key: cord-0752581-wleer4nn authors: Laguir, Issam; Modgil, Sachin; Bose, Indranil; Gupta, Shivam; Stekelorum, Rebecca title: Performance effects of analytics capability, disruption orientation, and resilience in the supply chain under environmental uncertainty date: 2022-01-23 journal: Ann Oper Res DOI: 10.1007/s10479-021-04484-4 sha: 5908d97a6be69b328ac3e5c4c3c329040c093234 doc_id: 752581 cord_uid: wleer4nn The relationship between Analytics Capability of an Organization (ACO) and both Supply Chain Disruption Orientation (SCDO) and Supply Chain Resilience (SCR) in order to achieve adequate operational performance in an era of environmental uncertainty is carried out in this study. Total three hypotheses (seven sub-hypotheses) using a survey of 405 respondents are collected via a pre-tested instrument and tested further. Results indicated the influence of ACO on both SCDO and SCR to achieve the desired degree of operational performance. However, under the moderation of environmental uncertainty, the link between ACO and SCDO was not supported, although the link between ACO and SCR was supported and this further enhanced operational performance. Further investigation of unsupported hypotheses using statistical analysis was conducted to gain deeper insights. It is explained how ACO impacted dynamic capabilities to influence operational performance. The contribution to theory of this study lies in explaining the role of dynamic capabilities that emerge from analytics as compared to the traditional view of supply chain classification. Further, the influence of environmental uncertainty on positioning dynamic capabilities strategically to address disruption in supply chains is discussed in the present study. In today's ambiguous business environment, organizations need to be particularly attentive to achieve the desired operational performance. Environmental uncertainty arises from the changing landscape of competition, consumer preferences, globalization and increased focus on innovation (Syed et al., 2020; Yayla & Hu, 2012) . Companies respond to this environmental uncertainty by adopting a variety of approaches and orientations to ensure their competitiveness and the desired level of operational performance (Liu et al., 2019; McLaren et al., 2011; Teo & Pian, 2003) . However, a disruption in the supply chain can bring the best plans to a halt, profoundly affecting business continuity (Baghersad & Zobel, 2021; Xu et al., 2016) . Disruptions in the supply chain hamper the efficiency of operations by impacting quality, cost, processing, sourcing and delivery of products and services (Chopra & Sodhi, 2014; Downes & Nunes, 2013; Pereira, 2009; Tomlin, 2006; Tönnissen & Teuteberg, 2020; Xue et al., 2018) . The disruptions may be due to events like pandemics, cyber-attacks, natural disasters or product and service problems (Min, 2019; Nguyen & Nof, 2019) . The recent Covid-19 outbreak disrupted many supply chains, although some were able to return to normal quickly (Ivanov, 2020a, b) . Other notable disruptions to supply chains in the past include Hurricane Katrina in 2005 and the SARS outbreak in 2003, but history attests to many other unanticipated disruptions, such as factory fires and political upheavals (Li et al., 2013; Simchi-Levi et al., 2014) . Today's supply chains need to be structurally strong enough to sense the arrival of undesirable events and be ready with agile, adaptable and alignment capabilities (Lee, 2004) . For instance, Dell responded better than Apple in 1999 when an earthquake in Taiwan disrupted the supply chain for memory chips (Chopra & Sodhi, 2004; Sheffi & Rice., 2005) . It is thus crucial for companies to build an appropriate amount of resilience in their supply chains. Both Supply Chain Disruption Orientation (SCDO) and Supply Chain Resilience (SCR) can positively impact an organization's performance planning (Bode et al., 2011; Konovalenko & Ludwig, 2019; Patel et al., 2013) . Top management therefore needs to consider these factors to minimize supply chains risks (Chopra & Sodhi, 2014; Villena et al., 2018) . Yet it has been hard to quantify risk in supply chains using traditional models. Over the last two decades, however, supply chains have started using data more intensively to design their strategies and companies are adopting analytics for this (Chen et al., 2015; LaValle et al., 2011; Shao et al., 2018) . The analytics capabilities of organizations (ACO) can facilitate the development of better authenticated and validated insights to transform their supply chains (Liu et al., 2020) . The ambidextrous organizations are better equipped with ACO. "Organizational ambidexterity refers to the ability of an organization to both explore and exploit-to compete in mature technologies and markets where efficiency, control, and incremental improvement are prized and to also compete in new technologies and markets where flexibility, autonomy, and experimentation are needed" (O'Reilly & Tushman, 2013) . ACO affects supply chain ambidexterity and rapidity, which then impact firm performance. The literature has shown the usefulness of the Resource Based View (RBV) and the Dynamic Capabilities View (DCV) to orient resources and enhance capabilities to achieve competitive gains (Chae et al., 2014; Dubey et al., 2020; Shibin et al., 2020) . DCV facilitates organizational alignment so that big data can be leveraged in a systematic manner (Agarwal & Dhar, 2014; Chen et al., 2015; Ghasemaghaei et al., 2017) . The capability to handle different types of data encourages companies to opt for analytic applications in their supply chains (Seddon & Currie, 2017) . ACO help companies develop unique capabilities for detecting quality problems, clustering customers, understanding their requirements, and setting the right price and margin for products (Grover et al., 2018; LaValle et al., 2011; Sheffi & Rice., 2005) . It further enhances the information processing capabilities that capture, integrate and analyse the big data that drives business value (Saggi & Jain, 2018) . Thus, analytics improves a firm's competitive intelligence capabilities in terms of infrastructure, assessment, and application to different business scenarios (Chen et al., 2012; Gupta & George, 2016) . Companies can use analytics to design their strategic orientation and impact performance (Grover