With the recognition of services and service innovation as central drivers of broader economic growth and innovation (Cuthbertson & Furseth, 2022; F. Gallouj, 2002; I. Miles, 1993), an increasing focus on service innovation has been identified in academic research (Droege, Hildebrand, & Forcada, 2009; Ordanini & Parasuraman, 2011). Coombs and Miles (2000) categorize existing research into three different perspectives: assimilation, demarcation, and synthesis. Although there are interesting differences in understanding service innovation, the view of service innovation as a new service (offering) is shared by the three perspectives (Witell, Snyder, Gustafsson, Fombelle, & Kristensson, 2016). Moreover, according to Witell et al. (2016), synthesis is replacing assimilation and demarcation in research on service innovation (Carlborg, Kindstrom, & Kowalkowski, 2014). This is especially true in the manufacturing sector. Service innovation is increasingly appearing in manufacturing firms, as it provides unique opportunities for developing competitive advantages through new services and integrated product-service bundles (Kindstrom, Kowalkowski, & Sandberg, 2013; Ulaga & Reinartz, 2011). Responding to this phenomenon, the synthesis perspective argues that service innovation should be broad enough to encompass innovation in both services and manufacturing (Choo, Narayanan, Srinivasan, & Sarkar, 2021; Coombs & Miles, 2000; Shin, Kim, Jung, & Kim, 2022)and should provide an integrative perspective that is not limited to technological innovations(Gonzalez-Blanco, Coca-Perez, & Guisado-Gonzalez, 2019). This encourages us to apply a synthesis perspective to understand and characterize service innovation in the manufacturing sector.

Drawing on the synthesis perspective, we use an integrated approach that includes nontechnological aspects (e.g.,services, processes, knowledge) along with technological (product) forms and nests both services and goods into an overarching service view (Gonzalez-Blanco et al., 2019; Lusch & Vargo, 2006; Ordanini & Parasuraman, 2011). We define service innovation as an offering not previously available to manufacturers’ customers, either as an addition to the current service offering or a change in the service delivery process that requires modifications in the sets of competences (technological or nontechnological) applied. Furthermore, by regarding service innovation processes as similar to product innovation processes (Atuahene-Gima, 1996; Blindenbach-Driessen & Ende, 2014; Nijssen, Bas Hillebrand, & Kemp, 2006; Ordanini & Parasuraman, 2011), we employ March's(1991) exploration-exploitation framework to characterize two basic types of service innovation (Myhren, Witell, Gustafsson, & Gebauer, 2017; Sok & O'Cass, 2015). Exploratory service innovation relates to the introduction of radical service offerings to the market in pursuit of new opportunities, whereas exploitative service innovation refers to extensions and refinements to existing services as well as improvements to service delivery processes to satisfy and retain existing customers. Thus, exploratory service innovation relates to the search and pursuit of completely new knowledge and skills, whereas exploitative service innovation refers to the use and refinement of existing knowledge and skills (He & Wong, 2004; Menor, Tatikonda, & E.Sampson, 2002; Zhou & Wu, 2010).

Because service innovation provides manufacturers with unique opportunities for developing competitive advantages(T. Baines et al., 2017; Choo et al., 2021; Cusumano, Kahl, & Suarez, 2015; F. H. Liu & Huang, 2018), existing scholars have suggested exploring the determinants of service innovation in manufacturing firms (Spring & Araujo, 2013). The resource-based view (RBV) of the firm is often considered to offer potential insights into understanding the determinants leading manufacturers to engage in service innovation and affect the possibilities of successful service innovation. For example, some studies explore the influence of information technology resources on service innovation (Bantau & Rayburn, 2016; Chen, Chen, Liu, & Xu, 2020; Suppatvech, Godsell, & Day, 2019). However, the competitive advantage can be derived in part from resources existing outside the firm (Fernandes, Milewski, Chaudhuri, & Xiong, 2022). Scholars have pointed out that firms must build relationships with external sources to seek knowledge dispersed beyond their boundaries (e.g., Corso, Martini, Paolucci, & Pellegrini, 2011; Hervas-Oliver, Sempere-Ripoll, & Boronat-Moll, 2021). Thus, a firm's networks may be critical for competitive success (Dyer, Singh, & Hesterly, 2018).

