developed from scratch. After scrutinising this first round of data analysis, we compared the codes to the subdimensions of the leadership styles described in Section 2.3. In doing so, whereas personalised leader-member exchange or the transactional and shared leadership styles were less prevalent, we did recognise the four theory-based subdimensions of transformational leadership in the interview data. We, therefore, adopted these theoretical subdimensions as second-order code labels and took “transformational leadership” as the aggregate dimension. In Section5, the theoretical underpinnings are elaborated.

The various data sources—the data structure based on the coded interview transcriptions and our experiences during the field visits—were then initially integrated into two case narratives, which followed a “weaving approach” to link the various qualitative findings (Fetters et al., 2013, p. 2142). These detailed case write-ups helped compare and contrast the emerging patterns (Barratt et al., 2011). The patterns based on which the two cases can be compared were then elaborated below, illustrated by the available quotes.

4.1 UTAUT model factors

The different UTAUT dimensions (Venkatesh et al., 2003, 2016; Williams et al., 2015) were perceived differently in both cases. In terms of facilitating conditions, training and other types of resources were offered (Table 2). An initial version of the Creator was developed at a neighbouring company's facilities specialising in developing such high-tech machines. Before its introduction, a wider group of managers and employees participated in a factory tour and various demos. An operator recalled: “We were informed about the machine, its precise workings, and we saw it in action.” The training enabled both operators and managers to work with the new machine, reducing the expected effort of using it. The prior engagement and consultation with employees and providing them with training instilled confidence in employees. In addition, frontline supervisors held daily meetings with their employees to discuss points for improving the Creator. At HoloLens, the management invested in a scrum team [1] of six people from different departments that worked with the intern in a series of two-week sprints to test and implement the HoloLens in other work areas. To convince people to participate, the operations manager held individual face-to-face meetings with selected employees to invite them into the scrum team; one of the maintenance engineers shared with us that he appreciated getting the opportunity to be a part of this scrum team. Apart from the HoloLens, managers also worked with other advanced technologies, such as remote desktops and software which enabled more detailed management reports. One of the in-company technical advisors illustrated the high level of facilitating conditions perceived as follows: “I think it is positive that they provide energy and resources to do it. This way we can move forward, we have to.”

Both firms also had considerable social influence to adopt the new technology. In the Creator case, there was considerable support from work-floor employees to adopt the Creator. An employee noted that people were quite proud of the machine and said things like “This is what we developed ourselves” and “we talk about what we are proud off and that we have the [Creator]. This is basically what every employee does.” In the HoloLens case, there was less enthusiasm for innovations in general. An employee complained: “I always feel that we tend to quickly switch back to the old stuff that is functioning for 20 years now.” Another employee illustrated his reservation regarding the HoloLens: “I support it to some extent.” Thus, in the HoloLens case, there was less social influence to adopt the Industry 4.0 technology compared to what we had observed in the Creator case.

Regarding the expected effort, in both firms, employees were initially uncertain, despite the training they had received. At the Creator, we experienced that, initially, employees were unsure how to use the new technology: “People were indeed a bit worried. Like: ‘What is going to happen?’ and ‘How should I apply that?’.” By the time we visited them on-site, the Creator had been fully integrated into their regular way of working. An operator stated that he expected the Creator to run smoothly relatively soon: “I want to get it to work to the best of its potential. When there are problems, I always report them and they pick it up immediately to solve these issues. I hope it will run smoothly in a few months from now.” In other words, employees had a relatively high future performance expectation of adopting the Creator.

Also in the HoloLens case, the employees had high-performance expectations of the HoloLens, although the ease of use was not optimal given the high expected effort. One of the maintenance engineers illustrated this as follows: “Well, it is kind of a big unit on your head, but if it would be a little bit smaller […] you can work much faster, you save time and are less likely to forget something or make mistakes.” The project coordinator stated: “While wearing the glasses, they [maintenance engineers] can move through the workspace, stand next to the machine, do all the checks. By making gestures and saying things like ‘OK’ they can fill out the maintenance forms. […] Normally we used to do that on paper or a laptop. This is of course, much easier. And more fun!”. An employee confirmed that “You can work much faster, you save time and are less likely to forget something or make mistakes.” Thus, in both cases, employees (and managers alike) expected reasonable effort in adopting the new technology and positive performance effects after adopting the new technology.