et al., 2018) . Apart from developing data-driven capabilities, companies need to take appropriate actions to deploy insights and critically scan for stakeholders' inactive participation in providing business value (Côrte-Real et al., 2017) . Inactive participation may be psychological, sociotechnical, economic, socio-cognitive or political in nature (Barnett & Pontikes, 2008; Kwon et al., 2014) , and this inertia can impact multiple stages of the analytics cycle. Companies also need to look at the external factors that may be barriers to turning analytics into a dynamic capability (Shorfuzzaman et al., 2019; Sun et al., 2018) . In highly turbulent and dynamic environments, the insights derived from analytics can influence SCR and hence operational performance (Chen et al., 2015; Tiwari et al., 2018) . Today's supply chains are time-sensitive and disruptions heavily impact their operational performance. It is therefore important that companies develop their own style of awareness, consciousness and recognition capabilities, which often emerge from the experience of dealing with disruptive events (Ambulkar et al., 2015) . These events help form the firm's orientation toward future supply chain disruptions (Patel et al., 2013) . In fact, greater SCDO is found to be associated with bigger buffers and an appetite for risk (Bode et al., 2011) . In addition to SCDO, scholars have found that SCR is also an effective means to attain desired operational performance (Min et al., 2019; Ortas et al., 2014) . SCR enables a firm to return to its original state or move to a new but stable state. It helps maintain visibility, flexibility, responsiveness and collaboration in operations during uncertain times. SCR is also a capability for achieving and sustaining the desired performance in complex and vulnerable situations (Ponomarov & Holcomb, 2009; Sun et al., 2020) . The primary objective of the study is to analyze the relationship between ACO capabilities to operational performance through SCDO and SCR. The secondary objective of the study is to examine the role of environmental uncertainty (UNC) in the relationship of ACO capabilities to SCDO and SCR respectively. It is hard to find evidence in the literature on the relationship between ACO and SCDO. Moreover, few studies have investigated the relationship between ACO and SCR as mediated by UNC, yet both impact operational performances. Hence, this study intends to answer the following questions: How are ACO, SC disruption orientation and supply chain (SC) resilience related to operational performance? RQ2. What is the impact of environmental uncertainty on operational performance, given that it influences ACO, SC disruption orientation and SC resilience? The remainder of this paper is structured into six sections. The second section describes the elements that underpin supply chain disruption, resilience and analytics. The third section presents the theoretical model and hypothesis development. The fourth section describes the research design and the fifth section presents the results. Section six discusses the results including the implications for theory and practice. In section seven, the study is concluded. The appendix showcases the operationalization of constructs used in the study. The term supply chain management was first mentioned in the Financial Times in the 1980s. It started to become main stream in the 1990s with the establishment of the Supply Chain Council (1996) and later the Council for Supply Chain Management Professionals (2004) . Sometime later, the two professional bodies merged to become the American Production and Inventory Control Society (APICS) (Alfalla-Luque & Medina-López, 2009) due to the reason of its importance in supply chain (Golinska-Dawson et al., 2011) . The need for advances in supply chain management have become pressing as companies are increasingly confronted with disruptions such as natural disasters, pandemic and political unrest (Ivanov, 2020a (Ivanov, , 2020b Marucheck et al., 2011) . For instance, Nokia and Ericsson (cellular phone manufacturer) faced a shortage of radio frequency chip components due to a fire at a supplier's plant in March 2000. This incident prompted Nokia to change its product configuration to meet demand during the supply disruption. Ericsson, on the other hand, was slow to respond and lost sales of 400 million euros. This incident illustrates how SCR and organizational capabilities can save a firm during a supply chain disruption (BCG, 2006; Pettit et al., 2019; Tang, 2006) . Similarly, in 1997, many US companies were unable to receive supplies from their Indonesian suppliers when the currency (Rupiah) was devalued by more than 50%. Two businesses, The Limited and Warner Bros., nevertheless managed to receive their supplies on time because the supplies had been further outsourced to Li & Fung in Hong Kong. This company responded by procuring from suppliers in other parts of Asia and helped Indonesian suppliers with loans and credit to ensure timely supplies. As these examples show, companies clearly need to focus on both internal and external capabilities in order to circumvent disruptions more easily (Karimi & Walter, 2015; Teece, 2007; Teece & Pisano, 2003) . In 1999, when the supply of memory chips was disrupted following an earthquake in Taiwan, Dell influenced its customers with a special price for those willing to buy computers using components produced in other countries, whereas Apple struggled to convince customers to accept a lower version of their computers. Dell displayed the capability to influence customers, which ultimately improved their revenue by 41% despite a supply chain disruption (Sheffi & Rice., 2005) . This example points to the need for SCDO, which better equips companies to pick up alerts quickly and ready themselves for organizational efforts (Golgeci & Ponomarov, 2013) . SCDO can be developed by analysing earlier events or by simulation-based methods that provide hints as to how a disruption can be avoided or how it can affect the organization (Ambulkar et al., 2015; Bode et al., 2011) . A parallel strategy is SCR, which enables the flow of information and physical goods to be quickly restored in the supply chain (Karimi & Walter, 2015; Kolinski et al., 2020; Min et al., 2019; Ortas et al., 2014) . Resilience in supply chains means tight