This study collected data from Slovakian companies to test its research hypotheses. A back-translation procedure translated the questionnaire from English to Slovak and back to English. Data were collected through a questionnaire survey of the employees and managers of the selected companies. An internal company database was used to obtain contact information from respondents. More than 70,000 respondents from Slovakian companies across various industries were contacted. Data were obtained from the electronic distribution of surveys. The final sample comprised 368 participants who completed the questionnaires between May and October 2023. A further description of the sample is provided in the Results section. The response rate was 0.6 percent. The control variables used to structure our respondents were the size of the organization (SIZE), sector (SECTOR), region (REGION), level of job position (POSI), years of experience (EXPER), years of working in a given position (SENI), sex (SEX), age (AGE), type of employment (EMPLOY), and education (EDU). The control variables were adopted from Ma et al. (2020) and Ali et al. (2021).

Data were collected as part of a more extensive study of knowledge-hiding behaviors. The questionnaire measured 12 factors: EH, PD, RH, KC, workplace friendships, AL, trust, task conflict, interpersonal conflict, specific goal achievement, TL, and team performance. These factors were measured using 51 items, in addition to ten items related to the qualification characteristics of the respondents (SIZE, SECTOR, REGION, POSI, EXPER, SENI, SEX, AGE, EMPLOY, and EDU). To ensure the content validity of the scales, previously validated survey questions were used with some modifications to fit our context.

As mentioned, the survey included 12 factors; all measured constructs are listed in Table 3. The authors measured knowledge hiding, classified into three dimensions—EH, PD, and RH— using 12 measurement indicators (four for each dimension). All factors were evaluated on a 7-point Likert scale adapted from a literature review based on previous research. The Likert scale ranged from 1 (strongly disagree) to 7 (strongly agree) and for the other measured factors, from 1 (never) to 7 (always).

In summary, this chapter presents an overview of the data collection process. It constructs measured in a study focused on knowledge-hiding behavior within organizations. The tools were adapted from previously validated scales to ensure the validity of the study's content. The next section presents the results of the structural equation modeling and descriptive statistics.

Before the structural equation modeling, a descriptive analysis was performed. Of the 398 respondents, 203 were male (55.16%) and 165 were female (44.84%). Half of the respondents were between 41 and 60 years old (54.34%), and 80 were older than 60 (21.74%). As shown in Table 4, most respondents (292; 79.35%) stated they had more than 15 years of work experience. Similarly, most respondents were from micro-enterprises (44.57%). In our context, microenterprises employ up to ten employees.

Most respondents, 281 (76.4%), had a university degree, whereas 79 (21.47%) had graduated from secondary school with a leaving exam. In terms of the management level within the company, 155 respondents (42.12%) occupied top management positions, 80 (21.74%) were in middle management positions, and 43 (11.68%) had lower management positions.

The constructs defined in our model were not collected directly from the respondents. Instead, factors (constructs) were defined as latent variables and their values were collected indirectly through individual questions (items). This procedure resulted in more reliable data. The first step was to create a conceptual model that defined individual latent constructs and specific questions belonging to them defined latent constructs. The proposed model includes five latent factors (AL, TL, PD, KC, and RH). The four constructs (AL, KC, PD, and RH) were defined using four items each, while the TL construct was defined using five items. Questions defined for each latent factor were included in the questionnaire.

To avoid problems related to the multicollinearity of indicators (items), dependency analysis was conducted using the variance inflation factor (VIF). VIF values for the indicators of the defined constructs were calculated for all items together because of the incorporation of the common latent factor, with VIF values greater than five considered problematic (James et al., 2013; Menard, 2001; Quinn and Keough, 2007). The VIF values, calculated for all items together, ranged from 1.380 to 5.824; three items had a VIF score above 5: AL3 (5.701), TL2 (5.824), and TL3 (5.292). For this reason, items AL3 and TL2 were removed from the individual factors. After recalculating the VIF of the adjusted factors, the VIF for all items ranged from 1.377 to 3.797, indicating that the problem of collinearity between the independent variables was resolved. Other procedures, including bias tests, were performed using this revised model.