And regarding voluntariness, in the Creator's case, management followed a top-down approach to implementing the new technology, which essentially reduced the level of voluntariness of adopting the new technology. This was compensated for by the fact that management informed staff about its introduction, personally invited a couple of volunteers to develop it further, and organised well-appreciated training and demos. An operator reflected: “I mean, we were involved […] As such, together with senior management, we moved towards accepting, in the sense that we wanted to bring the advanced technology in to further develop it.” Thus, despite reduced voluntariness, employees were optimistic about adopting the new technology. In contrast, the HoloLens case managers adopted a more gradual, bottom-up implementation approach, giving more freedom to their employees. This sign of voluntariness also led to some unclarity whether employees were going to follow up on further integrating the HoloLens in their daily operations; a manager noted: “It is now up to the department maintenance engineers to integrate the HoloLens.”

4.2 Leadership style throughout the introduction of new technologies in the workplace

The way managers introduced the new technologies in the workplace certainly also played a role in employees' intention to adopt the digital work-floor transformation. Their leadership style was characterised by a strong vision, challenging employees in working with high-end Industry 4.0 technologies and consideration for employees' views. As illustrated below, the quotes and observations show us clear signs of managers' “idealised influence”, “inspirational motivation”, “intellectual stimulation” and “individualised consideration” (Table 2). These themes are key parts of transformational leadership theory (Avolio et al., 1999; Bass, 1985, 1999; Bednall et al., 2018; Peng et al., 2021): Idealised influence is typically operationalised as providing vision and instilling pride; inspirational motivation concerns a leader's emotional qualities and building employees' confidence in the change; intellectual stimulation is manager's behaviour to motivate employees to see and deal with challenges in novel ways; and individualised consideration consists of providing personal support for employees (Bednall et al., 2018).

Managers enacted idealised influence by showing pride in the new technology and communicating their vision about seeing it as the future. For instance, in the Creator case, the operations manager stated, “I am proud to have this [Creator] as the first steel-based production facility. So yes, I stimulate that, both in relation to the guys as well as internally.” Later on, he proudly stated: “There is nothing better than this. […] This is smart industry.” He continued by providing his vision on the Creator's importance in enabling the firm to stay ahead of its competitors by upscaling their production capacity, delivering a constant quality level, while dealing with an increasingly tight labour market for highly skilled operators. The pride exhibited by managers also spilled over to the employees and instilled a similar sense of pride about the new advanced technology among employees. The operations manager illustrated: “When I ask employees in the hallway what they think of it, I feel they are quite proud of being able to work with the [Creator]. They do no longer see it as a threat, it is really like ‘We are [Firm name] and we already work with the [Creator], ahead of our competitors’.” In contrast, at HoloLens, despite the fact that the operations manager was “confident that this road will be successful and important”, his communication about the new technology was more practical. For instance, he explained management's intention to adopt the HoloLens was to replace bureaucratic processes with high-tech ones: “Through the HoloLens we expected to speed up certain processes that were initially based on paper files or opening a laptop.” Through this they expected to be an attractive feature for new hires (Table 1): “Instead of dull paperwork, you get interesting goggles to execute your job in a futuristic way”. However, although being supportive of the HoloLens, employees seemed a bit skeptical about how fast the management would pursue the technology adoption as it was their experience that innovations like the HoloLens “tend to be stalled a bit over time.”