collaboration in the form of risk-sharing with channel partners, ranging from suppliers to customers (Cavalcante et al., 2019; Heckmann et al., 2015; Pavlov et al., 2019) . Capabilities like trusted networks, information exchanges and forecasting, ensuring visibility, and knowing the status of entities in real time are key to resilient supply chains (Saggi & Jain, 2018) . After a disruption, supply chains do not always return to the pre-disaster form but may instead move to a new state for delivering goods and services. An adequate degree of SCR enables the dynamic capabilities to handle the financial outcomes of a disruption and maintain control over supply chain structure and functioning. Further, resilience makes it more likely that companies will be able to extract hidden information and insights in order to design even more robust supply chains that contribute to operational performance (Shamim et al., 2019; Shorfuzzaman et al., 2019; Sun et al., 2018) . Dynamic environments (where demand fluctuates) induce considerable uncertainty about supply chain functioning, and companies need to develop the dynamic capabilities of SCDO and resilience to achieve the desired operational performance (OP) Winter, 2003) . An organization's OP is measured by goods delivered on time, product quality maintained, capacity utilization, and a low rate of wastage in processes and inventory, all of which are difficult to control under environmental uncertainty (UNC) (Chowdhury et al., 2019; Helfat & Winter, 2011; Shi & Liao, 2015; Sreedevi & Saranga, 2017) . To achieve adequate control over these parameters of OP, companies need to ensure the right mix of risk resilience and disruption orientation for positive influence (Chopra & Sodhi, 2014; Tomlin, 2006 ). Yet, to develop risk resilience and disruption orientation, it is critical for companies to use advanced analytics techniques (optimization, simulation and regression) to facilitate the decision-making process (Chae et al., 2014; Golinska-Dawson et al., 2015; Shi & Liao, 2015) . Techniques like data visualization help companies spot abnormal trends or signs of upcoming disruption (Chae et al., 2014; . Analytic capabilities also can be used to track buying trends and offer more appropriate products and services to consumers at lower cost (LaValle et al., 2011; Miah et al., 2017) . Analytics can further help companies gain a deeper understanding of cause and effect of processes and design their capabilities with the resources at hand to tackle disruptive situations (Helfat & Winter, 2011; Kim et al., 2011 Kim et al., , 2015 . Resources are key to developing capabilities, while capabilities are the immediate means that companies use for economic gain (Hart & Dowell, 2011) . Therefore, ACO gives direction to the disruption orientation and type of resilience a firm may want to adopt, given the OP it has in mind (Grover et al., 2018; Kwon et al., 2014; LaValle et al., 2011; McAfee et al., 2012; Srinivasan & Swink, 2018) . The associations between ACO and SCDO and ACO and SCR can be impacted by UNC because manufacturing and supply chain dynamics cause recurrent variations in the mix of products, supply requirements, technical specifications, suppliers' need to adhere to frequent design changes, and the rising need for customization (Bode et al., 2011; Golgeci & Ponomarov, 2013; Majdzik et al., 2016; Syed et al., 2020; Yu et al., 2019) . Hence, it is appropriate to examine the relationships between ACO, SCDO, and SCR as dynamic capabilities for achieving OP under UNC. Figure 1 presents their relationships as dynamic capabilities to drive performance in competitive environments. Several types of analytics are increasingly being used by companies to manage processes and analyze data from different sources and measure the actions directed at achieving the desired operational performance (Agarwal & Dhar, 2014) . Developing analytics capability can mould business operations for a smooth flow in uncertain environments (Gupta & George, 2016; Saggi & Jain, 2018) . By using intelligent techniques, tools, setups and technologies, including mobile devices, companies gather information from social media and self-regulating technologies like the Internet of Things and Cloud Computing to develop adequate SCDO Grover et al., 2018; Miah et al., 2017) . Disruptions in supply chains point to the need for back-up plans, which themselves point to the need for appropriate amount of resilience (Min, 2019; Xia et al., 2000) . A high degree of SCR can improve the responsiveness through the effective use of analytics and lead to auto-cycles of resilience (Golgeci & Ponomarov, 2013) . The dynamic capability of analytics allows companies to manage their supply chains seamlessly by reducing delays and sharing insights with partners so that they can act quickly to have impact on the overall operational performance (Kim et al., 2011; Tirkolaee et al., 2020) . Hence, we propose: H1a. ACO positively influences SC disruption orientation. H1b. ACO positively influences SC resilience. H1c. ACO positively influences operational performance. Achieving high operational performance, a critical component of strategic goals, is a major challenge for companies. In today's information era with its frequent disruptions, a disruption orientation is critical for reconfiguring and reorganizing dynamic capabilities to keep business operations on track (Kim et al., 2015; Winter, 2003) . Companies with creative and strategically useful SCDO can mitigate the impact of disruptions to a significant extent (Bode et al., 2011) . This orientation needs to be aligned with multi-fold data emerging from a range of business activities (Shamim et al., 2019) . Apart from adequate SCDO, companies need resilience to reconfigure their capabilities and resources to ensure a minimum impact on business operations and an adaptation to earlier or new stable state as fast as possible (Chae et al., 2014) . SCR is further supported by diverse data on demand quantity, how supply chain partners are reacting, and the capabilities to influence operational performance (Hosseini & Ivanov, 2019; Shao et al., 2018) . Therefore, companies adopt analytics as a dynamic technological capability to achieve the desired operational performance (Mikalef et al., 2020) . Hence, we propose: H2a. ACO positively influences operational