Before the CFA analysis and SEM modeling, respondent bias was tested. Because the individual data were stored in the file according to how they were obtained, the authors conducted a non-response bias test by dividing the data into two equally large parts based on the order in which the data were collected. Subsequently, the Shapiro-Wilk test was performed for all items of the individual factors to determine whether the data showed a normal probability distribution. As the hypothesis of normality was rejected, the Mann-Whitney U test was used to compare the answers to all items. Statistical differences were tested for all the items. Of the 19 tested items, at an alpha level of 0.05, in 17 indicators, no statistically significant differences were found between the tested observation groups in 19 items (p > 0.05). At alpha = 0.10 level, in 16 indicators, no statistically significant differences were found between the tested observation groups for the 19 items, and statistical differences between answers were identified for items RH1 (p = 0.0141), RH2 (p = 0.0090), and TL4 (p = 0.0714). These findings were not considered high attention in the context of the entire test. Therefore, the authors decided to keep the data in the same form for CFA and SEM modeling purposes. A more detailed explanation can be found in the Limitations section.

In addition to the test for nonresponse bias, a test for the possible identification of common method bias (CMB) was conducted. Harman's one-factor test was used to detect the common method bias. One factor was modeled as part of the EFA, which included all indicators. According to Podsakoff and Organ (1986) and Fuller et al. (2016), common method bias arises when a single factor explains at least 50 percent of the variance. Based on the results, there was no common method bias because the explained variance of a single factor was 33.97 percent, which is less than the recommended value of 50 percent. A single-factor test was also performed using CFA, in which a CFA model with a single factor was created by assigning all indicators to it. The model achieved unacceptable values of fit measures (Comparative Fit Index - CFI = 0.428, AGFI = 0.405), indicating no common method bias.

Due to the limitations of the Harman one-factor test, the authors additionally conducted a test using the Common Latent Factor (CLF) within the CFA framework to confirm the absence of CMB further. The principle was to add a new uncorrelated factor to the CFA model, with this factor containing all the defined items of our model. By comparing the factor loadings, it was found that in three cases out of the 19 cases, the differences were significantly different from those of the original model. The fit measures also increased slightly with CLF (delta CFI = 0.0276, delta Root Mean Square Error of Approximation (RMSEA) = −0.0168, delta Standardized Root Mean Square Residual (SRMR) = - 0.0104). Additionally, in the two cases, the values of the factor loadings were significantly different (diff > 0.200) compared to the original model without CLF. Moreover, the chi-square difference test identified a significant difference between the tested models (p < 0.001). Therefore, the conceptual model was modified in the next phase to include a common latent factor with direct relationships with all indicators to eliminate CMB. The CLF factor was defined as uncorrelated with other constructs. The factor loadings between the items and the CLF factor were not equal; in our model, it was assumed that the CLF could influence different indicators. The authors subsequently subjected the CMB-corrected CFA model to further investigation and validation.

To confirm the correctness of the composition of the individual factors in our conceptual model, confirmatory factor analysis (CFA) was conducted. This chapter aims to confirm whether the proposed items for each factor capture individual factors sufficiently well. The results of the CFA did not include the CLF factor, as this factor was incorporated into the model only because of common method bias.

The CFA model was based on the conceptual model defined above but did not include individual linkages between latent factors at this stage. A confirmatory factor analysis (CFA) was implemented in R using the Lavaan library. CFA assessed several aspects of the model: the statistical significance of model parameters, internal consistency of scales, convergent validity, and discriminant validity. The CFA fit measures were used to evaluate the accuracy of the defined CFA model.

The CFA model was quantified using the variance standardization method; all constructs’ variances were fixed at one. After model quantification, statistical significance was assessed to verify whether the items were appropriate for defining the latent variables. We verified the statistical significance of each item for its respective latent factors. For all items related to the standard factors, the statistical significance of each item for the respective factors was strong (p-value < 0.001). However, when analyzing the statistical significance of items belonging to a common latent factor, the findings showed that some items were not statistically significant. Consequently, we removed items KC1, KC2, RH1, and RH2 from the definition of the CLF factor. All other items were significant, at least in alpha = 0.05. Based on these findings, the authors of this paper assumed that not all items were affected by common method bias.