In line with this logic, the importance of social relationships or networks in service innovation has been acknowledged in manufacturing settings, as social capital affects firms’ access to both tangible and intangible resources (Dyer et al., 2018; Savino et al., 2017; Syson & Perks, 2004). Additionally, the rise of open service innovation (Chesbrough, 2011)indicates the critical role of external ties in facilitating service innovation in manufacturing firms. Thus, the identification of external sources and developing relationships with external sources are related to the processes of service innovation. Savino et al. (2017) argue that the search for the needed external knowledge could be delegated to service intermediaries. The critical role of service intermediaries as external sources of knowledge for innovation is widely recognized in the literature (Colombo, Dell'Era, & Frattini, 2015; Howells, 2006; Howells & Thomas, 2022; Lin et al., 2016; Y. Zhang & Li, 2010). However, the research mainly focuses on how intermediaries drive product innovation (Lin et al., 2016; Tran, Hsuan, & Mahnke, 2011; Y. Zhang & Li, 2010).Few empirical studies examine how manufacturing firms’ ties with service intermediaries impact their service innovation activities.

In summary, although existing research highlights the determinants of service innovation from the perspective of RBV, the relational view and social network theories offer novel and important insights into the value of external relationships for service innovation. Since developing ties with service intermediaries may be a vital option for manufacturing firms to access new stocks of knowledge for service innovation, we are encouraged to analyze and examine the determinants of manufacturers’ service innovation from the perspective of relationships.

Service intermediaries refer to professional service organizations that rely heavily on professional knowledge(Desyllas, Miozzo, Lee, & Miles, 2018; Jamkhaneh, 2021; I. Miles et al., 1995).According to I. Miles et al. (1995), service intermediaries are experts in offering specific knowledge in multiple expertise domains(De Silva, Howells, & Meyer, 2018; Villani, Linder, Lechner, & Muller, 2021), such as technological consulting, market research, legal and financial services. Although service innovation researchers mainly focus on service intermediaries’ role in offering knowledge services (Chiaroni, Chiesa, De Massis, & Frattini, 2008; De Silva, Howells, Khan, & Meyer, 2022; Drejer & Vinding, 2003), the specific networking role of service intermediaries has been increasingly recognized by academic research (Gundlach & Hofmann, 2021; Howells & Thomas, 2022; Pinheiro & Pinheiro, 2021; Savino et al., 2017). Specifically, parallel to the rise in developing ties with external sources to access new stocks of knowledge, research on ties with service intermediaries has burgeoned (Lin et al., 2016; Savino et al., 2017).

Compared with prominent firms, universities and research institutions, service intermediaries are potentially available to all firms. More importantly, service intermediaries usually sit at the intersection of many firms, organizations and industries acting as network intermediaries for interaction and information exchange among firms (Howells, 2006; Kokshagina et al., 2017). Thus, it is not surprising that the literature on innovation search highlights the critical role of service intermediaries in facilitating firms’ search for innovation. Being potentially accessible to manufacturing firms and located at a unique network position(Howells & Thomas, 2022; Pinheiro & Pinheiro, 2021), service intermediaries are argued to have the potential to facilitate firms searching a broader range of firms, organizations, and industries for service innovation.

Drawing on the above arguments, Y. Zhang and Li (2010) argue that ties with service intermediaries can provide an entry ticket for firms to join rich networks and, thus, enable them to broaden their external search scope and reduce search costs(Clayton, Feldman, & Lowe, 2018). In their empirical study, Y. Zhang and Li (2010) provide evidence that new ventures’ ties with service intermediaries have a significantly positive impact on product innovation. Usinga sample of Chinese manufacturing firms, Lin et al. (2016)show that manufacturing firms' ties to intermediaries contribute to corporate innovation performance. Similarly, W. Zhang, Wang, and Zhao (2015)find that ties with service intermediaries have positive relationships with both service innovation and product innovation.