performance through SC disruption orientation. H2b. ACO positively influences operational performance through SC resilience. Today companies are open to more risks than ever before due to competition, regulatory requirements, demanding stakeholders and other market changes . This situation forces them to act quickly in making business decisions. A logical and methodical approach is thus needed to address decision-making in rapidly evolving markets (Kwon et al., 2014) . Under environmental uncertainty, analytics is a dynamic capability to simulate and predict compelling insights to achieve operational performance. By following a three-step process (manage data, perform analytics and drive decisions), analytics helps companies design their SCDO more swiftly and effectively (Agarwal & Dhar, 2014; Pigni et al., 2016) so that managers can make evidence-based decisions about developing even more significant SCDO (Shamim et al., 2019) . In uncertain circumstances, ACO can help a firm's supply chain in terms of demand and visibility, procurement decisions, and seamless running of operations, which contribute to SCR (Bateman & Bonanni, 2019) . Therefore, companies should develop ACO if they are operating in an uncertain environment, as this will strengthen their operational performance through a dynamic mix of SCDO and resilience. Hence, we propose: H3a. Environmental uncertainty enriches operational performance by strengthening the influence of ACO on SC disruption orientation. H3b. Environmental uncertainty enriches operational performance by strengthening the influence of ACO on SC resilience. The present study collected data from October 2019 to January 2020 using a structured questionnaire targeting about 3000 manufacturing companies in France. The manufacturing companies were identified in the DIANE 1 database, which stores key information about 28,986 licensed manufacturing companies in France. Further respondents were narrowed down to those with enough experience in analytics, supply chain and operations management to answer the questions of the survey. After this, a sampling procedure was adopted to carry out the survey with parameters ranging from formatting to reaching out and collecting the responses (Dillman, 2011) . This helped to design an accessible questionnaire for respondents. The confidentiality of information collected was assured to respondents. Three reminders were sent, once every two weeks, to increase the response rate. To ensure maximum involvement, it was assured to them that we would be sharing the research outcomes with them. In total, 405 completed responses were received, reflecting a 13.5% response rate. The completed questionnaires from various industries were collected, as shown in Fig. 3 . The largest share was from the metal machinery and engineering sector (23.45%), followed by the food, beverage and tobacco products industry (19.01%), and the electronic products and electrical appliances sector (18.02%). Most companies were medium-sized: 33.08%, and 32.83% were large and 27.40% were small (see Fig. 4 ). Further a flow chart is developed (see Fig. 3 ) addressing the achievement of research objectives and questions. This study employs 'a prior' and post-hoc power analyses (using the G*Power tool) to ensure the adequacy of sample size (Faul et al., 2009 ). To ensure sample adequacy, this study used a minimum value of R 2 (0.10), 95% statistical power and three predictors (operational performance had the most predictors). The G*Power and 'a priori' analyses indicated 159 respondents for the sample size. In addition, the post-hoc G*Power results for a sample size of 159, minimum value of R 2 (0.10), and three predictors pointed to a statistical power of 0.95, which is above Cohen's reference. Hence, the adequacy of sample size was not a problem in the present study. The early and late respondents were compared to test non-response bias (Cohen, 1988; Werner et al., 2007) and did so by conducting a t-test in terms of industry (respectively, N = 203 and N = 202). Findings revealed no significant difference in the industry (t = 1.521; p = 0.129) and confirmed that non-response bias was not a probable concern in the present study. Furthermore, the comparisons of respondents and non-respondents with regard to ownership characteristics showed no significant differences (Table 1) . Thus, the non-response tests indicated that sample was representative with a low likelihood of nonresponse bias. A summary of the respondents' characteristics is provided in Fig. 4 . To control the Common Method Variance (CMV), this study adopted procedural and statistical methods (Podsakoff et al., 2003) . To comply with procedural design, the instrument was designed and developed in consultation with senior academics in supply chains, operations management and information systems. In addition, to ensure that the questions in the instrument maintained a logical flow, a pre-test study on manufacturing companies was conducted, where the instrument was divided into sections on ACO, SCR and SCDO, UNC and OP (Podsakoff et al., 2003) . This further helped to align the measurement items for more clearly. Further a post-hoc examination of CMV was performed using Harman's guidelines (1967) for a single factor test and marker variable methods (Malhotra et al., 2006) . Six factors emerged (through eigenvalue-based unrotated exploratory factor analysis), indicating a one factor variance explanation of 26.135%. Therefore, CMV was not a concern in this study, as a substantial amount of the variance was not owing to one factor (Fraj et al., 2015) . Further, a PLS-SEM based marker variable method was employed in this study (Lee & Hallak, 2018) . A structural framework with and without an exogenous marker variable was employed, which further helped in predicting each construct. The legal status of the firm was the marker variable measured by a proxy as follows: "Is the legal form of firm 'Joint-stock company'? (Yes/No)." It should be noted that the marker variable and focal variables were collected simultaneously and in the same manner. The results indicated that the correlations between the marker and all other constructs in the model were very low: ACO: 0.105, SCDO: 0.123, SCR: 0.058, UNC: 0.015 and OP: 0.073. Also, the effect of the marker construct on the endogenous construct of OP (β = 0.003) was very low and not significant. These results supported the appropriateness of the marker construct. The comparative analysis of the structural framework with and without the marker variable indicated no significant variances, and the theorized links presented supportive values and statistical significance. Hence, CMV was unlikely to be a concern. All measures were drawn from well-established items in the research literature. ACO was assessed using an instrument developed by Srinivasan and Swink (2018) . SCDO was assessed using an instrument developed by Bode et al. (2011) and used by Yu et al. (2019) . SCR was measured with an instrument developed by Golgeci and Ponomarov (2013) and used by Yu et al. (2019) . UNC was measured based on the work of Sreedevi and Saranga (2017) . Finally, OP was assessed based on the work of Shi and Liao (2015) . The SmartPLS (v. 3.2.7) was employed to assess the measurement model and the PROCESS macro in SPSS 25 to investigate the structural model (Hayes, 2013) . More specifically, the adequacy of the measurement model was assessed through estimation of (i) item loadings and composite reliabilities, (ii) convergent validity (AVE), and (iii) discriminant validity. Thereafter, and using the latent variable scores from SmartPLS as input, PROCESS produced estimates and bias-corrected 90% bootstrap confidence intervals for multiple mediation and moderated mediation effects. PROCESS can evaluate a multifaceted model representing both mediator and moderator variables and it has been extensively used in recent works (e.g. Wang et al., 2019) . An analyses using model 4 and model 7 of the PROCESS macro was conducted (Hayes, 2013) . Thus, at first multiple mediation analysis was conducted (model 4) to test H1a/b/c and H2a/b (Preacher & Hayes, 2008 ). Further the study tested whether ACO affected OP directly and indirectly through the two mediators, SCDO and SCR. A linear regression analysis was performed to investigate the direct and indirect effects of ACO on OP as shown in Eqs. (1, 2 and 3). The approximation of SCDO/SCR from ACO is determined by Eqs. (1 and 2) , and Eq. (3) determines OP from ACO and SCDO/SCR. The regression of OP on ACO in Eq. (4) can also be utilized to estimate the total effect of ACO on OP. Likewise, to validate the notion of normality in the sample spread of the total and particular indirect effects, a bootstrapping procedure was conducted. To test H3a/b, model 7 was used for first-stage moderated mediation model. Specifically, this model enabled to test whether the moderator variable UNC affected OP by impacting the linkages between ACO and both SCDO and SCR. Thus, using regression analysis, the first-stage model (moderated-mediation) can be estimated as shown below: From these three Eqs. (5, 6 and 7) , the indirect effect of ACO on OP is the product of the effect of ACO on SCDO and SCR indicated in Eq. (8): The indirect effect represents a statistical mechanism through which ACO influences OP in the case of a linear relationship with moderator UNC. This indicates that the size or strength of a mechanism changes with changes in the moderator (Hayes, 2018) . As noted earlier, to check the adequacy of the measurement model in this study, the estimation of (i) item loadings along with composite reliabilities, (ii) convergent validity (AVE), and (iii) discriminant validity, was done. The reliability of the survey items in this regard was checked and found within the limits, as all loadings were above the threshold of 0.50 (Hair et al., 2012) and both Dillon-Goldstein's rho (composite reliability) and Cronbach's α values were above the minimum threshold of 0.60 (Hair et al., 2017) (Table 2) . Also, the values of convergent validity for all constructs were above the threshold of 0.50 (Table 2) . A Fornell-Larcker's criterion and the heterotrait-monotrait ratio of correlations (HTMT) were used to ensure the discriminant validity in this study. For Fornell-Larcker's criterion, the square root of AVE for every construct should be greater than its correlation with all other constructs. Table 3 indicates the fulfillment of the criterion for all constructs. Further the discriminant validity through HTMT was assessed. The acceptable values for HTMT should be at least below the threshold of 90% (< 0.90) (Henseler et al., 2015) . The values of HTMT for all constructs varied from 0.085 to 0.491 (Table 3 ) in this study, which supported the discriminant validity of the constructs. Tables 4 and 5 indicate the estimated results of the multiple mediation models and the first-stage moderated mediation model. A framework for regression to view the signs of multicollinearity among the explanatory variables was employed. The outcome indicated that no variance inflation factors (VIFs) exceeded 10, and thus multicollinearity was not a potential concern (Hair et al., 2006) . In Table 4 , the results showed positive and noteworthy associations between ACO as the independent variable and SCDO, SCR and OP. These results supported hypotheses H1a, H1b and H1c. Moreover, the results suggested positive and significant indirect effects between ACO and OP through both SCDO and SCR. This supported hypotheses H2a and H2b. Fig. 5 , the conditional indirect effect of ACO on OP through SCR was higher at a low level of UNC (coefficient = 0.1619) while it was lower at a high level The square root of variance common among constructs and their variables (AVE) is represented by the diagonal elements in bold. All those values above the values in bold are correlations between constructs and below are the HTMT values Table 6 summarizes the status of hypotheses after analysis. Multiple mediation and moderated mediation analyses suggested some interesting and exciting contributions to the theoretical discussions on the Analytics Capabilities of an Organization, Supply Chain Disruption Orientation, Supply Chain Resilience, and Operational Performance under the impact of Environmental Uncertainty. This study incorporated concepts from three fields of study: information systems, supply chains, and strategic management. Few studies in the literature have done so, instead drawing on information processing theory (OIPT), institutional theory or RCV along with DCV (Chae et al., 2014; Kim et al., 2011 Kim et al., , 2015 Wamba et al., 2020) . On this basis, this study