Impact of qualified gatekeepers on team absorptive capacity: the mediating role of knowledge combination capability

2.1 Absorptive capacity

The concept of AC was first introduced by Cohen and Levinthal (1990) and defined as “the ability of a firm to recognize the value of new, external information, assimilate it, and apply it to commercial ends” (p. 128). Since then, many empirical efforts have been made to investigate the nature, components, antecedents and outcomes of this concept. One of the reasons for the richness of this construct is its overlap with other popular theories such as organizational learning theory, social cognitive theory, resource dependence theory, social network theory, dynamic capability theory and KM theory (Apriliyanti and Alon, 2017; Lane et al., 2006). To better capture the accomplishments of a broad range of previous studies and the current state of AC research, prior studies were divided into four main streams based on four vital reviews in this field (Apriliyanti and Alon, 2017; Duchek, 2013; Volberda et al., 2010). The details of which are shown in Table 1.

Studies on the natural stream have demonstrated that AC is a higher-order dynamic capability comprising four dimensions: acquisition, assimilation, transformation and exploitation. Acquisition denotes routines and processes used to monitor external knowledge, evaluate the potential of new knowledge that external parties possess and quickly access it when necessary (Flatten et al., 2011; Todorova and Durisin, 2007). Assimilation refers to the ability to analyze, interpret and understand acquired knowledge (Marabelli and Newell, 2014). Transformation is based on organizational routines that help an organization construct new cognitive structures by integrating assimilated external knowledge into the existing knowledge base (Zahra and George, 2002). Exploitation refers to a firm’s ability to apply transformed knowledge to final products, services or systems (Flatten et al., 2011; Zahra and George, 2002). These four dimensions are then grouped into two separate but complementary subsets: potential AC (PAC) and realized AC (RAC) (Jansen et al., 2005; Zahra and George, 2002). The former represents knowledge acquisition and assimilation, while the latter includes the ability of an organization to transform and exploit external knowledge. This multifaceted character of AC also differentiates the effects of a specific organizational antecedent to AC depending on which component is analyzed (Jansen et al., 2005; Van den Bosch et al., 1999). Based on these findings, the following research empirically testifies the antecedents, outcomes, mediating and moderating effects of AC in the context of intraorganizational learning, social networks and inter- and intraorganizational knowledge sharing.

Recent research noticed that the specific processes and routines of AC remain a “black box” (Martinkenaite and Breunig, 2016), and therefore turned their attention into investigating AC at micro individual and team levels. Through a bibliometric analysis of 2,088 papers from 1990 to 2015, Apriliyanti and Alon (2017) also noticed this growing micro-foundation stream and Table 2 lists some critical studies on this. In sum, one of the objectives of current AC research is to investigate the development of AC at individual and team levels. Nevertheless, recent research emphasizes the effect of individuals’ characters rather than their activities, leaving the roles that individuals play in the processes of external knowledge acquisition, assimilation, transformation and exploitation unclear (Rafique et al., 2018; Ter Wal et al., 2017). Considering that investigating the role of gatekeepers can help us better understand individuals’ roles (Ebers and Maurer, 2014; Schillaci et al., 2013; Ter Wal et al., 2017), we believe that probing the relationships between qualified gatekeepers and team-level AC is necessary to overcome this limitation and achieve forementioned objective. In addition, the combined effect of individual and team-level factors on the team-level AC also needs further investigation (Martinkenaite and Breunig, 2016; Ojo et al., 2017). Investigating the potential mediating role of knowledge combination capability, which is thought to be one of AC’s most vital team-level antecedents (Lowik et al., 2016; Ojo et al., 2017), in the relationships between qualified gatekeepers and team-level AC, is necessary to achieve the aforementioned goal.

2.2 Gatekeeping theory

The term gatekeeper is firstly identified by Lewin (1947) to describe individuals who control information flows to manipulate the result of decision-making. Allen and Cohen (1969) first introduced this concept into R&D context by identifying the existence of “gates” in R&D labs as being individuals “who perform boundary-spanning roles in the laboratory; that is, those, to whom others in the laboratory most frequently turn for technical advice and consultation, will show more contact with technical activity outside of the laboratory” (p. 13). Allen (1977) used the term “technology gatekeepers” to describe these vital individuals. Tushman and Katz (1980) demonstrated that qualified gatekeepers can facilitate technology development projects through the development of internal and external relationships. Harada (2003) stated that gatekeeping activities may be performed by members highly connected with the external world and members highly connected internally. Whelan et al. (2010) reported that gatekeeping activities can be carried out jointly by external and internal communication stars.