However, the extant research mainly focuses on search scope to explain the relationshipswith service intermediaries without considering the function of search depth. Moreover, scholars have largely treated exploratory and exploitative innovation as a collective bundle and thus have failed to shed light on how relationships with service intermediaries may be differently related to exploratory versus exploitative innovation. Because exploration involves the pursuit of new knowledge, whereas exploitation builds on the use and development of existing knowledge(Bernal & Toro-Jaramilo, 2019; Rojas-Cordova, Williamson, Pertuze, & Calvo, 2022; Wenke, Zapkau, & Schwens, 2021), exploratory and exploitative service innovation require different knowledge components. Thus, exploratory and exploitative service innovation are likely to be facilitated by manufacturing firms’ different search behaviors (Angelidou, Mount, & Pandza, 2022; Katila & Ahuja, 2002; Mun, 2022), i.e., search scope and search depth and are, therefore, influenced by ties with service intermediaries differently. By combining search scope and search depth, our research aims to fill the gap by examining the differential effects that ties with intermediaries might have on exploratory versus exploitative service innovation.

A manufacturing firm is expected to connect to various kinds of organizationswith which it has no direct contacts before it develops relationships with service intermediaries. Correspondingly, the manufacturing firm is bridged and exposed to a variety of knowledge sources (Howells, 2006; Howells & Thomas, 2022; Wolpert, 2002), enabling it to search in rich networks rather than searching only within immediate personal networks (Lin et al., 2016; Y. Zhang & Li, 2010). The more interaction with service intermediaries there is, the greater the search scope of the manufacturing firm to access multiple knowledge domains (Y. Zhang & Li, 2010). Hence, a greater amount of novel and heterogeneous knowledge beyond existing technologies and markets may be sourced for the development of exploratory service innovation (Kitsios & Kamariotou, 2021; March, 1991; Rosenkopf & Nerkar, 2001). Moreover, repeated interactions with service intermediaries enable manufacturers to gain more insights into the value of new information and opportunities, which in turn offers the potential for new, truly innovative combinations of knowledge for exploratory service innovation.

However, although ties with service intermediaries may start as nonredundant contacts, they are likely to become redundant over time in terms of indirect contacts and knowledge (Burt, 1992; Hansen, 1999). This is especially true when relationships with service intermediaries become strong. Consequently, the manufacturing firm is enabled to search similar knowledge repeatedly, which likely brings in ideas for minor refinement or extension of existing knowledge for exploitation, although not the discovery of novel ideas.

Therefore, after reaching a certain point, an increase in the strength of the relationship is more likely to lead to an increase in search depth and a decrease in search scope. This tendency may encourage the manufacturing firm to source familiar or similar knowledge for exploitation instead of sourcing new knowledge for exploration, which, in turn, results in a decrease in the positive effect of strong ties with exploratory service intermediaries.

• H1:The stronger the ties with service intermediaries are, the more likely the manufacturing firm is to develop exploratory service innovation. However, after reaching a specific level of tie strength, the stronger the ties with service intermediaries are, the less likely the manufacturing firm is to develop exploratory service innovation.

Exploitative service innovation involves the ongoing use of a firm's knowledge base (Blindenbach-Driessen & Ende, 2014; He & Wong, 2004; Wenke et al., 2021; Z. G. Zhang & Luo, 2020). Following network research(Neulandtner & Scherngell, 2022), it seems reasonable to argue that strong ties may enable manufacturing firms to conduct deep searches, which in turn facilitates exploitative service innovation.