claim unique contributions to theory and practice. This study makes three main contributions. First, it empirically supports the view that dynamic capabilities are not universal. It strengthens the frontiers of dynamic capabilities theory, which is critical for expanding grounded theory as a way to enrich the literature. Second, the present study confirms the key role of environmental uncertainty in the relationships between the ACO, SCDO, SCR and OP of an organization. Hence, it addresses two main research questions: How are ACO, SC disruption orientation, and SC resilience related to operational performance? And what is the impact of environmental uncertainty on operational performance, given that it influences ACO, SC disruption orientation and SC resilience? These are critical research questions in information systems, operations and supply chain management (Shamim et al., 2019; Yu et al., 2019) . Earlier studies in these fields (Ambulkar et al., 2015; Bode et al., 2011; Chen et al., 2012; Kwon et al., 2014; Miah et al., 2017; Saggi & Jain, 2018) agree with the role of analytics as a dynamic capability and its impact on operations and supply chains. However, a consensus on how analytics capability influences a firm's supply chain disruption orientation is lacking. This was further supported by Sheffi and Rice (2005) , who noted that supply chains would be better positioned in their disruption orientation if they drew on Dell's data-based insights following the 1999 earthquake in Taiwan. Although Oke and Gopalakrishnan (2009) highlighted the classification of risk categories and mitigation strategies, in the age of information it is critical to harness analytics as a capability that can further influence SCDO, which seems crucial in today's dynamic environment (Chae et al., 2014; DuHadway et al., 2019; Srinivasan & Swink, 2018) . Although this study reports on the means for achieving operational performance, the findings particularly indicate that OP is influenced by dynamic capabilities such as ACO, SCDO and SCR in company operations, which further challenges the traditional view of supply chain classification (efficient/risk hedging, responsive and agile) (Hassini et al., 2008; Lalmazloumian et al., 2016) . It is suggested that supply chains can facilitate better operational performances by mobilizing the dynamic capabilities that emerge from analytics. Third, this study integrates aspects of dynamic capabilities under diverse impacts of environmental uncertainty. It can be difficult to orient a specific strategy to combat disruption in supply chains, especially in highly dynamic environments . Hence, to achieve the desired operational performance, companies may need to shift between various strategies or use them in an on-and-off manner to tackle a given situation. The findings of present study can act as guidelines for chief information officers, chief supply chain officers and other top executives who are thinking about investing in analytics-enabled dynamic capabilities for their organizations. They need to carefully consider the following: (i) the capability of their supply chains to recognize dynamic fluctuations due to both upstream and downstream activities, (ii) the capability to orient their supply chains from a disruptionpreparedness perspective, and (iii) the ability of their supply chains to recover from disruptive events to ensure the desired operational performance. This study suggests that strengthening analytics capabilities will help companies acquire dynamic resilience and disruption orientation in their supply chains in order to improve operational performance. Analytics also facilitates the emergence of dynamic capabilities to advance operational performance by optimizing the association between ACO and SCR under the influence of UNC. Some routines in companies are standard and others are dynamic in nature. Therefore, to ensure efficient decision-making processes in dynamic environment, managers need to regularly align their supply chain strategies and build capabilities to increase competitive advantage. Environmental uncertainty has the potential to change the fate of businesses and may well render existing capabilities irrelevant due to changing circumstances (Swamidass & Newell, 1987) . Accordingly, managers need to recognize and safeguard analytics-enabled dynamic capabilities with regard to decisions to make supply chains better prepared and responsive to disruptions while simultaneously achieving adequate operational performance. The present study has a few limitations. The lens of DCV was used in this study and thus it is limited by context insensitivity (Teece, 2014) . DCV also cannot be used to categorise the right mix of options that may make organizational capabilities much more respectable (Schilke, 2014) . Although the present study tried to circumvent this limitation by employing a contingency view of companies (moderating impact of environmental uncertainty), it is recommended that researchers can consider more dynamic conditions such as flexibility to achieve greater operational performance in the future. The present study also can have limitations in terms of endogeneity and common method bias (CMB), since it is surveybased (Guide & Ketokivi, 2015; Sande & Ghosh, 2018) . Though the study took precautions to safeguard endogeneity and CMB and note that either longitudinal or multi-informant data from a single firm can help with this issue. It may be interesting to examine how analytics capabilities can be further enhanced through big data and other means (Wamba et al., 2018) . Furthermore, the results of this study can be investigated in diverse contexts to address the limitations. This study examines analytics-enabled dynamic capabilities that further strengthen the supply chain system to achieve greater operational performance. Through the lens of DCV, this study analyses how analytics capabilities help build supply chain resilience and supply chain disruption orientation. The present study also assumes the influence of uncertain environment and shows that they strengthen the dynamic capabilities for the ultimate objective of enhanced operational performance. Addressing the objectives, this study opens a potentially enriching debate on the association between dynamic capabilities and environmental uncertainty. The findings