Prior studies (Huang et al., 2018; Walsh, 2015; Whelan et al., 2013) identified three vital functions of gatekeepers: they serve as the team’s antennae to scan the outside world for the acquisition of emerging new knowledge relevant to their labs’ current project (Allen, 1977; Allen and Cohen, 1969); they translate valuable external knowledge into a form that can be understood by other colleagues (Macdonald and Williams, 1993); they disseminate the translated knowledge to their colleagues for the use (Whelan et al., 2013). In sum, the current literature in this field believes that the contribution of gatekeepers “stops after they share the information they acquired” (El Samra, 2021, p. 4). This is why AC researchers argue that gatekeepers mainly contribute to the acquisition and assimilation parts of organizational AC (Cohen and Levinthal, 1990; Daghfous, 2004; Schillaci et al., 2013; Tzeng, 2021).

Nevertheless, the role of gatekeepers is highly likely to be evolving, and their contributions may not stop at the acquisition and assimilation parts, as current research suggested (El Samra, 2021). For instance, based on a case study of an Irish R&D unit in a multinational telecommunications company, Whelan et al. (2013) found that gatekeepers are “highly sociable with very good networking skills enabling them to develop extensive internal and external networks” (p. 207). From this point, gatekeepers may also perform an internal-networking role, which can help their colleagues access and combine internal knowledge in the company more effectively and eventually facilitate the efficiency of their teams’ transformation and exploitation activities. In addition, considering that gatekeepers are those who are highly talented (Allen and Cohen, 1969; Messeni Petruzzelli et al., 2010), and enjoy helping others (Whelan et al., 2013), they may also act as a consultant, making their colleagues more capable for knowledge transformation and exploitation. In conclusion, further exploration of the gatekeepers’ overall role is one of the objectives in this field. Based on the above arguments, we believe investigating how gatekeepers affect organizational knowledge combination, and AC could effectively accomplish this objective.

2.3 Knowledge combination capability

It has been largely agreed that the combination of internal knowledge distributed among companies’ specialized individuals is a central problem for knowledge-based companies’ management (Kogut and Zander, 1992). However, the specialization of knowledge creates boundaries among individuals and internal suborganizations, leading the combination mentioned above process extremely difficult (Postrel, 2002). Consequently, the capability to exchange knowledge among specialized individuals and work teams within the company is needed (Nur et al., 2019). Prior research used the term knowledge combination capability to describe processes and routines that help organization members absorb and combine knowledge of an entire company (Carmeli and Azeroual, 2009; Smith et al., 2005). At the team level, knowledge combination capability can help team members absorb and integrate knowledge initially held by certain team members, as well as knowledge residing in other teams within the company. The former can be described by the term “knowledge integration capability” (KIC) (Gardner et al., 2012; Zahra et al., 2020), while the latter can be encompassed by the concept “inter-team coordination” (IC) (Hoegl et al., 2004).

Knowledge combination capability is essentially different from AC, even though it may seem similar (Berggren et al., 2016; Carmeli and Azeroual, 2009; Ruiz-Jiménez et al., 2016). The theory of AC focus on investigating how organizations acquire, assimilate, transform and exploit new knowledge from external environment of the company. Cohen and Levinthal (1990) emphasized that organizations cannot absorb new knowledge without related background knowledge. AC is thus a kind of capability related to the accumulation of knowledge in a specific domain. For instance, with the help of AC, an R&D team can effectively understand and evaluate a new technology from a college based on the existing background knowledge in this discipline. Once this new knowledge is transformed and combined with existing knowledge, the depth of the knowledge base will be enlarged, leading the subsequent absorption of new technology in this discipline easier. In this context, AC is the ability to contribute to the depth of teams’ knowledge base.

On the other hand, knowledge combination capability focuses on integrating differentiated knowledge held by specialized firm’s employees (Berggren et al., 2016; Carmeli and Azeroual, 2009). By relying on the knowledge combination capability, an R&D team can combine differentiated knowledge held by both internal team members and members in other teams and eventually form a knowledge base with a broad array of disciplines (Distel, 2019). In essence, the ability of knowledge combination mainly results in the scope expansion of teams’ knowledge base. Figure 1 provides a depiction of the differences mentioned above.