In terms of inspirational motivation, the managers in the Creator case understood that the journey towards full integration of the machine in their operations would take quite some time and that, throughout, they had to keep motivating their people by showing that the change could turn out to be positive. A manager said: “[…] that took a trajectory of about two years, to show them it is not bad for them. […] that we do things with their ideas.” In more practical terms, he stated that when workers voiced concerns of (future) job loss due to the Creator, he would repeat that this was not the goal and, instead, “we want to increase output and revenue with the [Creator] working alongside our people”. Employees at the Creator case also confirmed that “the support from management is quite strong”, which further motivated them to accept the Creator. In the HoloLens case management had chosen a bottom-up approach and had not dictated its use in daily work; employees also noticed managers' positive attitude, which spilled over to employees and made them “see the benefits” of adopting the HoloLens. In reflection, one of the managers noted: “We are now at the point of: what is the next step? ]…] We have tried to plant a seed and enthuse people. ]…] It is now up to the department maintenance engineering to integrate the HoloLens.”

In the Creator case, we also found examples of managers' intellectual stimulation of employees. The Creator's adoption was a gradual process: First, managers had selected and invited several operators to be involved in earlier stages of the development; they personally invited them during face-to-face meetings. And one of the managers explained he always seeks employees' ideas: “Like with the guys I can ask them, during our daily meeting, what do we need to improve upon and what are the issues? This also makes the guys proud again of their product.” Altogether, employees felt professionally challenged; one of the operators stated: “The [Creator] immediately appealed to me. I liked the challenge. Good that they build such a smart machine.” At HoloLens, though, the adoption was not so much intellectually stimulated but more about the need for internal efficiency, as noted by one of the operational managers: “Through these glasses we try to force them a bit to work with the system and optimise the processes. Well, it is a bit pushing them to work in a standardised and efficient way. […] You hope to stimulate multi-tasking, and thereby the speed of work.” Indeed, employees felt more stimulated by the HoloLens itself than management per se: “I always get stimulated by these things.” Employees even suggested that management could do more to ask for employees' input about the technology adoption: “In fact, they should put more employees together [in a room] to discuss the next steps [of the HoloLens].”

Finally, regarding individualised consideration, we found that the managers in the two cases took rather different approaches. In the Creator case, employees were involved during the director's annual presentation of the yearly objectives and financial results. Afterwards, there was a drinks session where all employees could ask questions to the director. The manager confirmed that he took the employees' voices and input seriously: “Before we start using such a new machine, we always sit with the guys.” This personal approach to change characterised their care for the people working in their firm and their opinions. Employees confirmed their managers' engaging attitude: “When I explain my suggestions to my supervisor they will take further actions.” In the HoloLens case, however, we found that the managers were trying to make employees feel heard throughout the technology adoption process, including the ones who were not part of the initial scrum team: “I think the effect is that people feel heard and feel we do not disregard their viewpoints” one of the managers said. However, the manager also openly reflected upon the initial resistance the HoloLens had caused among employees; he noted: “It really struck me that there were a couple of people who resisted the plans directly. […] Apparently more energy was needed to enthuse people for the product.” Management was well aware of the (theoretical) effects of creating a better understanding of employees' concerns, although they had more difficulties realising such an individualised approach: “I think the effect is that people feel heard and feel we do not disregard their viewpoints.” Employees at the HoloLens case stated that their managers' attitude towards their ideas was a point for improvement because they did not always perceive that management was receptive to their ideas: “So if you have an innovative idea for a new product, they [management] can be a bit reserved.” This thus confirms that employees in the HoloLens case felt less heard by their managers, which impacted their appetite to adopt the new technology.

4.3 Managers' and employees' way of dealing with emotions throughout the change process

The data also revealed various examples of how managers and employees dealt with their feelings about the technology adoption. For instance, we found various examples of managers showing signs of “understanding their own emotions” and “understanding emotions of their employees”, “using their emotions” well, as well as “regulating their own emotions” (Table 2). These elements are strongly linked to a phenomenon in Organisational Behaviour literature identified as “emotional intelligence” (EI), defined as the ability to recognise and regulate one's own and other's emotions (Wong and Law, 2002; Zeidner et al., 2004). EI tends to be operationalised in four subdimensions, whereby self-emotional appraisal refers to an “individual's ability to understand their deep emotions”, others' emotional appraisal stands for “peoples' ability to perceive and understand the emotion of those people around them”, use of emotion relates to “the ability of individuals to make use of their emotions by directing them towards constructive activities and personal performance” and regulation of emotions is seen as peoples' ability “to regulate their emotions, which will enable a more rapid recovery from psychological distress” (Mayer and Salovey, 1997; Salovey and Mayer, 1990; Wong and Law, 2002, p. 246).

In terms of the Creator case, for instance, managers acknowledged that they “tend to be positive about change” and also used this enthusiasm to take away any employee feelings of job insecurity about the Industry 4.0 technology adoption: “Sometimes they fear that the [Creator] will steal their jobs. And then […] So I respond immediately, like: ‘This is total nonsense!’ They probably notice my enthusiasm about the [Creator].” On the contrary, at HoloLens a manager confessed that he did not like change: “I like things to stay as they were.” In addition, he responded in a frustrated manner to employees' resistance to the technology adoption: “Well, I felt mainly frustration. […] Banging my hands on the table like ‘Just start!’ […]”. Thus, although managers showed signs of self-emotion appraisal in both cases, the effective use of their own emotions differed considerably given that the latter example did not reduce employees' resistance to change.

We also identified in the data other-emotion appraisal as the Creator managers explained that they, over time, had developed an awareness of employees' emotions. An operator confirmed that management was sensitive about employees' feelings at work: “When I walk around all day with bad temper, they [management] notice.” Indeed, managers showed their understanding of employees' attitudes towards the Creator: “It helps that André [one of the operators] supports it; he is open to the development and welcomes change and says: ‘Yes, please let's get started, what can I do?’.” Another manager also showed to be sensitive to employees' feelings related to the implementation of the Creator: “I noticed that […] when it had not yet been communicated, that there was a bit of unrest among staff, like ‘What will happen?’ and ‘How does this affect me?’.” This awareness helped the manager effectively respond to their employees by addressing their concerns about the Industry 4.0 technology adoption. The HoloLens managers showed a somewhat less developed radar for others' emotions, although they could identify, in their eyes, rather “cynical” employees.

Finally, the Creator management tried to consciously regulate their own feelings: “You try to always respond to them in a positive way.” One of the managers noted that the management also betterunderstood people's feelings regarding the Creator because of the joint demo and training sessions they had participated in with employees. This led management to respond better to employee feelings in relation to the Creator: “Yes, we symphathise with them.” In the HoloLens case, managers also understood the need to give attention to both negative and positive feelings, although we found fewer examples of them regulating their feelings effectively.

Next to managers' way of dealing with their own and employees' feelings, we also found similar themes in the quotes related to employee responses to adopting the Industry 4.0 technology, although a bit less pronounced. In the Creator case, some employees noticed that other peers initially feared job loss and were worried about the use of the Creator, whereas the interviewed operators themselves did not perceive such insecurities and stated that they were able to regulate their emotions and subsequently support the technology adoption. One operator noted: “I knew everything would be fine.” These positive feelings also stemmed from the fact that the Creator's high-tech possibilities enthused operators. In the HoloLens case, the interviewed operators reflected more on their affective responses throughout the technology adoption process. One of them, for instance, shared that he was “less extraverted in those kind of things. Like, I will not start to cheer immediately”, showing he understood his feelings. In addition, he noticed that other peers started “to resist a little” because the HoloLens were restricting them in task execution. Another added that, even though others slept badly, “this is something you need to let go of.” One of the other technical advisors illustrated employees' relatively rational way of regulating their response to change: “the first response [to changes at work] is to let it sink in and think about the underlying reasons for change.” In other words, managers and employees showed to acknowledge and deal with their emotions throughout the change process, which impacted their intention to adopt the Industry 4.0 technology in their daily jobs.