Abstract
Purpose
This study aims to examine and understand the impact of reverse logistics adoption on firms' digitalization and collaboration activities. Specifically, leveraging the knowledge-based view, this study examines how adopting sustainable logistic practices (reverse logistics) prepares firms to embrace digitalization and encourages them to collaborate with other organizations.
Design/methodology/approach
The study used longitudinal survey data from two waves (2017 and 2019) from the Mannheim Centre for European Economic Research. The authors used the negative binomial regression analyses to test the impact of reverse logistics adoption on the digitalization and inter-organizational collaboration dependent count variables.
Findings
The study's findings highlight the usefulness of reverse logistics in enabling digitalization and inter-organizational collaboration. The results show that the firms investing in sustainable supply chains will be better positioned to nurture digitalization and inter-organizational collaboration.
Practical implications
For resource-bound managers, this study provides an important insight into prioritizing activities by highlighting how reverse logistics can facilitate digitalization and collaboration. The study demonstrates that the knowledge generated by reverse logistics adoption can be an essential pillar and enabler toward achieving firms' digitalization and collaboration goals.
Originality/value
The study is among the first to examine the effect of reverse logistics adoption on firm activities that are not strictly associated with the circular economy (digitalization and collaboration). Utilizing the knowledge-based view, this study reports on the additional benefits of reverse logistics implementation previously not discussed in the literature.
Keywords
Citation
Rasool, F., Greco, M., Morales-Alonso, G. and Carrasco-Gallego, R. (2023), "What is next? The effect of reverse logistics adoption on digitalization and inter-organizational collaboration", International Journal of Physical Distribution & Logistics Management, Vol. 53 No. 5/6, pp. 563-588. https://doi.org/10.1108/IJPDLM-06-2022-0173
Publisher
:Emerald Publishing Limited
Copyright © 2023, Faisal Rasool, Marco Greco, Gustavo Morales-Alonso and Ruth Carrasco-Gallego
License
Published by Emerald Publishing Limited. This article is published under the Creative Commons Attribution (CC BY 4.0) licence. Anyone may reproduce, distribute, translate and create derivative works of this article (for both commercial and non-commercial purposes), subject to full attribution to the original publication and authors. The full terms of this licence may be seen at http://creativecommons.org/licences/by/4.0/legalcode
1. Introduction
Logistics is the process of strategically managing the procurement, transport, and storage of materials, components, and finished goods within and outside the boundaries of an organization while maximizing current and future profitability through cost control and process optimization. In other words, logistics entails delivering goods to suppliers and customers in the best possible way (Min et al., 2019). However, managing only forward logistics (traditional logistics) has become inadequate to compete and grow in an ever-changing global business environment (Baah and Jin, 2019). In addition, government regulations, stakeholder pressure and customer demands compel firms to take responsibility for their products at the end of life stage (Andiça et al., 2012; Ni et al., 2021). As a result, it has become essential for a firm to manage the forward and reverse flow of materials and goods. This reverse flow of goods is generally referred to as “reverse logistics”. Reverse logistics activities focus not only on recycling the products but also on properly disposing of harmful components and repurposing the useful components in the returned products, for example, using old computer chips in toy manufacturing (Meade et al., 2007). Studies have reported many benefits of successful reverse logistics activities, such as higher profits, increased customer satisfaction and loyalty, cost reduction and better environmental performance (Del et al., 2019; Harold, 2011; Hazen et al., 2012; Marić and Opazo-Basáez, 2019; Ni et al., 2021; Sangwan, 2011; Sehnem et al., 2019).
Though necessary, the process of implementing and managing reverse logistics is not easy and requires a significantly larger amount of resources and expertise compared to forward logistics to manage and implement it successfully (Gaur et al., 2017; Giri et al., 2017; Jayaraman et al., 2008). Such a process includes building an appropriate infrastructure, IT capabilities and culture to share information with internal and external partners (Hudnurkar et al., 2014; Marić and Opazo-Basáez, 2019; Moktadir et al., 2020; Olorunniwo and Li, 2010; Zhang and Cao, 2018). As a result, companies invest in business operations and personnel to facilitate reverse logistics operations. Many studies have investigated how digitalization and collaboration activities can facilitate the reverse logistics adoption process and improve system efficiency (Aksin-Sivrikaya and Bhattacharya, 2017; Chen et al., 2017). But surprisingly, no study has investigated the impact of reverse logistics adoption on firm digitalization and collaboration levels. First of its nature, by utilizing Knowledge-Based View (KBV), this study aims to empirically investigate the impact of reverse logistics adoption on firm digitalization and collaboration levels. Such investigation will be useful in advancing theory and managerial practices related to reverse logistics, digitalization and collaboration. The study aims to empirically investigate the impact of reverse logistics adoption on firm digitalization and inter-organizational collaboration by leveraging KBV and to demonstrate that newly created knowledge can serve as a competitive advantage for the firm. This study is the first of its nature to explore such relationships. Unlike the former flow of actions (implementation of digitalization and then reverse logistics), the law often imposes the adoption of reverse logistics on firms to achieve SDG 2030 goals. Therefore, in many cases, firms will not have the choice to delay or ignore the implementation of reverse logistics activities. Therefore, it is crucial to understand the impacts of reverse logistics adoption on firm activities and study the unintended consequences of reverse logistics on firm operations.
The outcome of this study confirms that adopting reverse logistics positively influences digitalization and collaboration in firms. As a result, the study presents several theoretical, managerial and policy implications. The manuscript is organized into seven sections. The following section, section two, presents the study's theoretical background. Section three focuses on developing and rationalizing the two hypotheses studied and tested in the study. Section four presents the methodology and data sets used to test the hypotheses. Section five is dedicated to reporting the results, while section six discusses the findings of the study. Finally, section seven concludes the study and discusses the theoretical, managerial and policy implications. This section also reports on the limitation of the study and presents possible future developments.
2. Theoretical background
2.1 Knowledge-based view
Barney (1991) argued that in the current information age, the Resource-Based View (RBV) proposed by Wernerfelt (1984) has evolved into KBV. According to KBV, knowledge is the most valuable resource created within the firm's boundaries by utilizing and enhancing employees' experience, skills and abilities (Curado and Bontis, 2006). Teece (2000) argued that a firm's competitive advantage is inextricably tied up with its ability to create, diffuse, maintain and use difficult-to-imitate knowledge. In other words, knowledge management enables firms to share information produced by different employees and sections to gain a competitive advantage (Nisar et al., 2019). Ode and Ayavoo (2020) confirmed the positive relationship between knowledge creation, management activities and firm innovativeness. Knowledge is created when learning occurs at the individual level within an organization (Ganesh et al., 2014). This individual learning is translated into organizational learning and eventually into organizational knowledge that has a positive impact on a firm's financial performance (Silvestre, 2016), purchasing performance (Schütz et al., 2020), flexibility (Blome et al., 2014), innovation and operations capabilities (Javaid et al., 2021), and serves as a source of major competitive advantage (Teece, 2000). These advantages are accumulated by capturing and transferring implicit and explicit knowledge during the knowledge creation and transfer process. Therefore, it is vital for a firm to create and manage information to remain competitive.