To achieve the objectives above, we developed a novel research model including the mechanisms between gatekeepers’ abilities, team-level knowledge combination capability and team-level AC in the following section.

3.1 Direct effect of qualified gatekeepers on teams’ absorptive capacity

Gatekeepers’ knowledge-acquiring abilities can help their organizations search for and acquire external knowledge (Allen, 1977; Allen and Cohen, 1969; Ettlie and Elsenbach, 2007; Tushman and Katz, 1980). Specifically, they may act as antennae that scan the outside world to capture and absorb valuable new knowledge (Whelan et al., 2010). Involvement in these external searches makes it possible for gatekeepers to frequently interact with a diverse range of external third parties or other teams. Consequently, qualified gatekeepers tend to have abundant experience in interacting with external organizations. Furthermore, they have high-value external networking skills and strong ties and trusting relationships with external organizations (Ebers and Maurer, 2014; Whelan et al., 2010). Moreover, frequent interaction with outsiders can help gatekeepers build more reflective routines and networks for processing knowledge, which, according to prior research (Zahra and George, 2002), can contribute to the organization’s PAC. Through frequent external interaction, gatekeepers can also “coach external organizations to communicate external knowledge in ways that facilitate subsequent internal assimilation” (Ter Wal et al., 2017, p. 1044) and therefore further enhance their own team PAC. Moreover, they can also quickly identify which external actors may have access to new knowledge that their team needs, to introduce more valuable new knowledge and ideas to their own team (Ebers and Maurer, 2014). Furthermore, the greater the trust developed, the more willing they are to share their knowledge (Uzzi and Lancaster, 2003) and motivate receivers to acquire knowledge from them (Wu, 2008). In this regard, qualified gatekeepers can promote the introduction of external knowledge into the team, thus promoting team PAC.

Gatekeepers’ activities of translating knowledge into an understandable form and passing it on to other team members who may need it facilitates the receipt of valuable external knowledge with diverse coding schemes (Allen and Cohen, 1969; Harada, 2003; Tushman and Katz, 1980; Whelan et al., 2010). Qualified gatekeepers are thus highly capable of disseminating knowledge to other team members in a way that they understand. Through this process, the gatekeepers will also explain why they think the knowledge is valuable and how it can be applied to the current project. From this perspective, members of a team that comprises qualified gatekeepers can easily assimilate, internalize and utilize external knowledge without much time and effort. Consequently, teams’ PAC and RAC are facilitated. In addition, by showing how to find links that will combine new knowledge with existing knowledge and projects, qualified gatekeepers can provide experience and know-how related to the transformation and exploitation of new knowledge to other members. This kind of “on the job training (OJT)” effect will benefit teams’ RAC. Moreover, there is a gap between the time the knowledge was acquired and the time it was needed. Therefore, qualified gatekeepers may serve as a “knowledge pool” with an abundance of translated external knowledge (Ter Wal et al., 2017), facilitating both the depth and breadth of their team’s prior knowledge base. Prior research (Cohen and Levinthal, 1990; Ojo et al., 2017) has demonstrated that relevant prior knowledge is the foundation of both PAC and RAC. It is, therefore, reasonable to suppose that a qualified gatekeeper contributes to his or her team’s PAC and RAC.

Qualified gatekeepers also possess the ability to access internal networks to perform the aforementioned translation and dissemination activities (Whelan et al., 2010). For example, Cross and Prusak (2002) stated that the “go-to” character indicated by Allen and Cohen (1969) may make gatekeepers a central connector linking other individuals. In a case study of an R&D group at a medical device manufacturing firm, Whelan et al. (2010) demonstrated that gatekeepers access high-level networking and thus can help their organizations develop extensive internal networks. Dahlander et al. (2016) found that individuals who engage in external knowledge searches also make such efforts internally. Similarly, Ebers and Maurer (2014) reported that qualified gatekeepers can access strong ties and trust relationships with other team members. From this perspective, qualified gatekeepers promote knowledge sharing within the team and are thus more aware of what kinds of knowledge other members need. As a result, their external knowledge search and dissemination activities can be more effective, leading to greater team PAC. In addition, acting as a “technology consultant,” qualified gatekeepers can also teach other members how to internalize and use new technological knowledge, therefore, facilitating the efficiencies of their further transformation and exploitation activities. Consequently, teams with qualified gatekeepers are likely to consist of individuals with high transformation and exploitation abilities, and therefore high RAC.

