Knowledge-based view and learning processes

Based on the knowledge-based view of the firm (Kogut & Zander, Reference Kogut and Zander1992), knowledge is seen as the critical asset of organizations and the major source of competitive advantage. While individuals in organizations contribute to learning through recognizing knowledge and sharing it, emergence of a shared knowledge and learning throughout the organization requires organizational-level processes, routines, and skills that engage synergies among individuals (Matusik & Heeley, Reference Matusik and Heeley2005). A stock-and-flow metaphor is useful for understanding learning processes and capabilities (Jansen, Van Den Bosch, & Volberda, Reference Jansen, Van Den Bosch and Volberda2005). Knowledge stocks can be found within individuals, projects, functions, or organizations (Bontis, Crossan, & Hulland, Reference Bontis, Crossan and Hulland2002). However, learning requires the flow of the knowledge among individuals, projects, and functions and between different levels to integrate the stocks of knowledge and create and internalize the new knowledge (Vera & Crossan, Reference Vera and Crossan2005).

However, past research (e.g., Distel, Reference Distel2019; Martinkenaite & Breunig, Reference Martinkenaite and Breunig2016) refers to the limited examination of the multilevel perspective, which covers both the stock of knowledge and the flow of knowledge incorporating the individual and organization levels. Stocks and flows of knowledge coevolve as prior knowledge is needed before the learning process begins, and prior knowledge accumulates based on the learning process (Cohen & Levinthal, Reference Cohen and Levinthal1990). However, the flow of tacit knowledge (which is context-specific, embedded in actions, and difficult to transfer) is challenging, while explicit knowledge (which is transferable through simple communication means such as words and symbols) flows easily (Polanyi, Reference Polanyi1966).

Huber (Reference Huber1991) identified four learning processes associated with organizational learning including knowledge acquisition, information distribution, information interpretation, and organizational memory. Later, focusing on the internalization of external knowledge, Zahra and George (Reference Zahra and George2002) suggested a new set of four learning processes which they referred to as dimensions of absorptive capacity. Firstly, new knowledge is acquired using exploratory learning processes to identify external knowledge with a potential value for the organization (March, Reference March1991). Contrary to previous R&D approaches, external knowledge acquisition does not require the recruitment of new employees. Instead, firms need to promote critical assessment of existing knowledge and alternative knowledge seeking among their employees. The second dimension is related to the newly acquired knowledge which must be embedded in the individuals as well as in organizational routines. Hence, cross functional learning processes become critical for assimilating externally sourced knowledge. Knowledge assimilation includes sharing and communicating the valuable external knowledge with other individuals across the organization using social interactions and interpretations (Tidd & Bessant, Reference Tidd and Bessant2020). This dimension refers to development of a shared knowledge among individuals and groups by lowering the cognitive distance between them (Nemanich, Keller, Vera, & Chin, Reference Nemanich, Keller, Vera and Chin2010).

The learning processes associated with the third dimension support the development and refinement of the organizational routines which enable the integration of the acquired and assimilated knowledge with knowledge already existing in the organization. Transformational learning related to this dimension can add to, or remove from, the existing knowledge or configure and interpret it in a new way (Camisón & Forés, Reference Camisón and Forés2010). The final dimension is related to the application of the transformed knowledge. The exploitation learning processes apply the newly reconfigured knowledge to the organizational outputs and commercial ends (March, Reference March1991). Hence, the nature and underlying mechanisms of absorptive capacity are dynamic and change through the process of organizational learning (Todorova & Durisin, Reference Todorova and Durisin2007).

Knowledge and absorptive capacity development in emerging market firms

Referring to the ability of a firm to identify, absorb, and utilize new knowledge from external sources, the existence and development of absorptive capacity depends on the firm's prior knowledge (Zahra & George, Reference Zahra and George2002). A large gap in technological knowledge between the source firm and the recipient firm may lower the chance of realizing the benefits of external knowledge (Chen et al., Reference Chen, Yao, Zan and Carayannis2021). This puts firms with different levels of prior knowledge on different trajectories for absorptive capacity development, which is the case when comparing knowledge development processes between firms from advanced countries and those from emerging markets (Cuervo-Cazurra & Rui, Reference Cuervo-Cazurra and Rui2017).