2.2 Knowledge management
Knowledge management bridges the gap between information demand and supply by encouraging learning processes that improve organizational performance (Curado and Bontis, 2011). The studies have argued that even though a firm needs external knowledge and information, a lasting competitive advantage comes from creating and utilizing in-house knowledge (Azyabi, 2018; Chong et al., 2014; Emden et al., 2005). However, the firm can only enjoy these knowledge creation and sharing advantages when employees share information freely with their co-workers (Caputo et al., 2021a). Bhatt (2019) defined knowledge as expertise gained through accumulation of experiences or study to understand facts, procedures and rules. For capitalization and value capture of knowledge, Loon (2019, p. 433) categorized knowledge management mechanisms into “a. Learning and knowledge creation culture; b. organizational knowledge architecture for adaptive and exaptive capacity; and ‘c. business model’”. Knowledge is created in cycles and transferred within the organization through different means and actions (Nonaka, 1994), making it vital to continuously produce new knowledge to maintain a competitive advantage by implementing new systems and processes. In other words, a valuable transferable knowledge is created whenever a firm performs a new activity that will shorten the learning curve in future projects (de Machado et al., 2022).
2.3 Sustainability
Knowledge transfer and management activities can be important mediators in using sustainability tools in medium- and large-sized firms (Hörisch et al., 2015), making them essential for achieving sustainability goals. In the last two decades, the concept of sustainability has gained significant interest from the popular press, policymakers and scientific journals in various technical fields (Lintona et al., 2007). Sustainability can be defined as the extent to which current business actions affect the natural environment, society and firms’ economic viability in the future (Krysiak, 2009). In other words, it requires a conscious decrease in the use of resources while still maintaining a steady flow of products to allow commercial entities to gain revenues from deliverables to market. The scarcity of resources and uninterrupted increase in pollution mainly caused by industrialized nations (Tahvonen, 2000) combined with ever-increasing economic, social and environmental uncertainties in recent years have encouraged researchers and practitioners to investigate and develop solutions from many points of view. In addition, the stakeholders (customers, shareholders, governments) are putting immense pressure on firms to change their habits of indiscriminately using and discarding natural resources. As a result, sustainability has become a major concern in decision making. Unlike in the past, where decisions were mainly economic (Ohnishi et al., 2012), the decision-makers are being forced to consider the impact of their decisions on the triple bottom line of sustainability (economic, environmental, social). If implemented correctly, sustainable actions can offer firms several benefits and competitive advantages. These include, among others, decreased cost for materials, waste reduction, production/operations efficiency, increased firm reputation, brand value, better working conditions, and profits (Sangwan, 2011), innovation (Nidumolu et al., 2009) and shared value creation (Porter and Kramer, 2011a). These benefits are often the result of introducing sustainable initiatives in the firms' value chain to make the supply chain green and lean. This new supply chain is not just about cost and efficiency: it also considers the triple bottom line of sustainability (Silvestre, 2016). Sustainable initiatives' success depends on using the right strategies and frameworks at both the implementation and operational stages (Preuss and Fearne, 2022) to increase the success of sustainable supply chain initiatives.
2.4 Supply chain and sustainability
In recent years, the pursuit of sustainability has been recognized as a viable strategy to resolve many of the contemporary challenges global supply chains face (Giannakis and Papadopoulos, 2016). Sustainable supply chains manage materials, information and capital flows and result in cooperation between different actors along the supply chain (Karaosman et al., 2020). Sustainability in supply chain practices improves firms' financial performance and enhances competitiveness (Wang and Sarkis, 2013). Furthermore, it creates a moral capital that firms can utilize to mitigate the consequences of potential business risks (Jiang et al., 2020) and create new opportunities. To this end, one powerful strategy used by the firms is to decrease the use of virgin materials by bringing back the material for reuse or repurposing at the end of life and creating a loop for the material. The process is generally termed as a “closed-loop supply chain”. Min et al. (2006, p. 311) defined a closed-loop supply chain as the process associated with the “acquisition, distribution, and marketing activities involved in product returns/recoveries, source reduction/conservation, inspection, recycling, salvage, substitution, reuse, disposal, disassembly, refurbishment, repair, and remanufacturing”. In other words, an ideal closed-loop supply chain is a supply chain with zero-waste where all the products at their end of life are recovered for reuse/repurpose or disposed of properly. However, the studies have argued that the closed-loop supply chain systems are often complex and unpredictable compared to the forward supply chain (Gaur et al., 2017; Giri et al., 2017) and, therefore, often require greater resources and commitments to manage (Morgan et al., 2018). But firms are still willing to invest in these risky endeavors to reap the tangible and intangible benefits (Schenkel et al., 2015) they offer.
2.5 Reverse logistics
Drivers such as legislation, stakeholder pressure, social accountability, economic interests and ethics compel a firm to adopt green activities in their supply chain (Andiça et al., 2012), including the reuse of materials and end-of-life products. Reusing materials/products is generally referred to as “reverse logistics”. Reverse logistics is a key element of green supply chain management since it helps decrease waste produced by processing and disposing returned and used goods by implementing a variety of disposition alternatives (Pokharel and Mutha, 2009). Many factors and points in the supply chain can lead to product returns, including production, distribution and returns connected to customers (Rogers and Tibben-Lembke, 2001), and reverse logistics aims to facilitate appropriate reuse, recycling and disposal of these returns. In the past, reverse logistics was viewed as the process of recycling used/malfunctioned products. However, in recent years, the definition and concept have expanded to include processes connected with product return and collection for recovery, repair, refurbishment, recycling, remanufacturing or disposal of used/end-of-life items (Rogers and Tibben-Lembke, 2001). The expansion in concept has increased the benefits obtained from reverse logistics, including increased profits (Marić and Opazo-Basáez, 2019; Toffel, 2004), cost reduction (Sangwan, 2011), customer loyalty (Jayaraman et al., 2007), customer satisfaction (Hazen et al., 2012) and environmental performance (Harold, 2011). Reverse logistics is a complex process and requires a significantly higher level of competencies and resources than forward logistics (Gaur et al., 2017; Giri et al., 2017). Therefore a greater level of investment and organizational commitment is needed to implement reverse logistics successfully (Morgan et al., 2018).
2.6 Digital technologies and supply chain
By directly connecting suppliers and consumers and vice versa, digital technology can tackle some of the most pressing challenges in supply chain management by decreasing information delays, cost, and increasing volume and flexibility, leading to greater service levels (Agrawal and Narain, 2018). Although there have been academic contributions dealing with the repair, reuse and refurbishment of items for decades, the advent of digitalization in recent years has allowed a whole new set of tools to be implemented at the firm level (Hidalgo-Carvajal et al., 2021). Unlike traditional supply chains, the Digital Supply Chain (DSC) depends primarily on technologies (such as software, hardware and communication networks) to enable operations such as buying, making, storing, moving and selling a product by globally dispersed partners (Bhargava et al., 2013). Rasool et al. (2021, p. 1204) defined DSC as “a seamlessly interconnected transparent supply chain, that independently performs decision support activities to minimize human input needs”. Studies have reported several benefits of DSC over the traditional supply chain, including improved transparency, speed, flexibility, productivity and profitability (Haoud and Hasnaoui, 2019; Oorschot et al., 2022). The list of these benefits expands when applied to a closed-loop supply chain. Some studies have argued that without digital technologies, the activities associated with a closed-loop supply chain are impossible to manage and control (Jayaraman et al., 2008; Pagoropoulos et al., 2017; Wilson et al., 2022). The ability of digital technologies to facilitate a closed-loop supply chain is well acknowledged and documented in the literature (Antikainena et al., 2018; Awan et al., 2021; Pagoropoulos et al., 2017). Studies have reported that the technologies such as A.I, M.L, data mining and IoT enable firms to not only trace, monitor and make decisions on returned products/materials but also on the products still in circulation and their end-of-life destination (Pagoropoulos et al., 2017; Rosa et al., 2020).
2.7 Collaboration and supply chain
In the fast-moving globalized economy, firms have realized that they cannot provide high-quality products to their customers at competitive prices and with speed in silos. Therefore, they are forced to collaborate and leverage the knowledge and skills of the entities outside of their boundaries (Hudnurkar et al., 2014). Gulati (1998, p. 293) defined collaboration as “voluntary arrangements between firms involving exchange, sharing, or co-development of products, technologies, or services”. It can involve just two firms that have created a bilateral agreement or a complex system of multiple independent and interconnected entities working together to achieve the same goals by creating a shared value ecosystem (Grant and Baden-Fuller, 1995; Porter and Kramer, 2011b). The benefits of such collaborative activities often include expedited product development and launch processes at a reduced cost with significantly higher quality and technical specifications (Singh et al., 2018; Walter, 2003). In addition, the collaborative activities help firms to share risk (Li and Nguyen, 2017) and reduce transaction costs (Kalwani and Narayandas, 1995) by accessing complementary resources (Park et al., 2004) and knowledge (Grant and Baden-Fuller, 1995). As a result, firms improve their productivity (Kalwani and Narayandas, 1995), profits and competitive advantage (Mentzer et al., 2000). Depending on the project's objective and need, the firms may seek both vertical (supplier and customers) and horizontal (competitors) collaboration together with private-private (among firms) or cross-sectoral collaboration (public-private-third sector collaboration). To identify which partners are best suited for collaboration in any given project, Barratt (2004) recommended asking why, where, what and whom before undertaking collaboration projects.
3. Hypotheses
3.1 Reverse logistics and digitalization
Adopting reverse logistics is a complex process and often requires firms to undergo substantial changes and overcome multiple internal and external barriers (González-Torre et al., 2010). Some of these barriers include a lack of firm infrastructure readiness, employee skills, an appropriate support system to handle new activities, management commitment, strategic planning as well as market uncertainties and high initial cost (de Campos et al., 2017; González-Torre et al., 2010; Govindan and Bouzon, 2018; Prakash et al., 2015; Prakash and Barua, 2017; Waqas et al., 2018). To overcome these barriers, firms must unlearn and relearn several important competencies and develop new skills and knowledge. According to KBV, knowledge is created by individual actors within a firm and is transferred to other members and sections of organizations (Ganesh et al., 2014). As a result, firm performance and maturity improve in different domains (Matos et al., 2020). The case is no different for reverse logistics, whose adoption increases a firm's capabilities in different areas (Mihi Ramírez, 2012; Ramirez and Girdauskiene, 2013), including IT competencies (Daugherty et al., 2005) that will help in increasing the firm's digitalization level. Azyabi (2018) reported that the management of internally developed knowledge is the only factor influencing the adoption of e-practices in Saudi SMEs. One of the most frequently reported barriers to adopt digitalization and reverse logistics is management commitment. The main reasons behind this attitude are the friction to change and the lack of understanding of the benefits of these changes (Agrawal et al., 2020; Tham and Atan, 2021). Prior experience and knowledge can help in reducing such friction and encourage management to invest in new initiatives.
KBV dictates that valuable transferable knowledge is created whenever a firm performs a new activity that will shorten the learning curve in future projects. Following this view, we infer that the managers have already developed the knowledge and experience needed to manage and embrace change during their reverse logistics adoption activities. As a result, participating managers will be more open to changes in the system for future endeavors. Another big barrier to adopting digitalization is the initial cost of switching over (Agrawal et al., 2020). This cost is mainly needed for employee training activities, building systems and updating firm infrastructure to handle this new way of doing business. To a firm's advantage, these are all activities performed by a firm before successfully implementing reverse logistics. Generally, a newer IT system is adopted to increase efficiency and enhance communication among stakeholders for reverse logistics, which often require employee training and system upgrades. KBV dictates that this knowledge and resources will be used in future firm activities (Marqués and Garrigós-Simón, 2006). Eller et al. (2020) confirmed this relation in their study of Australian SMEs, where employee skills and IT positively influence the level of digitalization. Similarly, SMEs in Malaysia were reported to have increased their digitalization level by managing internally and externally created knowledge (Chong et al., 2014). Caputo et al. (2020) reported higher returns on big data investments for firms having skilled employees. Therefore, this study argues that the knowledge and competencies gained during the reverse logistics adoption process will help firms overcome digital transformation barriers and serve as antecedents for digital transformation. Hence, resulting in an increased level of digitalization. Therefore, we hypothesize that.
The adoption of reverse logistics will lead to a higher level of digitalization.
3.2 Reverse logistics and collaboration
Strong collaboration has been reported as one of the most critical activities that a firm can perform to improve its performance (Mofokeng and Chinomona, 2019) and speed (Walter, 2003) to gain a competitive advantage (Mentzer et al., 2000). The activity is complex and expensive, but the benefits outweigh the cost and efforts needed to implement it (Barratt, 2004). Studies have reported on both barriers hindering and antecedents enabling successful collaboration. The commonly reported barriers include commitment, firm culture, trust and market uncertainties (Enkel and Heil, 2014; Grant and Baden-Fuller, 1995; Hudnurkar et al., 2014; Qazi and Appolloni, 2022; Zhang and Cao, 2018). Similarly, inter-organizational systems, information sharing, and technology adoption, regulatory pressure (Enkel and Heil, 2014; Hsu et al., 2013; Hudnurkar et al., 2014; Zhang and Cao, 2018) are important antecedents for successful collaboration. Several of these coincide with barriers and antecedents for adopting reverse logistics, such as market uncertainties (Bressanelli et al., 2018), management commitment (Agrawal et al., 2020; González-Torre et al., 2010; Tham and Atan, 2021), complexity (Govindan and Bouzon, 2018; Waqas et al., 2018), coordination and information sharing (Bressanelli et al., 2018; Zhu et al., 2018), and appropriate support systems (de Campos et al., 2017; Govindan and Bouzon, 2018; Prakash et al., 2015).
Leaning on KBV, we argue that the competencies developed to adopt reverse logistics will facilitate collaboration activities. A similar argument was also confirmed by Emden et al. (2005) when they reported the experience gained in performing internal functions is a valuable asset during collaboration activities. For example, an important competency required to implement reverse logistics is to embrace the collaborative culture and information sharing routines. These were also the prime antecedents that Hudnurkar et al. (2014) identified in their literature review to increase collaboration activities. Similarly, information-sharing practices, trust and appropriate infrastructure are needed for reverse logistics success (Bressanelli et al., 2018; Govindan and Bouzon, 2018) and to kickstart and increase collaboration levels with external entities (Barratt, 2004; Enkel and Heil, 2014; Zhang and Cao, 2018). Additionally, Grant and Baden-Fuller (1995) argued that higher levels of uncertainty encourage firms to collaborate more with external entities, and the introduction of reverse logistics has been reported to introduce additional uncertainties in the firm value chain (Gaur et al., 2017; Giri et al., 2017; Wilson et al., 2022). Therefore, the firms adopting reverse logistics will be motivated to increase collaboration activities, resulting in an increased level of collaboration.
The adoption of reverse logistics will lead to a higher level of collaboration.
4. Methodology
4.1 Data
The data for this analysis comes from two waves (2017 and 2019) of the German Community Innovation Survey (CIS) performed by the Centre for European Economic Research (ZEW) in Mannheim. The binomial regression analysis of the panel data was conducted using STATA 16.0. Using secondary data from Germany to test the hypothesis is useful for several reasons.