In conclusion, qualified gatekeepers may directly contribute to their teams’ PAC and RAC by introducing external knowledge on their own and facilitating the performance of other team members’ new knowledge assimilation, transformation and exploitation activities. Hence, the following hypothesis is proposed:

3.2 Mediating role of knowledge combination capability

Qualified gatekeepers may also help their teams develop a higher knowledge combination capability, which can support other team members in better absorbing and implementing external knowledge. This supporting role of qualified gatekeepers should also be noted because it is extremely difficult for a team to rely on only a few “superheroes” to obtain all necessary new knowledge, particularly in our modern knowledge-based society where knowledge of various domains is vital. Therefore, this study also focuses on the indirect effects that qualified gatekeepers have on team AC through mediating these two knowledge combination capabilities.

4.1 Research setting and data collection

This study examined its model in the context of R&D teams because both AC and gatekeeping theories were generated in an R&D context. Two leading Japanese manufacturers (X and Y – both of which operate very well-known R&D labs) were chosen through a purposive sampling technique. Both firms’ R&D labs are regarded as among the top 10 in Japan and place great value on open innovation. Thus, the study believed that the R&D teams in these two firms were representative. Considering that companies may be sensitive to this study because of technology privacy issues, the heads of the R&D labs of these two companies were contacted for permission to conduct the survey. After the research was explained, they both agreed to it. Next, voluntary response sampling was used to choose sample teams because all members’ questionnaire responses were needed to form an accurate social network. Consequently, 32 teams working in different fields were selected. To avoid biased samples resulting from nonprobability sampling, the researchers then asked the heads and submanagers of the R&D labs whether there are team-level differences in average age, education level, work experience and performance between sample teams and those who did not volunteer to participate. However, we did not ask for specific information about each member to avoid possible privacy issues. Based on their answers, no significant differences were found. In addition, the researchers asked a few R&D professors and practitioners to ensure that the research fields of these 32 teams were representative of industrial R&D in Japan. Thus, this study believed that the sample teams were representative and deemed sufficient for this study.

A short online questionnaire (Appendix 1) modified from the original English version proposed by Whelan et al. (2010) was administered from May 2019 to September 2021 to identify individuals who perform gatekeeping roles (including gatekeepers and external and internal communication stars). A total of 378 responses were received for the social network analysis (SNA), resulting in a response rate of 100%. The study used Gephi 0.9.2, a popular SNA software package, to map the social networks of these teams. Furthermore, only reciprocated interaction was incorporated into the sociogram social network mapping works to confirm the validity of our results (Whelan et al., 2010). Some examples of social network maps are shown in Figure 3. We also use Gephi to calculate the betweenness centrality of each member, which can reflect the influence of a specific member on the internal information flow, to grasp each member’s internal communication distributions. The area of a circle in Figure 3 reflects the level of each member’s betweenness centrality.

Then, the researchers adapted the method indicated by Whelan et al. (2010) to calculate each member’s external communication distributions. External communication stars were only those ranked in the top 20% of external distributions, while internal communication stars were individuals ranked in the top 20% of internal distributions on their respective teams. Moreover, gatekeepers were individuals who ranked in the top 20% of both the internal and external communication distributions. Eventually, 137 individuals (including 48 internal communication stars, 68 external communication stars and 21 gatekeepers) were identified. The demographic details of the sample teams and individuals are shown in Table 3. Eighty-seven percent of the respondents were male, being consistent with male-dominant R&D lab occupations. In addition, only 4% of the respondents were foreigners. This is understandable because Japanese labs tend to hire Japanese people rather than foreigners to avoid risks such as technology spillover or conflicts resulting from language problems (English is not an official language in most labs). Almost half of the respondents had acquired PhDs and 13% had only bachelor’s degrees. This is consistent with the prior indication that demonstrated gatekeepers were individuals who are highly educated and access a deep knowledge base (Allen and Cohen, 1969; Whelan et al., 2010). Therefore, the researchers believe that our sample represented the actual circumstances of gatekeepers in R&D labs.