Despite their considerable performance, firms from emerging markets are perceived as latecomers and technological laggards, compared with their counterparts in the more advanced economies (Harzing, Reference Harzing2000), suffering from technological disadvantages due to weak innovation systems, undeveloped supporting institutions, and poor protection of intellectual property rights in the countries in which they are located (Khanna & Palepu, Reference Khanna and Palepu2010; Zhao, Reference Zhao2006). As a result, emerging market firms are perceived to lack sophisticated firm-specific advantages, and compete mainly based on their national comparative advantage and economy of scale (Rugman, Reference Rugman2010), with a focus on the lower value-added parts of global value chains (Mudambi, Reference Mudambi2008). To cover the gap in technological knowledge, emerging market firms endeavor to incorporate technologies from firms coming from more advanced countries through copying their innovation (Luo, Sun, & Wang, Reference Luo, Sun and Wang2011), establishing alliances (Kumaraswamy, Mudambi, Saranga, & Tripathy, Reference Kumaraswamy, Mudambi, Saranga and Tripathy2012), or acquiring firms in the advanced economies (Madhok & Keyhani, Reference Madhok and Keyhani2012). While firms from advanced economies develop knowledge at technological frontiers (Hobday, Rush, & Bessant, Reference Hobday, Rush and Bessant2004), firms from emerging markets are a step behind technology frontiers, trying to ‘catch-up’ or ‘leapfrog’ (Lee & Lim, Reference Lee and Lim2001). Emerging market firms may also access knowledge embedded in returnees, products, parts and components, and foreign patent files, or transfer it from advanced counterparts in exchange for access to their home market (Hennart, Reference Hennart2012). However, while being highly motivated to incorporate the knowledge from external sources, emerging market firms are less likely to do so, due to lack of absorptive capacity and ability to establish and benefit from connection with foreign knowledge centers (Cantwell & Mudambi, Reference Cantwell and Mudambi2011). To benefit from the sophisticated knowledge transferred across borders (Pérez-Nordtvedt, Kedia, Datta, & Rasheed, Reference Pérez-Nordtvedt, Kedia, Datta and Rasheed2008), emerging market firms need to be able to integrate and use the technology, based on a level of absorptive capacity (Awate, Larsen, & Mudambi, Reference Awate, Larsen and Mudambi2012). Therefore, absorptive capacity, via social integration mechanisms (such as learned social relationships inside the organization), affects the knowledge-seeking behavior of these firms (Todorova & Durisin, Reference Todorova and Durisin2007).

The lack or endowment of absorptive capacity is frequently reported as one of the reasons for failure or success in knowledge transfer and innovation processes of emerging market firms (Scaringella & Burtschell, Reference Scaringella and Burtschell2017). However, and surprisingly, there are few detailed analyses of absorptive capacity in the context of emerging market firms (e.g., Mehreen, Rammal, Pereira, & Del Giudice, Reference Mehreen, Rammal, Pereira and Del Giudice2022; Scaringella & Burtschell, Reference Scaringella and Burtschell2017). Particularly, there are very limited insights about the process of developing absorptive capacity in the emerging market firms. Considering the different knowledge positions of emerging market firms and advanced economy firms, the research findings from such processes in the advanced economies can hardly be applied to the context of emerging markets. Kim (Reference Kim1998) provided evidence that the knowledge processes are different in developed and developing countries, and while firms in developing countries start with product innovation and then move into process innovation, firms in the developing countries start from process innovation and imitation to learn and ‘catch up’ before moving to product innovation. Such difference can be reflected in the absorptive capacity trajectories taken by these firms.

Social interactions as drivers of absorptive capacity

To conceptualize the relationships between micro–macro levels of absorptive capacity, the existing literature suggests that absorptive capacity can be developed at the organizational level as a result of the development of prior knowledge among individuals who engage with learning processes (Cohen & Levinthal, Reference Cohen and Levinthal1990) and the social interaction patterns among them (Van Den Bosch, Volberda, & De Boer, Reference Van Den Bosch, Volberda and De Boer1999). While employees' prior knowledge is an essential part of individuals' absorptive capacity, collecting the knowledge of these individuals does not represent absorptive capacity at the organizational level. Also, although individuals' prior knowledge is important for acquiring external information (Inkpen & Tsang, Reference Inkpen and Tsang2005), it does not contribute as much to the process of internal knowledge transformation and application.

In the traditional approach to absorptive capacity research, prior knowledge is mainly used to represent absorptive capacity which is then measured using R&D investments (Apriliyanti & Alon, Reference Apriliyanti and Alon2017). With the existing emphasis of literature on narrowing research on absorptive capacity to prior knowledge, a good understanding has not yet been developed of the mechanisms underlying knowledge acquisition, assimilation, transformation, and application and how individuals' learning processes can contribute to these organizational learning processes (Ali, Musawir, & Ali, Reference Ali, Musawir and Ali2018).