First, close links with service intermediaries reflect an intense use of those indirect knowledge sources, resulting in an increase in the depth of knowledge search (M. X. Wang & Wang, 2022). In this case, ongoing and repeated accessing and acquiring specific knowledge in similar knowledge fields is available, which deepens a manufacturing firm's understanding of how to integrate these specific elements of knowledge within the existing knowledge base. Second, as the manufacturing firm accumulates the experience of interacting with service intermediaries and develops a common language, unique processes and routines, the knowledge search becomes more reliable and predictable. Henceforth, the manufacturing firm becomes more competent in searching for new knowledge in its own expertise fields, which, thus, strengthens the exploitation of existing know-how. Third, network inertia resulting from strong relationships(Hansen, 1999) may lead the manufacturing firm to stay with existing links and correspondingly encourage them to rely on existing, specialized domains to engage in a deep search for exploitative service innovation.

Therefore, we contribute to the literature by proposing that strong ties with service intermediaries may facilitate exploitative service innovation at an accelerated rate, such that a greater strengthof the ties between the manufacturing firm and service intermediaries relates to increasingly higher levels of exploitative service innovation.

• H2: The stronger the ties with service intermediaries, the more likely it is for the manufacturing firm to develop exploitative service innovation.

While prior studies have examined the moderating role of external environmental factors, such as industry growth (Y. Zhang & Li, 2010), environmental munificence and complexity (Lin et al., 2016), scant attention has been given to the possible moderators from the internal resource or capability perspective.Both absorptive capacity and dynamic capability theories can be considered as extensions of RBV and have been employed in several service innovation studies(e.g. Tsou & Chen, 2020). Absorptive capacity theory has been applied mainly to analyze possible determinants of service innovation (e.g., Koch & Strotmann, 2008; Xie, Wang, & García, 2021). Dynamic capability enables firms to continually integrate, build, and reconfigure internal and external resources (Eisenhardt & Martin, 2000; Randhawa, Wilden, & Akaka, 2022; Teece et al., 1997). Thus, activating dynamic capabilities is considered critical in helping firms continually recombine resources to develop new services (Fischer, Gebauer, Gregory, & Ren, 2010; Janssen, Castaldi, & Alexiev, 2016).

Following the view of innovation as a process of searching and recombining knowledge sources(Nelson & Winter, 1982; Petruzzelli & Savino, 2014; Savino et al., 2017), external searches maybe useless if the accessed knowledge is not properly integrated with firms’ existing knowledge (Enkel & Gassmann, 2010; Kim & Park, 2013; Zahra & George, 2002).Thus, it is suggested that manufacturers have matched absorptive capacity or dynamic capabilityto absorb and recombine externally accessed knowledge with internal knowledge for service innovation (Savino et al., 2017; Xie et al., 2021). On the one hand, according to Cohen and Levinthal (1990), a firm's knowledge base underpins how well it can use new knowledge to achieve desired innovation outcomes. For product-centric manufacturers, technological capability is regarded as the core component of internal capabilities and represents an important source of absorptivecapacity (M. K. Srivastava, Gnyawali, & Hatfield, 2015; Zhou & Wu, 2010). Hence, the accumulation of technological capability increases a manufacturer's ability to evaluate and use new technologies and skills in service innovation (Zahra & George, 2002).

Although it is challenging for manufacturers to effectively apply existing limited knowledge stocks to combine externally accessed knowledge, the dynamic resource management view suggests that resource portfolios can be extended by accumulating multifunctional resources and reconfiguring resource bundles (Sanchez, 1995, 1997). Strategic flexibility, as a special type of dynamic organizational capability to reconfigure and redeploy resources (Brozovic, 2018; Sanchez, 1995), may have a significant influence on the relationship between ties with service intermediaries and exploratory versus exploitative service innovation.

We propose, therefore, that technological capability, representing an important source of absorptive capacity, and strategic flexibility, as one type of dynamic capability (Brozovic, 2018; Sanchez, 1995; Zhou & Wu, 2010), may play important and differential roles in achieving the potential of ties with service intermediaries for exploratory and exploitative service innovation.