Moreover, the results of our SNA were reported to each team between November 2019 and October 2021 and found that the social network maps were representative of the communications. Furthermore, the identified individuals in each team did play vital roles. This result also provided further evidence to support the method of finding gatekeepers using SNA, as suggested by Whelan et al. (2010). Then, all identified individuals were asked to participate in the final online survey conducted from March 2020 to October 2021. Consistent with prior research (Larson, 2019), confidentiality assurances were added to reduce social desirability bias. Specifically, in the opening questionnaire statement, results were promised to only be reported at an aggregate level to prevent the identification of any teams and all individual responses were kept confidential. When the researchers reported the results to each team between March and November 2021, we also checked the social desirability bias by privately asking some members whether they provided socially acceptable answers. Based on their replies, we believe that social desirability bias can be largely excluded from this study. Furthermore, the researchers also compared the earlier questionnaire responses to those submitted later and found no difference. Thus, it is believed that systematic nonresponse bias was not observed in this study. Harman’s single factor test was conducted after data collection to assess possible common method bias (Podsakoff et al., 2003). The result shows that the total variance for a single factor is 27.9%, which is less than the threshold of 40%, indicating the absence of common method bias.

4.2 Measures

Respondents ranked all the above variables on a 5-point Likert scale ranging from 1 (“strongly disagree”) to 5 (“strongly agree”). The original items were translated from English to Japanese. All items are shown in Appendix 2.

To measure gatekeepers’ abilities, we created a reflective-formative second-order construct consisting of three reflective first-order factors (knowledge acquisition, knowledge dissemination and networking) based on the indications of Whelan et al. (2010). Reviewing 216 paper publications, Hung (2017) used “the proportion of paper references citing foreign authors and the proportion of new references made within 5 years” to measure how well gatekeepers fulfilled their knowledge acquisition function (p. 310). Therefore, the above two items were used to measure knowledge acquisition abilities. According to Whelan et al. (2010), knowledge dissemination abilities depend on the ability of gatekeepers to understand, translate and disseminate complex external knowledge, while internal networking roles can be determined by the extent to which gatekeepers enjoy helping others and their networking skills. Accordingly, three items for each of these abilities were created.

This study combined research that divides PAC into acquisition and assimilation (Jansen et al., 2005; Zahra and George, 2002) and research that divides AC into science-push and demand-pull (Murovec and Prodan, 2009) to create a reflective-formative third-order construct of PAC. Specifically, the formative third-order of PAC consists of two formative second-order factors: demand-pull and science-push PAC, to which then contribute reflective first constructs: demand-pull acquisition (DAC), demand-pull assimilation (DAS), science-push acquisition (SAC) and science-push assimilation (SAS). DAC includes four market sources: suppliers, clients or customers, competitors within the same industry and informal contacts with industry friends or trade partners (revised from Murovec and Prodan, 2009). SAC, in contrast, consists of three scientific knowledge sources: fairs and exhibitions, universities or other higher education institutions and government or private nonprofit research institutes (revised using Murovec and Prodan, 2009). Moreover, questions about SAS (two items) and market-related assimilation (MAS, three items) were revised using Jansen et al. (2005). RAC was also measured by a reflective-formative second-order construct revised using Jansen et al. (2005). Transformation (TRA, seven items) and exploitation (EXP, five items) are reflective first-order factors of RAC.

A KIC measurement scale was created based on the study by Gardner et al. (2012). Three out of the ten original items were deleted because their low loading scores resulted in low average variance extracted (AVE) scores. Accordingly, we used four of the original five items proposed by Hoegl et al. (2004) to investigate respondents’ perceptions of the effectiveness of their teams’ coordination with other teams.

4.3 Analytical methods

The data were analyzed using different statistical tools. Instead of using covariance-based structural equation modeling (CB-SEM), which Amos often executes, we choose partial least squares structural equation modeling (PLS-SEM) in this study. The reason is that this study meets the following conditions proposed by Hair et al. (2019) in which PLS-SEM should be used in preference to CB-SEM:

• the object of the study is to explore theoretical extensions of existing theories instead of purely testifying a model combined of established theories;

• the study uses relatively small sample sizes to testify an extremely complex structural model with a lot of constructs and a lot of indicators;

• the model includes more than one reflective-formative higher-order constructs; and

• the study requires latent variable scores for further analyses.

PLS-SEM was executed by the SmartPLS 3 software package (Ringle et al., 2015), which has also been widely adopted by recent studies in the AC literature (Ali et al., 2018; García-Villaverde et al., 2018). Although PLS-SEM analyzes how well the structural model fits the data, it cannot ensure the predictive validity of the model (Shmueli et al., 2016). Therefore, the study also used cross-validation tests with holdout samples suggested by Cepeda Carrión et al. (2016) to check the predictive validity. The results are presented in the next section.