Individuals' knowledge leads to the development of organizational absorptive capacity only if the mechanisms underlying knowledge acquisition, transformation, and application, as well as the type of social interaction patterns among employees, allow them to be involved with the process of integrating new and existing organizational knowledge. The type of dialogue among individuals and the speed and efficiency in the development of shared understanding depend on the patterns of social interactions promoted by the organization (Martinkenaite & Breunig, Reference Martinkenaite and Breunig2016). Thus, the depth of knowledge transformation and applications depends on the pattern of social interactions among employees. The mechanisms in firms that promote suitable social interactions, required for internal transfer of tacit or explicit knowledge, are referred to as combinative capabilities (Van Den Bosch, Volberda, & De Boer, Reference Van Den Bosch, Volberda and De Boer1999).

Firms may manage knowledge coordination, socialization, and systemization through the development of relevant combinative capabilities that promote different learning processes (Zollo & Winter, Reference Zollo and Winter2002). In accordance with different knowledge process requirements, Van Den Bosch, Volberda, and De Boer (Reference Van Den Bosch, Volberda and De Boer1999) argue that firms may develop different combinative capabilities including socialization, systems, and coordination capabilities. They refer to coordination capabilities as the mechanisms for cross-functional coordination, employees' engagement with decision processes, and coordination of lateral interactions. The extent of documentation, instructions, guidelines, and systematic mechanisms for storage, retrieval, and sharing of explicit knowledge represents systems capabilities. Socialization capabilities provide mechanisms which help individuals engage and interact with each other for the purpose of tacit knowledge transfer and development of shared interpretation and mental models (Van Den Bosch, Volberda, & De Boer, Reference Van Den Bosch, Volberda and De Boer1999). Each of these combinative capabilities can promote a particular pattern of social interaction (Distel, Reference Distel2019). We argue that different patterns of social interactions are required at different stages of absorptive capacity development, which will be promoted by the firm's application of the relevant combinative capabilities.

Despite the importance of social interactions in linking individuals' behavior to organizations' absorptive capacity, there is a limited understanding of the interrelationships between different social interaction patterns among individuals and different organizational outcomes, and whether and how specific social interaction patterns can generate a desired learning outcome for the organization (e.g., Todorova & Durisin, Reference Todorova and Durisin2007).

Microfoundations view of absorptive capacity

To conceptualize the relationships between micro-level activities and organization-level processes in the context of knowledge processes, we adopted the microfoundations view in strategy (Felin, Foss, & Ployhart, Reference Felin, Foss and Ployhart2015). This view is relevant because it uses micro-level factors to explain the emergence of organizational-level phenomena. A microfoundations approach aims to explain collective phenomena, particularly the processes for capability generation, renewal, and management (Foss, Reference Foss2011). Like parallel work in the contemporary strategy research on lower-level sources of organizational capabilities (Teece, Reference Teece2007), the basic motive for investigating the microfoundations of organizational capabilities is to explain differences in firms' capabilities. The enhanced understanding gained using this view about the micro-level factors and the interactions among them may help researchers explain the dynamics of organizational-level capability development based on the dynamics in micro-level behavior.

Having roots in sociology and institutionalism (e.g., Coleman, Reference Coleman1986), this view focuses on the role of individuals and their interactions with processes and structures at the micro level. Since individuals play a critical role in creating, storing, sharing, and integrating knowledge, the microfoundations view, with its focus on the role of individuals, provides an advantage for research aimed at understanding the process of knowledge development and the mechanisms underlying absorptive capacity (Foss, Reference Foss2011). Emphasizing the critical role of individuals in organizational-level knowledge development, Argote and Ingram (Reference Argote and Ingram2000) highlight that ‘it has been at the level of identifying consistencies in organizations’ knowledge development paths and almost never at the level of human interactions that are the primary source of knowledge and knowledge transfer’ (p. 156).

Sjödin, Frishammar, and Thorgren (Reference Sjödin, Frishammar and Thorgren2019) identified some of the individual-level activities and practices which contribute to the knowledge processes and the process of developing absorptive capacity but did not unpack the multilevel interaction mechanisms involved in the process. Aligned with Martinkenaite and Breunig (Reference Martinkenaite and Breunig2016) and Distel (Reference Distel2019), we suggest that elaborating the interactions between individual-level knowledge processes and firm-level macro routines of absorptive capacity may provide more explanatory power over the complex relationships between absorptive capacity and its antecedents. This approach builds upon Felin et al.'s (Reference Felin, Foss, Heimeriks and Madsen2012) and Foss's (Reference Foss2011) suggestion to find the linkages between individual-level behavior and higher-level outcomes and understand how higher-level variables (like environmental dynamism and absorptive capacity routines) can be the antecedents and outcomes of individuals' behavior (Coleman, Reference Coleman1990).

Investigation of the microfoundations and multilevel mechanisms embedded in the emergence of organizational absorptive capacity (this study's research question) requires an enhanced understanding of the interactions between macro-level antecedents and micro-level mechanisms in influencing the development of absorptive capacity. To conceptualize such multilevel interactions, we referred to the model suggested by Coleman (Reference Coleman1990) for micro–macro relations in explanation of social science phenomenon, which was used for the same purpose in other microfoundational studies (see e.g., Abell, Felin, & Foss, Reference Abell, Felin and Foss2008; De Massis & Foss, Reference De Massis and Foss2018; Felin, Foss, & Ployhart, Reference Felin, Foss and Ployhart2015). Coleman (Reference Coleman1990) conceptualized multilevel casual mechanisms through which a macro-level phenomenon can be explained by both a macro-level antecedent and micro-level processes which underlie the casual relationship between the antecedent and the phenomenon at the macro level. In the suggested model, the macro-level antecedent influences the conditions faced by individuals; the conditions influencing the individuals (i.e., the opportunities and constraints he or she faces) will influence their actions; and finally the individuals' actions aggregate to the explanandum phenomenon. Abell, Felin, and Foss (Reference Abell, Felin and Foss2008) argue that this general conceptualization can be adopted when using different theoretical lenses to explain different social phenomena based on macro–micro interactions. For the purpose of this research, we used the co-evolutionary mechanism of absorptive capacity suggested by Van Den Bosch, Volberda, and De Boer (Reference Van Den Bosch, Volberda and De Boer1999) and knowledge integration requirements suggested by Grant (Reference Grant1996). Van Den Bosch, Volberda, and De Boer (Reference Van Den Bosch, Volberda and De Boer1999) argue that the type of knowledge environment (the extent to which the new knowledge is tacit versus explicit/codifiable) informs the type of organizational form and patterns of social interactions promoted in the organization to absorb that knowledge. Depending on the type of knowledge, the organizational forms and patterns of social interactions promoted can enhance explorative or exploitative learning. As illustrated in Figure 1, we suggest that the level of knowledge tacitness provides a certain condition for individuals requiring certain knowledge processing among them. To promote such knowledge processes of individuals, specific social interactions and organizational forms need to be promoted in the organization which will in turn shape the learning process.

Figure 1. Conceptualization model of micro-macro dynamics. AC, absorptive capacity.

Source: Own elaboration.

The dynamics in the learning process can promote different aspects of absorptive capacity at the organizational level. This multi-level conceptualization includes reciprocal relationships between micros and macros. Following Gupta et al. (Reference Gupta, Tesluk and Tayloe2007), we believe that it is dependent on the researcher to reveal how absorptive capacity routines at higher levels emerge from interaction with lower-level micro processes.

Research context

This study investigated our research question in the context of Iran. As an emerging economy, Iran has progressed significantly in science and technology development through knowledge transfer, best practices imitation, learning from partners, and innovating in different sectors, with the aim of bridging the technological gaps between it and advanced economies (Ghazinoory, Bitaab, & Lohrasbi, Reference Ghazinoory, Bitaab and Lohrasbi2014). Based on a ‘national technology strategy’ integrating both ‘national technology policy’ and ‘firm technology strategy’ (Ghazinoory, Divsalar, & Soofi, Reference Ghazinoory, Divsalar and Soofi2009), Iran intends to transform its traditional economy into a knowledge-based economy. There is a limited, but increasing, interest in the empirical research in technology development in an Iranian context (Scaringella & Burtschell, Reference Scaringella and Burtschell2017).

As several studies in emerging economies have shown (Mathews, Reference Mathews2002; Park & Lee, Reference Park and Lee2014), new technology and knowledge are not developed internally within R&D departments but sourced mainly externally and from companies in advanced countries through knowledge transfer and different forms of partnerships. These studies show that, while being beneficial, knowledge transfer has proven to be challenging in many cases (Kogut & Zander, Reference Kogut and Zander1992; Ponomariov & Toivanen, Reference Ponomariov and Toivanen2014). This makes the exploration of barriers and enablers of knowledge transfer in emerging economies a topic of interest for research (Argote, McEvily, & Reagans, Reference Argote, McEvily and Reagans2003) and a good setting to study our problem. A lack of absorptive capacity has been emphasized as a reason behind unsuccessful knowledge transfers (Scaringella & Burtschell, Reference Scaringella and Burtschell2017). To address the above purpose with an in-depth investigation, a single case study was conducted in one organization, IKCO, as an exemplar of absorptive capacity development during a period of technological knowledge development.

More specifically, the Iranian Government, as an emerging economy, has planned for economic transformation toward liberalization (Ghazinoory, Bitaab, & Lohrasbi, Reference Ghazinoory, Bitaab and Lohrasbi2014). Therefore, policy-making has been aimed at enabling firms to enter global markets and compete using free-market-based mechanisms (Ghazinoory, Divsalar, & Soofi, Reference Ghazinoory, Divsalar and Soofi2009). At the center of this policy lies the triggering and supporting of the process of knowledge development in the key players in the strategic industries for the purpose of transforming and developing those industries. The auto industry was selected as one of the target industries for transformation (in terms of creating substantial job opportunities and having a high, but achievable, technology base).