The internal consistency of the scales for the five factors (excluding CLF) was assessed to verify whether the individual items were consistent within the selected group, that is, how consistent the individual items were as a group defining the factor. The internal consistency of the scales was measured using Cronbach's alpha with a threshold value of 0.70, which is widely considered desirable (Taber, 2018) as a cut-off value for verifying consistency. The mean of the five internal scales tested was 0.8353, with Cronbach's alpha values ranging from 0.7417 (RH) to 0.8911 (TL).

According to some authors, McDonald's omega is a better indicator of the internal consistency of scales than Cronbach's alpha (Trizano-Hermosilla & Alvarado, 2016). The mean value of the McDonald's omega coefficient for the five defined factors was 0.8493, with a minimum value of 0.7986 (RH factor) and a maximum value of 0.9018 (TL factor). Moreover, when evaluating the internal consistency of the scales using McDonald's omega coefficient, the omega2 metric from the semTools package in R was used. Flora (2020) states, “omega2 is calculated using the model-implied variance of the total score in its denominator.” The mean value of the McDonald's omega2 coefficient for the five defined factors was 0.8009, with a minimum value of 0.7602 (FI factor) and a maximum value of 0.8510 (KC factor). All omega values were compared using a threshold value of 0.70.

To test whether individual items correlated with other items within the same common construct (i.e., whether individual items within the same latent variable converged), the convergent validity of the CFA model was assessed using the Average Variance Extracted (AVE) metric. The AVE values were calculated as the sum of the squared factor loadings divided by the number of indicators. A threshold of 0.50 was considered for individual AVE values (Bentler, 1990), indicating that the construct should explain at least 50% of the variance of the indicators. The AVE values were above this threshold for the KC, FI, TL, and AL factors. However, the AVE value for the RH factor was 0.4458, below the threshold, indicating a potential issue.

According to some authors (Wei & Nguyen, 2020; Hair et al., 2009), the convergent validity of a model can also be assessed using standardized factor loadings. The standardized factor loadings except CLF were above 0.50, except for FI4 and RH4. Moreover, the composite reliability index was calculated for each construct to check the convergent validity further. The composite reliability indices ranged from 0.7526 (RH factor) to 0.8595 (AL factor), which were above the accepted threshold value of 0.60 (Hair et al., 2014; Bagozzi & Yi, 1988). The model was retained despite the AVE value being below the threshold in one case and the standardized factor loadings being below 0.50 for two items. As Fornell and Larcker (1981) reported, if the AVE value is less than 0.50 but the composite reliability indices are greater than 0.60, the convergent validity of the construct may still be adequate.

The next part of the CFA tested the extent to which the individual latent variables differed, that is, to validate discriminant validity. Discriminant validity checks whether individual latent variables measure different aspects and whether they are dissimilar. Discriminant validity was tested in several ways. Although the chi-square test comparing our free model with constrained models, where correlations between two selected latent factors were set to a cutoff value of 0.80—could not be performed (likely because of the identification of a common latent factor variable), discriminant validity was tested using other methods. The discriminant validity of the CLF construct was not evaluated.

First, the correlation values between latent factors should not exceed a defined threshold to confirm discriminant validity. The threshold was set at 0.85 (Garson, 2002; Kenny, 2016). From Table 5, it can be concluded that the maximum correlation value between the latent factors was 0.590 (KC-TL). Based on this, the model satisfied the discriminant validity criterion.

The accuracy of the discriminant validity of the model was also confirmed using the calculated Fornell-Larcker criterion (Fornell and Larcker, 1981). Within this criterion, the correlations between the constructs were compared with the square root of AVE. Table 6 presents a matrix of these values, with the square root of the AVE values shown on the diagonal. The values of the inter-factor correlations were lower than the square root of the AVE for all factors tested, reaffirming the acceptance criterion for discriminant validity.

To confirm the discriminant analysis, this aspect of the model was validated using the Heterotrait-Monotrait Ratio (HTMT) matrix proposed by Henseler et al. (2015). The HTMT matrix evaluates the number of subsumed individual factors. It is assumed that the individual factors are not very similar. A threshold value was used to evaluate this property. When evaluating discriminant validity, a threshold value of 0.85 was used (Kline, 2011) to distinguish between discriminant validity and factor invalidity. In our case, the values in the HTMT matrix among the five latent variables (the common latent factor was excluded from these results) ranged from 0.171 to 0.630 (TL-KC). These values were below the threshold, confirming that all observed factors were discriminant-valid. This test confirmed the discriminant validity of the CFA model.

In addition to testing the validity of the various aspects of the CFA model, accuracy measurements were performed using fit measures. Regarding accuracy, the model was verified using two types of fit measures: absolute and relative. The reported values of our model were compared with the defined threshold values listed in Table 7.

The only problematic metric was the chi-square test, which confirmed a difference between the sample-implied covariance matrix and the observed covariance matrix (p < 0.001). However, given the test's sensitivity, this result was not unique. The results of the other metrics confirmed the high accuracy of the model. The ratio of the chi-square to the degrees of freedom was 1.708, which was below the cut-off value. The goodness-of-fit index was 0.939, exceeding the defined threshold, and was therefore deemed acceptable. The excellent accuracy of the model was also confirmed by the Standardized Root Mean Residual (SRMR), which was 0.055, below the required value of 0.08. The point estimate of the root mean square error of approximation (RMSEA) was 0.044, with a 90 percent confidence interval ranging from 0.034 to 0.054 (p-value RMSE ≤ 0.05 = 0.843). Relative fit measures were performed satisfactorily. The Comparative Fit Index (CFI) value was 0.976, above the acceptable level of 0.90. Similarly, the other metrics were above the defined threshold values (NFI = 0.946, IFI = 0.977), confirming a good fit for the quantified model.

Structural equation modeling (SEM) was used to test these hypotheses. They are used for several reasons using SEM modeling. First, the SEM is a system of multiple relationships between several variables in which one variable can be simultaneously dependent and independent in a defined system. Second, the SEM model enables the verification of the statistical significance of individual relationships, as it is a model whose purpose is not just prediction. Third, SEM is a white-box model that enables the interpretation of individual relationships. SEM modeling, thus, SEM allows us to assess the effect of one variable on another and the strength of the relationship between variables. Fourth, SEM allows latent variables to be combined into regression modeling through CFA. Finally, because the SEM model forms a system of multiple relationships, it also allows for investigating the indirect effects of one variable on another through mediators within the context of the entire system. This study aimed to examine the impact of AL on employees' knowledge-hiding behavior. SEM modeling enabled us to investigate and analyze indirect relationships, that is, the mediating effects of other factors on the relationship between AL and knowledge-hiding behavior.

In SEM modeling, two basic approaches are used: partial least squares SEM (PLS-SEM) and covariance-based SEM (CB-SEM). CB-SEM modeling was selected as the preferred method because our study focused more on verifying or confirming known theories rather than conducting exploratory research.

A validated CFA model was used to develop a structural equation (SEM) that contained defined regression relationships based on the conceptual model and theory. As previously mentioned, our goal was to determine the statistically significant relationships. If a given relationship was statistically significant, we were interested in its strength. Additionally, we investigated the role of mediators in the model and examined whether our model had mediating effects. Based on the constructed SEM model and the statistical evaluation of individual regression relationships, we proceeded to confirm or reject the hypotheses defined in the conceptual model (Byrne, 2013; Schumacker & Lomax, 2004). The SEM was quantified using the maximum likelihood estimator, the default estimator in the Lavaan R package.

Nine hypotheses are defined in the conceptual model. Based on the theoretical background mentioned in Section 1, we hypothesized that there would be a direct relationship between AL and KC (Kanungo & Mendonca, 1996; Lin et al., 2020; Obrenovic et al., 2020), AL and RH (Abdillah et al., 2022; Obrenovic et al., 2020; Zhang et al., 2010), AL and FI (Abdillah et al., 2022; Obrenovic et al., 2020; Zhang et al., 2010), TL and RH (Fong et al., 2018; He et al., 2021; Lu et al., 2012; Zhang & Min, 2019), and TL and FI (Fong et al., 2018; He et al., 2021; Lu et al., 2012; Zhang & Min, 2019).

In addition, we hypothesized several indirect relationships between variables. We hypothesized that a mediation effect would increase (decrease) the strength of individual relationships between latent variables. Based on this theory, we hypothesized the mediating roles of TL and KC factors. Specifically, we hypothesized that in addition to the direct relationship between AL and KC, a relationship through the mediator TL could amplify this relationship (H10). Simultaneously, based on (Drucker, 1999; Gupta & Govindarajan, 2000; DeLong & Fahey, 2000; Wenger et al., 2002), we hypothesized that the mediator TL could have an indirect effect on the AL-KC (H11) and AL-FI (H12) relationships based on (Bucic et al., 2010; Edmondson, 1999). Moreover, since the influence of TL and KC on PD and RH factors (Edmondson et al., 2007; Kucharska, 2021; Zhang & Min, 2019) is also known from theory, we hypothesized a compound indirect effect via the two mediators, TL and KC, on both latent variables (H13 and H14).

The mediators, TL and KC, were the main elements of the proposed and tested conceptual model. We predicted a mediating indirect effect of the TL factor on five hypotheses (H10–H14). We predicted the mediating effect of KC on the three hypotheses tested (H10, H13, and H14). We hypothesized that these two factors would indirectly affect the latent output variables PD and RH. In other words, we hypothesize that TL and KC would have statistically significant effects on the output factors of our model. Thus, these factors can contribute to understanding the importance of these elements in a firm's knowledge-sharing system. Therefore, based on the above indirect effects, we hypothesized that the total effect for the relationships defined by H1 to H5 would be the sum of the direct and indirect effects, where the indirect effects result from the mediators, in our case, mainly TL and KC.

To eliminate the influence of common method bias, we added a common latent factor (CLF) that was uncorrelated with other factors to the model. The CLF factor contained links to all defined items in our CFA model. Due to problems with model identification, we did not limit these links to equal weights. To identify the model, we used the variance standardization method; we standardized the variance of the five constructs and the variance of the common latent factor to one.

We quantified the standard errors using a bootstrapping method based on 5000 bootstrap samples to obtain more robust results. Of the 5000 bootstrap draws performed, 4929 runs were successful, while 71 bootstrap runs failed or did not converge. Thirty-eight bootstrap runs resulted in nonadmissible solutions. Based on the bootstrap results, we calculated the bias-corrected and accelerated lower-level confidence intervals (LLCIs) and upper-level confidence intervals (ULCIs) for the unstandardized parameter estimates. Moreover, we calculated the standardized regression coefficient estimates with percentile confidence intervals. Table 8 presents the results for each conceptual model hypothesis.

Our study extends the knowledge on the role of AL about knowledge hiding and offers several theoretical implications. As mentioned in the literature review, previous studies have confirmed that AL positively impacts organizational culture and performance. Specifically, Abdillah et al. (2022) examined the functions of AL concerning counterproductive knowledge behaviors, such as knowledge hiding. While previous studies have focused on why subordinates hide knowledge, leadership styles that can prevent this behavior have not received sufficient attention. The main contribution of their study is that the direct relationship between AL and knowledge hiding is weak but is mediated by two other factors: leader-triggered positive emotions and leader-member exchange (Abdillah et al., 2022).