5.1 Assessment of the measurement model

The reliability and validity of the items were evaluated through tests of reliability, convergent validity and discriminant validity. The results are presented in Tables 4 and 5. The Cronbach’s alpha (CA) values of all first-order reflective latent variables and composite reliability (CR) values were above the threshold of 0.7. Thus, the reliability of the study’s model was acceptable. Standardized loadings of reflective first-order items can reflect individual item reliability and should exceed the threshold of 0.707 (Carmines and Zeller, 1979). As shown in Table 4, all values of reflective items in our model exceed this threshold, except for three items (KD1, TRA4 and TRA7), which are above 0.62. Items with a factor loading between 0.40 and 0.70 can be retained if their removal does not lead to an increase in CA, AVE and CR values (Hair et al., 2017). Thus, all three items were retained. The results of the resampling bootstrap method with 5,000 show that all loadings are significant at a level of 0.01, indicating that the indicator reliability is acceptable. All AVE values were above 0.5, showing that the chosen measurement model had acceptable convergent validity (Fornell and Larcker, 1981).

Furthermore, three approaches to evaluate discriminant validity were used in this study: all indicators’ outer loadings on the associated construct are greater than the highest correlation with other constructs; the AVE square root of all constructs was above the highest correlation with other constructs (Fornell–Larcker criterion); and the greatest heterotrait–monotrait value is 0.80, which is below the threshold of 0.85. Thus, all three of these results indicate that discriminant validity is acceptable.

5.2 Testing the structural model

We used five different tests to evaluate the structural model (Ali et al., 2018; García-Villaverde et al., 2018) including: variance inflation factor (VIF) values, R², Q², path coefficients and significance levels of path coefficients. All VIF values for all possible sets of predictor constructs were below 1.3, which is far below the maximum threshold of 5. Therefore, collinearity is not a concern in this study.

As shown in Figure 4, the R² values of PAC (0.54) and RAC (0.45) meet the minimum acceptable level (Falk and Miller, 1992), demonstrating that that model has in-sample predictive power. Figure 4 also shows that the Q² values of PAC (0.53) and RAC (0.44) generated from blindfolding with an omission distance of 7 exceeded zero, supporting the predictive relevance of the chosen model (Hair et al., 2017). Bootstrap analysis with 5,000 resamples was used to test the study’s hypotheses of direct effects. The results are presented in Table 6.

Both the bootstrapping method and variance accounted for (VAF) were used to test these mediating effects (Hair et al., 2017). Specifically, the bootstrapping procedure was first used to investigate indirect path significance. As shown in Table 7, all three indirect paths proposed by our hypotheses are significant. The VAF scores of these three specific indirect paths were above 20%, meaning that mediations do exist (Hair et al., 2017). As the direct effects between gatekeeper abilities (GAs) and PAC are not significant, the two knowledge combination capabilities in this study fully mediate the relationships between GA and PAC (Hair et al., 2017). The results are shown in Figure 4.

5.3 Assessment of predictive validity

Consistent with prior research (Ali et al., 2018), we used eight-step cross-validation tests with holdout samples suggested by Cepeda Carrión et al. (2016) to test the predictive validity of the above mediation model. First, the original data were randomly divided into a training sample (n = 91) and a holdout sample (n = 46). A training sample was used to estimate the parameters in our model. Each holdout sample was standardized, and their scores were calculated using the weights from the training sample. Then, the researchers standardized the above construct scores and calculated predictive scores of two endogenous constructs, PAC and RAC, through the path coefficients obtained from the training sample. Finally, the correlation between predictive and construct scores was tested. Results show that the correlations between predictive and construct scores of PAC and RAC are 0.80 and 0.78 (p < 0.01), respectively, suggesting that the mediation model had highly predictive validity.

6.1 Discussion

Four critical findings of this study will be discussed as follows. First, the results of SNA showed that 87% of gatekeepers had obtained at least a master’s degree, providing evidence to the arguments of prior studies that the gatekeeper role tends to be performed by highly educated individuals (Allen and Cohen, 1969; Whelan et al., 2010). In addition, based on the results of SNA, we found only two teams in which gatekeeping activities were centralized. An interview with the corresponding gatekeepers also showed that they all felt extremely stressed and agreed that it would be more effective if other members shared their gatekeeping functions. These findings provide extra evidence to the proposition of Harada (2003) and Whelan et al. (2010) that gatekeeping activities in modern R&D organizations should better be undergone a division of labor.

Second, despite an implicit consensus that gatekeepers directly contribute to the acquisition and assimilation (Daghfous, 2004; Schillaci et al., 2013), our results showed that qualified gatekeepers could only indirectly affect team-level PAC. This finding sheds light on the role of individuals in the process of external knowledge absorbing activities. Specifically, in a modern knowledge-based society, in which more diverse knowledge is needed and the gap between the education level of employees has been largely reduced, the external knowledge acquisition and assimilation activities should better be deconcentrated, and each member is likely to dedicate themselves to a range of absorption efforts. This is consistent with the findings that normal organizational individuals play a vital role in the knowledge absorption processes (Distel, 2019; Sjödin et al., 2019; Yao and Chang, 2017), and the innovative activities (Bogers et al., 2018; Enkel et al., 2017; Spithoven et al., 2010). On the other hand, gatekeepers perform a “coach” role of supporting their colleagues’ acquisition and assimilation activities. Specifically, they help a colleague access knowledge residing in other colleagues more effectively or simply bring required knowledge to that person from other colleagues, thus contributing to the extension of his/her knowledge base. This extension of an individual prior knowledge base can reduce the likelihood of the mismatch between external knowledge and knowledge base and thus make individuals more capable of absorbing specific external knowledge they were not familiar with.

Third, both the direct and indirect effect of qualified gatekeepers on RAC is supported, which supports the arguments of El Samra (2021) that the role of gatekeepers is likely to be evolving, and they may also play a vital role in the implementation of knowledge. Specifically, gatekeepers can give valuable advice about how to transform and apply a specific new knowledge to their colleagues, thus directly affecting the RAC. This “go-to” or “consultant” character of gatekeepers has already been proposed in some prior studies (Whelan et al., 2010; Whelan et al., 2013). Besides giving the advice directly, gatekeepers can also indirectly promote the efficiency of their colleagues’ transformation and exploitation activities through the aforementioned positive effect on their colleagues’ knowledge base.

Fourth, our results showed that a R&D team with qualified gatekeepers could have high abilities of knowledge combination, providing evidence to the assumption of Zahra et al. (2020) that “knowledge integration processes are better left to specialists” (p. 31). Considering the trade-off between time and effort individuals can devote to external and internal knowledge sourcing (Dahlander et al., 2016; Monteiro and Birkinshaw, 2017), it is understandable that internal knowledge processing activities should be centralized when external knowledge sourcing is decentralized. The significant positive effects of knowledge combination capabilities on AC were also testified, thereby supporting the findings of Distel (2019) and Lowik et al. (2016) that an organization’s internal integration plays a vital role in the process of AC.

6.2 Implications for theory

The researchers believe that three distinct theoretical contributions were made in this study. The first contribution of the study is that we extend gatekeeping theory by investigating the overall role of gatekeepers in modern R&D teams. Some researchers have already realized that the current gatekeeping theory, mainly generated between 1970s and 1990s, were likely to be outdated, and the roles of gatekeepers may be evolving, especially as the world has changed rapidly during the past 30 years. For instance, with the development of internet technologies, individuals can now more easily access external knowledge through a large variety of channels. The original gatekeeping role of introducing new knowledge from outside is now vastly mitigated and some new roles of gatekeepers can be expected (Kyprianos et al., 2020; Whelan et al., 2010). In addition, the original division of labor in the process of external knowledge absorption is likely to change when inhabiting a modern knowledge-based society where organizations need a wide variety of knowledge and the gap in the educational environment is vastly reduced. Consequently, there is likely to be a corresponding change in the roles and responsibilities of gatekeepers (El Samra, 2021). Based on the results of this study, we confirmed the change mentioned above and suggest that instead of acting as “superheroes” and introducing external new knowledge from external third parties all by themselves, gatekeepers in modern R&D teams mainly perform a “coach” function and make their colleagues more qualified for external knowledge absorbing and applying. This “coach” role includes helping their colleagues better acquire knowledge reside in the whole company through creating networking ties; bringing required knowledge to a specific colleague from members both within the team and in other teams; giving highly valuable advice to their colleagues for their better transforming and applying a specific new knowledge.