indicate positive influence of UNC in the link between ACO and SCR to derive operational performance, as compared to the link between ACO and SCDO. In brief, the findings demonstrate that ACO has a critical and superior impact on operational performance, as opposed to earlier studies that have presented different dynamics. The role of UNC in the link between ACO and SCDO and SCR has not yet been studied in detail. To summarize, the present study offers theory-based food for thought and reasoning around analytics-enabled dynamic capabilities and further clarifies the need for capabilities related to SCDO and SCR. This study presents a more comprehensive understanding about the design of SCR and SCDO through ACO to achieve the desired operational performance in an era of accelerating uncertainty. Further studies can be conducted on the quickly changing landscape such as technology, laws and regulations, regional and international politics and how analytics capability of organizations can play a critical role in deriving the operational performance. These issues can be better addressed by a case-based study, which will help correlate theory with analytics capabilities for better supply chain management and operational performance. Construct items. Items Indicators Please use the scale to indicate the most appropriate response: ACO1In our organization, we use advanced analytics techniques (e.g., simulation, optimization, regression) to improve decision-making In our company, we use a wide variety of data sources to advance decision-making ACO3 In our organization we use data visualization techniques (e.g., dashboards) to assist users to decision-makers in understanding complex information ACO4 Our organization's use of dashboards helps display information for undertaking root cause analysis and ensuring continuous improvement Big data, data science, and analytics: The opportunity and challenge for IS research Transforming business using digital innovations: The application of AI, blockchain, cloud and data analytics Supply chain management: Unheard of in the 1970s, core to today's company Firm's resilience to supply chain disruptions: Scale development and empirical examination Assessing the extended impacts of supply chain disruptions on firms: An empirical study The Red Queen, success bias, and organizational inertia Creating the optimal supply chain. Accessed on 12th Understanding responses to supply chain disruptions: Insights from information processing and resource dependence perspectives A supervised machine learning approach to data-driven simulation of resilient supplier selection in digital manufacturing The impact of advanced analytics and data accuracy on operational performance: A contingent resource based theory (RBT) perspective How the use of big data analytics affects value creation in supply chain management Business intelligence and analytics: From big data to big impact Supply-chain breakdown Reducing the risk of supply chain disruptions Supply chain resilience for performance: Role of relational practices and network complexities Statistical power analysis for the behavioral sciences Assessing business value of big data analytics in European firms Mail and Internet surveys: The tailored design method -2007 update with new Internet, visual, and mixed-mode guide Big bang disruption Upstream supply chain visibility and complexity effect on focal company's sustainable performance: Indian manufacturers' perspective Understanding risk management for intentional supply chain disruptions: Risk detection, risk mitigation, and risk recovery Statistical power analyses using G* Power 3.1: Tests for correlation and regression analyses Environmental strategies and organizational competitiveness in the hotel industry: The role of learning and innovation as determinants of environmental success Increasing firm agility through the use of data analytics: The role of fit Does firm innovativeness enable effective responses to supply chain disruptions? An empirical study. Supply Chain Management Production flow control in the automotive industry-quick scan approach Grey decision making as a tool for the classification of the sustainability level of remanufacturing companies Creating strategic business value from big data analytics: A research framework Notes from the editors: Redefining some methodological criteria for the journal Toward the development of a big data analytics capability Multivariate data analysis A primer on partial least squares structural equation modeling An assessment of the use of partial least squares structural equation modeling in marketing research Modern factor analysis Invited editorial: A natural-resource-based view of the firm: Fifteen years after Organizational culture and supply chain strategy: A framework for effective information flows Introduction to mediation, moderation, and conditional process analysis: A regressionbased approach Partial, conditional, and moderated mediation: Quantification, inference, and interpretation A critical review on supply chain risk-Definition, measure and modelling Untangling dynamic and operational capabilities: Strategy for the (N) ever-changing world A new criterion for assessing discriminant validity in variance-based structural equation modeling A new resilience measure for supply networks with the ripple effect considerations: A Bayesian network approach Predicting the impacts of epidemic outbreaks on global supply chains: A simulation-based analysis on the coronavirus outbreak (COVID-19/SARS-CoV-2) case Viable supply chain model: Integrating agility, resilience and sustainability perspectives--lessons from and thinking beyond the COVID-19 pandemic The impact of digital technology and Industry 4.0 on the ripple effect and supply chain risk analytics The role of dynamic capabilities in responding to digital disruption: A factorbased study of the newspaper industry IT capabilities, process-oriented dynamic capabilities, and firm financial performance Toward an integrated framework for innovation in service: A resourcebased view and dynamic capabilities approach Integration of Information Flow for Greening Supply Chain Management Event processing in supply chain management-The status quo and research outlook Data quality management, data usage experience and acquisition intention of big data analytics A