Service innovation in the manufacturing context involves both technological and nontechnological aspects (F Gallouj & Savona, 2009; Faïz Gallouj & Weinstein, 1997), which indicates that technological knowledge is one basic element for service innovation, such as technologies on product development, service design, customer interaction, and service delivery(F Gallouj & Savona, 2009; Faïz Gallouj & Weinstein, 1997; L. Wang, Zheng, & Huang, 2018). Thus, a high technological capability not only allows manufacturing firms to identify and integrate diverse technological knowledge beyond their current knowledge boundaries but also enables manufacturing firms to be more sensitive to opportunities within their existing technological trajectory. The accumulation of technological capability increases manufacturing firms’ ability to evaluate, absorb and use new technologies and skills in exploratory and exploitative service innovation (Seo, Song, & Jin, 2022; Zahra & George, 2002). Specifically, a prior technological knowledge base facilitates focusing the search for new knowledge on the most likely areas of novel opportunity and eliminating search areas likely to be fruitless.

It is worth noting that technological capability not only facilitates the absorption of technical-related knowledge but also provides a manufacturing firm with more technical expertise to discern the potential value of market-related knowledge (Song, Droge, Hanvanich, & Calantone, 2005)and combine it with its current technological knowledge for the development and commercialization of service innovation.

Based on the above arguments, we propose that ties with service intermediaries have stronger positive effects on both exploratory and exploitative service innovation in the presence of higher levels of technological capability.

• H3a: Technological capability strengthens the positive effect of ties with service intermediaries on exploratory service innovation.

• H3b: Technological capability strengthens the positive effect of ties with service intermediaries on exploitative service innovation.

In the extant literature, strategic flexibility, resource flexibility and coordination flexibility stand out as the most critical capabilities of strategic flexibility (Y. Li, Su, & Liu, 2010; Sanchez, 1995). Resource flexibility focuses on the inherent flexibility ofthe resources available to the firm, while coordination flexibility focuses on the firm's flexibility in applying those resources toalternative courses of action (Sanchez, 1995). Thus, we propose that, together, theyinfluence the linkageswith service intermediaries and exploratory versus exploitative service innovation.

Resource flexibility reflects the mechanism of resource accumulation for the flexible bundle of diverse internal resources (Sanchez, 1995, 1997). When resource flexibility is low, manufacturing firms’ existing resources are strongly attached to specified targets and can hardly be employed for the targeted service innovation, either exploratory or exploitative. Moreover, it is costly to find complementary resources for assimilating and using external knowledge and opportunities during the service innovation process (Gerwin, 1993; Koste, Malhotra, & Sharma, 2004). In contrast, a high level of resource flexibility ensures that the matched resource bundles can be used in combination with external knowledge for service innovation, and the time along with the cost spent on seeking new resources and switching one resource to another may decrease (Y. Liu, Li, & Wei, 2009; Matthyssensa, Pauwelsc, & Vandenbempta, 2005; Wei, Yi, & Guo, 2014). In this case, resource flexibility enhances the value of relationships with service intermediaries for exploratory and exploitative service innovation.

Moreover, it has been argued that service innovation follows a different logic than product innovation (Janssen et al., 2016)and violates manufacturing firms’ existing systems of organizational routines (Kindstro¨m & Kowalkowski, 2014). Hence, service innovation requires the support of a new set of processes that may be incompatible with existing ones and, thus, in the great need for higher coordination flexibility (Sanchez, 1995). In fact, due to the inherent problems of inertia and core rigidity (Gilbert, 2005), internal resources developed for product innovation tend to become obsolete more often (Kraatz & Zajac, 2001). Hence, external service-related resources tend to become more difficult to integrate (M. K Srivastava & Gnyawali, 2011). According to Grewal and Tansuhaj (2001), coordination flexibility reflects a firm's capabilities in defining, configuring, and deploying diverse resources, which indicates that it can overcome routine inertia and enables the exploration of new bundles of resources; thus, it encourages manufacturers to efficiently integrate and recombine externally acquired knowledge with their internal resources for service innovation opportunities (Katsuhiko & Hitt, 2004).