First, Germany is at the forefront of legislation on reverse logistics. In 1991, Germany introduced the first-ever legislation on packaging materials and made manufacturers responsible for collecting, sorting and recycling packaging material for their products (Álvarez-Gil et al., 2007). The 1994 European Union “Directive on Packaging and Packaging Waste” and subsequent updates further intensified German efforts on reverse logistics. The target is to recycle at least 65% of the product weight by 2025. Second, along with several drives that can be used to test and control hypotheses, the 2017 wave of the CIS survey specifically asked the participating firms about the adoption of reverse logistics in the past three years (2014–2016). Similarly, the 2019 CIS wave asked the firms about adopting AI techniques and collaboration activities in their day-to-day operations. Third, though the responses are anonymized, the changes in a firm over time can be tracked using the firm ID, and the impact of actions taken in the past can be estimated. Finally, by anonymizing the responses, CIS has reduced the chances of self-serving bias (i.e. respondents have no incentive to make their firm appear “better” than it is). Self-serving biases are a major concern for researchers when analyzing system traits using self-reported responses (Ketokivi, 2019).
4.2 Variables used in study
The study needed one independent (reverse logistics adoption) and two dependent (digitalization and collaboration) variables to test the proposed hypotheses. These three variables will be sufficient to measure the changes in digitalization and collaboration level in a given firm after adopting reverse logistics. Independent variables will be responsible for information regarding reverse logistics adoption, and the dependent variable will be responsible for information related to changes in digitalization and collaboration levels. The collaboration variable's development is consistent with similar studies (Cricelli et al., 2021). At the same time, the available information from the survey instrument was used to develop the digitalization variable. Along with these three main variables, multiple control variables were also used in the study, discussed in detail in the following subsections.
4.2.1 Independent variable
We assess the impact of reverse logistics adoption on the digitalization and collaboration increase in the firm through the “logi5” question in CIS 2017. The independent variable “AdoptedRL17” (renamed logi5) is described with a Yes/No answer to the question, “During the three years from 2014 to 2016 did your enterprise introduce any of the following innovations in logistics? Reverse logistics (reuse and return of products and materials, etc.)”.
4.2.2 Dependent variables
The two dependent variables, “DigitalizationCount” and “CollaborationCount”, were generated by combining multiple variables from the CIS 2019 wave. The process and rationale for generating variables are given below.
4.2.2.1 DigitalizationCount
We defined the “DigitalizationCount” dependent variable by considering all the items in the survey that could describe the use of digital technologies by the focal firm. To this aim, we resorted to three sets of items.
The first describes the use of AI technologies in the firm activities. The CIS 2019 inquired about using five different types of AI technologies for five different activities, producing 25 binary variables. In addition, two different binary variables focusing on AI use were also available in the group. These 27 binary variables were merged into one binary variable digi_AI, having a value of 0 and 1. Where one represents a firm that has participated in any activities related to AI (regardless of intensity), and zero represents the firms that have not participated in any activity related to AI. The rationale for merging multiple variables from the AI group into one binary variable was rooted in the idea that all groups should have similar weightage and that one type of digitalization does not skew the results.
The second describes the use of software/big data for firm activities. Three binary variables inquiring about using big data/software for firm activities were merged into one count variable, digi_bd, having a value of 0–3.
The third describes the use of information processing techniques for firm activities. The one variable focusing on the use of digital information processing techniques for firm activities was renamed to digi_ip, having a value of 0–1.
The resulting three variables were merged into one “DigitalizationCount” dependent count variable for further analysis. The count variable is useful in identifying firms that have increased their level of digitalization and can help distinguish firms with a greater increase in digitalization. The resulting count variable can have a value of 0–5 for any focal firm. For example, a firm that has participated in both information processing and AI will have a value of two, and the firm that has only participated in AI will have a value of one. In addition, multiple other specifications have been attempted as a robustness check (see section 5.4). This new “DigitalizationCount” variable contains information from all variables that deliver information on the increase in digitalization levels between 2016 and 2018 in any given firm (Figure 1).
4.2.2.2 CollaborationCount:
Similar to the previous dependent variable, we defined the “CollaborationCount” by considering all the items in the survey that could describe the variety of inter-organizational collaborations pursued by the focal firm. To this aim, we resorted to four sets of items.
The first describes the location (domestic or foreign) of the collaborating partner. The CIS 2019 inquired about the location of the ten types of collaborating partners producing 20 binary variables. These 20 variables were merged into ten count variables, having one variable for each type of partner. For example, collaboration with domestic and foreign universities was merged into one count variable called collab_univer with a value of 0–2. Merging these variables into ten count variables provides a greater depth of information on inter-organization collaboration. It can distinguish firms with a higher level of collaboration from firms with a lower level of collaboration. To keep the variables in a manageable form, these ten variables were merged into one single count variable collab_location with a value of 0–20 (No information was lost).
The second describes the collaboration for innovation. Five binary variables inquiring about the collaboration activities specifically focusing on innovation activities were merged into one count variable collab_innov, having a value of 0–5.
The third describes the collaboration for R&D. Three binary variables inquiring about the collaboration for activities associated with R&D were merged into one count variable, collab_rnd, having a value of 0–3.
The fourth describes the collaboration for other activities. Two binary variables inquiring about the collaboration for other activities (AI and others) were merged into one count variable collab_oth with a 0–2.
The resulting 13 count variables were merged into one “CollaborationCount” dependent variable for further analysis. Similar to the previously developed variable, the “CollaborationCount” variable can have a value of 0–30. Where 0 means no involvement in collaboration activities and 30 means the involvement in all activities associated with collaboration (Figure 2). Multiple other specifications have been attempted as robustness checks (see section 5.4).
4.2.3 Control variables
For testing hypotheses H1 and H2, we introduced multiple control variables discussed in previous studies (Agrawal et al., 2020; Agrawal and Narain, 2021; Becker et al., 2018; Wrede et al., 2020) that can facilitate the adoption of digitalization and collaboration practices (Table 1). Becker et al. (2018) reported several cases where a hiring Chief Technical Officer (CTO) expedited the digitalization process. Similarly, employee skills and training (Agrawal et al., 2020) and the acquisition of newer technologies were major contributors to increased digitalization and collaboration (Agrawal and Narain, 2021; Usman Ahmad et al., 2019). Furthermore, we controlled the impact of public funding and international competition by introducing variables “public_funding” and “export_perc” in the model, as studies have reported that the firms engaging in these activities demonstrate higher levels of engagement in both collaboration and digitalization activities (Caputo et al., 2021b; Ito and Pucik, 1993; Matt et al., 2011). For example, a higher percentage of export revenue is linked with higher foreign competition and higher R&D spending (Ito and Pucik, 1993), leading to greater digitalization investment. Similarly, public funding positively influences collaboration (Matt et al., 2011) and digitalization activities (Nedilska and Oleniuk, 2020). Therefore, controlling these variables will eliminate any impact these two variables have on the study's dependent variables. The firm size, sector and sales volume were also introduced as the additional control variables.
4.3 Econometric approach
This study uses the binomial regression analysis method to test the proposed hypotheses. The binomial regression analysis of the panel data was conducted using STATA 16.0. Regression analysis is a reliable method of identifying which variables impact a topic of interest (independent variables). Several studies in the past have used regression analysis to empirically test the impact of one variable over another while utilizing similar data sets (Czarnitzki et al., 2020; Horbach and Rammer, 2020; Kobarg et al., 2020). The process of performing a regression allows you to confidently determine which factors matter most, which factors can be ignored and how these factors influence each other (Myrtveit and Stensrud, 1999). The dependent variables used in the study are count variables. The data prediction based on count variables is supported perfectly by the Poisson-Gamma mixed distribution (Hilbe, 2011), which the negative binomial regression is based on. We employed the negative binomial regression method because the variance of dependent variables is greater than the mean and contains only non-negative integer values (Table 2). According to Joe and Zhu (2005), this dataset cannot support standard linear regression techniques pertaining to the dependent variable's abnormal, highly skewed and discontinuous nature. The independent and control variables were then subjected to a Variance Inflation Factor (VIF) test. VIF has an average value of 1.36 and a maximum value of 1.77. According to Baltagi (2005) and Peter (1998), the multicollinearity problem among the variables is not serious when the VIF value is below 10. Furthermore, to test the best fit for data AIC of the independent variable was calculated. The lower value of AIC indicates a better fit for the data. Hence, the model with the smallest AIC value was selected.