Hypothesis H1 was confirmed (β = 0.218, p < 0.01), indicating that altruistic leaders significantly contribute to creating an environment that supports knowledge sharing. This aligns with previous studies highlighting AL's role in fostering team trust and collaboration (Abdillah et al., 2022). Hypothesis H2 was also supported (β = −0.088, p = 0.053), suggesting that altruistic leaders can reduce employees’ tendency to withhold information under the pretext that they cannot share, thereby promoting transparency within the organization (Obrenovic et al., 2020). Hypothesis H6 was confirmed with a strong relationship (β = 0.238, p < 0.001), showing that AL significantly positively impacts the TL process. This supports previous research (Barghouti et al., 2022; Guinot et al., 2016), emphasizing that altruistic leaders encourage communication and collaboration, improving TL. This is crucial in environments in which new skills and innovations are required. Hypothesis H7 was strongly supported (β = 0.72, p < 0.001), suggesting that effective team-level learning promotes a broader culture of knowledge sharing within the organization, consistent with Edmondson et al. (2007). A strong KC helps organizations respond to new challenges and utilize internal knowledge more effectively. Hypothesis H9 was confirmed (β = −0.109, p = 0.021), indicating that a strong knowledge-sharing culture can reduce behaviors where employees pretend not to know something to avoid sharing information. This aligns with Serenko and Bontis (2016), who emphasized that a healthy knowledge-sharing culture minimizes willful ignorance and increases transparency. Hypothesis H10 was confirmed (β = 0.171, p < 0.001), showing that TL is a significant mediator between AL and knowledge-sharing culture. AL promotes TL, which, in turn, strengthens knowledge sharing within an organization (Salas-Vallina & Alegre, 2018). Lastly, Hypothesis H13 was confirmed with marginal significance (β = −0.019, p = 0.082), suggesting that AL may indirectly reduce the occurrence of “PD” through the mechanisms of TL and knowledge-sharing culture. Although weak, the effect highlights the importance of TL and culture in improving knowledge sharing and reducing passive-aggressive behaviors in teams.

However, some of the hypotheses were not supported by these results. Hypothesis H3 was not confirmed (p = 0.773), suggesting that AL does not significantly reduce ”PD” behavior, contrary to expectations and previous studies (e.g., Obrenovic et al., 2020). This may be because factors such as personality traits or organizational norms influence this behavior more strongly than leadership alone. H4 was also not supported (p = 0.201), indicating that TL does not significantly reduce rationalized knowledge hiding. This contrasts with previous research (Fong et al., 2018) and suggests that learning within teams might not be sufficient to overcome knowledge-hiding tendencies with additional interventions, such as promoting open communication. Similarly, Hypothesis H5 was not confirmed (p = 0.224), meaning that TL does not play a major role in reducing “PD”. Individuals may still resort to pretending ignorance due to other factors such as personal motivations or organizational dynamics. Hypothesis H8 is not supported (p = 0.217), suggesting that a strong knowledge-sharing culture does not significantly reduce rationalized knowledge hiding. Employees may use rationalized excuses to withhold information even in environments that encourage sharing. Hypothesis H11 (p = 0.213) proved that contrary to expectations, TL does not mediate the relationship between AL and rationalized knowledge hiding. This could indicate that AL alone cannot fully eliminate knowledge hiding, which may have deeper individual or organizational roots. Hypothesis H12 (p = 0.303) was not supported, indicating that TL does not mediate the relationship between AL and FPD Organizational norms or employee motivation could play a more significant role in reducing this behavior. Finally, Hypothesis H14 (p = 0.274) was not confirmed, suggesting that the combination of TL and a knowledge-sharing culture does not significantly mediate the relationship between AL and rationalized knowledge hiding. Employees may still use rationalized excuses for hiding information, even in environments promoting learning and knowledge sharing.

This research provides important insights that contribute to expanding both the theory and practice of knowledge management, while deepening our understanding of the relationship between AL and knowledge-hiding behaviors (e.g., Connelly et al., 2012; Černe et al., 2014, Kucharska & Rebelo, 2022). The authors focused on the role of AL in reducing employees' tendencies to hide information, thus fostering transparency and collaboration within organizations. They also explored the role of TL and KC as mediators in this relationship. The hypotheses confirm that altruistic leaders create an environment that promotes knowledge sharing and TL, indirectly reducing negative employee behaviors such as PD. This leads to better organizational outcomes through effective knowledge-sharing and team collaboration.

The originality of this research lies in examining the relatively unexplored relationship between AL and knowledge-hiding processes, emphasizing mediators such as TL and a knowledge-sharing culture. This approach provides a fresh perspective on how AL positively affects organizational outcomes. Theoretically, this research extends the existing leadership literature by demonstrating how AL fosters a culture of knowledge sharing and TL, reducing negative behaviors such as knowledge hiding. The findings also suggest that other factors such as organizational norms and individual motivations need to be considered to reduce such behaviors effectively.