Based on the above arguments, we propose that resource flexibility and coordination flexibility together facilitate the integration and combination of external knowledge accessed through relationships with service intermediaries, enhancing the positive effects of ties with service intermediaries on exploratory and exploitative service innovation.

• H4a: Strategic flexibility strengthens the positive effects of ties with service intermediaries on exploratory service innovation.

• H4b: Strategic flexibility strengthens the positive effects of ties with service intermediaries on exploitative service innovation.

Research framework is demonstrated in Fig. 1.

Fig. 1.

Research framework

(0.09MB).

We administered a survey to manufacturing firms located in Chongqing and Ningbo, China. Our reasons for collecting data in these two cities are as follows. First, both are the main manufacturing cities in China. Chongqing is one of the most important manufacturing bases in southwestern China, while Ningbo, located in southeastern China, has a large number of innovative small- and medium-sized manufacturing firms. Second, local governments in Chongqing and Ningbo actively advocate the transition from a product-based economy to a service-oriented economy, which allows us to observe service innovation activities among the sampled firms. Third, the first author used to provide consulting services for the local Economy Commerce Committee in Chongqing and Ningbo, which was keyfor the research team obtaining the committee's assistance.

We hired and trained research assistants from the local Economy Commerce Committee to deliver our surveys. These local officers often personally know the managers of manufacturing firms well, and such personal relations are highly valued in Chinese culture, which ensures respondents’ qualifications for and speed of survey completion. We obtained a list of 858 manufacturing firms compiled by the local Economy Commerce Committee. We searched on the internet as well as company websites to obtain information and news about the 858 manufacturing firms and finally identified 388 manufacturing firms that meet two criteria: (1) they carry out a mix of product-service design and development activities and (2) they hold a certain solid relationship with outside service intermediaries, either formally or informally. The research assistants contacted senior or middle managers of 388 sampled manufacturing firms via phone, e-mail or on-site visits to seek participation. Managers from 283 firms agreed to respond to our questionnaire in e-mail format, while 105 firms welcomed on-site interviews.

The questionnaire was originally prepared in English and then translated into Chinese by three scholars competent in both languages with substantial research experience in the service innovation field in China. The survey questionnaire was adopted after all three scholars agreed on the Chinese translation. To ensure the content and face validity of the measures, we conducted 5 initial, semistructured interviews with 5 senior managers from 5 manufacturing firms to learn their views about the importance of service innovation for them and the role of service intermediaries in their service innovation. Meanwhile, we invited them to verify the relevance and completeness of the questionnaire items and revised a few questionnaire items to enhance the clarity of the questionnaire based on their responses.

Finally, we acquired 125 usable responses via emailand 90 usable responses in person. In total, we obtained 215 usable responses, generating a usable response rate of 55.4 percent. Sampling firms represent a wide span of industries. As Table 1 shows, our sample involves automobiles and motorcycles (Industry 1: 20%), telecommunication and computers (Industry 2: 22%), mechanical and electric equipment (Industry 3: 18%), pharmaceutical and bioengineering (Industry 4: 13%), the textile and garment industry (Industry 5: 11%), and new energy environmental protection (Industry 6: 16%), which allowed us to increase the external generalizability of our results to different industry contexts. To assess the nonresponse bias, we compared responding manufacturing firms with those that were unresponsive and found no significant difference in firm size or age.

Multi-item scales were used to measure the study constructs (see Table 1). We operationalized the constructs using reflective measures; we controlled the number of items to ensure that the questionnaire was reasonably short and that the response rate was reasonable. A 7-point Likert scale from 1 (“strongly disagree”) to 5 (“strongly agree”) was used to measure all constructs based on the literature.