5. Results
5.1 Descriptive statistics
Table 2 presents descriptive statistics and a correlation matrix of the variables used. For example, the variable “AdoptedRL17” is a binary variable that represents the firm responses (Yes/NO) to the question of adopting reverse logistics between 2014 and 2016. These descriptive statistics indicate heterogeneity in the firms' reverse logistics adoption and offer validity as control variables.
5.2 Regression results
We used STATA 16.0 to perform negative binomial regression on panel data from the CIS 2017 and 2019 waves to test the proposed hypothesis. The regression results for both proposed hypotheses are reported in Tables 3 and 4. The first hypothesis investigating the increase in digitalization level is accepted at the 99% confidence level (p-value <0.01). Similarly, the second hypothesis investigating the increase in firm collaboration level is also accepted at a 95% confidence level (p-value <0.05). As a result, it is confirmed that the firms adopting reverse logistics are more likely to have higher levels of digitalization and collaboration than those that do not adopt reverse logistics. All the control variables used in the study are also significant, hence confirming their impact and power in predicting digitalization and collaboration adoption. The control variables “newemployee_knowl”, “new_tech_acq”, “export_perc”, “public_funding”, and “sales” are strong predictors of both increased digitalization and collaboration levels in a firm. When combined, the control variable “sector” is significant. However, the analysis of individual sectors shows that the control is more significant for some industries than others. Furthermore, the percentage of graduate employees impacts both digitalization and collaboration levels, but it does not matter what percentage of employees possess a university degree. This finding contrasts with the earlier studies, such as those performed by Agrawal et al. (2020), where it was reported that employees with higher technical skills would be better able to guide firms in adopting digitalization and collaboration practices.
5.3 Robustness check
The robustness of the model was tested by changing the definitions of dependent variables. Multiple alternate “DigitalizationCount” and “CollaborationCount” variables were generated using different combinations of variables to see if the test results would vary. The list of these alternate variables and obtained regression results is presented in Table 5. The results in Table 5 confirm the robustness of the dependent variables as the varied definitions of the variables do not change the results significantly. Another measure adopted to check the robustness of the model was using the Logit and Probit models instead of negative binomial regression. The obtained results confirmed the robustness of the model as the results of these new tests did not produce values notably different from the original model.
6. Discussion
The existing literature has discussed the impact of digitalization and collaboration on reverse logistics and how these competencies facilitate a firm in moving toward sustainability (Aksin-Sivrikaya and Bhattacharya, 2017; Chen et al., 2017) and eventually toward the circular economy (Antikainen et al., 2018; Mishra et al., 2021; Pagoropoulos et al., 2017). However, the literature has not investigated the impact of reverse logistics adoption on digitalization and firm collaboration. This study aimed to empirically test this reverse relation and highlighted the advantages firms can reap by implementing reverse logistics earlier in their system, including greater levels of collaboration and digitalization. Furthermore, KBV dictates that firms, while performing any activity, create new knowledge, and this process of creating new knowledge is multiplied when firms perform new activities or introduce new systems (Hörisch et al., 2015; Yang, 2013). Therefore, the management and utilization of this internally generated knowledge play a vital role in the firm's future endeavors. This impact also emerges after the adoption of reverse logistics. It was argued earlier that while adopting reverse logistics, firms produce new implicit and explicit knowledge that will provide a competitive advantage and learning to the practicing firm. Proper knowledge management practices will help the firms effectively utilize these advantages and knowledge. It is important to note that these advantages can only be derived if the employees are willing to freely share this newly generated knowledge (Caputo et al., 2021a). Therefore managers should focus on developing collaborative culture inside and outside the firm boundaries.
Relying on institutional theory, Fauzi and Sheng (2022) argued that all firms would eventually introduce digitalization into their system. But the introduction of digitalization will pose several challenges for implementing firms during the implementation process and before even starting the process. D'Este et al. (2012) divided barriers into two categories and argued that firms should focus on overcoming deterring (hindering firms from initiating new activities) barriers. The elimination of deterring barriers is an intricate process requiring top management commitment. Leaning on the KBV, the study results confirm that firms that implement reverse logistics are better positioned to overcome deterring barriers and engage in digitalization activities, including the initial cost that was reported as one of the biggest barriers toward digitalization (Agrawal et al., 2020; Tham and Atan, 2021). In addition, additional gained employee skills and IT competencies will serve as enablers for the higher digitalization levels (Chong et al., 2014; Eller et al., 2020). This argument aligns with the previous studies that reported a positive impact on firm performance and capabilities after adopting reverse logistics activities (Matos et al., 2020; Mihi Ramírez, 2012; Ramirez and Girdauskiene, 2013). Similarly, introducing reverse logistics will lead to higher IT capabilities for the practicing firm (Daugherty et al., 2005) as the initial training required to implement digitalization will be already available to firm employees (Eller et al., 2020; Marqués and Garrigós-Simón, 2006). Furthermore, the results obtained in this study are in line with Azyabi's (2018) findings. The author reported that knowledge acquisition activities (creation and transfer) are the most significant factors influencing the increase in the use of digital technologies in Saudi SMEs. Therefore, the study results confirm that adopting reverse logistics generates knowledge that not only encourages firms to participate in digitalization activities but is also helpful in overcoming barriers associated with adopting digitalization. This argument is in line with Chong et al. (2014), where authors reported that the knowledge creation process facilitates the firms in introducing newer technologies.
Similarly, it is no longer feasible for a firm to thrive in silos. Instead, firms need to collaborate with external entities to reduce risk and increase productivity and speed. Appropriate knowledge creation and management activities (implementing new processes) will enable the firm to share the newly created knowledge with both internal and external partners (Nisar et al., 2019). The study's findings also confirm that reverse logistics adoption will help firms overcome collaboration barriers and make them open to utilizing external knowledge and techniques. Inter-firm collaboration was also reported by Hudnurkar et al. (2014) as an important activity to maximize success in reverse logistics activities. Similarly, an appropriate infrastructure and knowledge sharing capabilities are created during reverse logistics adoption to serve as a base for inter-organization collaboration (Enkel and Heil, 2014; Zhang and Cao, 2018). These findings are in line with Yang (2013), where author confirmed that knowledge acquisition and dissemination activities significantly improve firms' collaborative relations. Furthermore, the findings also confirm the view of Olorunniwo and Li (2010), who argued that collaboration with partners and competitors is needed for any successful reverse logistics operation, which increases over time with the maturity of reverse logistics operations.
The adoption of reverse logistics offers many benefits and has become essential today. However, the adoption of reverse logistics is often involuntary. It is adopted to respond to policymakers and customers (Álvarez-Gil et al., 2007; Hsu et al., 2013) and, in general, is viewed as a money losing activity (Eltayeb and Zailani, 2011). The study's findings assert that though the activity is complex and expensive, it has lasting beneficial impacts on operational activities and has the potential to help in future changes.
7. Conclusion
The study investigated the impact of sustainability practices (reverse logisticsadoption) on firms’ operational activities. In particular, it explored whether adopting reverse logistics increased firms' digitalization and collaboration activities. To this end, an econometric analysis was conducted using Germany's Community Innovation Survey data from the 2017 and 2019 waves. The analysis of the results confirms a strong relationship between reverse logistics adoption and digitalization/collaboration increase. Furthermore, the study confirms a positive relationship between sustainability practices and digitalization/collaboration, confirming the proposed hypotheses. Therefore, the results highlight additional benefits offered by investments in sustainability practices. Furthermore, the study's findings advance the KBV theory by confirming the view that the knowledge created during the adoption of one activity is useful in performing different activities and can significantly shorten the learning curve for future activities. The findings have several implications for theory, practice and policymaking discussed below.