Accordingly, unique attention was placed on IKCO as the major car maker within the Iranian auto industry (having between 65% and 90% of market share over the history of the industry) to develop the competitive technological knowledge and lead the process of industry transformation. The government imposed tariffs on car imports which provided IKCO with a protected local market prior to this company developing the necessary competitive capabilities and helped in the development of a local network of suppliers. During a period of technological knowledge development, IKCO was transformed from a car assembler, into the leading carmaker in the Middle East, Central Asia, and North Africa.

The special situation of IKCO made this company an excellent ‘case of’ (Stake, Reference Stake, Denzin and Lincoln2008) absorptive capacity development over a period of technological knowledge development, and an extreme case where the phenomenon under study is ‘closer to the surface’ and easier to observe (Eisenhardt, Reference Eisenhardt1989; Pettigrew, Reference Pettigrew1990). As opposed to ‘intrinsic’ case studies (for better understanding cases), we adopted an ‘instrumental’ case study approach to examine a particular instance to provide insights into an issue or refinement of a theory (Stake, Reference Stake, Denzin and Lincoln2008). Eisenhardt (Reference Eisenhardt1989: 547) states that ‘it makes sense to choose cases such as extreme situations and polar types in which the process of interest is “transparently observable”.’ Due to availability of rich data in this company, the authors decided to gain in-depth understanding of this single case and emphasize the ‘analytic generalizability’ of findings (Yin, Reference Yin2003) rather than their external validity. Dyer and Wilkins (Reference Dyer and Wilkins1991: 615) argued that ‘theory that is born of such deep insights [from a single “deep case study”] will be both more accurate and appropriately tentative because the researcher must take into account the intricacies of a particular context.’ While the process of knowledge transfer and development at IKCO slowed down and even stopped over time due to political conflicts and global economic sanctions on Iran, this company did experience a 12-year golden period of technological knowledge development which was covered in this study.

A number of critical product innovation projects commenced during the 12-year technological knowledge development period. This allowed us to examine the product innovation projects that promoted the development of absorptive capacity as they progressed, instead of presuming which actors, technologies, and events might be critical (Czarniawska, Reference Czarniawska2004). The initial investigation showed that IKCO had developed its knowledge over the course of four major product innovation projects, namely the Pars, Samand, Soren, and Dena projects.

Data collection

Data were mainly collected using semi-structured interviews. Secondary sources of information included company websites, annual reports, newsletters, and news websites, other related websites, and the company archive. Snowball sampling (Patton, Reference Patton2002) was used to make sure that the most suitable participants were identified for interviews. The aim was to identify the key informants from functional areas of the company who were actively involved, influential, and who could provide insights into each case project.

Because IKCO has a high strategic value and high secrecy levels are maintained, it is extremely difficult for researchers to gain access. Approval was gained from the Deputy Minister of Industry only after lengthy negotiations. The first author and a dedicated liaison were assigned to our project. The benefit of taking this top-down approach in getting approval was gaining high-level access to all necessary informants, including ex-employees. The head of the Technology Strategy department acted as the dedicated liaison, and because he was instructed by the top management to facilitate access to the best informants, we could select high caliber interviewees who had the relevant experience, high level of engagement with the case projects, direct interaction with foreign and local suppliers, good overview of the technology transfer process at IKCO, and insights related to our investigation. The selection was made after a few sessions between the first author and the liaison person during which the first author discussed the nature of the research project, the main aspects of investigation, and the type of data required, and the liaison person explained the technology transfer at IKCO and the role of case projects. These sessions helped the development of a common understanding between the researchers and the liaison person to ensure a fully informed selection of interviewees.

As indicated in Table 1, interviewees were drawn from multiple functional areas (e.g., R&D, marketing, and manufacturing), and from various organizational levels. Interviewees had at least 6 years of experience in the case company and a high level of engagement with case projects. Some of them were involved with a particular project and some had participated in different projects. According to their information and the stage of data collection, interviewees were asked about one or more projects. There were two waves of interviews. The first round of interviews was conducted at IKCO's site in Tehran (at the R&D department) between October and November 2011 including a total of 37 interviews with senior managers and senior engineers. The interviews were conducted during 22 site visits. In the second round, which occurred 1 year after the primary round of data collection, we interviewed nine informants in IKCO's site in Tehran (at R&D department) during October 2012. The second round of interviews were mostly of a confirmatory nature. The interviews were in Persian and were recorded and translated and transcribed by one of the researchers. The interviewers were then coded by two of the researchers and notes were compared.

Table 1. Summary of interviewees' details

Source: Own elaboration.

Data analysis

A highly iterative approach (particularly between data and literature) was used to analyze the data, including two separate phases of analysis with distinct analytic characteristics.

Phase one. This phase commenced with open coding of the interview transcripts and the related organizational documents and evidence. The transcripts and documents were carefully read to identify themes and patterns (Miles & Huberman, Reference Miles and Huberman1994). Two of the authors conducted multiple reviews of the data, and constantly searched for critical passages, highlighted them and created memos as their understanding of the phenomenon of study progressed in the context of the research (Strauss, Reference Strauss1987). This continuous process of reviewing data, revisiting our interpretations, relabeling codes, and fine-tuning our memos (Eisenhardt, Reference Eisenhardt1989) supported the grouping of codes into conceptual clusters (Berg, Reference Berg2004). While addressing the data and empirical evidence, the emerging conceptual clusters pointed to the relevant literature, leading to further elaboration in the second phase of analysis.

Phase two. An abductive approach, including moving back and forth between data and the literature (Behfar & Okhuysen, Reference Behfar and Okhuysen2018), was taken for the second round of coding, once the initial categories had emerged in the first round of coding. We looked at the extant literature on absorptive capacity to find associations between the evidence from the first round of coding and the existing theoretical constructs and factors, to see how our empirical findings might add to the categories existing in the literature. As a result, we used current operationalizations and definitions of absorptive capacity and the related factors to understand and illustrate what had happened at IKCO. Although our empirical evidence was inclined to reveal alternative, concrete, and perhaps more coherent indicators of absorptive capacity, all our data did fall into current categories within the broad absorptive capacity literature. Such interrelationships between the first and second rounds of coding followed Gioia, Corley, and Hamilton's (Reference Gioia, Corley and Hamilton2013) multi-layer approach, using first- and second-order codes to organize and outline themes and aggregate dimensions while analyzing and comparing key events and ideas pointed out by the participants. Accordingly, following the first round of open coding (first-order coding), axial coding (Gioia, Corley, & Hamilton, Reference Gioia, Corley and Hamilton2013) was then used in the second round of coding, to search for interrelationships between and among the emergent clusters, and gather them into higher-order categories. Finally, related themes were combined into multiple overarching concepts of absorptive capacity, which formed the basis for the emerging processes. This process is presented in Figure 2, showing how this approach was used to link the knowledge process measures to the development of routines of absorptive capacity. A number of knowledge processes emerged in relation to different knowledge processes of absorptive capacity, including acquisition, assimilation, transformation, and exploitation.

Figure 2. Data structure. AC, absorptive capacity.

Source: Own elaboration.

Pars project

Prior to the Pars project, IKCO was focused on assembly at the firm level and did not have even basic car design knowledge; in other words, knowledge of how different parts interact with each other and how that interaction influences performance. During the Pars project, based on a policy of self-sufficiency, IKCO made significant use of its strategic alliance with Peugeot to have all parts produced by local suppliers and also to have their assembly carried out in IKCO.

Through the process of aligning the production of all car parts and their assembly with a world-class standard, IKCO identified where strategic knowledge could be obtained for designing the components required to assemble the whole product. In fact, during the localization process, IKCO developed the capacity to acquire new knowledge, which, as defined by the literature, is ‘a firm's ability to locate, identify, value, and acquire external knowledge that is critical to its operations’ (Camisón & Forés, Reference Camisón and Forés2010: 709).

At the individual level, and based on the nature of the project, employees were encouraged to gain new knowledge from engineers in Peugeot in their particular area of work. Multiple methods were applied to exchange tacit knowledge with teams of engineers from Peugeot. IKCO's engineers in different sections like power train, suspension, electrical systems, interior design, exterior design, and others received specialized training from their counterparts in Peugeot. Such training took place either at IKCO, where Peugeot's engineers could involve a larger number of IKCO's employees, or at Peugeot, where IKCO's lead engineers had the chance to visit different sites and operations. As a senior engineer commented: ‘Sometimes they [Peugeot engineers] came over here and joined us and completed the work and sometimes we went there and worked with them on our projects.’ In some cases, such as exterior design, some lead engineers stayed longer at Peugeot and collaborated with engineers in the labs to receive first-hand experience of how new knowledge or technologies were applied at Peugeot.

This stage required employees to be engaged with different types of searches for information (desktop searches and fieldwork) about the new technology relevant to their functions. The head of electric systems provided an example of such situations:

Regular meetings with Peugeot's engineers were in place in different functions. There was a hunger to learn in all areas, and, on some occasions, the best experts in the world (e.g., a lead exterior designer from BMW) were invited to provide feedback on Peugeot and their work, bringing new insights. Employees seeking to master new areas of knowledge were promoted. In the R&D department, employees were engaged with research projects in collaboration with Peugeot's engineers to adjust technologies with local requirements in terms of market, environment, and safety regulations.

Samand project

While, in the Pars project, Peugeot was the single source of knowledge as the key foreign partner leading the project, during the Samand project (when there was a national determination to develop a new national product), IKCO replaced Peugeot and led the project. In this project, the locus of knowledge transfer (from foreign partners) moved into individual functions.

Within each function, the required knowledge identified during collaboration with Peugeot in the Pars project was transferred from different functional suppliers. As a result, the single source of knowledge during the Pars project was broken down into multiple sources of knowledge within functions, and staff in functions could develop components (as a set of parts) of their functions, tailored to the specific needs of IKCO's local market (in a newly designed car, not a copy).

During the Samand project, IKCO was able to assimilate the new knowledge and develop a shared understanding of the new knowledge among employees in each function. Assimilation capacity is defined as ‘the processes and routines that allow new information or knowledge acquired to be analyzed, processed, interpreted, understood, internalized, and classified’ (Camisón & Forés, Reference Camisón and Forés2010: 709).

During this project, IKCO had clear instructions in all the collaborative projects with different foreign partners to transfer the knowledge to IKCO's engineers and local suppliers who were immediately involved with each project. IKCO applied a different means of codification to transform and communicate tacit knowledge gained to others. For example, it used collaborative work between IKCO's employees and foreign suppliers, as noted by a senior suspension systems engineer:

This also helped individuals to understand their newly acquired knowledge from foreign partners. Employees likewise were engaged with on-the-job training, coaching, and mentorship by foreign partners' lead engineers to gain hands-on skills and explore ways in which they could apply the new technology or knowledge, as explained by a senior engineer in the exterior body system: ‘The relationships between us and the Korean experts was sort of a teacher and student relationship where the Korean experts did the job, and we observed and then we did the next samples under Korean supervision.’ Many seminars and workshops were organized to introduce the new areas of knowledge and discuss the implications for each function.

Employees, particularly the lead engineers, were engaged mainly with transferring learnings from the Pars project to others in their functional unit and also to other functions. A senior engineer in braking systems described one way of doing this: ‘In our organizational structure, you were located within one function, but your function could serve three different projects. I was representing the braking system in all our cross-functional meeting[s] for designing the Samand.’ In addition, collaborative and cross-functional problem solving was encouraged and facilitated at times through employee transfers. This helped IKCO's employees learn more through knowledge sharing combined with intuition. The Technology Strategy Unit promoted activities for sharing new developments, achievements, and problems in each function with other relevant functions through seminars, reports, newsletters, and other publications to help them create mental maps, establishing new connections among stored related patterns.

The sources of information were known to employees; if they wanted to learn or solve a particular problem, they knew what the reference was, as described by a senior engineer:

In most functions, particularly the power train or suspension functions, foreign partners were still engaged on-site to assist. Compared with interactions in the Pars project, however, individuals were able to understand and interpret the partners' knowledge better.

Soren project

While the Samand project focused on designing new components, the Soren project concentrated on changing and integrating new components and designing new subsystems. Each function had to face a higher level of complexity in designing new subsystems, which required integrating new components with other components in the existing subsystems. While employees in each function were engaged with a new subsystem which was basically designed by the foreign partners during the Samand project (leaving no opportunity to use their own ideas and previous experience), during the Soren project, employees had the chance to include their own insights and knowledge of the local market into the new design of subsystems. At the same time, IKCO was determined to use new subsystem-level technologies which could either resolve the issues raised in the market or improve the subsystem performance. As a result, IKCO's engineers found the opportunity to apply their knowledge in the local context and learn about new technologies, thus formalizing their knowledge through continuous learning and deepening their experience.

IKCO established an education center to systematically engage employees with knowledge improvement to help them transform old approaches into new ones based on new technologies and knowledge. Employees with learning capabilities were promoted by the company. This helped them to master how to manipulate knowledge they had learned in the way they wanted. To support such knowledge dissemination and accumulation, and connect the knowledge of different experts, IKCO established knowledge management systems to facilitate storing new knowledge developments and provide access to relevant employees to apply those developments in their areas or let others use their developments. The knowledge management systems facilitated sharing and combining employees' knowledge with each other to better integrate different components in each function. Soren's project manager gave an example of such knowledge management systems:

As a result, employees were exposed to the ideas and knowledge of other employees or experts through the exchange of documents and codified information.