We took several steps to ensure data validity and reliability. As previously stated, we pretested the survey with 5 senior managers from 5 manufacturing firms. In the questionnaire itself, we used previously validated measurement items whenever possible to help ensure the validity of our measures. We assessed the reliability of the multi-item constructs with Cronbach's alpha, and all scales had reliabilities greater than the recommended 0.70 (see Table 2).

We conducted a confirmatory factor analysis to assess the convergent and discriminant validity of the multi-item constructs. As presented in Table 1, the results of the confirmatory factor analysis indicated that the measurement model achieves a satisfactory fit to the data (goodness-of-fit index [GFI]=0.90, comparative fit index [CFI]=0.91, incremental fit index [IFI]=0.91; and root mean square error of approximation [RMSEA]=0.05), all of which confirmed the unidimensionality of each construct in the model. Convergent validity is observed when the path coefficients from the latent constructs to their corresponding manifest indicators are statistically significant (Anderson & Gerbing, 1988). All items loaded significantly on their corresponding latent construct, providing evidence of convergent validity.

To assess discriminant validity, we conducted a chi-square difference test for all of the multi-item constructs in pairs to see if they were distinct from one another. The process involved collapsing each pair of constructs into a single model and comparing its fit with that of a two-construct model (Anderson & Gerbing, 1988). In every case, a two-factor model had a better fit than a single-factor model, thus supporting the discriminant validity of the constructs.

Based on a comprehensive literature review, Podsakoff, MacKenzie, Lee, and Podsakoff (2003)suggested that common method variance (CMV) is often a problem in behavioral research (often involving self-report data collected by surveys). Following the recommendation by Podsakoff et al. (2003), we implement both preprocedural and poststatistical techniques to reduce the potential of CMV.

The procedural methods were as follows. (1) We discussed our questionnaire in two rounds with experts in both academia and industry and performed a pilot study. This way, we resolved all issues with the measuring items that might have confused the respondents or inclined them toward social desirability, and we reduced the length of the questionnaire to a reasonable level. Additionally, we provided our contact information and encouraged the respondents to contact us if they had problems during the process of completing the questionnaire. This procedure guaranteed the content validity of the constructs. (2) We assured the respondents that their answers were confidential and that there were no right or wrong answers to the questions in the survey. Moreover, the questionnaire was distributed anonymously. We also informed the respondents that if they had no interest in ourresearch topic or did not have enough time to complete the questionnaire, they should not accept our survey, and we conveyed our appreciation for their responsible rejection. These procedures likely reduced the respondents’ evaluation apprehension and helped "make them less likely to edit their responses to be more socially desirable, lenient, acquiescent, and consistent with how they think the researcher wants them to respond" (Podsakoff et al., 2003, p. 888). (3) To encourage the respondents to participate in our survey actively and seriously, we informed them that if they were interested in our research results, we would send the results to their email address, which they provided on the questionnaire.

For the postmeasure to remedy CMV, Harman's one-factor test was conducted to examine whether this problem affected our data. An exploratory factor analysis with all items yielded no single factor that accounted for a threshold of 50% of the total variance before rotation, indicating that the CMV problem is not severe. Harman's one-factor test of our data demonstrated that the first factor before rotation accounted for less than half of the total variance (i.e., 33%). This result suggests that CMV is unlikely to have caused any significant relationships among the variables in our study.

We used the statistical software program SPSS 26.0 to analyze the data. SPSS was employed to analyze the descriptive statistics, CFA, Cronbach's alpha, and EFA. Descriptive statistics were used to describe the profiles of the sample firms; CFA was employed to assess the convergent and discriminant validity of the multi-item constructs; Cronbach's α was used as a criterion for reliability, as it reflects the internal consistency of the indicators of individual constructs; and EFA was applied to estimate cross-loading issues and to identify common method variance (CMV) based on Harman's single-factor test. SPSS was further employed to run a stepwise hierarchical regression analysis.