7.1 Theoretical implications
Previous studies have focused on the relationship between digitalization and reverse logistics and digitalization and collaboration. However, the reverse relation among these two pairs has never been explored. In particular, studies have not reported the knowledge-generating capabilities of reverse logistics and its potential to facilitate the process of digitalization and collaboration. This study is the first of its nature that explores this relationship. This is important as, unlike the former flow of actions, the adoption of reverse logistics is often involuntary and is adopted to comply with the law to achieve SDG 2030 goals. The outcome of this study confirms that adopting reverse logistics has significant power in explaining the increased digitalization and collaboration in German firms. This was confirmed by developing two hypotheses that focused on the impact of reverse logistics adoption on firm digitalization and collaboration levels. This experimental setting contributed to the growing literature on digitalization, collaboration and reverse logistics (sustainability). As a result, this study contributes to the literature to better understand these concepts and explain how they are connected. Respectively, the findings contribute to management literature. The study also contributes to the debate on the importance of KBV and provides empirical evidence to support the theory. A recent literature survey by Pereira and Bamel (2021) emphasized the need for further studies to demonstrate the usability and power of KBV. The authors argued that KBV could explain the performance variance among firms. Furthermore, they highlighted that knowledge generating firms are better off in the long run and can easily transform their operations to respond to future technologies. The research results confirm these views of Pereira and Bamel (2021).
7.2 Managerial implications
Higher levels of collaboration and digitalization have been reported to bring a significant competitive advantage as they make the firm's value chain fast, innovative, responsive and cost effective. As a result, the firm becomes competitive and well-positioned to take advantage of future opportunities. From the managerial perspective, identifying a key enabler to increase firm collaboration and digitalization levels is important as firms are constantly searching for ways to improve business in the current disruptive environment. For example, when faced with the dilemma of investing in reverse logistics or digitalization/collaboration, managers can choose reverse logistics to respond to stakeholder demand (government, distributors, customers). This reverse logistics adoption will encourage firms to increase their digitalization and collaboration levels while enjoying the benefits of reverse logistics adoption. That includes customer loyalty, employee satisfaction, increased firm reputation and higher profits. Furthermore, the knowledge generated by reverse logistics adoption can be essential to achieving firms' digitalization and collaboration goals. This was demonstrated by Schlüter et al. (2021) in their pilot study of a manufacturing firm where machine learning triggered by reverse logistics (adopted to support reverse logistics) significantly improved the reverse logistics performance. Therefore, adopting reverse logistics can be an agent of change toward more digitalized operations. Wilson et al. (2022) reported several examples where firms already performing reverse logistics adopted AI technologies to improve their reverse logistics process. Similarly, Olorunniwo and Li (2010) reported that it is vital for a firm to collaborate and share information with its partners to manage reverse logistics operations successfully. Hence, reverse logistics strongly incentivizes information sharing and collaboration with other organizations. As a result, firms are more prepared to collaborate with their partners and competitors. SIGRAUTO in Spain can be cited as an example of different bodies and organizations collaborating to improve their reverse logistics operation. Where a single entity (SIGRAUTO) coordinates all elements of end-of-life returned auto parts from different automotive manufacturers in Spain. Hence, increasing collaboration and transparency among partners to enhance their reverse logistics operations.
7.3 Policymakers implication
Reverse logistics adoption promotes resource conservation, recycling and material reuse at the end-of-life stage. Europe in general and Germany, in particular, are working toward achieving a maximum of 10% of municipal waste in the landfill by 2035, which means a technical zero-waste. Numerous governmental regulations such as China's “Circular Economy” directive or European WEEE, the two EU Circular Economy Action Plans (2015 and 2020) push firms toward adopting reverse logistics, together with the impulse coming from the Next GenEU post-pandemic recovery program for a cleaner, circular and digital Europe. Policy directives are among the most important drivers in the western world for implementing reverse logistics. However, the adoption of reverse logistics is slow in countries where there are fewer regulations to bind firms to reduce their waste. Hence, strong regulations are essential for the speedy and early adoption of reverse logistics. This study provides important information to policymakers by demonstrating the usefulness and capability of reverse logistics in enabling firms to improve firm productivity and manage future changes. This information is vital for policymakers to persuade firms to implement reverse logistics earlier in their system. Though the study results come from the German industries, policy implications can be implemented in other European countries as they all have similar work ethics and are moving towards achieving 2030 SDG goals, particularly targets 12.1, 12.2, 12.3, 12.5 and 11.6.
7.4 Limitations
This study is not without limitations, which warrant future studies. Firstly, the article uses data from only German firms. Germany is at the forefront of environmental and reverse logistics regulations. Hence, some contextual results may not apply to other countries. Secondly, this study did not differentiate between the types of digitalization and collaboration activities. The study considered all types of activities related to digitalization and collaboration to be equal. This is not often the case, and some activities are more intense than others in practice. This may have undermined the importance and value of some activities performed by the firm. Future studies should consider the relative importance of these activities. Thirdly, the study only reported on a simple increase in digitalization and collaboration levels and did not go into details about the breadth of this increase. Future studies may consider the actual amount of increase in digitalization and collaboration levels. Lastly, the data was collected in a pre-covid era, and industry and society have changed drastically in the last three years. The adoption of digital technologies and collaboration has increased initially, but its long-term impact is yet to be determined. Further empirical and longitudinal studies are needed to answer these questions.
Figures
Description of variables used in the study
Variables | Type | Description | Reference year |
---|---|---|---|
newemployee_knowl | Ordinal factor variable | Did the firm hire new employees who bring in know-how from other firms | 2017 |
new_tech_acq | Binary Variable | Did the firm purchase new machines that are based on totally new technologies | 2017 |
cost_employ_train17 | Ordinal factor variable | How much did the firm spend on further education and training of current employees in 2015 and 2016 | 2017 |
graduate_employee17 | Ordinal factor variable | Share of employees in percentage holding a university degree in 2015 and 2016 | 2017 |
Sector | Ordinal factor variable | Classification of participating firms in 21 economic sectors | 2019 |
export_perc | Ordinal factor variable | Percentage of revenue coming from exports in 2016 | 2016–2018 |
public_funding | Binary Variable | Did the firm receive public funding between 2014 and 2016 | 2016–2018 |
firm_size | Ordinal factor variable | Firm size >50 50–249 ≤250 | 2019 |
Sales | Sales volume in millions | 2018 | |
AdoptedRL17 | Binary Variable | If firms adopted reverse logistics between 2014 and 2016 | 2014–2016 |
DigitalizationCount | Count variable | Generated by merging multiple variables to report on all digitalization activities performed by the firm (see: Section 4) | 2016–2018 |
CollaborationCount | Count variable | Generated by merging multiple variables to report on all collaboration activities performed by the firm (see: Section 4) | 2016–2018 |
Source(s): Table by authors
Summary of descriptive statistics and correlation matrix
Variable | Obs | Mean | Std. Dev | Min | Max | newemployee_knowl | new_tech_acq | cost_employ_train17 | graduate_employee17 | Sector | export_perc | public_funding | firm_size | Sales |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
newemployee_knowl | 1,961 | 0.2193 | 0.4139 | 0 | 1 | 1 | ||||||||
new_tech_acq | 1,830 | 0.1607 | 0.3673 | 0 | 1 | 0.19 | 1 | |||||||
cost_employ_train17 | 1,642 | 0.0082 | 0.0148 | 0 | 0.12 | 0.093 | 0.023 | 1 | ||||||
graduate_employee17 | 2,060 | 3.3966 | 2.6681 | 0 | 8 | 0.128 | 0.033 | 0.166 | 1 | |||||
Sector | 2,161 | 11.6622 | 5.9670 | 1 | 21 | 0.015 | −0.046 | 0.124 | 0.268 | 1 | ||||
export_perc | 1,916 | 0.1296 | 0.2337 | 0 | 0.85 | 0.162 | 0.131 | −0.0503 | 0.109 | −0.237 | 1 | |||
public_funding | 2,161 | 0.2189 | 0.4136 | 0 | 1 | 0.147 | 0.210 | 0.0366 | 0.105 | −0.096 | 0.201 | 1 | ||
firm_size | 1,889 | 1.4325 | 0.6451 | 1 | 3 | 0.249 | 0.174 | −0.0571 | −0.068 | −0.085 | 0.24 | 0.104 | 1 | |
Sales | 1,966 | 20.7927 | 73.8848 | 0 | 1373.45 | 0.177 | 0.061 | −0.0178 | 0.02 | −0.095 | 0.149 | 0.020 | 0.519 | 1 |
AdoptedRL17 | 4,491 | 0.0448 | 0.2068 | 0 | 1 | |||||||||
DigitalizationCount | 4,491 | 0.3295 | 0.7625 | 0 | 5 | |||||||||
CollaborationCount | 4,491 | 0.4438 | 0.9868 | 0 | 5 |
Source(s): Table by authors
The results of the regression for the digitalization level
Model 1: Base model | Model 2: H1 digitalization | |||||
---|---|---|---|---|---|---|
Coef | Std. Err | P > z | Coef | Std. Err | P > z | |
AdoptedRL17 | 0.4217 | 0.1322 | 0.001 | |||
newemployee_knowl | 0.5169 | 0.0769 | 0.000 | 0.5203 | 0.0761 | 0.000 |
new_tech_acq | 0.4612 | 0.0816 | 0.000 | 0.4552 | 0.0810 | 0.000 |
cost_employ_train17 | 4.3537 | 2.0854 | 0.037 | 3.9750 | 2.0710 | 0.055 |
graduate_employee17 | ||||||
0 ≤ × < 5 | 0.4871 | 0.1721 | 0.005 | 0.4894 | 0.1712 | 0.004 |
5 ≤ × < 10 | 0.3767 | 0.1645 | 0.022 | 0.3617 | 0.1638 | 0.027 |
10 ≤ × < 15 | 0.4359 | 0.1671 | 0.009 | 0.4262 | 0.1665 | 0.010 |
15 ≤ × < 20 | 0.4810 | 0.1835 | 0.009 | 0.4446 | 0.1835 | 0.015 |
20 ≤ × < 30 | 0.6474 | 0.1645 | 0.000 | 0.6615 | 0.1637 | 0.000 |
30 ≤ × < 50 | 0.4889 | 0.1676 | 0.004 | 0.4639 | 0.1673 | 0.006 |
50 ≤ × < 75 | 0.6556 | 0.1724 | 0.000 | 0.6490 | 0.1717 | 0.000 |
75 ≤ ×<=100 | 0.6898 | 0.1887 | 0.000 | 0.6764 | 0.1882 | 0.000 |
sector | ||||||
Food/Tobacco | 0.0050 | 0.2958 | 0.987 | −0.0404 | 0.2947 | 0.891 |
Textiles | 0.4666 | 0.2701 | 0.084 | 0.4673 | 0.2681 | 0.081 |
Wood/Paper | 0.0648 | 0.3312 | 0.845 | 0.0788 | 0.3293 | 0.811 |
Chemical | −0.0585 | 0.2856 | 0.838 | −0.0600 | 0.2837 | 0.832 |
Plastics | 0.4129 | 0.2814 | 0.142 | 0.3451 | 0.2806 | 0.219 |
Glass/Ceramics | 0.2474 | 0.3208 | 0.441 | 0.1886 | 0.3206 | 0.556 |
Metals | 0.2126 | 0.2462 | 0.388 | 0.2119 | 0.2446 | 0.386 |
Electrical equipment | 0.4905 | 0.2318 | 0.034 | 0.4607 | 0.2303 | 0.045 |
Machinery | 0.3584 | 0.2664 | 0.179 | 0.3588 | 0.2641 | 0.174 |
Retail/Automobile | 0.4406 | 0.2886 | 0.127 | 0.4288 | 0.2868 | 0.135 |
Furniture/Toys/Medical tech. | 0.0571 | 0.2685 | 0.831 | 0.0545 | 0.2666 | 0.838 |
Energy/Water | 0.0293 | 0.2603 | 0.910 | 0.0538 | 0.2591 | 0.835 |
Wholesale | 0.5950 | 0.2571 | 0.021 | 0.5397 | 0.2562 | 0.035 |
Transport equipment/Postal. | 0.3649 | 0.2535 | 0.150 | 0.3823 | 0.2520 | 0.129 |
Media services | 0.4939 | 0.2480 | 0.046 | 0.4933 | 0.2460 | 0.045 |
IT/Telecommunications | 0.6066 | 0.2512 | 0.016 | 0.6111 | 0.2495 | 0.014 |
Banking/Insurance | 0.9538 | 0.2497 | 0.000 | 0.9605 | 0.2480 | 0.000 |
Technical services/R&D serv. | 0.5572 | 0.2397 | 0.020 | 0.5740 | 0.2385 | 0.016 |
Consulting/Advertisement | 0.6978 | 0.2443 | 0.004 | 0.7175 | 0.2429 | 0.003 |
Firm-related services | 0.6432 | 0.2595 | 0.013 | 0.6316 | 0.2577 | 0.014 |
firm_size | ||||||
50–249 employees | 0.3377 | 0.0887 | 0.000 | 0.3231 | 0.0882 | 0.0000 |
>=250 employees | 0.2750 | 0.1307 | 0.035 | 0.2694 | 0.1296 | 0.0380 |
export_perc | 0.4120 | 0.1504 | 0.006 | 0.4072 | 0.1489 | 0.0060 |
public_funding | 0.1773 | 0.0802 | 0.027 | 0.1672 | 0.0796 | 0.0360 |
sales | 0.0012 | 0.0004 | 0.005 | 0.0012 | 0.0004 | 0.0040 |
_cons | −1.7453 | 0.2363 | 0.000 | −1.7439 | 0.2349 | 0.0000 |
Source(s): Table by authors
The results of the regression analysis for the collaboration level
Model1: Base model | Model 2: H2: Collaboration | |||||
---|---|---|---|---|---|---|
Coef | Std. Err | P > z | Coef | Std. Err | P > z | |
AdoptedRL17 | 0.436 | 0.189 | 0.021 | |||
newemployee_knowl | 0.4154 | 0.0989 | 0.000 | 0.410 | 0.099 | 0.000 |
new_tech_acq | 0.5045 | 0.1084 | 0.000 | 0.514 | 0.108 | 0.000 |
cost_employ_train17 | 15.1095 | 2.6465 | 0.000 | 14.905 | 2.637 | 0.000 |
graduate_employee17 | ||||||
0 < × < 5 | 0.7133 | 0.1995 | 0.000 | 0.705 | 0.199 | 0.000 |
5 ≤ × < 10 | 0.5278 | 0.1913 | 0.006 | 0.516 | 0.191 | 0.007 |
10 ≤ × < 15 | 0.6626 | 0.1908 | 0.001 | 0.627 | 0.191 | 0.001 |
15 ≤ × < 20 | 0.8876 | 0.2124 | 0.000 | 0.863 | 0.212 | 0.000 |
20 ≤ × < 30 | 0.7498 | 0.1981 | 0.000 | 0.753 | 0.198 | 0.000 |
30 ≤ × < 50 | 0.6810 | 0.1947 | 0.000 | 0.649 | 0.195 | 0.001 |
50 ≤ × < 75 | 0.8769 | 0.2092 | 0.000 | 0.856 | 0.209 | 0.000 |
75 ≤ ×<=100 | 1.1072 | 0.2239 | 0.000 | 1.091 | 0.224 | 0.000 |
sector | 0.705 | 0.199 | 0.000 | |||
Food/Tobacco | −0.1923 | 0.3431 | 0.575 | −0.2439 | 0.3434 | 0.478 |
Textiles | 0.5158 | 0.3102 | 0.096 | 0.5300 | 0.3094 | 0.087 |
Wood/Paper | 0.1236 | 0.3585 | 0.730 | 0.1485 | 0.3579 | 0.678 |
Chemical | 0.7921 | 0.3096 | 0.011 | 0.7738 | 0.3088 | 0.012 |
Plastics | 0.4342 | 0.3311 | 0.190 | 0.4072 | 0.3313 | 0.219 |
Glass/Ceramics | 0.5411 | 0.3657 | 0.139 | 0.5063 | 0.3666 | 0.167 |
Metals | 0.4172 | 0.2789 | 0.135 | 0.4194 | 0.2784 | 0.132 |
Electrical equipment | 0.4129 | 0.2817 | 0.143 | 0.3909 | 1.3900 | 0.165 |
Machinery | 0.6945 | 0.3138 | 0.027 | 0.7127 | 0.3131 | 0.023 |
Retail/Automobile | 0.5486 | 0.3623 | 0.130 | 0.5148 | 0.3619 | 0.155 |
Furniture/Toys/Medical tech. | 0.4623 | 0.2906 | 0.112 | 0.4404 | 0.2898 | 0.129 |
Energy/Water | −0.1791 | 0.2953 | 0.544 | −0.1479 | 0.2948 | 0.616 |
Wholesale | 0.0510 | 0.3249 | 0.875 | 0.0294 | 0.3249 | 0.928 |
Transport equipment/Postal. | −0.2496 | 0.3108 | 0.422 | −0.2273 | −0.7300 | 0.464 |
Media services | 0.5580 | 0.2962 | 0.060 | 0.5722 | 1.9400 | 0.053 |
IT/Telecommunications | 0.4912 | 0.3140 | 0.118 | 0.5147 | 0.3135 | 0.101 |
Banking/Insurance | 0.4703 | 0.3237 | 0.146 | 0.4994 | 0.3231 | 0.122 |
Technical services/R&D serv. | 0.5916 | 0.2880 | 0.040 | 0.6196 | 2.1600 | 0.031 |
Consulting/Advertisement | 0.6319 | 0.2897 | 0.029 | 0.6670 | 0.2894 | 0.021 |
Firm-related services | 0.3549 | 1.130 | 0.257 | 0.3523 | 1.1300 | 0.260 |
firm_size | ||||||
50–249 employees | 0.4057 | 0.1085 | 0.000 | 0.3996 | 3.6900 | 0.000 |
>=250 employees | 0.3921 | 0.1783 | 0.028 | 0.3814 | 2.1500 | 0.032 |
export_perc | 0.7455 | 0.1958 | 0.000 | 0.7557 | 0.1953 | 0.000 |
public_funding | 0.7378 | 0.0996 | 0.000 | 0.7326 | 0.0995 | 0.000 |
sales | 0.0021 | 0.0007 | 0.006 | 0.0021 | 0.0008 | 0.005 |
_cons | −1.6438 | 0.2658 | 0.000 | −1.6531 | 0.2655 | 0.000 |
Source(s): Table by authors
Robustness check
Impact of reverse logistics adoption on digitalization | Impact of reverse logistics adoption on collaboration | ||||
---|---|---|---|---|---|
Alternate definitions for DigitalizationCount variable | Coef | p-value | Alternate definitions for CollaborationCount variable | Coef | p-value |
AI | 0.7326 | 0.087 | collab_dom + collab_inno + collab_rnd + collab_oth | 0.4192 | 0.024 |
SDB | 0.3563 | 0.049 | collab_for + collab_inno + collab_rnd + collab_oth | 0.3926 | 0.013 |
AI_lu + SDB + IP | 0.4217 | 0.001 | collab_inno + collab_rnd + collab_oth | 0.3660 | 0.017 |
AI_ir + SDB + IP | 0.4249 | 0.001 | collab_dom + collab_for + collab_inno + collab_oth | 0.4200 | 0.024 |
AI_ml + SDB + IP | 0.4217 | 0.001 | collab_dom + collab_for + collab_rnd + collab_oth | 0.3356 | 0.183 |
AI_kbs + SDB + IP | 0.4252 | 0.001 | collab_dom + collab_for + collab_rnd + collab_inno | 0.4970 | 0.016 |
AI_oth + SDB + IP | 0.4217 | 0.001 | collab_dom + collab_rnd + collab_oth | 0.3133 | 0.203 |
AI + IP | 0.4972 | 0.009 | collab_dom + collab_for + collab_inno | 0.4843 | 0.017 |
SDB + IP | 0.4001 | 0.004 | collab_for + collab_rnd + collab_inno | 0.4390 | 0.009 |
Note(s): AI = Artificial Intelligence (Language understanding + Image recognition + Machine Learning + Knowledge based systems + Others)
AI_lu = AI–Language understanding AI_ir = AI- Image recognition AI_ml = AI–Machine Learning
AI_kbs = AI–Knowledge based systems AI_oth = AI – others SDBs= Software data bases
IP = information processing collab_oth = Other type of collaboration
collab_dom = Domestic collaboration collab_for = Domestic collaboration
collab_rnd = Collaboration for R&D collab_inno = Collaboration for innovation
Source(s): Table by authors
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Acknowledgements
The authors wish to thank the data provider, the Leibniz-Zentrum für Europ¨aische Wirtschaftsforschung, which granted access to the Mannheim Innovation Panel (MIP), ZEW, Mannheim, Germany.
Corresponding author
About the authors
Faisal Rasool is currently a PhD student in the Department of Enterprise Engineering, University of Rome “Tor Vergata”, Italy. He received his master's degree in Industrial and Manufacturing Engineering from the Asian Institute of Technology, Thailand. His research interests focus on sustainable and digital supply chains and their impact on firm performance.
Marco Greco is an Associate Professor of Industrial Marketing and Corporate Governance at the University of Cassino and Southern Lazio. He published articles in reputed journals such as Technological Forecasting and Social Change, European Management Journal, Journal of Business Research, and International Journal of Project Management. His main research interests include open innovation, intellectual capital, strategic management, negotiation and project management.
Gustavo Morales-Alonso is an Associate Professor in Economics, Entrepreneurship and Innovation at Universidad Politécnica de Madrid (UPM). With a sound interest in the drivers of economic development, the sharing economy and sustainability, he has published in SCI-indexed journals such as Technological Forecasting and Social Change, Journal of Business Research and Sustainability, among others. Belongs to the Editorial Advisory Board of the European Journal of Innovation Management.
Ruth Carrasco-Gallego is an Associate Professor of Regenerative Value Ecosystems at Universidad Politécnica de Madrid (UPM), where she is the Dean for SDGs at the Industrial Engineering School. Dr Carrasco-Gallego has published extensively in her areas of expertise and has participated in or led several research projects. Currently, she leads the CircularizatE initiative, an on-campus living lab of real circular economy, aiming to demonstrate that regenerative business models are technically viable, economically profitable and socially inclusive.