During this project, employees learned about the system-level tests and standards that were needed to deliver components from the parties to which IKCO had outsourced the knowledge of a component or the knowledge together with the task. As a result, foreign and local suppliers were also involved, and their knowledge and ideas were integrated into the project. The knowledge management systems were used across IKCO, SAPCO (Supplier of Automotive Parts Company), and its foreign partners. The information flow was established from marketing to functions to foreign and local suppliers to collect information to identify and assess the problems and develop solutions.

IKCO organized different teams in each function to use these knowledge processes and solve the problems related to each function and benefit from new technologies available. Each team within the function was responsible for a small project, usually targeted at solving customer or production problems, and, subsequently, the team monitored and sought feedback on their solutions for further improvements. Different functional teams had to integrate their design decisions and approaches to address the issues, as reflected in the comments of a senior engineer in the suspension system: ‘The team leaders were not independent in decision-making, and we had members working across different teams. The final decisions needed approval of the head of function which had a coordinating role among different teams.’ In addition, during the team discussions, diverse views from foreign partners and local engineers were presented, and employees had to resolve conflicts and communicate a collective view, as described in an example provided by a senior engineer in the power train system:

Developing the new subsystems for the Soren included integrating components into each system (like the braking system) based on the principles of new knowledge. During this project, the knowledge about the existing components, which already existed in codified format, was combined with the new knowledge for car design, which was codified during the Samand project, and with new pieces of technology. In fact, during this project, IKCO applied the knowledge assimilated during the previous project (Samand) within functions to reconfigure the components in a new way (based on new knowledge) and, through that, develop new subsystems. This included transforming the already existing knowledge within functions through reintegration and combining it with new knowledge and technologies. This aligns with transformation learning as described by Camisón and Forés (Reference Camisón and Forés2010: 709) as ‘developing and refining the internal routines that facilitate the transference and combination of previous knowledge with newly acquired or assimilated knowledge.’

Dena project

While IKCO made subsystem changes to address the issues with functionalities and features in each function in the Soren project, in the Dena project IKCO took another step forward and decided to provide a new architectural design reflecting IKCO's differentiating strengths. By this time, IKCO understood the knowledge of car design at the functional level, but the overall product looked the same as those existing in the market.

However, over the previous three projects, IKCO had developed its own specific ideas in some areas. Accordingly, in the Dena project, IKCO endeavored to shape its car design competences and establish a brand based on a realistic picture of its own strengths and weaknesses. The Dena project provided an opportunity for employees in each function to apply the subsystem knowledge developed during the Soren project to a new product architecture. While IKCO was more focused on the new architectural design for Dena based on its own signature and competence, the subsystem design within functions was delegated to local suppliers, which had grown along with IKCO during the past projects and had become experts. In fact, the locus of functional/subsystem knowledge that used to be in IKCO's functions during the Soren project was moved to local suppliers in the Dena project. This helped IKCO quickly apply its existing knowledge within each function in new ways by incorporating the new technologies offered by suppliers working with each function. This enabled IKCO to quickly adopt new technologies, such as automatic lights, wiper blades, environment-friendly engine designs, safety features, computerized engine and electronic systems, and improved panel and navigation, among others, that could add competitive features and meet a range of customer expectations.

Since the new subsystems were developed in collaboration with local suppliers, IKCO focused on integrating the new subsystems into a new product system that reflected the firm's specific car design competence. In this project, it had the opportunity to learn about interactions among different functions as a result of the new technologies used in the subsystems. At the firm level, IKCO learned more about how a subsystem can work with other subsystems so that the product achieves proper performance. In other words, IKCO learned more about the tests and standards that were needed to deliver subsystems produced by suppliers to which they had outsourced the subsystem knowledge or knowledge together with the subsystem task.

IKCO had tried to find product issues and deal with them within functions in the Soren project, whereas during the Dena project it formalized cross-functional processes to find issues and market requirements for new features and technologies and address them in its new design, as indicated by the Dena project manager: ‘Engineers working in each function continuously traced technology and collected feedback from customers, where they found room for improvement, they sent through the company-wide forms for other functions to adjust their design with the changes made.’ Employees in the functions were less focused on functional tasks and were more engaged with cross-functional commitments. The locus of control moved from the head of functions (which was the case in Soren) into the project managers dealing with designing different aspects of the new product architecture. While applying their functional knowledge to the new product system, IKCO's employees had to create their own ideas and new knowledge while working with others. The head of the exterior body system function gave an example of this:

This helped employees internalize the knowledge and become experts in their area, ready to export their expertise to other companies – particularly in areas like safety, LNG-based engines, and equipment design, among others.

Such application of knowledge within functions occurred during the integration of newly transformed knowledge within each function with knowledge of other functions to create a new car design (changing the whole system architecture). This process is aligned with the knowledge application component of absorptive capacity, which is defined by Camisón and Forés (Reference Camisón and Forés2010: 709) as