The second contribution is the extension to current AC literature at the micro-level. Although prior research has investigated the effect of the variations in the level of AC on multifaceted performance outcomes, an understanding of how organizations develop greater or lesser AC remains neglected (Bouguerra et al., 2021; Martinkenaite and Breunig, 2016). One reason for this is the limited understanding of how different components of AC arise from the actions and interactions of lower-level actors, such as individuals (Lane et al., 2006; Volberda et al., 2010). Although recent researchers have started focusing on this new interest and have testified some vital individual characters (Table 2), current studies have not yet realized its full potential. Moreover, further investigations related to the micro-processes formed by individuals’ roles and activities are also believed to be essential (Badir et al., 2020; Ter Wal et al., 2017). By investigating the gatekeepers’ roles in AC process, this study has responded to this research call and opened the “black box” of individual activities that constitute an organization’s AC.

Finally, we contribute to the KM literature by investigating knowledge combinations at the micro-level. As a central concept in the KM process, knowledge combination has attracted considerable research attention (Balle et al., 2020; Kogut and Zander, 1992). Nevertheless, little is known about the “consequences of knowledge integration and its processes for the individual members of an organization” (Zahra et al., 2020, p. 14). This study provides interesting insights into this limitation. Specifically, our results suggest that knowledge-integrating activities are highly likely to be centralized in R&D teams. Furthermore, our results show that teams with a high level of knowledge integrating capability tend to acquire more external knowledge. Consequently, these team members will have a greater chance of expanding their personal knowledge base to accelerate their personal growth.

6.3 Implications for managerial practice

This study has some practical implications for managerial strategy. Specifically, it was widely accepted that organizations should simultaneously pursue both exploration and exploitation innovation (Chen and Kannan-Narasimhan, 2015). Facilitating PAC and RAC and supporting the individuals’ activities in this process, based on prior research, are critical for aching the ambidextrous organizations (Enkel et al., 2017; Limaj and Bernroider, 2019; Swart et al., 2019). Our results showed that both gatekeepers and combination capabilities were critical factors supporting the AC-related activities of individuals. We thus suggest managers achieve their organizations’ ambidexterity from these two dimensions.

The managerial contributions have also been made. Organizations increasingly count on their R&D staff for the introduction of diverse new knowledge from external third parties. There is no doubt that employees in R&D labs face a new set of challenges and have a lot of pressure on employees in R&D labs. Organizations, therefore, need to prepare a new supporting system to encourage and enable their employees to perform these roles successfully. This study offers some insights into these organizations. Specifically, individuals typically struggle to absorb and apply external new knowledge from disciplines unfamiliar with. To overcome this mismatch resulting from the restriction on individual knowledge base, managers should pay attention to find individuals who perform gatekeeping activities using the SNA method in this study and develop specific supporting and reward systems to promote these individuals’ abilities and motivation to perform knowledge-combining activities. In addition, developing formal communication systems and mechanisms, such as regular progress meetings inside teams and public staff meetings that teams in different apartments attend, is also recommended.

6.4 Limitation and further research

Despite the contributions of this study, the limitations should also be reported. First, the data used to test our hypothetical model came from 32 R&D teams at major R&D institutions. This may have limited the general validity of the findings of this study, such that our model may not apply to R&D teams in small- or medium-sized R&D laboratories or nonlaboratory contexts. Further research thus may test the proposed theoretical model in more different contexts.

Second, despite the considerable effort made to ensure that the data factually represent respondents’ perceptions of variables in our model, the results generated in an individual-level analysis may differ from those generated in a team-level analysis. It may be fruitful for future research to conduct multilevel analyses, using a method that takes both the organizational context and individual respondents into consideration to overcome this limitation.

Third, causal complexity, including the problem of equifinality, conjunctural causation and causal asymmetry, may result from a quantitative research design and limit our ability to get more detail about the complex mechanisms between the constructs under study. Considering the intricacies of the concepts and their relationships in this study, qualitative research designs, such as qualitative comparative analysis (QCA) would be useful.

Fourth, although this study revealed the vital role of gatekeepers in the process of AC, we did not mention how to support them. Gatekeepers normally play a “buffer” role and thus experience typically perceived uncertainty. In addition, developing networks and communicating knowledge to others necessitate a lot of time and effort. Consequently, gatekeeping activities can be exhausted and thus require adequate organizational support. Future studies may investigate antecedents of the efficiency of gatekeeping activities.