In addition to theoretical implications, our results provide several insights for managers that could help eliminate the negative effects of subordinates’ knowledge hiding. The first is that AL has a direct impact on TL and, consequently, on KC. To build a KC in which knowledge is shared across an organization at the right time, quantity, and quality, focusing solely on teams and internal knowledge sharing is not enough. Our results show that a leader with altruistic traits positively affects TL, manifested by a higher level of KC and a lower level of knowledge hiding (specifically in RH and PD). Therefore, selecting work team leaders should include an evaluation of the degree of altruism among potential leaders.

Second, our results indicate a strong relationship between TL and cultural knowledge. Work teams are crucial for knowledge sharing, and managers should consider the significant roles of team effectiveness and mutual communication. Third, our study revealed a mechanism affecting one component of knowledge hiding, namely PD. This form of knowledge hiding can be mitigated by systematically building a KC that includes TL and AL.

Finally, our study contributes to practice by providing several recommendations and guidelines for managers to eliminate the knowledge-hiding culture within organizations. First, it emphasizes the direct influence of AL on TL, which fosters a positive KC. Furthermore, the findings highlight the importance of altruism when selecting team leaders to promote effective knowledge sharing. Finally, this study identifies a mechanism to reduce one aspect of knowledge hiding, specifically, the dimension of PD, by systematically cultivating a KC that involves TL and AL.

All survey-based studies have certain limitations, and this study is no exception. The first was geography. The data were collected in Slovakia, a country characterized by relatively high societal mistrust. This could have affected the identified relationships' data quality and intensity. Research conducted in culturally different countries with higher trust and willingness to share knowledge could help validate the proposed model. The second limitation was the heterogeneity of the sample. The sample represented a non-stratified set of organizations from different sectors, which could have influenced the results.

Additionally, lower p-values (<0.05) were identified for the two items when testing for non-response bias, indicating statistically significant differences between the groups. Although this may suggest the presence of non-response bias, it does not necessarily confirm the presence of non-response bias in our data. It is unclear why there were statistically significant differences between older and newer respondents in their answers. A closer analysis of the data revealed that among the older responses, there were more answers from respondents from micro and small businesses (147 vs. 131). Conversely, more recent responses came from medium and large enterprises with fewer employees than 50 (37 versus 53). The low p-values in these cases indicate that the method of sharing knowledge related to RH may have been influenced by the size of the companies in which the respondents worked.

Another limitation is the self-reported measurement used for data collection. Respondents' views may not accurately reflect the actual attributes of teamwork. Expanding data collection to include more respondents from a single organization could be a suitable way to mitigate this risk. Our study focuses on three factors that positively impact and can mitigate some form of knowledge hiding. However, several potential factors associated with leadership, such as abusive supervision, humble leadership, and ethical leadership, have not been explored in depth.

In conclusion, our study provides valuable insights into preventing knowledge hiding by considering TL and KC as mediators. Overall, it contributes a new direction for altruistic leaders and organizations to design suitable concepts and strategies for preventing knowledge-hiding behavior among employees and confirms the importance of AL in organizations.

The relationship between leadership style and knowledge-hiding behavior should be further investigated, and more detailed empirical research is required because there are many variables within both concepts. Special focus should be placed on the influence of different leadership styles and cultural knowledge settings within different organizations. The proposed conceptual model can be tested in more specific sectors where knowledge hiding represents a critical risk of dramatically changing process efficiency (e.g., the IT sector). Future studies can collect data not only at the individual level but also at the team level, for example, from the manager's perspective. The phenomenon of knowledge hiding still represents a strong potential for further research in specific types of knowledge (tacit/explicit), as knowledge hiding probably occurs because of different causes and motives. It is also important to understand and study individual/team/organizational antecedents that could decrease knowledge-hiding behaviors. The authors of this study aim to address some of the identified limitations and explore the proposed research directions for future studies.