robust optimization model for agile and build-to-order supply chain planning under uncertainties Big data, analytics and the path from insights to value Investigating the moderating role of education on a structural model of restaurant performance using multi-group PLS-SEM analysis The triple-A supply chain Reliable facility location design under disruptions Assessing product competitive advantages from the perspective of customers by mining user-generated content on social media How IT wisdom affects firm performance: An empirical investigation of 15-year US panel data A fault-tolerant approach to the control of a battery assembly system Common method variance in IS research: A comparison of alternative approaches and a reanalysis of past research Product safety and security in the global supply chain: Issues, challenges and research opportunities Big data: The management revolution A multilevel model for measuring fit between a firm's competitive strategies and information systems capabilities A big data analytics method for tourist behaviour analysis Exploring the relationship between big data analytics capability and competitive performance: The mediating roles of dynamic and operational capabilities. Information and Management Blockchain technology for enhancing supply chain resilience Collaborative response to disruption propagation (CRDP) in cyber-physical systems and complex networks Managing disruptions in supply chains: A case study of a retail supply chain Organizational ambidexterity: Past, present, and future Does sustainability investment provide adaptive resilience to ethical investors? Evidence from Spain The effects of strategic and structural supply chain orientation on operational and customer-focused performance Optimization of network redundancy and contingency planning in sustainable and resilient supply chain resource management under conditions of structural dynamics The new supply chain's frontier: Information management The evolution of resilience in supply chain management: A retrospective on ensuring supply chain resilience Digital data streams: Creating value from the real-time flow of big data Common method biases in behavioral research: A critical review of the literature and recommended remedies Understanding the concept of supply chain resilience Asymptotic and resampling strategies for assessing and comparing indirect effects in multiple mediator models A survey towards an integration of big data analytics to big insights for value-creation. Information Processing and Management Endogeneity in survey research On the contingent value of dynamic capabilities for competitive advantage: The nonlinear moderating effect of environmental dynamism A model for unpacking big data analytics in high-frequency trading Role of big data management in enhancing big data decision-making capability and quality among Chinese firms: A dynamic capabilities view. Information and Management A data-analytics approach to identifying hidden critical suppliers in supply networks: Development of nexus supplier index A supply chain view of the resilient enterprise Inter-firm dependence, inter-firm trust, and operational performance: The mediating effect of e-business integration Examining sustainable supply chain management of SMEs using resource based view and institutional theory Harnessing the power of big data analytics in the cloud to support learning analytics in mobile learning environment From superstorms to factory fires: Managing unpredictable supply chain disruptions Uncertainty and supply chain risk: The moderating role of supply chain flexibility in risk mitigation An investigation of visibility and flexibility as complements to supply chain analytics: An organizational information processing theory perspective Virgin or recycled? Optimal pricing of 3D printing platform and material suppliers in a closed-loop competitive circular supply chain. Resources, Conservation and Recycling Understanding the factors affecting the organizational adoption of big data Manufacturing strategy, environmental uncertainty and performance: A path analytic model Resolving paradoxes in IT success through IT ambidexterity: The moderating role of uncertain environments. Information & Management Robust strategies for mitigating supply chain disruptions Explicating dynamic capabilities: The nature and micro foundations of (sustainable) enterprise performance A dynamic capabilities-based entrepreneurial theory of the multinational enterprise Uncertainty, innovation, and dynamic capabilities: An introduction Dynamic capabilities and organizational agility: Risk, uncertainty, and strategy in the innovation economy The dynamic capabilities of firms. Handbook on Knowledge Management A contingency perspective on Internet adoption and competitive advantage A robust green traffic-based routing problem for perishable products distribution Big data analytics in supply chain management between 2010 and 2016: Insights to industries On the value of mitigation and contingency strategies for managing supply chain disruption risks Analysing the impact of blockchain-technology for operations and supply chain management: An explanatory model drawn from multiple case studies Is top management team-supply chain manager interaction the missing link? An analysis of risk-bearing antecedents for supply chain managers The performance effects of big data analytics and supply chain ambidexterity: The moderating effect of environmental dynamism Big data analytics in operations and supply chain management Reverse transfer of innovation and subsidiary power: A moderated mediation model The reporting of nonresponse analyses in survey research Understanding dynamic capabilities A model for portfolio selection with order of expected returns Modelling and mitigating the effects of supply chain disruption in a defender-attacker game Managing the supply disruption risk: Option contract or order commitment contract? The impact of IT-business strategic alignment on firm performance in a developing country setting: Exploring moderating roles of environmental uncertainty and strategic orientation Dynamism, disruption orientation, and resilience in the supply chain and the impacts on financial performance: A dynamic capabilities perspective Publisher's Note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations